 A method of manufacturing a pellicle for a lithographic apparatus, a pellicle for a lithographic app
专利摘要:
Methods of manufacturing a pellicle for a lithographic apparatus are disclosed. In one arrangement the method comprises depositing at least one graphene layer on a planar surface of a substrate. The substrate comprises a first substrate portion and a second substrate portion. The method further comprises removing the first substrate portion to form a freestanding membrane from the at least one graphene layer. The freestanding membrane is supported by the second substrate portion. 公开号:NL2017606A 申请号:NL2017606 申请日:2016-10-11 公开日:2017-05-10 发明作者:Péter Mária;Achilles Abegg Erik;Theodorus Anthonius Johannes Van Den Einden Wilhelmus;Hendrik Klootwijk Johan;Johannes Maria Giesbers Adrianus;Aleksandrovich Nasalevich Maxim;Van Zwol Pieter-Jan;Petrus Martinus Bernardus Vermeulen Johannes;Joan Van Der Zande Willem;Ferdinand Vles David;Voorthuijzen Willem-Pieter 申请人:Asml Netherlands Bv; IPC主号:
专利说明:
A METHOD OR MANUFACTURING A PEFFICFE FOR A LITHOGRAPHIC APPARATUS, A PELLICLE FOR A LITHOGRAPHIC APPARATUS, A LITHOGRAPHIC APPARATUS, A DEVICE MANUFACTURING METHOD, AN APPARATUS FOR PROCESSING A PELLICLE, AND A METHOD FOR PROCESSING A PELLICLE FIELD The present invention relates to a method of manufacturing a pellicle for a lithographic apparatus, a pellicle for a lithographic apparatus, a lithographic apparatus, and a device manufacturing method. BACKGROUND A lithographic apparatus is a machine that applies a desired pattern onto a substrate, usually onto a target portion of the substrate. A lithographic apparatus can be used, for example, in the manufacture of integrated circuits (ICs). In that instance, a patterning device, which is alternatively referred to as a mask or a reticle, may be used to generate a circuit pattern to be formed on an individual layer of the IC. This pattern can be transferred onto a target portion (e.g., including part of, one, or several dies) on a substrate (e.g., a silicon wafer). Transfer of the pattern is typically via imaging onto a layer of radiation-sensitive material (resist) provided on the substrate. In general, a single substrate will contain a network of adjacent target portions that are successively patterned. Lithography is widely recognized as one of the key steps in the manufacture of ICs and other devices and / or structures. However, as the dimensions of features made using lithography become narrower, lithography is becoming a more critical factor for enabling miniature IC or other devices and / or structures to be manufactured. A theoretical estimate of the limits of pattern printing can be given by the Rayleigh criterion for resolution as shown in equation (1): where λ is the wavelength of the radiation used, NA is the numerical aperture of the projection system used to print the pattern, ki is a process-dependent adjustment factor, also called the Rayleigh constant, and CD is the feature size (or critical dimension ) or the printed feature. It follows from equation (1) that reduction of the minimum printable size or features can be obtained in three ways: by shortening the exposure wavelength λ, by increasing the numerical aperture NA or by decreasing the value of ki. In order to shorten the exposure wavelength and, thus, reduce the minimum printable size, it has been proposed to use an extreme ultraviolet (EUV) radiation source. EUV radiation is electromagnetic radiation with a wavelength within the range of 10-20 nm, for example within the range of 13-14 nm. It has further been proposed that EUV radiation with a wavelength or less than 10 nm could be used, for example within the range of 5-10 nm such as 6.7 nm or 6.8 nm. Such radiation is termed extreme ultraviolet radiation or soft x-ray radiation. Possible sources include, for example, laser-produced plasma sources, discharge plasma sources, or sources based on synchrotron radiation provided by an electron storage ring. A lithographic apparatus includes a patterning device (e.g., a mask or a reticle). Radiation is provided through or reflected off the patterning device to form an image on a substrate. A pellicle may be provided to protect the patterning device from airborne particles and other forms of contamination. Contamination on the surface of the patterning device can cause manufacturing defects on the substrate. Pellicles may also be provided for protecting optical components other than patterning devices. Pellicles may also be used to provide a passage for lithography radiation between regions of the lithography apparatus which are sealed from each other. Pellicles may also be used as filters. The pellicle may comprise a freestanding graphene membrane. A mask assembly may include the pellicle which protects a patterning device (e.g., a mask) from particle contamination. The pellicle may be supported by a pellicle frame, forming a pellicle assembly. The pellicle may be attached to the frame, for example by gluing a pellicle border region to the frame. The frame may be permanently or releasably attached to a patterning device. The freestanding graphene membrane may be formed by floating a thin film or graphene on a liquid surface and scooping the thin film onto a silicon frame. The quality of graphene membranes formed in this way has been found to be variable and difficult to control. Furthermore, it is difficult to produce large graphene membranes reliably. [0009] It has been found that the lifetime of pellicles including freestanding graphene membranes is limited. It is desirable to improve consistency and control in methods of manufacturing pellets using freestanding graphene membranes, improve the ability to produce large pellets using freestanding graphene membranes, or improve the lifetime of pellicles. SUMMARY OF THE INVENTION [0011] According to an aspect of the invention, there is provided a method of manufacturing a pellicle for a lithographic apparatus, including: depositing at least one graphene layer on a planar surface of a substrate, including the substrate comprising a first substrate portion and a second substrate portion; and removing the first substrate portion to form a freestanding membrane from the at least one graphene layer, the freestanding membrane being supported by the second substrate portion. [0012] According to an aspect of the invention, there is provided a pellicle for a lithographic apparatus, including at least one graphene layer forming a freestanding membrane supported by a planar surface or a portion of a substrate on which the graphene layer was grown, said planar surface being located outside of the freestanding membrane when viewed in a direction perpendicular to the planar surface. According to an aspect of the invention, there is provided a pellicle including a membrane support, such as: the membrane comprises a graphene layer; and the membrane is bonded to and created on the membrane support with a thin film deposition process. According to an aspect of the invention, there is provided a device manufacturing method including: using a patterning device to impart a pattern to a beam of radiation; using a pellicle including at least one graphene layer forming a freestanding membrane to protect the patterning device; and passing an electrical current through the at least one graphene layer to heat the at least one graphene layer. [0015] According to an aspect of the invention, there is provided an apparatus for processing a pellicle, the pellicle including at least one graphene layer forming a freestanding membrane, the apparatus including: a current driving apparatus for driving an electrical current through the freestanding membrane to heat the least one graphene layer. [0016] According to an aspect of the invention, there is provided a method of processing a pellicle, the pellicle including at least one graphene layer forming a freestanding membrane, the method including driving an electrical current through the freestanding membrane to heat the freestanding membrane . [0017] According to an aspect of the invention, there is provided a method of processing a pellicle, the pellicle including at least one graphene layer forming a freestanding membrane, the method including using electrochemical deposition to apply carbon to the least one graphene layer . [0018] According to an aspect of the invention, there is provided a method of manufacturing a pellicle for a lithographic apparatus, including: transferring at least one graphene layer from a surface or a liquid to a frame including an opening, forming forming a freestanding membrane from the least one graphene layer, the freestanding membrane tension the opening and being supported by the frame, being a portion of the frame in contact with the least one graphene layer is hydrophobic. [0019] According to an aspect of the invention, there is provided a method of manufacturing a pellicle for a lithographic apparatus, including: transferring at least one graphene layer from a surface or a liquid to a frame including an opening, forming forming a freestanding membrane from the at least one graphene layer, the freestanding membrane tension the opening and being supported by the frame, the liquid has a temperature in the range of 25-80 degrees Celsius during the transfer of the least one graphene layer to the frame . [0020] According to an aspect of the invention, there is provided a method of manufacturing a pellicle for a lithographic apparatus, including: transferring at least one graphene layer from a surface or a liquid to a frame including an opening, forming forming a freestanding membrane from the at least one graphene layer, the freestanding membrane tension the opening and being supported by the frame, the liquid comprising water, an alcohol, and a further solvent that is not an alcohol. According to an aspect of the invention, there is provided a pellicle including a freestanding membrane, the freestanding membrane including at least one layer or a two-dimensional material other than graphene. [0022] According to an aspect of the invention, there are provided a pellicle assembly and a mask assembly including a freestanding membrane from the least one graphene layer or another layer of a two-dimensional material. [0023] According to an aspect of the invention, there is provided a method of manufacturing a pellicle for a lithographic apparatus, including: depositing at least one layer of a two-dimensional material on a planar surface of a substrate, according to the substrate comprises a first substrate portion and a second substrate portion; and removing the first substrate portion to form a freestanding membrane from the at least one layer of a two-dimensional material, the freestanding membrane being supported by the second substrate portion. LETTER DESCRIPTION OF THE DRAWINGS Embodiments of the invention will now be described, by way of example only, with reference to the accompanying schematic drawings in which corresponding reference symbols indicate corresponding parts, and in which: [0025] Figure 1 depicts a lithographic apparatus according to an embodiment of the invention; Figure 2 is a more detailed view of the lithographic apparatus; Figure 3 is a schematic side sectional view of a substrate and at least one graphene layer prior to processing to form a pellicle; Figure 4 depicts the arrangement of Figure 3 after processing to form a pellicle; Figure 5 is a schematic top view of the pellicle or Figure 4; Figure 6 is a schematic side sectional view of a silicon base layer after processing to form a silicon oxide layer; Figure 7 is a schematic side sectional view of the arrangement or Figure 6 after further processing to form at least one graphene layer on a first graphene support layer; Figure 8 is a schematic side sectional view of the arrangement or Figure 7 after further processing to form a second graphene support layer; Figure 9 is a schematic side sectional view of the arrangement or Figure 8 after further processing to form a further layer on the second graphene support layer and remove a portion of the silicon oxide layer on a lower surface; Figure 10 is a schematic side sectional view of the arrangement or Figure 9 after further processing to form an encapsulation layer or sacrificial layer; Figure 11 is a schematic side sectional view of the arrangement or Figure 7 after further processing to form a further layer on the least one graphene layer and remove a portion of the silicon oxide layer on a lower surface; Figure 12 is a schematic side sectional view of the arrangement or Figure 11 after further processing to form an encapsulation layer or sacrificial layer; Figure 13 is a schematic side sectional view of the arrangement or Figure 10 after photolithographic formation or windows in the encapsulation layer or sacrificial layer and a further encapsulation layer or sacrificial layer; Figure 14 is a schematic side sectional view of the arrangement or Figure 13 after further processing to a portion of the base layer; Figure 15 is a schematic side sectional view of the arrangement or Figure 14 after further processing to remove the further encapsulation layer or sacrificial layer; Figure 16 is a schematic side sectional view of the arrangement or Figure 15 after further processing to remove a portion of the further layer; Figure 17 is a schematic side sectional view of the arrangement or Figure 16 after further processing to remove portions of the first and second graphene support layers and form a freestanding membrane; Figure 18 is a schematic side sectional view of the arrangement or Figure 10 after further processing according to an alternative edition in which a further encapsulation layer or sacrificial layer is not used, the further processing including photolithographic formation or windows in the encapsulation layer or sacrificial layer; Figure 19 is a schematic side sectional view of the arrangement or Figure 18 after further processing to remove a portion of the further layer; Figure 20 is a schematic side sectional view of the arrangement or Figure 19 after further processing to remove portions of the first and second graphene support layers and form a freestanding membrane; Figure 21 is a schematic side sectional view of a silicon base layer after processing to form a silicon oxide layer, for use in an alternative embodiment; Figure 22 is a schematic side sectional view of the arrangement or Figure 21 after processing to remove a portion of the silicon oxide layer on a lower surface and apply an encapsulation layer or sacrificial layer; Figure 23 is a schematic side sectional view of the arrangement or Figure 22 after photolithographic processing to form windows in the encapsulation layer or sacrificial layer; Figure 24 is a schematic side sectional view of the arrangement or Figure 23 after processing to apply a graphene support layer; Figure 25 is a schematic side sectional view of the arrangement or Figure 24 after processing to deposit at least one graphene layer; Figure 26 is a schematic side sectional view of the arrangement or Figure 25 after processing to deposit a protection layer; Figure 27 is a schematic side sectional view of the arrangement or Figure 26 after processing to remove a portion of the base layer, silicon oxide and graphene support layer beneath the least one graphene layer; Figure 28 is a schematic side sectional view of the arrangement or Figure 27 after processing to remove the protection layer and form a freestanding membrane; Figure 29 is a schematic side sectional view of a stack including a base layer, graphene support layer and at least one graphene layer, for use in an alternative embodiment; Figure 30 is a schematic side sectional view of the arrangement or Figure 29 after photolithographic processing to form mask layers on upper and lower surfaces of the stack; Figure 31 is a schematic side sectional view of the arrangement or Figure 30 after processing to partially etch a region of the base layer that is not protected by a mask layer; Figure 32 is a schematic side sectional view of the arrangement or Figure 31 after processing to remove a first portion or a graphene support layer; Figure 33 is a schematic side sectional view of the arrangement or Figure 32 after processing to deposit a control layer; Figure 34 is a schematic side sectional view of the arrangement or Figure 33 after processing to complete etching or the base layer to penetrate through to the graphene support layer; Figure 35 is a schematic side sectional view of the arrangement or Figure 34 after processing to remove a second portion of the graphene support layer; Figure 36 is a schematic side sectional view of the arrangement or Figure 35 after processing to lift off layers above the previous location or the second portion of the graphene support layer, forming a freestanding membrane; Figure 37 is a schematic side sectional view of pellicle having a freestanding membrane including at least one graphene layer, an additional layer on an upper surface and an additional layer on a lower surface; Figure 38 is a schematic side sectional view of a portion of an at least one graphene layer with a layer of catalytically active metal on a top surface and a bottom surface of the least one graphene layer; Figure 39 is a schematic side sectional view or a portion or at least one graphene layer with an internal layer or catalytically active metal; Figure 40 is a schematic side sectional view or a portion or at least one graphene layer with nanoparticles or dopant atoms or catalytically active metal; Figure 41 depicts an apparatus for processing a pellicle; Figure 42 depicts applying tensile forces to at least one graphene layer formed on a substrate by deforming the substrate; Figure 43 depicts applying compressive forces to a least one graphene layer formed on a substrate by deforming the substrate; Figure 44 is a schematic side sectional view of a portion of an at least one graphene layer on a top surface and on a bottom surface of the at least one graphene layer; Figure 45 is a schematic side sectional view of a portion or at least one graphene layer with a capping layer on a top surface and on a bottom surface or the at least one graphene layer, and an adhesion layer in between each of the capping layers and the least one graphene layer; Figure 46 depicts an electrochemical cell for processing a pellicle; Figures 47-52 depicts an example process flow in which a stack is provided with a graphene support layer after formation or an encapsulation layer or sacrificial layer; Figures 53-56 depict an alternative example process flow in which a stack is provided with a graphene support layer after formation or an encapsulation layer or sacrificial layer; Figures 57-60 depict a further alternative example process flow in which a stack is provided with a graphene support layer after formation or an encapsulation layer or sacrificial layer; Figures 61-67 depict an example process flow continuing from the process flow shown in Figures 47-52 and leading to formation of a freestanding membrane; Figure 68 depicts a graphene support layer including a Mo layer and a silicized Mo layer; Figure 69 depicts vapor etching or a graphene support layer; Figure 70 depicts transfer of at least one graphene layer from the surface of a liquid onto a frame; Figure 71 depicts a freestanding membrane including an alternating sequence or at least one graphene layer alternating with at least one two-dimensional material other than graphene; Figure 72 depicts a freestanding membrane having capping layers each including at least one layer or a two-dimensional material other than graphene; and [0080] Figure 73 depicts a freestanding membrane in which at least one layer of a two-dimensional material other than graphene is sandwiched between at least one layer of graphene on one side and at least one layer of graphene on the other side. The features and advantages of the present invention will become more apparent from the detailed description set forth below when tasks in conjunction with the drawings, in which like reference characters identify corresponding elements throughout. In the drawings, like reference numbers generally indicate identical, functionally similar, and / or structurally similar elements. DETAILED DESCRIPTION Figure 1 schematically depicts a lithographic apparatus 100 including a source collector module SO according to one embodiment of the invention. The apparatus 100 comprises: an illumination system (or illuminator) IL configured to condition a radiation beam B (e.g., EUV radiation). a support structure (e.g., a mask table) MT constructed to support a patterning device (e.g., a mask or a reticle) MA and connected to a first positioner PM configured to accurately position the patterning device; a substrate table (e.g., a wafer table) WT constructed to hold a substrate (e.g., a resist-coated wafer) W and connected to a second positioner PW configured to accurately position the substrate; and a projection system (e.g., a reflective projection system) PS configured to project a pattern imparted to the radiation beam B by patterning device MA onto a target portion C (e.g., including one or more dies) of the substrate W. The illumination system IL may include various types of optical components, such as refractive, reflective, magnetic, electromagnetic, electrostatic or other types of optical components, or any combination thereof, for directing, shaping, or controlling radiation. [0084] The support structure MT holds the patterning device MA in a manner that depends on the orientation of the patterning device, the design of the lithographic apparatus, and other conditions, such as for example whether or not the patterning device is hero in a vacuum environment. The support structure MT can use mechanical, vacuum, electrostatic or other clamping techniques to hold the patterning device MA. The support structure MT may be a frame or a table, for example, which may be fixed or movable as required. The support structure MT may ensure that the patterning device is at a desired position, for example with respect to the projection system PS. The term "patterning device" should be broadly interpreted as referring to any device that can be used to impart a radiation beam B with a pattern in its cross-section such as to create a pattern in a target portion C of the substrate W. The pattern imparted to the radiation beam B may correspond to a particular functional layer in a device being created in the target portion C, such as an integrated circuit. The patterning device MA may be transmissive or reflective. Examples of patterning devices include masks, programmable mirror arrays, and programmable liquid-crystal display (LCD) panels. Masks are well known in lithography, and include mask types such as binary, alternating phase shift, and attenuated phase shift, as well as various hybrid mask types. An example of a programmable mirror array employs a matrix arrangement of small mirrors, each of which can be individually tilted so as to reflect an incoming radiation beam in different directions. The tilted mirrors impart a pattern in a radiation beam, which is reflected by the mirror matrix. The projection system PS, like the illumination system IL, may include various types of optical components, such as refractive, reflective, magnetic, electromagnetic, electrostatic or other types of optical components, or any combination thereof, as appropriate for the exposure radiation being used, or for other factors such as the use of a vacuum. It may be desired to use a vacuum for EUV radiation since other gases may absorb too much radiation. A vacuum environment may therefore be provided for the whole beam path with the aid of a vacuum wall and vacuum pumps. As depicted here, the lithographic apparatus is 100 or a reflective type (e.g., employing a reflective mask). The lithographic apparatus 100 may be of a type having two (dual stage) or more substrate tables WT (and / or two or more support structures MT). In such a "multiple stage" lithographic apparatus the additional substrate tables WT (and / or the additional support structures MT) may be used in parallel, or preparatory steps may be carried out on one or more substrate tables WT (and / or one or more support structures MT) while one or more other substrate tables WT (and / or one or more other support structures MT) are being used for exposure. Referring to Figure 1, the illumination system IL receives an extreme ultraviolet radiation beam from the source collector module SO. Methods to produce EUV light include, but are not necessarily limited to, converting a material into a plasma state that has at least one element, e.g., xenon, lithium or tin, with one or more emission lines in the EUV range. In one such method, often produced laser plasma (“LPP”) the required plasma can be produced by irradiating a fuel, such as a droplet, stream or cluster or material with the required line-emitting element, with a laser beam. The source collector module SO may be part of an EUV radiation system including a laser, not shown in Figure 1, for providing the laser beam exciting the fuel. The resulting plasma emits output radiation, e.g., EUV radiation, which is collected using a radiation collector, disposed in the source collector module. The laser and the source collector module SO may be separate entities, for example when a CO2 laser is used to provide the laser beam for fuel excitation. In such cases, the laser is not considered to be part of the lithographic apparatus 100 and the radiation beam B is passed from the laser to the source collector module SO with the aid of a beam delivery system including, for example, suitable directing mirrors and / or a beam expander. In other cases the source may be an integral part of the source collector module SO, for example when the source is a discharge produced plasma EUV generator, often termed as a DPP source. The illumination system IL may include an adjuster for adjusting the angular intensity distribution of the radiation beam. Generally, at least the outer and / or inner radial extent (commonly referred to as σ-outer and σ-inner, respectively) or the intensity distribution in a pupil plane of the illumination system IL can be adjusted. In addition, the illumination system IL may include various other components, such as faceted field and pupil mirror devices. The illumination system IL may be used to condition the radiation beam B, to have a desired uniformity and intensity distribution in its cross-section. The radiation beam B is incident on the patterning device (e.g., mask) MA, which is hero on the support structure (e.g., mask table) MT, and is patterned by the patterning device MA. MA, the radiation beam B passing through the projection system PS, which radiation beam B onto a target portion C or the substrate W. With the aid of the second positioner PW and position sensor PS2 (harrow, an interferometric device, linear encoder or capacitive sensor), the substrate table WT can be moved accurately, harrow, so as to position different target portions C in the path of the radiation beam B. Similarly, the first positioner PM and another position sensor PS1 can be used to accurately position the patterning device (eg, mask) MA with respect to the path of the radiation beam B. The patterning device (eg, mask) MA and the substrate W may be aligned using mask alignment marks M1, M2 and substrate alignment marks P1, P2. A controller 500 controls the overall operations of the lithographic apparatus 100 and in particular performs an operation process described further below. Controller 500 can be embodied as a suitably-programmed general purpose computer including a central processing unit, volatile and non-volatile storage means, one or more input and output devices such as a keyboard and screen, one or more network connections and one or more interfaces to the various parts of the lithographic apparatus 100. It will be appreciated that a one-to-one relationship between controlling computer and lithographic apparatus 100 is not necessary. In an embodiment of the invention one computer can control multiple lithographic apparatus 100. In an embodiment of the invention, multiple networked computers can be used to control one lithographic apparatus 100. The controller 500 may also be configured to control one or more associated process devices. and substrate handling devices in a lithocell or cluster of which the lithographic apparatus 100 forms a part. The controller 500 can also be configured to be subordinate to a supervisory control system or a lithocell or cluster and / or an overall control system or a fab. Figure 2 shows the lithographic apparatus 100 in more detail, including the source collector module SO, the illumination system IL, and the projection system PS. An EUV radiation emitting plasma 210 may be formed by a plasma source. EUV radiation may be produced by a gas or vapor, for example Xe gas, Li vapor or Sn vapor in which the radiation emitting plasma 210 has been created to emit radiation in the EUV range of the electromagnetic spectrum. In an embodiment, a plasma or excited tin (Sn) is provided to produce EUV radiation. The radiation emitted by the radiation emitting plasma 210 has passed from a source chamber 211 into a collector chamber 212. The collector chamber 212 may include a radiation collector CO. Radiation that traverses the radiation collector CO can be focused in a virtual source point IF. The virtual source point IF is commonly referred to as the intermediate focus, and the source collector module SO is arranged such that the virtual source point IF is located at or near an opening 221 in the enclosing structure 220. The virtual source point IF is an image of the radiation emitting plasma 210. Subsequently the radiation traverses the illumination system IL, which may include a facetted field mirror device 22 and a facetted pupil mirror device 24 arranged to provide a desired angular distribution of the unpatterned beam 21, the patterning device MA, as well as a desired uniformity of radiation intensity at the patterning device MA. Upon reflection of the unpatted beam 21 at the patterning device MA, hero by the support structure MT, a patterned beam 26 is formed and the patterned beam 26 is imaged by the projection system PS via reflective elements 28, 30 onto a substrate W held by the substrate table WT. More elements than shown may generally be present in the illumination system IL and the projection system PS. Further, there may be more mirrors present than those shown in the Figures, for example there may be 1-6 additional reflective elements present in the projection system PS than shown in Figure 2. Alternatively, the source collector module SO may be part of an LPP radiation system. As depicted in Figure 1, in an embodiment of the lithographic apparatus 100 comprising an illumination system IL and a projection system PS. The illumination system IL is configured to emit a radiation beam B. The projection system PS is separated from the substrate table WT by an intervening space. The projection system PS is configured to project a pattern imparted to the radiation beam B. onto the substrate W. The pattern is for EUV radiation or the radiation beam B. The space intervening between the projection system PS and the substrate table WT can be at least partially evacuated. The intervening space may be limited at the location of the projection system PS by a solid surface from which the employed radiation is directed toward the substrate table WT. In an embodiment the lithographic apparatus 100 comprises a dynamic gas lock. The dynamic gas lock comprises a pellicle 80. In an embodiment the dynamic gas lock comprises a hollow part covered by a pellicle 80 located in the intervening space. The hollow part is situated around the path of radiation. In an embodiment the lithographic apparatus 100 comprises a gas blower configured to flush the inside of the hollow part with a flow of gas. The radiation travels through the pellicle 80 before impinging on the substrate W. In an embodiment the lithographic apparatus 100 comprises a pellicle 80. As explained above, in an embodiment the pellicle 80 is for a dynamic gas lock. In this case the pellicle 80 functions as a filter for filtering DUV radiation. Additionally or alternatively, in an embodiment of the pellicle 80 protects an optical element, for example a patterning device MA. The pellicle 80 of the present invention can be used for a dynamic gas lock or for protecting an optical element or for another purpose. In an embodiment the pellicle 80 is configured to seal off the patterning device MA to protect the patterning device MA from airborne particles and other forms of contamination. Contamination on the surface of the patterning device MA can cause manufacturing defects on the substrate W. For example, in an embodiment of the pellicle 80 is configured to reduce the likelihood that particles might migrate into a stepping field of the patterning device MA in the lithographic apparatus 100. If the patterning device MA is left unprotected, the contamination may require the patterning device MA to be cleaned or discarded. Cleaning the patterning device MA interrupts valuable manufacturing time and discarding the patterning device MA is costly. Replacing the patterning device MA also interrupts valuable manufacturing time. The above-described below references to upper / lower, up / down, top / bottom, above / below, etc. are made relative to the orientations on the page of the side sectional views. A front side of the pellicle faces downwards and a back side of the pellicle faces downwards. The substrate 6 is therefore always located on a back side of the least one graphene layer 2 within this convention. Figures 3-5 schematically depict stages in a method of manufacture of a pellicle 80 according to an embodiment. The method comprises depositing at least one graphene layer 2 on a planar surface 4 or a substrate 6. The substrate 6 may comprise a single layer or multiple layers of material. In an embodiment, the substrate 6 comprises a base layer 8 and one or more further layers 10 formed on top of the base layer 8. In an embodiment, the base layer 8 comprises a silicon wafer. In other variants, the base layer 8 may be formed from other materials. In an embodiment, the substrate 6 comprises a first substrate portion 11 and a second substrate portion 12. The method of manufacture of the pellicle 80 comprises removing the first substrate portion 11 to form a freestanding membrane 14 from the least one graphene layer 2. The freestanding membrane 14 is supported by the second substrate portion 12. In an embodiment the freestanding membrane 14 is at least 80% transparent to EUV radiation used in an EUV lithographic apparatus such as 13.5 nm or 6.7 nm (eg 80% transparent to radiation having a wavelength or 13.5 nm or 6.7 nm), optionally at least 90% (eg 90% transparent to radiation having a wavelength or 13.5 nm or 6.7 nm), optionally at least 95% (eg 95% transparent to radiation having a wavelength or 13.5 nm or 6.7 nm). The freestanding membrane 14 is formed exclusively from a portion or the least one graphene layer 2, optionally with a coating, described below with reference to Figures 3-36. Each of the various, can be adapted to the freestanding membrane 14 comprises a portion of the least one graphene layer 2 in combination with an additional layer on an upper surface of the graphene layer 2 or an additional layer on a lower surface of the graphene layer 2. An example of such an embodiment is shown schematically in Figure 37, where an additional layer 3 is formed on an upper surface of the at least one graphene layer 2 and an additional layer 5 is formed on a lower surface of the least one graphene layer 2. Such additional layers may be formed for example by stopping an etching process configured to remove a layer adjacent to the least one graphene layer 2 before the layer has been completed removed. In the particular example shown in Figure 37, the additional layers 3 and 5 are formed by stopping the etching away or graphene support layers 36 and 38 before the at least one graphene layer 2 has been reached, forming additional layers 3 and 5 from thin layers of the material forming the graphene support layers 36 and 38. Further details about the graphene support layers 36 and 38 are given below. In other variants, the additional layers 3 and 5 may have a different composition. The additional layers 3 and 5 may provide additional mechanical support for the freestanding membrane 14. The additional layers 3 and 5 are configured to be thin enough that the freestanding membrane 14 remains adequately transparent to radiation that is transmitted through the freestanding membrane 14 ( eg EUV radiation, as described above). It has been understood in the field of pellicles that a freestanding membrane is distinguished from a mesh-supported membrane. A freestanding membrane spans freely over a continuous area without any supports positioned within the area (when viewed perpendicular to the freestanding membrane). A mesh-supported membrane, in contrast, is supported by a mesh positioned in the area over which the membrane spans (when viewed perpendicular to the membrane). In an embodiment, the least one graphene layer 2 consists of a single layer or graphene, a bilayer or graphene or more than two monolayers or graphene (eg between 3 and 50 layers of graphene, optionally between 10 and 50 layers of graphene). A single layer, or a small number of layers, or graphene provides good transparency, particularly where folds and other imperfections are minimized. Higher numbers or graphene layers are more robust. It has been found that 10 layers of graphene and above provides satisfactory rigidity in a range or expon. It has also been found that less than 50 layers of graphene provides satisfactory transparency in a range or different (e.g. 90% transmission or EUV radiation). Graphene is understood to mean a one atom thick layer or graphite: a layer or sp2 bonded carbon atoms in a hexagonal or honeycomb lattice. Multiple layers of graphene are sometimes referred to as graphite, especially where the number of layers is larger than about 10 layers. As the number of sheets or graphene increases the electronic structure becomes increasingly similar, and eventually indistributable from, bulk graphite. Multiple layers of graphene (or graphite) are also sometimes referred to as graphite nanoplatelets or graphene nanoplatelets. In an embodiment one or more of the layers in the least one graphene layer 2 may include one or more layers of graphene derivatives, such as functionalized graphene or graphene with modifications, such as oxidized graphene, graphane, graphyne, fluorinated graphene , graphene bromide, graphene chloride, graphene iodide and graphene with other functionalities attached to the graphene. Graphene and graphene derivatives have in common that they are all membranes which have carbon sp2 bonded bases. The mechanical properties of graphene derivatives may be the same or similar to the mechanical properties of graphene, although the chemical properties may be different. Graphene fluoride may provide the advantage that it has bonds which are less susceptible than graphene bonds to breaking when illuminated by EUV radiation. In an embodiment a coating is provided on the freestanding membrane 14. The coating is configured to protect the least one graphene layer 2 or the freestanding membrane 14. The coating may provide one or more of thermal protection, mechanical protection, and chemical protection. In the example shown in Figures 3-5, the freestanding membrane 14 comprises a portion of the least one graphene layer 2 delimited by a boundary line 15 (see Figure 5) marking the edge of the first substrate portion 11. The freestanding membrane 14 is thus formed from the portion of the least one graphene layer 2 that was positioned over the first substrate portion 11. The freestanding membrane 14 is thus not supported by any material positioned immediately below the freestanding membrane 14 (ie along a direction perpendicular to the planar surface 4 or the substrate 6). In an embodiment, the first substrate portion 11 is removed by selective etching of the substrate 6. In an embodiment, an encapsulation layer or sacrificial layer is coated at least on a front and side surface or a stack comprising the at least one graphene layer 2 and the substrate 6 during the removal of the first substrate portion 11. The encapsulation layer or sacrificial layer provides mechanical support to the stack during the processing to remove the first substrate portion 11, which can involve relatively long etching steps. Covering the side surface prevents unwanted ingress or etchant into the stack from the sides. The encapsulation layer or sacrificial layer may contain any suitable material that is resistant to the processing steps (e.g., etching) needed to remove the first substrate portion 11. In an embodiment the encapsulation layer or sacrificial layer comprises an organic polymer. In an embodiment the encapsulation layer or sacrificial layer comprises a poly (p-xylylene) polymer such as Parylene or ProTEK® type materials. In an embodiment the encapsulation layer or sacrificial layer comprising PMMA. In other variables the encapsulation or sacrificial material comprises an inorganic material, such as a metal layer. Examples of different encapsulation or sacrificial layers are mentioned below with reference to the detailed examples of Figures 6-36. In an embodiment, the first substrate portion 11 comprises a continuous volume of material positioned underneath a portion of the least one graphene layer 2 that will form the freestanding membrane 14. In an embodiment, the first substrate portion 11 is surrounded by the second substrate portion 12 when viewed in a direction perpendicular to the planar surface 4 or the substrate 6 (ie in a vertical direction in the page in the orientation or the side sectional views in the figures). Configuring the second substrate portion 12 in this way helps to provide reliable and spatially homogeneous support to the freestanding membrane 14. In such an embodiment, removal of the first substrate portion 11 forms a hole passing through the substrate 6 in a direction perpendicular to the planar surface 4. The hole is spanned continuously (ie with no gaps) by the freestanding membrane 14. A pellicle 80 formed in this way may be configured such that the freestanding membrane 14 spans continuously (ie with no gaps) across an optical element (eg patterning device MA) to be protected by the pellicle 80. The freestanding membrane 14 is supported by the second substrate portion 12. In an embodiment the support is provided by adhesion or a portion of the least one graphene layer 2 to the second substrate portion 12. The example shown in Figure 5 the adhesion occurs in the region outside of the boundary line 15. The freestanding membrane 14 is thus supported laterally via the portion or the least one graphene layer that is positioned over the second substrate portion 12. The freestanding membrane 14 may remain substantially planar even after the first substrate portion 11 has been removed. Alternatively, the freestanding membrane 14 may sag under its own weight. The amount of sag may be controlled by changing a tension in the freestanding membrane 14. The amount of sag that is acceptable will depend on the particular application of the pellicle 80. In addition where the pellicle 80 protects an optical element, such as the patterning device MA, it may be desirable to arrange for the sag to be small enough to avoid contact between the pellicle 80 and the optical element. For example in one embodiment the pellicle 80 is positioned about 2 + 0.5 mm from the patterning device MA and the tension in the freestanding membrane 14 is set so that a maximum sag in use will not exceed about 500 microns. In an embodiment the freestanding membrane 14 has a surface area of at least 1 mm 2, preferably at least 10 mm 2, preferably at least 100 mm 2, preferably at least 1000 mm 2, preferably at least 5000 mm 2, preferably at least 10000 mm 2 , when viewed in a perpendicular direction to the planar surface 4 of the substrate 6. The minimum size of the freestanding membrane 14 will depend on the particular application in question and may be significantly greater than this value. Where the pellicle 80 is to protect an optical component, the freestanding membrane 14 will typically be configured to be least as large as a cross-sectional area through which all radiation incident on the optical element, and / or all radiation leaving the optical element , passes. Forming the freestanding membrane 14 using the above methods provides several benefits. High quality adhesion is achieved between the second substrate portion 12 and the least one graphene layer 2 because the least one graphene layer 2 remains on the surface on which it was originally deposited. The problems of folding, entrapment or gas bubbles and tearing of the graphene, which have been observed to occur when handling graphene films floating on liquids, are avoided. Tension in the freestanding membrane 14 can be controlled accurately and reliably. Variations in tension due to unpredictable adhesion and handling variations, which have been observed to occur when handling graphene films floating on liquids, are avoided. The techniques used in the method, including the depositing of graphene and processing of the substrate to selectively remove a part of the substrate, can be scaled up to allow larger freestanding membranes to be formed reliably. Figures 6 and 7 schematically depict initial stages in a method of manufacturing the pellicle 80 according to an embodiment. In this embodiment a base layer 8 including a silicon wafer is processed to form a silicon oxide layer 34 (S1O2) on an outer surface of the silicon wafer (Figure 6). The processing may include thermal processing. In a subsequent step a graphene support layer 36 is formed on an upper surface of the silicon oxide layer 34. In an embodiment the graphene support layer 36 comprises a layer of metal or a metal in silicized form. In an embodiment, the graphene support layer 36 comprises one or more of the following: transition metals such as Mo, Ni, Ru, Pt, Cu, Ti, V, Zr, Nb, Hf, Ta, W, Cr, silicized Mo , silicized Ni, silicized Ru, silicized Pt, silicized Cu, silicized Ti, silicized V, silicized Zr, silicized Nb, silicized Hf, silicized Ta, silicized W, silicized Cr, carbide or Mo, carbide or Ni, carbide or Ru, carbide or Pt, carbide or Cu, carbide or Ti, carbide or V, carbide or Zr, carbide or Nb, carbide or Hf, carbide or Ta, carbide or W, carbide or Cr. In this context, the reference to a silicized metal is understood to mean a layer of the metal covered by a layer of the metal silicide at a surface. It has been found that the metal silicon tends to have a lower melting point than the corresponding metal, which means that the graphene can be grown in conditions in which the metal part of the graphene support layer is solid and the metal silicon part of the graphene support layer is a liquid or liquidlike. The liquid or liquid-like surface provided by the metal silicide provides a very smooth surface for the graphene layer, continuously improving the quality of the graphene layer. Use of Mo or silicized Mo may be particularly desirable because it is possible to directly synthesize high quality multilayer graphene on Mo or silicized Mo using CVD. Multilayer graphene may be more robust that single layer graphene while still providing adequate transparency to radiation. Where Mo or silicized Mo is used for a controllable and uniform thickness can be achieved by controlling the CVD process. The direct synthesis avoids the need to manually transfer multiple individual monolayers formed using other processes, for example using CVD on a graphene support layer formed from Cu. The process of transferring the individual monolayers would tend to increase defectivity relative to direct formation without any transfer. Multilayer graphene can also be formed directly on graphene support layers including Ni but the quality tends to be inferior in comparison to Mo or silicized Mo. For example a non-continuous layer including flakes may be formed. The quality of graphene when growth by CVD may be largely influenced by the catalyst surface on which it grows, mostly because the grown graphene will conformally follow the catalyst surface. The catalyst surface may provide morphological changes at the high temperature required to grow graphene. Grain boundaries of the catalyst surface may occur and graphene may grow over surface grain boundaries sporadically. Reduction of the grain boundaries may be done by optimization for larger grain sizes, by influencing the growth rate dependence on crystal orientation by forming epitaxial layers or monocrystalline layers, by the improvement of layer thickness and layer thickness uniformity or CVD grown graphene and / or by improvement or changes in catalyst surface roughness. The catalyst surface can be optimized by optimization of gran sizes, which is influenced by temperature, growth time, internal stress and roughness. Epitaxial or monocrystalline surfaces may be formed by sputtering or CVD or any other PVD technique. A better quality graph will improve imaging performance and the pellicle life time. Transition metal carbides from metals in groups IVB, VB and VIB in the Periodic Table, such as the carbides of Mo, Ni, Ru, Pt, Cu, Ti, V, Zr, Nb, Hf, Ta, W, Cr mentioned above, catalytic activity exhibit which resembles that of noble metals. These catalysts are particularly active towards dehydrogenation and aromatization of hydrocarbons and therefore provide a particularly suitable support for synthesis of graphene. In practice, when graphene is grown on a nominally bare surface of a metal from group IVB, VB or VIB, it is expected that for some metals a layer of a carbide or the metal will be formed (eg a surface layer of the metal will be partially or completely converted to the carbide) initially as part of the process of forming the least one graphene layer 2 on the graphene support layer 36. This is expected for example in the case of Mo due to the negative enthalpy of formation of Mo2C. For metals or processes where this does not occur, a separate process may be provided for forming the carbide on the metal prior to formation of the least one graphene layer 2. In either case, where it is expected that the least one graphene layer 2 will be formed on a carbide layer, the process (eg CVD) for forming the least one graphene layer 2 should be adapted to take the carbide layer into account. The carbide layer provides opportunities to pursue different strategies towards optimizing the growth of the least one graphene layer 2. For example, it is possible to control properties of the surface of the carbide to improve the formation of the least one graphene layer 2. Properties such as surface morphology, grain size and crystal orientation may be controlled for example. Account may be tasks of the growth mechanism or the least one graphene layer 2 on the carbide. The growth mechanism may involve for example growth from the bulk by either isothermal growth or segregation upon cooling or growth from the surface by chemisorption. The growth mechanism may involve epitaxial growth by direct deposition of the graphene with a desired crystal orientation. The overall thickness of the least one graphene layer 2 may be controlled based on differences in diffusion coefficients versus crystal orientation. In a variation on the above, the step of forming the silicon oxide layer is embedded and the graphene support layer 36 is formed directly on the base layer 8 (e.g. directly on a silicon wafer). Due to the relatively low solid solubility or C in Mo and the relatively high diffusion coefficient or Mo in C, the rate limiting step for growth or the least one graphene layer 2 on Mo is the low solid solubility. The low solid solubility will limit the thickness of the least one graphene layer 2 that can be efficiently grown directly on Mo. In an embodiment, the least one graphene layer 2 is grown on silicized Mo (e.g., MoSi 2). The solid-solubility of C in MoSi2 is higher than the solid-solubility of C in Mo, allowing the thickness of the least one graphene layer 2 to be increased. In an embodiment, the silicized Mo (e.g., MoSi 2) is provided in a tetragonal phase form. The tetragonal phase form provides a better epitaxial match with the least one graphene layer 2 (the lattices of MoSi2 and graphene are more similar than the lattices of Mo and graphene). Providing an improved epitaxial match will promote growth or at least one graphene layer 2 with fewer defects and grain boundaries. In an embodiment, the graphene support layer 36 comprises a layer of Mo and a layer of silicized Mo (e.g. MoSi2) grown on the layer of Mo. In an embodiment the layer of Mo has a thickness of 50-100 nm and the layer of silicized Mo (e.g. MoSi2) has a thickness of 5-50 nm. The layer of silicized Mo (e.g., MoSi 2) may be grown by sputtering (or any other suitable physical or chemical deposition technique). In an embodiment an annealing step is performed to drive a phase transition or the grown layer or silicized Mo (e.g. MoSi2) from a hexagonal phase to the desired tetragonal phase. In an embodiment the annealing comprises heating the layer of silicized Mo (e.g. MoSi 2) at a minimum temperature of 1000 degrees C for a minimum time of 20 minutes. Figure 68 depicts an example configuration in which a graphene support layer 36 comprises a Mo layer 36A and a silicized Mo (e.g., MoSi2) layer 36B. The silicized Mo (e.g., MoSi2) layer 36B was grown directly on the Mo layer 36A and subsequently annealed as discussed above to provide the silicized Mo (e.g., MoSi2) in the tetragonal (epitaxially matching) phase. In a subsequent step the least one graphene layer 2 is formed on the graphene support layer 36. In one embodiment, the least one graphene layer 2 is formed by chemical vapor deposition (CVD). The number of graphene layers 2 in the least one graphene layer 2 may depend on the composition of the graphene support layer 36. For example, where the graphene support layer 36 comprises Cu, CVD will typically produce a monolayer or graphene. CVD on Ni or Mo can produce multilayers. The resulting structure is shown in Figure 7. In an embodiment of the graphene support layer 36 has a root mean squared roughness or less than 5 nm, optionally less than 1 nm, optionally less than 0.5 nm, optionally less than 0.nm. Increasing the smoothness of the graphene support layer 36 reduces the risk of significant folding in, or other disruption to, the portion of the least one graphene layer 2 that forms the freestanding membrane 14 when the underlying graphene support layer 36 is removed. Increasing the smoothness will also tend to increase the tension in the freestanding membrane 14 because the surface area of the graphene will tend to be lower where it does not have to follow large irregularities in the surface on which it is deposited. Conversely, decreasing the smoothness will tend to decrease the tension in the freestanding membrane 14. In an embodiment the degree of smoothness or the graphene support layer 36 is selected to achieve a desired tension in the freestanding membrane 14 during use. Alternatively, one or both of thermal and chemical processing may be applied to the least one graphene layer 2, and / or to one or more surrounding layers, to achieve a desired tension in the freestanding membrane 14 during use. In an embodiment, the substrate 6 comprises a base layer 8, a first graphene support layer 36 and a second graphene support layer 38. The least one graphene layer 2 is formed on the first graphene support layer 36 and the second graphene support layer is formed on top of the least one graphene layer 2. The first graphene support layer 36 and the second graphene support layer 38 may have the same composition or a different composition. Arranging for the first and second graphene support layers 36 and 38 to have the same composition, for example both including Mo or silicized Mo, and / or the same thickness, may desirably balance capillary forces exerted on the at least one graphene layer 2 during wet etching steps. Arranging for the first and second graphene support layers 36 and 38 to have different compositions or thicknesses may be used to control a tension in the freestanding membrane 14 to be formed. For example, the second graphene support layer 38, which may still be present after the freestanding membrane 14 has been formed, may be selected to act as a control layer for controlling the tension. For example, the second graphene support layer 38 may be formed from a material that can be processed to change a tension in the freestanding membrane 14. For example, the material may shrink on heating and pull the freestanding membrane 14 into a state of higher tension. Control layers are discussed in further detail below, particularly in relation to the discussed with reference to Figures 29-36. In one embodiment the first graphene support layer 36 comprises a metal or silicized metal and the second graphene support layer 38 comprises hexagonal boron nitride. Hexagonal boron nitride is chemically more insert than graphene so a thin layer of the hexagonal boron nitride can be left on the least one graphene layer 2 as a coating or additional layer to protect the graphene and / or act to reduce DUV reflection. The combination of the first graphene support layer 36 and the second graphene support layer 38 protect the at least one graphene layer 2 during subsequent processing steps (eg preventing damage to the graphene or to the adhesion between the graphene and other layers ), provides mechanical support to the least one graphene layer 2 (eg facilitating handling), or both. Figures 8-10 depict example stages in a manufacturing method starting from the arrangement or Figure 7 in the case where both of a first graphene support layer 36 and a second graphene support layer 38 are provided. In this example the second graphene support layer 38 is formed by e-beam evaporation (or other deposition technique) to provide the arrangement shown in Figure 8. Subsequently, a further layer 40 is formed on the second graphene support layer 38. The further layer 40 may include one or more of the following: an adhesion layer, a plasma enhanced chemical vapor deposition (PECVD) tetraethyl orthosilicate (TEOS) layer, or a PECVD oxide layer. The further layer 40 provides further protection during subsequent processing steps. The further layer 40 provides predictable and therefore reliable adhesion with encapsulation layer or sacrificial layer 42 or further encapsulation layer or sacrificial layer 48 (e.g. Parylene). The further layer 40 may protect the graphene support layer 38 from attack by etching steps, such as the O2 barrel etch mentioned below. The further layer 40 may also increase the symmetry of the stack, providing better mechanical support for the least one graphene layer 2. In a subsequent step the silicon oxide layer 34 on a lower surface of the base layer 8 is removed by etching to provide the structure shown in Figure 9. In a subsequent step the structure is encapsulated in an encapsulation layer or sacrificial layer 42 (which may be referred to as an etch mask) to provide the structure shown in Figure 10. In an embodiment the encapsulation layer or sacrificial layer 42 comprises SixNy but other materials may also be used depending on the etching processes to be used in subsequent steps. The encapsulation layer or sacrificial layer 42 should be resistant to at least a subset of etchants used in subsequent steps. In other variables the encapsulation layer or sacrificial layer 42 is omitted from the top of the stack. In an alternative embodiment, schematically depicted in Figures 11 and 12, the step of forming the second graphene support layer 38 is omitted. In this case the further layer 40 is formed directly on the least one graphene layer 2, as shown in Figure 11. Figure 12 shows the result of applying the encapsulation layer or sacrificial layer 42. Figures 13-17 depict example subsequent processing stages starting from the arrangement of Figure 10. The same processing could also be carried out starting from the arrangement of Figure 12. To achieve the arrangement shown in Figure 13, the arrangement of Figure 10 is photolithographically patterned and then processed to form windows 44 and 46 in the encapsulation layer or sacrificial layer 42 (e.g. by dry etching in SixNy). A further encapsulation layer or sacrificial layer 48 is then deposited around the resulting arrangement and processed (eg by dry etching or selective deposition) to open window 50. The further encapsulation layer or sacrificial layer 48 may be a poly (p-xylylene) polymer such as Parylene or ProTEK® type materials for example. In a subsequent step a KOH etch is used to remove the silicon forming the base layer 8, producing the arrangement shown in Figure 14. The presence of the further encapsulation layer or sacrificial layer 48 during this processing provides mechanical strength to facilitate handling and also acts to protect layers which are not being etched (eg preventing damage to the least one graphene layer 2 itself or damage to a quality of adhesion between the least one graphene 2 and other layers). In a subsequent step the further encapsulation layer or sacrificial layer 48 is removed to produce the arrangement shown in Figure 15. In an embodiment the further encapsulation layer or sacrificial layer 48 is removed using a (rel barrel etch, Rie etch or other removal techniques. In a subsequent step a portion of the further layer 40 within window 44 and a portion of the silicon oxide layer 34 in window 46 are removed to produce the arrangement shown in Figure 16. In an embodiment these layers are removed using a buffered oxide etch. In a subsequent step portions of the first and second graphene support layers 36 and 38 are removed (via windows 44 and 46) to leave a freestanding membrane 14, as shown in Figure 17. In an edition, the first and second graphene support layers 36 and 38 are removed using a metal etch. Figures 18-20 depict alternative subsequent processing stages starting from the arrangement of Figure 10. The same processing could also be carried out starting from the arrangement of Figure 12. The processing of Figures 18-20 does not require the further encapsulation layer or sacrificial layer 48 (as used in the processing described above with reference to Figures 13-17). In the case where the further encapsulation layer or sacrificial layer 48 comprises Parylene, the processing which does not use this layer may be referred to as a Parylene-free processing flow. To produce the arrangement shown in Figure 18, the arrangement of Figure 10 is photolithographically patterned and then processed to form windows 44 and 46 in the encapsulation layer or sacrificial layer 42 (e.g. by dry etching in SixNy). In a subsequent step a buffered oxide etch is used to remove a portion of the further layer 40 in window 44. A KOH etch is used to remove a portion of the silicon forming the base layer 8 within window 46, producing producing the arrangement of Figure 19. In a subsequent step portions of the first and second graphene support layers 36 and 38 in windows 44 and 46 are removed to leave a freestanding membrane 14, as shown in Figure 20. In an embodiment, the portions of the first and second graphene support layers 36 and 38 are removed using a suitable etch. The methods described above with reference to Figures 13-20 are example expired in which a stack including the least one graphene layer 2 is encapsulated with an encapsulation layer or sacrificial layer 42 about at least a front and a side surface of the stack during the removing of the first substrate portion 11. In the particular examples shown, the stack comprises the base layer 8, the silicon oxide layer 34, the first graphene support layer 36, the at least one graphene layer 2 and the further layer 40 when starting from the arrangement of Figure 12. When starting from the arrangement of Figure 10, the stack further comprises the second graphene support layer 38. The first substrate portion 11 comprises the portions of the base layer 8, silicon oxide layer 34 and first graphene support layer 36 which are removed in order to form the freestanding membrane 14, as shown for example in Figures 17 and 20. The encapsulation layer or sacrificial layer 42 protects the at lea st one graphene layer 2 from damage during the processing steps used to remove the first substrate portion 11 and form the freestanding membrane 14. The layers provided above the least one graphene layer 2 may also enhance mechanical rigidity of the stack, facilitate facilitating safe handling or the stack during processing to remove the first substrate portion 11. Figures 21-28 depict stages in an alternative embodiment. In this embodiment, a base layer 8 comprising a silicon wafer is processed to form a silicon oxide layer 34 (S1O2) on an outer surface of the silicon wafer (Figure 21). In a subsequent step a lower side of the stack is etched to remove the silicon oxide layer 34 on the lower side of the base layer 8. In a subsequent step an encapsulation layer or sacrificial layer 42 is applied to produce the arrangement shown in Figure 22 The encapsulation layer or sacrificial layer 42 in this embodiment may include for example a PECVD nitride etch mask. In a subsequent step of the arrangement of Figure 22, photolithographically patterned and then processed to form windows 44 and 46 in the encapsulation layer or sacrificial layer 42 (e.g., by SixNy dry / wet etch), as shown in Figure 23. In a subsequent step a graphene support layer 36 is formed that fills window 44. The graphene support layer 36 may take any of the forms described above (e.g., including a metal or metal silicide). In a subsequent step the least one graphene layer 2 is formed on the graphene support layer 36 to produce the arrangement shown in Figure 25. The least one graphene layer 2 may take any of the forms described above (eg formed using CVD). In a subsequent step a protection layer 43, applied over the least one graphene layer 2 to produce the arrangement is shown in Figure 26. In an embodiment the protection layer 43 comprises PMMA or another organic material. PMMA can be applied (e.g. by spin coating) with minimum risk of disruption or damage to previously deposited layers (e.g. the at least one graphene layer 2 or any other layers). PMMA is known to be compatible with graphene and various techniques are known for removing PMMA effectively without damaging graphene layers. In a subsequent step a portion of the base layer 8, silicon oxide layer 34 and graphene support layer 36 in window 46 are removed in a region beneath the least one graphene layer 2 to produce the arrangement shown in Figure 27. In an embodiment the removal is implemented using a dry / wet etch or SixNy following by a KOH etch. In a subsequent step the protection layer 43 above the at least one graphene layer 2 is removed to leave a freestanding membrane 14, as shown in Figure 28. In an embodiment the protection layer 43 is removed by thermal decomposition or by liquid / vapor solvation. In an embodiment a control layer 44 is provided over a portion of the least one graphene layer 2 outside of the freestanding membrane 14. The control layer 44 can be used to control a tension in the freestanding membrane 14. For example, in an embodiment the control layer 44 is processed (eg by heating or cooling) to cause a change in an internal structure or the control layer 44. The change in the internal structure transfers forces to the freestanding membrane, causing a change in tension in the freestanding membrane 14. The change in the internal structure may be such as to persistent after processing (eg by heating or cooling) has stopped. In an embodiment, the control layer 44 is deposited on the least one graphene layer 2 in such a way that the density of the layer is lower than an equilibrium bulk density. Subjecting such a layer to an external influence (e.g. by applying heat) can cause the layer to shrink so as to bring the density closer to the bulk density. This shrinking is an example of a change in the internal structure of the control layer 44 which would be effective in changing a tension in the freestanding membrane 14 (e.g. increasing the tension as the control layer 44 shrinks). In other expands the control layer 44 may be processed to change the tension in the freestanding membrane 14 by causing the control layer 44 to undergo a phase transition, by thinning the control layer 44, for example by dry or wet etching, or by changing a chemical composition of the control layer 44. In an embodiment the tension in the freestanding membrane 14 is controlled so that the freestanding membrane 14 will remain sufficiently flat during use. If the tension in the freestanding membrane 14 is too low, the freestanding membrane 14 may be undesirably flappy, leading to excessive sagging, or wrinkled. Wrinkling may lead to non-uniform thickness of the freestanding membrane 14. A freestanding membrane 14 that is loose or non-uniform thickness can have poorer imaging properties. If the tension in the freestanding membrane 14 is too high, the freestanding membrane 14 can be brittle and more susceptible to breaking. It is desirable to control the tension in the freestanding membrane 14 within a target range at the manufacturing stage. In an embodiment the tension in the freestanding membrane 14 is controlled at the manufacturing stage so that heat transferred to the freestanding membrane 14 during use (eg due to heating by absorption or lithography radiation) does not cause buckling or other deformation or breakage or the freestanding membrane 14. In an embodiment, the tension is controlled at the manufacturing stage so that expected heating of the freestanding membrane 14 during use leads to the tension in the freestanding membrane 14 reaching a desired range of values. For example, in the case where the heating in use raises the tension in the freestanding membrane 14, the tension may be controlled at the manufacturing stage to be lower than the desired range of values by an amount which is such that the expected level of heating will cause the tension to rise to a value within the desired range of values. In an embodiment, a method of manufacturing a pellicle 80 is provided which is particularly well adapted for providing a pellicle 80 with a control layer 80 for controlling a tension in the freestanding membrane 14. Figures 29-36 schematically depict stages in an example of such an embodiment. In this embodiment a substrate 6 is provided which has a base layer 8 and a graphene support layer 36. The least one graphene layer 2 is formed on the graphene support layer 36. Figure 29 schematically depicts such an arrangement. The graphene support layer 36 and base layer 8 may be formed according to any of the above discussed above. The graphene support layer 36 may include for example a metal layer or a metal silicide layer. The base layer 8 may include a silicon wafer for example. The at least one graphene layer 2 may be formed according to any of the above discussed above. The least one graphene layer 2 may be formed using CVD for example. The method comprises removing a first portion 48 or the graphene support layer 36 without removing a portion 50 or the least one graphene layer 2 that was deposited on the first portion 48 or the graphene support layer 36. Figures 30- 32 schematically depict one way in which this may be achieved. As shown in Figure 30, mask layers 46 are deposited on the front and back of the stack. The mask layers 46 are processed photolithographically so that the mask layers 46 cover selected regions on the front and back of the stack. In an embodiment, the selected region on the front of the stack contains the region in which the freestanding membrane 14 is formed, when viewed perpendicularly to the planar surface 4 of the substrate 6. The selected region on the back of the stack is outside of the region in which the freestanding membrane 14 is formed, when viewed perpendicularly to the planar surface 4 of the substrate 6. In a subsequent step a region of the base layer 8 that is not protected by the mask layer 46 on the back of the stack is partially etched to produce the arrangement shown in Figure 31. In the case where the base layer 8 is formed from a silicon wafer a KOH etch may be used. In a subsequent step to a side etch (which may also be referred to as an undercut) is carried out to remove the first portion 48 or the graphene support layer 36. The first portion 48 to be removed is indicated in Figure 31 by shading. The arrangement after removal is shown in Figure 32. After removal of the first portion 48 the previously overlying portion 50 or the least one graphene layer 2 falls downwards and adheres to the previously underlying base layer 8. The method further comprises depositing a control layer 44 above the least one graphene layer 2. An example of the resulting arrangement is shown in Figure 33. The control layer 44 may be deposited for example using sputtering or evaporation (eg e- beam evaporation). In a subsequent step etching of the base layer 8 (e.g., using KOH etch) from the back of the stack, continued in order to penetrate through to the graphene support layer 36, arriving at the arrangement shown in Figure 34. The method further comprises removing a second portion of the graphene support layer 36. The removal of the second portion of the graphene support layer 36 causes weakening or removal of adhesion between the least one graphene layer 2 and layers which were positioned above the second portion of the graphene support layer 36 (immediately prior to the removal of the second portion of the graphene support layer 36). Figure 35 schematically depicts example processing. In this particular example the second portion of the graphene support layer 36 consists of all of the remaining graphene support layer 36. Removal of the second portion of the graphene support layer 36 therefore leads to complete removal of the graphene support layer 36 in this embodiment. The method further comprises lifting off the layers which were positioned above the second portion of the graphene support layer 36, forming the freestanding membrane 14 as shown in Figure 36. In an embodiment, the removing or either or both of the first portion 48 or the graphene support layer 36 and the second portion of the graphene support layer 36 is performed using side etching. In an embodiment, a tension in the freestanding membrane 14 is controlled during manufacture of the pellicle by processing the substrate 6 and which is at least one graphene layer 2 is initially deposited. The processing of the substrate 6 may be performed prior to or after removal of the first substrate portion 11. In an edition the processing of the substrate 6 comprises deforming the planar surface of the substrate 6 on which the least one graphene layer 2 is initially formed. Example deformations are schematically depicted in Figures 42 and 43. In Figure 42, the substrate 6 has been processed to cause the substrate 6 to bow outwards on the side of the substrate 6 on which the least one graphene layer 2 has been deposited. This applies to a tensile force at least one graphene layer 2. In Figure 43, the substrate 6 has been processed to cause the substrate 6 to bow inwards on the side of the substrate 6 on which the least one graphene layer 2 has been deposited. This applies a compressive force to the least one graphene layer 2. The deformation of the substrate 6 may be performed in various ways. In one embodiment, the deformation is achieved by applying heating or cooling non-uniformly to the substrate 6. The non-uniform heating or cooling causes a corresponding non-uniform thermal expansion or contraction, which can deform the substrate 2. When a pellicle comprising graphene is used in an EUV lithography apparatus, EUV photons, oxygen, hydrogen and / or water present near the pellicle can create defects in the graphene lattice. Defects may also be present due to intrinsic limitations in the processes used to deposit the graphene (e.g. CVD processes). Damage or intrinsic defects may reduce the mechanical robustness of the graphene and further increase the chance of pellicle failure. Defect free graphene is more robust against damage induced by EUV photons, oxygen, hydrogen and / or water. Undesirable etching away or carbon from the graph will preferentially occur at defect sites. Reducing the number of defects will therefore reduce the extent and / or rate of undesirable etching. Reducing undesirable etching will help maintain the pellicle's transmissive properties and lateral imaging uniformity longer. Amorphous carbon deposition is inherent to the use of EUV. This process is normally unwanted for pellicles because carbon reduces the pellicle transmission. However, for pellicles having a freestanding membrane including one or more layers of graphene, deposition of amorphous carbon on the pellicle surface can be used to repair inherently present defects or defects induced by EUV photons, oxygen, hydrogen and / or water. Conversion of amorphous carbon to graphene can be i) thermally activated, ii) catalytically activated, or iii) achieved by applying shear forces. Embodiment exploiting (i) and (ii) are described below. In an embodiment, thermal activation is used. This approach may be particularly applicable for example where a freestanding membrane comprises at least one graphene layer and no capping layer. The temperature of a pellicle being used in a lithographic apparatus will depend on the particular operating parameters or the lithographic apparatus. Typically, it is expected that temperatures between 500K and 800K will be reached in normal use for a 1000 W source power. Such pellicle temperatures will only increase upon increasing source power if the thickness of the pellicle is not reduced concomitantly. For thermal activation or conversion or amorphous carbon to graphene pellet temperatures or greater than 800K are preferred. In an embodiment, a device manufacturing method is provided in which a pellicle 80 including at least one graphene layer 2 forming a freestanding membrane 14 is used to protect a patterning device MA. An electrical current is passed through the at least one graphene layer 2 to heat the at least one graphene layer 2. The heating thermally active conversion of amorphous carbon to single or multilayer graphene, damage effect repair or defects or damage present in the least one graphene layer 2. The pellicle 80 is at least partially repaired in-situ, improving average performance and longevity of the pellicle 80. In an embodiment, the least one graphene layer 2 is heated to above 800K, optionally above 850K, optionally above 900K, optionally above 1000K. In an embodiment, a flow of material including a source of carbon may be provided onto the pellicle 80. The flow may include one or both of the following: a flow of evaporated carbon (e.g., amorphous carbon); and a flow or a carbon-based precursor gas. The carbon-based precursor gas is a gas acting as a source or carbon (e.g., amorphous carbon). The carbon-based precursor gas may comprise one or more of the following for example: methane (CH4) or acetylene (C2H2). Providing a flow of material including a source of carbon makes it possible to control the supply of carbon. Controlling the supply of carbon may be desirable for example to ensure uniformity of the repair process and / or to avoid excessive deposition of carbon (which may be impaired transmissivity through the pellicle). The flow of material may be applied during heating of the freestanding membrane. The provision of carbon is not limited to the above example methods. Carbon may be provided in any form. In an embodiment, the pellicle 80 is provided with two or more conductive contact regions 314 positioned to allow an electrical current to be driven through the freestanding membrane 14 through the two or more conductive contact regions 314. The two or more conductive contact regions 314 may be formed in direct contact with the least one graphene layer 2. An example of a pellicle 80 provided with conductive contact regions 314 is depicted in Figure 41 in the case where the pellicle 80 is repaired offline. However, the pellicle 80 may also be configured in this manner for allowing heating to be applied while the pellicle 80 is in-situ within the lithography apparatus (e.g., protecting an optical element or the lithography apparatus, such as a patterning device). Fabrication of conductive (e.g. metallic) contact regions can easily be integrated into the fabrication process (e.g. where fabrication is CMOS / MEMS based). In an embodiment, examples or which are shown in Figures 41 and 46, apparatus 300 for processing (e.g., repairing) a pellicle 80 is provided. The apparatus 300 may be configured to operate offline or inline. When used offline, the apparatus 300 may be used to repair intrinsic defects in the least one graphene layer before the pellicle 80 is first used in the lithographic apparatus. Alternatively or additionally, the apparatus 300 may be used to repair pellicles 80 after they have been damaged during use in the lithographic apparatus. The pellicle 80 comprises at least one graphene layer 2 forming a freestanding membrane 14. The pellicle 80 may take any of the various forms disclosed elsewhere in this application, for example. The pellicle 80 may be available or obtained by any of the methods disclosed in this application for example. In an embodiment, as shown in Figure 41, the apparatus 300 comprises a current driving apparatus 312 for driving an electrical current through the freestanding membrane 14 to heat the freestanding membrane (and therefore also the least one graphene layer 2 in the freestanding membrane 14). The current driving apparatus 312 may include a power source of any type suitable for driving the required electrical current through the freestanding membrane 14. The current driving apparatus 312 may include suitable leads and / or electrical connectors for connecting to the conductive contact regions 314. In an embodiment, the apparatus 300 comprises one or more supply ports 316,318 for applying a flow of material including a source of carbon (eg amorphous carbon) onto the pellicle 80. The apparatus 300 may contain suitable containers for disturbing the material including the source of carbon. Where the source of carbon comprises evaporated carbon, apparatus for evaporating carbon may be provided. In an embodiment, the apparatus 300 further including an enclosure 310 for containing the pellicle 80 during repair of the pellicle 80. The one or more supply ports 316, 318 may, in such an embodiment, convey the flow of material including the source of carbon from the outside of the enclosure 310 to the inside of the enclosure 310. In an embodiment, as shown in Figure 46, the apparatus 300 is configured to use electrochemical deposition to apply carbon to the least one graphene layer 2. This may be achieved using an electrochemical cell. In the electrochemical cell the freestanding membrane 14 is immersed in a bath 424 containing a solution 426 or an electrolyte and / or carbon precursor. The freestanding membrane 14 acts as a working electrode. When an electrochemical potential is applied, a redox reaction on the surface of the freestanding membrane 14 will take place. The organic precursor forms carbon (by reduction or oxidation) and the carbon deposits on the surface of the freestanding membrane 14. The freestanding membrane 14 is thus processed (e.g. repaired) as desired. Many suitable configurations or electrochemical cell are available. In the example shown in Figure 46, the apparatus 300 comprises an electrochemical cell having three electrodes: the freestanding membrane 14 (as a working electrode), a counter-electrode 422, and a reference electrode 423. The principle of operation of three- electrode electrochemical cells are well known in the art. Other types of electrochemical cell (e.g. two-electrode or four-electrode) may also be used. Details for performing electrochemical carbon deposition in a general context may be found in the literature. These techniques may be used to process a pellicle according to the present method. Examples are given below. In Surface and Coatings Technology 124 (2000) 196-200, Q. Fu et al. Disclose use of various organic solvents as carbon precursor and investigated the influence of the carbon precursor (DMF, CH3CN etc.) on the sp2 / sp3 carbon ratio in the films obtained by electrodeposition on indium tin oxide. In Journal of The Electrochemical Society, 155 E49-E55 2008, Sadoway et al. Disclose the electrochemical growth of diamond-like carbon (DLC) coatings on substrates. In many of the described techniques for electrochemical carbon deposition, relatively large positive potentials are used (for example, in the region of 1000V), but there are also described techniques in which deposition is performed at lower voltages and at room temperature. In ACS Nano, 2016, 10 (1), pp. 1539-1545, Kim et al. Show that the current density at the defect sites and grain boundaries is higher thus enabling selective electrochemical deposition on these sites. In J. Mater. Chem., 2008, 18, 3071-3083, Burghard et al. Showed that carbon nano tubes can be decorated with polymers obtained electrochemically. In Small 2011, 7, 1203-1206, Liu et al. Disclose that graphene can be obtained electrochemically from graphene oxide. An alternative method has been described in US 2013/0098768. Graphite is suspended in a solvent and doped with a Lewis or Bronzeed acid to make the graphite sheets positively charged. A negative potential is then applied to a substrate so that the doped graphite migrates to the surface of the substrate forming graphene. The method is suitable for many children or substrates. In an embodiment the freestanding membrane 14 is used as the substrate. The method is thus used to deposit carbon on the least one graphene layer 2 or the freestanding membrane 14. In ACS Nano 2012, 6, 205-211, Z. Yang et al. Disclose that doping or graphene with atoms with a lower electronegativity than carbon such as boron (B) can provide a distribution of positive charge on the graphene surface . In an embodiment, such doping is applied to graphene and a negative potential is applied to a freestanding membrane 14 to cause graphite to migrate to the surface of the freestanding membrane 14. In an embodiment, a catalytically active metal which promotes the conversion of carbon to single or multilayer graphene is provided within or in contact with the least one graphene layer 2 of the pellicle 80. The catalytic metal can be provided in any form, including for example one or more of the following: atoms, molecules, nanoparticles, vapor, or thin film. The catalytic metal can be provided at any stage of the manufacturing process. When present during use of the pellicle 80 or during processing to repair the pellicle 80 after use, the catalytically active metal may enable desirable conversion of carbon to single or multilayer graphene to occur efficiently at lower temperatures than would be possible without the catalytically active metal . In an embodiment, the catalytically active metal is provided before or during the deposition of the least one graphene layer 2. The catalytically active metal may in this case improve the quality of the least one graphene layer 2. The catalytically active metal may reduce the number of defects present in the least one graphene layer 2. The catalytically active metal may be provided as a vapor. In this case, the requirement to etch away a metal film provided instead of the metal vapor, during manufacture of the pellicle 80, may be desirably be avoided. Alternatively or additionally, the use of a metal vapor instead of a metal film may improve the quality of the least one graphene layer 2 by allowing improved optimization of grain sizes and / or surface morphology because graphene does not generally adhere conformally to a metal surface . In an embodiment the least one graphene layer 2 is grown on a dielectric surface while catalytic activation is provided by a metal vapor. Optionally, the dielectric substrate is seeded prior to growth or at least one graphene layer 2. The seeding may be performed, for example, by deposition or a small exfoliated graphene flake on the dielectric. In an embodiment, the catalytically active metal comprises a transition metal. In an embodiment, the catalytically active metal includes one or more of Fe, Co, Ni, and Cu, but other materials could be used [00195] In an embodiment, an example of which is depicted schematically in Figure 38, the catalytically active metal is provided via formation of a layer 302.304 or the catalytically active metal on one or both sides of the least one graphene layer 2. Shown in the particular example, the layer 302.304 is provided on both sides but this is not essential. The layer may be provided on the top side only or on the bottom side only. Alternatively or additionally, in an embodiment, an example or which is depicted schematically in Figure 39, the catalytically active metal is provided via formation of a layer 306 or the catalytically active metal within the least one graphene layer 2. Alternatively or additionally, in an embodiment, an example or which is depicted schematically in Figure 40, the catalytically active metal is provided via inclusion of nanoparticles 308 or the catalytically active metal within the least one graphene layer 2. Alternatively or additionally, in an embodiment, the catalytically active metal is provided via doping or the graphene in the least one graphene layer by atoms or the catalytically active metal. In an embodiment, the catalytically active metal is provided by performing the depositing (e.g., by CVD) or the least one graphene layer 2 in the presence of a vapor or the catalytically active metal. In an embodiment, an example or which is depicted schematically in Figure 44, the freestanding membrane 14 is formed with a capping layer 402,404 on either or both sides or the least one graphene layer 2. In the particular example shown in Figure 44, the capping layer 402,404 is provided on both sides of the least one graphene layer 2. The capping layer 402,404 protects the least one graphene layer 2 from chemical attack by radical species such as hydrogen, oxygen and hydroxyl radical species. Such radical species are likely to be present during scanning conditions and may cause degradation of the freestanding membrane 14 in the absence of the capping layer 402,404. The inventors have performed experiments demonstrating for example the effects of exposure or graphite to a flux or hydrogen (H *) radicals. After 28 hours of exposure in a hydrogen radical generator, the number of holes seen in secondary electron images (SEM) was significantly greater than prior to the exposure. In an embodiment the capping layer 402.404 comprises a metal or a metal oxide. Capping layers 402,404 formed from metal or metal oxide have been found to be particularly effective at protecting graphene. In an embodiment, the capping layer comprises one or more material selected from the following group: Ru, Mo, B, MOS12, h-BN (hexagonal boron nitride), HfCF, ZrCF, Y2O3, Nb2Os, I ^ 0 () 3. and Al 2 O 3. The metals Ru and Mo, the compounds M0S12 and h-BN, and the metal oxides HfCF, Zr () 2, Y2O3, Nb2 (F La203, and AI2O3 have been found to be particularly effective as capping layers 402.404. Other high-k dielectric materials could also be used. The capping layers 402.404 can be deposited using a variety of techniques, including for example physical vapor deposition (PVD), chemical vapor deposition (CVD), evaporation, or atomic layer deposition (ALD). The capping layers 402.404 should be relatively thin (or nanometer order) in order to minimize EUV transmission losses. The inventors have found that ALD is particularly effective for producing layers which are very thin and yet still fully closed. In an embodiment, an example or which is shown in Figure 45, adhesion between the capping layer 402.404 and the least one graphene layer 2 is improved by providing an adhesion layer 412.414 between the capping layer 402.404 and the least one graphene. layer 2. In the absence of any adhesion layer, adhesion between graphene and materials coated on the graphene can be poor. It is possible to improve adhesion by creating hydrophilic -OH groups on the surface. Hydrophilic -OH groups on the surface allow good adhesion or oxides for example. It has been found however that creating hydrophilic -OH groups on the surface can compromise the electronic stability of graphene by disrupting the sp2 bonded network. Compromising the electronic stability can cause atomic sites to be created which act is starting points for further defect generation. In an embodiment the adhesion layer 412,414 is configured to reduce or avoid compromising the electronic stability of the graphene. In an embodiment, the adhesion layer 412,414 comprises a material having sp2-bonded carbon and hydrophilic groups. The presence of the sp2-bonded carbon reduction or avoids compromising of the electronic stability of the graphene. The presence of the hydrophilic groups promotes good adhesion. In an embodiment the adhesion layer 412,414 comprises amorphous carbon (a-C). In an embodiment the amorphous carbon is partly oxidized. Partly oxidized amorphous carbon is expected to possess both sp2-bonded carbon and hydrophilic groups such as Cn-OH or Cn-COOH. Described in the above-described graphene support layer 36 is provided. The graphene support layer comprises one or more of the following: transition metals such as Mo, Ni, Ru, Pt, Cu, Ti, V, Zr, Nb, Hf, Ta, W, or their silicides, such as silicized Mo, silicized Ni, silicized Ru, silicized Pt, silicized Cu, silicized Ti, silicized V, silicized Zr, silicized Nb, silicized Hf, silicized Ta, silicized W. Due to the risk of contamination or processing apparatus, it is undesirable for some of these materials to be present when certain high temperature processing steps are being carried out. For example, it is undesirable for Mo or silicized Mo to be present during a low pressure chemical vapor deposition (LPCVD) process, which may be typically performed at around 800 degrees C. It has been found that such an LPCVD process can be used to form particularly effective encapsulation or sacrificial layers 42 or SixNy. PECVD may also be used to form an encapsulation layer or sacrificial layer 42 or SixNy but it has been found that pinholes in the encapsulation layer or sacrificial layer 42 can allow etchants (eg KOH) in subsequent law etching steps to pass through the encapsulation layer or sacrificial layer 42. It has further been found that adhesion to the least one graphene layer 2 is poor, which limits the extent to which processing steps can be carried out after the least graphene layer 2 has been formed. It has further been found that stresses in the graphene support layer 36, particularly when including Mo or silicized Mo, can be changed by processing at high temperatures. Control of stresses in the graphene support layer 36 is therefore made more complex by each high temperature processing step that is carried out while the graphene support layer 36 is present. Process flows in which the above problems are avoided or reduced are described below with reference to Figures 47-67. In each process flow, a stack is provided in which a graphene support layer 36 is formed after an encapsulation layer or sacrificial layer 42 is formed. Three alternative process flows are depicted respectively in Figures 47-52, 53-56 and 57-60. Each process flow starts from a silicon wafer (with its native oxide) and produces a multi-layer structure in which a patterned encapsulation layer or sacrificial layer 42 is formed using LPCVD before a graphene support layer 36 is formed and before the least one graphene layer 2 is formed. In the process flow of Figures 47-52, a base layer 8 including a silicon wafer (Figure 47) is processed to form a silicon oxide layer 34 (S1O2) on an outer surface of the silicon wafer (Figure 48). The silicon oxide layer 34 may be formed using thermal oxidation at about 1000 degrees C, for example. In a subsequent step a lower side of the stack is etched to remove the silicon oxide layer 34 on the lower side of the base layer 8 (Figure 49). In a subsequent step an encapsulation layer or sacrificial layer 42, applied to produce the arrangement is shown in Figure 50. The encapsulation layer or sacrificial layer 42 in this edition comprises an LPCVD SixNy layer (deposited at around 800 degrees C for example). In a subsequent step the arrangement of Figure 50, photolithographically patterned and then processed to form windows 44 and 46 in the encapsulation layer or sacrificial layer 42 (eg by RIE), as shown in Figure 51. In a subsequent step a graphene-support layer 36 is formed that fills window 44. The graphene support layer 36 may take any of the forms described above (eg including a metal or metal silicide, for example Mo or silicized Mo). In an embodiment the graphene support layer 36 comprises Mo deposited using CVD at 20 degrees C (or at a higher temperature, for example any temperature between room temperature and about 1000 degrees C). In the process flow of Figures 53-56, a base layer 8 including a silicon wafer (Figure 53) is processed to apply an encapsulation layer or sacrificial layer 42 around the base layer 8 (Figure 54). The encapsulation layer or sacrificial layer 42 in this edition comprises an LPCVD SixNy layer (deposited at around 800 degrees C for example). In a subsequent step the arrangement of Figure 54 is photolithographically patterned and then processed to form a window 46 in the encapsulation layer or sacrificial layer 42 (eg by RIE), as shown in Figure 55. In a subsequent step a graphene-support layer 36 is formed on an upper side of the stack to provide the arrangement shown in Figure 56. The graphene support layer 36 may take any of the forms described above (eg including a metal or metal silicide, for example Mo or silicized Mo). In an embodiment the graphene support layer 36 comprises Mo deposited using CVD at 20 degrees C (or at a higher temperature, for example any temperature between room temperature and about 1000 degrees C). In the process flow of Figures 57-60, a base layer 8 including a silicon wafer (Figure 57) is processed to apply an encapsulation layer or sacrificial layer 42 around the base layer 8 (Figure 58). The encapsulation layer or sacrificial layer 42 in this edition comprises an LPCVD SixNy layer (deposited at around 800 degrees C for example). In a subsequent step the arrangement of Figure 58, photolithographically patterned and then processed to form a window 46 is in the encapsulation layer or sacrificial layer 42 (e.g., by RIE). A TEOS layer 504 is then formed on an upper side of the stack, using PECVD or LPCVD at 400 degrees C for example, to provide the arrangement shown in Figure 59. In a subsequent step a graphene support layer 36 is formed on an upper side of the stack to provide the arrangement shown in Figure 60. The graphene support layer 36 may take any of the forms described above (eg including a metal or metal silicide, for example Mo or silicized Mo). In an embodiment the graphene support layer 36 comprises Mo deposited using CVD at 20 degrees C (or at a higher temperature, for example any temperature between room temperature and about 1000 degrees C). Figures 61-67 depict an example process flow to be performed further to a process flow (such as the process flow of Figures 47-52, the process flow of Figures 53-56, or the process flow of Figures 57-60 ) that has provided the graphene support layer 36 after forming an encapsulation layer or sacrificial layer 42 at an earlier stage using a high temperature LPCVD process (eg to form an LPCVD SixNy layer at around 800 degrees C). In the particular example of Figures 61-67 the process flow starts from the arrangement of Figure 52. The arrangement of Figure 52 is processed to form the least one graphene layer 2 on an upper surface of the graphene support layer 36 (Figure 61). The least one graphene layer 2 may take any of the forms described above (e.g. formed using CVD at a temperature of 900-1000 degrees C). In a subsequent step, a further graphene support layer 38 is formed on the least one graphene layer 2 to produce the arrangement shown in Figure 62. In an explanation the further graphene support layer 38 has the same composition as the graphene support layer 36 and is formed using the same methods. In an embodiment, both the graphene support layer 36 and the further graphene support layer 38 include Mo deposited using CVD at 20 degrees C (or at a higher temperature, for example any temperature between room temperature and about 1000 degrees C). In a subsequent step the stack is encapsulated by a further encapsulation layer or sacrificial layer 48 to produce the arrangement shown in Figure 63. In an embodiment the further encapsulation layer or sacrificial layer 48 comprises Parylene deposited using CVD. In a subsequent step, a KOH etch (or partial etching by deep RIE followed by a KOH etch) is used to remove a portion of the silicon forming the base layer 8 within window 46, producing producing the arrangement or Figure 64. In a subsequent step, the further encapsulation layer or sacrificial layer 48 is removed (eg in barrel etcher by O2 microwave plasma) to produce the arrangement of Figure 65. In a subsequent step an oxide etch (eg BHF) is applied to the lower side or the stack to remove an exposed portion of the silicon oxide layer 34 underneath the graphene support layer 36 (Figure 66). Finally, the graphene support layer 36 and the further graphene support layer 38 are removed (e.g. using a wet H2O2 etch or a vapor etching process), to leave a freestanding membrane 14, as shown in Figure 67. In the above described above with reference to Figures 47-68, a stress in the encapsulation layer or sacrificial layer 42, in the graphene support layer 36 and / or in the further graphene support layer 38, may be tuned during deposition, from tensile to compressive or from compressive to tensile, in order to control a stress in the freestanding membrane 14. In where the at least one graphene layer 2 is formed on a graphene support layer 36, the removing of the first substrate portion 11 to form the freestanding membrane 14 will include removing a portion of the graphene support layer 36 underneath a portion of the at least one graphene layer 2 that is to form the freestanding membrane 14. Removal of such a portion of the graphene support layer 36 is described above with reference to the transitions between Figures 16 and 17, between Figures 19 and 20 , between Figures 26 and 27, between Figures 34 and 35, and between Figures 66 and 67. It is possible to remove the portion of the graphene support layer 36 using a wet etch. For example, Mo can be removed using a wet etch including hydrogen peroxide in water. The inventors have found, however, that wet etching can cause damage to the freestanding membrane 14 and reduce yield. The inventors have found that yield can be increased by using a vapor etching process instead of a wet etching process. The improvement in yield is believed to be due to a reduction or removal of capillary force effects, concentration gradient effects and Brownian motion effects, relative to wet etching. Reduction or removal of capillary force effects, concentration gradient effects and Brownian motion effects also facilitates upscaling of the method of manufacturing a pellicle to larger size pellicles. Example apparatus 500 for removing a portion of a graphene support layer 36 using a vapor etching process is depicted in Figure 69. In this example, a reservoir 502 containing a liquid to be vaporized (eg water) is heated to produce vapor (eg steam). A stack (such as is depicted in any of Figures 16, 19, 34 and 66) is positioned so that a portion or a graphene support layer 36 is exposed to the vapor. The vapor is chosen so that the exposed portion of the graphene support layer 36 is removed by vapor etching. The inventors have found this approach to be particularly applicable where the graphene support layer 36 comprises Mo or silicized Mo (e.g. MoSi2) and the vapor comprises steam. The above-described methods of manufacture, and other methods of manufacture, provide a pellicle 80 including a membrane bonded to a membrane support. In the context of the methods discussed above the membrane support is referred to as a second substrate portion 12. In those methods the second substrate portion 12 is manufactured by removing a first substrate portion 11 from a substrate. However, it is not essential that the membrane support be formed in this way. The membrane comprises a graphene layer (e.g., at least one graphene layer 2, as described above). The membrane is bonded to and created on the membrane support with a thin film deposition process. The thin film deposition process may comprise chemical vapor deposition or another thin film deposition process. The bond between the membrane and the membrane support is an intrinsic bond between the membrane and the membrane support induced by the thin film deposition process or the membrane layer on the membrane support. The bond may be an intrinsic bond between the graphene layer and the membrane support induced by a thin film deposition process or the graphene layer onto the membrane support. The intrinsic bonding has a bonding strength such that the membrane remains bonded to the membrane support under a gravity force acting on a membrane, optionally for all orientations of the pellicle relative to the direction of gravity. In an alternative embodiment, as depicted schematically in Figure 70, a pellicle for a lithographic apparatus is manufactured by transferring at least one graphene layer 2 from a surface of a liquid 608 onto a frame 600. The frame 600 comprises an opening 606 and a border region 604 surrounding the opening 606. In Figure 70, the frame 600 is shown from the side so the opening 604 is not directly visible. A boundary of the opening 604 is depicted by broken lines. The opening 604 comprises a hole penetrating through from the right of the frame 600 to the left of the frame 600 in the orientation shown in Figure 70. After transfer to the frame 600, the least one graphene layer 2 spans the opening 606, forming a freestanding membrane 14. In the embodiment shown in Figure 70 the frame 600 is dipped into the liquid 608 in a direction perpendicular to the surface of the liquid 608 (ie vertically in the orientation shown) and then removed. Capillary and adhesion forces drag the least one graphene layer 2 onto the frame 600. Other arrangements are however possible. It is challenging to produce large freestanding membranes 14 with high yield. Due to the high aspect ratio of the freestanding membrane, surface tension and capillary force effects can cause tearing or rupturing of the freestanding membrane 14. It is also difficult to ensure reliable adhesion between the least one graphene layer 2 and the frame 600. In an embodiment, the liquid 608 has a composition which reduces surface tension or capillary effects and reduces the risk of tearing or rupture. In an embodiment, the liquid 608 comprises a mixture of water, an alcohol (e.g., ethanol at a concentration of less than 50%), and a further solvent that is not alcohol (e.g., a ketone such as acetone, or acetonitrile). Preferably, the further solvent is selected such as to reduce the likelihood of, or prevent, the formation of a droplet of the liquid that completely spans the opening 606 in the frame 600, after transfer of the least one graphene layer 2 to the frame 600 (relative to case where the liquid comprises water and alcohol, eg ethanol at a concentration or less than 50%, only). When the further solvent is not present and a droplet of the liquid that completely spans the opening 606 forms, breaking up or such a droplet can cause failure of the freestanding membrane 14 due to surface tension or capillary forces applied to the freestanding member 14. In an embodiment the further solvent is fully miscible with water and / or a mixture of water and alcohol (eg ethanol at a concentration or less than 50%). The further solvent is capable of form and disrupt hydrogen bonds in solution significantly. In an embodiment, the further solvent has a boiling point which is at least 10 degrees C (optionally at least 20 degrees C, optionally at least 25 degrees C) less than the boiling point of the liquid 608 without the further solvent. For example, in the case where the further solvent is acetone the boiling point will be about 57 degrees C, whereas the boiling point of a mixture of water and ethanol is typically in the range of 85-90 degrees C. Arranging for the boiling point of the further solvent to be significantly different in this manner promotes the formation of narrower droplets on the freestanding membrane 14. Formation of narrower droplets will cause surface tension effects to be more local and therefore less likely to cause failure of the freestanding membrane 14. A similar effect can be achieved for further solvent compositions which have a more similar boiling point to the water / ethanol mixture (eg a higher boiling point than acetone) but have a significantly different vapor pressure (eg lower than acetone). Acetonitrile is an example or such a further solvent composition. In an embodiment, adhesion of the least one graphene layer 2 to the frame 600 is improved by configuring the frame 600 such that at least a portion of the frame 600 in contact with the least one graphene layer 2 (the border region 604 in the example of Figure 70) is hydrophobic. In an embodiment, the hydrophobic portion is provided by forming at least a portion of the frame 600 from Si that has been treated to form Si-H at the surface (eg by immersion or the Si in an HF solution, for example a 48% HF solution). In an embodiment, the transfer of the least one graphene layer 2 to the frame 600 is performed while the liquid has a temperature in the range of 20-80 degrees Celsius, preferably 25-80 degrees Celsius, more preferably 25- 60 degrees Celsius, more preferably 30-55 degrees Celsius, particularly 30-40 degrees Celsius or substantially at 35 degrees Celsius. It has been found that this modifies surface tension in such a way as to reduce the risk of surface tension or capillary effects causing failure of the freestanding membrane 14. In an embodiment, the method of manufacturing a pellicle is adapted so that the freestanding membrane 14 comprises a sequence of layers having different chemical compositions, the sequence comprises the least one graphene layer 2 and at least one layer of a two -dimensional material other than graphene 700. Example arrangements are depicted in Figures 71-73. A broad class of two-dimensional materials are available. When provided as a single layer, two-dimensional materials are sometimes referred to as 2D topological materials or single layer materials, and include a single layer of atoms. Layered combinations or different 2D materials are sometimes referred to as van der Waals heterostructures. Examples of 2D materials include graphene, graphyne, borophene, silicene, stanene, phosphorene, molybdenite, graphane, h-BN (hexagonal boron nitride), germanane, MXenes and transition metal dichalcogenides, including for example M0S2, MoSe2 and WSe2. MXenes are layered transition metal carbides and carbonitrides with a general formula of Mn + iXnTx, where M stands for early transition metal, X stands for carbon and / or nitrogen and Tx stands for surface terminations (mostly = 0, -OH or -F). The incorporation into the freestanding membrane 14 or one or more layers of a two-dimensional material other than graph can provide various benefits. Firstly, the one or more layers of a two-dimensional material other than graph can be used to control (e.g., reduce) etching by radicals (such as H * and OH *) during use of the pellicle in lithography. The control of etching improves pellicle reliability and performance. Secondly, the one or more layers of two-dimensional material other than graphene can provide additional mechanical strength to the freestanding membrane 14. The additional mechanical strength improves pellicle robustness and lifetime. Phosphorene, an analog or graphene where every C atom is a P atom, can sustain tensile strain up to 30% and is chemically inert. Phosphorene is particularly well suited to being incorporated into the freestanding membrane 14 to provide additional mechanical strength to the freestanding membrane 14. Thirdly, the one or more layers of a two-dimensional material other than graphene can improve the thermal properties of the freestanding membrane 14. The improvement may include reducing a heat load on the freestanding membrane 14 during use, for example by improving DUV emission characteristics. h-BN is particularly well suited to this application. h-BN has a bandgap or about 6 eV, which allows DUV emission. h-BN is also chemically inert and thermally stable up to 1500 K. Furthermore, there is a good atomic lattice match between h-BN and other two-dimensional materials (including graphene), which favors epitaxial growth or stacks including graphene starting from a two-dimensional material such as h-BN. Figures 71-73 illustrate three different modes of incorporation or at least one layer or a two-dimensional material other than graphene 700 into the freestanding membrane 14. Figure 71 depicts an arrangement in which a sequence of layers is provided that comprises an alternating sequence or at least one graphene layer 2 alternating with at least one layer or a two-dimensional material other than graphene 700. Thus one or more layers or graphene 2 are followed by one or more layers of a different two-dimensional material 700 which are in turn followed by one or more layers of graphene 2, etc. Arrangements of this type may protect the least one graphene layer 2 from chemical attack from radicals, provide additional mechanical strength to the freestanding membrane 14 and / or improve the thermal properties of the freestanding membrane 14. Figure 72 depicts an arrangement in which layers of two-dimensional material other than graphene are provided as capping layers on the outside of the freestanding membrane 14. Arrangements of this type are particularly well suited to protecting the least one graphene layer 2 from chemical attack from radicals. Figure 73 depicts an arrangement in which at least one layer of a two-dimensional material other than graphene 700 is sandwiched between at least one layer of graphene 2 on one side and at least one layer of graphene 2 on the other side. Arrangements of this type are particularly well suited to providing additional mechanical strength and / or controlling etching or the freestanding membrane 14 during use. [00231] Each of the layers in the arrangements of Figures 71-73 (and in other arrangements including graphene layers and layers of two-dimensional materials other than graphene) can be formed in a variety of different ways, including CVD, ALD, PVD or any other deposition technique suitable for the selected material. In any of the described described, the least one graphene layer 2 may be replaced with at least one layer or a two-dimensional material other than graphene. A pellicle may be provided for example that comprises a freestanding membrane 14 comprising at least one layer of a two-dimensional material other than graphene, and optionally containing no graphene. The least one layer of a two-dimensional material other than graphene comprises at least one layer of one or more of the following: graphyne, borophene, silicene, stanene, phosphorene, molybdenite, graphane, h-BN, germanane, an MXene, a transition metal dichalcogenide, MOS2, MoSe2, WSe2. In any of the described described, the pellicle may be attached to a frame arranged to provide additional support to the free-standing membrane. The pellicle attached to the frame form a pellicle assembly. The pellicle assembly may be permanently or releasably attached to a patterning device, such as a lithographic mask, forming a mask assembly. Although specific reference may be made in this text to the use of lithographic apparatus in the manufacture of ICs, it should be understood that the lithographic apparatus described may have other applications, such as the manufacture of integrated optical systems, guidance and detection patterns for magnetic domain memories, flat-panel displays, LCDs, thin-film magnetic heads, etc. The substrate referred to may be processed, before or after exposure, in a track example (a tool that typically applies to a layer) or resist to a substrate and develops the exposed resist), a metrology tool and / or an inspection tool. Where applicable, the disclosure may be applied to such and other substrate processing tools. Further, the substrate may be processed more than once, for example in order to create a multi-layer IC, so the term substrate used may also refer to a substrate that already contains multiple processed layers. While specific according to the invention have been described above, it will be appreciated that the invention may be practiced otherwise than as described. For example, the various lacquer layers may be replaced by non-lacquer layers that perform the same function. The descriptions above are intended to be illustrative, not limiting. Thus it will be apparent to one skilled in the art that modifications may be made to the invention as described without departing from the scope or the clauses set out below. Other aspects of the invention are set out as in the following numbered clauses: 1. A method of manufacturing a pellicle for a lithographic apparatus, including: depositing at least one graphene layer on a planar surface of a substrate, including the substrate comprises a first substrate portion and a second substrate portion; and removing the first substrate portion to form a freestanding membrane from the at least one graphene layer, the freestanding membrane being supported by the second substrate portion. 2. The method of clause 1, where the first substrate portion is surrounded by the second substrate portion when viewed in a perpendicular direction to the planar surface of the substrate. 3. The method of any preceding clause in which the freestanding membrane is at least 80% transparent to radiation having a wavelength or 13.5 nm. 4. The method of any preceding clause when viewed in a direction perpendicular to the planar surface of the substrate the freestanding membrane has a surface area or at least 1 mm2. 5. The method of any preceding clause, the least one graphene layer comprising a variety of graphene layers. 6. The method of any preceding clause, where the freestanding membrane comprises a portion of the least one graphene layer and at least one additional layer on an upper surface or a lower surface of the least one graphene layer. 7. The method of any preceding clause, including a stack including the least one graphene layer and the substrate is coated with an encapsulation layer or sacrificial layer about at least a front and a side surface of the stack during the removing of the first substrate portion. 8. The method of any preceding clause, the first substrate portion is removed by selective etching or the substrate. 9. The method of any preceding clause, which is the least one graphene layer, is deposited using chemical vapor deposition. 10. The method of any preceding clause, where: the substrate comprises a base layer and a graphene support layer; the least one graphene layer is deposited on the graphene support layer. 11. The method of clause 10, the graphene support layer comprises one or more of the following: Mo, Ni, Ru, Pt, Cu, Ti, V, Zr, Nb, Hf, Ta, W, Cr, silicized Mo , silicized Ni, silicized Ru, silicized Pt, silicized Cu, silicized Ti, silicized V, silicized Zr, silicized Nb, silicized Hf, silicized Ta, silicized W, silicized Cr, carbide or Mo, carbide or Ni, carbide or Ru, carbide or Pt, carbide or Cu, carbide or Ti, carbide or V, carbide or Zr, carbide or Nb, carbide or Hf, carbide or Ta, carbide or W, carbide or Cr. 12. The method of clause 10 or 11, comprising: a stack including the least one graphene layer and the substrate comprising an encapsulation layer or sacrificial layer coated over at least a front and a side surface of the stack during the removing of the first substrate portion; and the graphene support layer is formed after the encapsulation layer or sacrificial layer is formed. 13. The method of clause 12, the encapsulation layer or sacrificial layer is formed using LPCVD and the graphene support layer comprises Mo or silicized Mo. 14. The method of any of clauses 10-13, the removing of the first substrate portion to form the freestanding membrane comprising a step or removing a portion of the graphene support layer using a vapor etching process. 15. The method of any preceding clause, where: the substrate comprises a base layer and a first graphene support layer; the least one graphene layer is deposited on the first graphene support layer; and a second graphene support layer is deposited on the least one graphene layer. 16. The method of clause 15, the first graphene support layer and the second graphene support layer have the same composition. 17. The method of any preceding clause, providing a control layer is provided over a portion of the least one graphene layer outside of the freestanding membrane, when viewed in a perpendicular direction to the planar surface of the substrate, the control layer being usable to control a tension in the freestanding membrane. 18. The method of any preceding clause, where: the substrate comprises a base layer and a graphene support layer; the least one graphene layer is deposited on the graphene support layer; and the method comprises the following steps in order: removing a first portion of the graphene support layer without removing a portion of the at least one graphene layer that was deposited on the first portion of the graphene support layer; depositing a control layer above the at least one graphene layer; removing a second portion of the graphene support layer, causing weakening or removal of adhesion between the at least one graphene layer and layers which were positioned above the second portion of the graphene support layer; and lifting off said layers which were positioned above the second portion of the graphene support layer, forming the freestanding membrane. 19. The method of clause 18, whether the removing or either or both of the first portion of the graphene support layer and the second portion of the graphene support layer is performed using side etching. 20. The method of any of clauses 17-19, further including processing the control layer to change an internal structure or the control layer and change a tension in the freestanding membrane. 21. The method of any preceding clause, the pellicle is configured to protect an optical element in a lithographic apparatus. 22. The method of any preceding clause, the freestanding membrane is configured to span continuously across a patterning device in a lithographic apparatus. 23. The method of any preceding clause, further comprising forming two or more conductive contact regions positioned to allow an electrical current to be driven through the freestanding membrane via the two or more conductive contact regions. 24. The method of any preceding clause, where a catalytically active metal which promotes the conversion of carbon to single or multilayer graphene is provided within or in contact with the least one graphene layer. 25. The method of clause 24, where the catalytically active metal comprises a transition metal. 26. The method of clause 24 or 25, catalytically active metal is provided via one or more of the following: doping of the least one graphene layer by atoms of catalytically active metal, formation of a layer of catalytically active metal within the at least one graphene layer, formation of a layer of the catalytically active metal on one or both sides of the at least one graphene layer, and inclusion of nanoparticles or the catalytically active metal within the least one graphene layer. 27. The method of any of clauses 24-26, where the catalytically active metal is provided by performing the depositing or the least one graphene layer in the presence of a vapor or the catalytically active metal. 28. The method of any preceding clause, further comprising processing the substrate to deform the planar surface of the substrate after deposition or the least one graphene layer, changing a tension in the freestanding membrane. 29. The method of clause 28, the processing of the substrate causes the substrate to bow inwards on the side of the substrate on which the least one graphene layer has been deposited, applying a compressive force to the least one graphene layer , or causes the substrate to bow outwards on the side of the substrate on which the least one graphene layer has been deposited, applying a tensile force to the least one graphene layer. 30. The method of clause 28 or 29, the processing of the substrate comprises applying heating or cooling non-uniformly to the substrate. 31. The method of any preceding clause, the freestanding membrane is formed with a capping layer on either or both sides or the least one graphene layer. 32. The method of clause 31, the capping layer is configured to protect the least one graphene layer from chemical attack by radical species. 33. The method of clause 31 or 32, in which the capping layer comprises a metal or metal oxide. 34. The method of clause 33, the capping layer comprises one or more materials selected from the following group: Ru, Mo, B, M0S12, h-BN, HfCT, ZrCT, Y2O3, La 2 O 3, and Al 2 O 3. 35. The method of any of clauses 31-34, where the capping layer is formed by atomic layer deposition. 36. The method of any of clauses 31-35, where an adhesion layer is provided between the capping layer and the least one graphene layer. 37. The method of clause 36, where the adhesion layer comprises a material having sp2-bonded carbon and hydrophilic groups. 38. The method of clause 35 or 36, comprising the adhesion layer comprising amorphous carbon. 39. The method of clause 38, including the amorphous carbon is partly oxidized. 40. The method of any preceding clause, the freestanding membrane comprising a sequence of layers having different chemical compositions, the sequence comprising the least one graphene layer and at least one layer or a two-dimensional material other than graphene. 41. The method of clause 40, the sequence of layers comprises an alternating sequence or at least one graphene layer alternating with at least one layer or a two-dimensional material other than graphene. 42. The method of clause 40 or 41, comprising the sequence of layers comprises at least one layer of a two-dimensional material other than graphene sandwiched between at least one layer or graphene on one side and at least one layer or graphene on the other side. 43. The method of any of clauses 31-39, the capping layer comprises at least one layer or a two-dimensional material other than graphene. 44. The method of any of clauses 40-43, according to the least one layer of a two-dimensional material other than graphene comprises at least one layer or one or more of the following: graphyne, borophene, silicene, stanene, phosphorene, molybdenite, graphane, h-BN, germanane, an MXene, a transition metal dichalcogenide, MOS2, MoSe2, WSe2. 45. A method of manufacturing a pellicle for a lithographic apparatus, including: transferring at least one graphene layer from a surface of a liquid to a frame containing an opening, forming a freestanding membrane from the least one graphene layer, the freestanding membrane tension the opening and being supported by the frame, being a portion of the frame in contact with the least one graphene layer is hydrophobic. 46. A method of manufacturing a pellicle for a lithographic apparatus, including: transferring at least one graphene layer from a surface of a liquid to a frame including an opening, forming a freestanding membrane from the least one graphene layer, the freestanding membrane tension the opening and being supported by the frame, the liquid has a temperature in the range of 25-80 degrees Celsius during the transfer of the least one graphene layer to the frame. 47. A method of manufacturing a pellicle for a lithographic apparatus, including: transferring at least one graphene layer from a surface of a liquid to a frame containing an opening, forming a freestanding membrane from the least one graphene layer, the freestanding membrane tension the opening and being supported by the frame, containing the liquid comprises water, an alcohol, and a further solvent that is not an alcohol. 48. The method of clause 47, the further solvent is such as to reduce the likelihood of, or prevent, formation of a droplet of the liquid that completely spans the opening in the frame, after transfer or the least one graphene layer to the frame, relative to if the further solvent were not present in the liquid. 49. A pellicle for a lithographic apparatus, including at least one graphene layer forming a freestanding membrane supported by a planar surface or a portion of a substrate on which the graphene layer was grown, said planar surface being located outside of the freestanding membrane when viewed in a direction perpendicular to the planar surface. 50. The pellicle of clause 49, the least one graphene layer is a layer formed by chemical vapor deposition on the substrate. 51. The pellicle of clause 49 or 50 configured to protect an optical element in a lithographic apparatus. 52. The pellicle of any of clauses 49-51 configured to span continuously across a patterning device in a lithographic apparatus. 53. The pellicle of any of clauses 49-52, the freestanding membrane comprising a capping layer on either or both sides of the least graphene layer. 54. The pellicle of clause 53, the capping layer is configured to protect the least one graphene layer from chemical attack by radical species. 55. The pellicle of clause 53 or 54, in which the capping layer comprises a metal or metal oxide. 56. The pellicle of clause 55, the capping layer comprises one or more materials selected from the following group: Ru, Mo, B, MOS12, h-BN, HfCT, ZrCT, Y2O3, Nb2 () 5. La 2 O 3, and Al 2 O 3. 57. The pellicle of any of clauses 53-56, the capping layer is formed by atomic layer deposition. 58. The pellicle of any of clauses 53-57, where an adhesion layer is provided between the capping layer and the least one graphene layer. 59. The pellicle of clause 58, containing the adhesion layer comprises a material having sp2-bonded carbon and hydrophilic groups. 60. The pellicle of clause 58 or 59, containing the adhesion layer comprising amorphous carbon. 61. The pellicle of clause 60, including the amorphous carbon is partly oxidized. 62. The pellicle of any of clauses 49-61, the freestanding membrane comprising a sequence of layers having different chemical compositions, the sequence comprising the least one graphene layer and at least one layer or a two-dimensional material other than graphene . 63. The pellicle of clause 62, the sequence of layers comprises an alternating sequence or at least one graphene layer alternating with at least one layer or a two-dimensional material other than graphene. 64. The pellicle of clause 62 or 63, the sequence of layers comprises at least one layer of a two-dimensional material other than graphene sandwiched between at least one layer or graphene on one side and at least one layer or graphene on the other side. 65. The pellicle of any of clauses 53-61, the capping layer comprises at least one layer or a two-dimensional material other than graphene. 66. The pellicle of any of clauses 62-65, which is the least one layer of a two-dimensional material other than graphene comprises at least one layer or one or more of the following: graphyne, borophene, silicene, stanene, phosphorene, molybdenite, graphane, h-BN, germanane, an MXene, a transition metal dichalcogenide, MOS2, MoSe2, WSe2. 67. A lithographic apparatus including: a patterning device configured to impart a pattern to a beam of radiation; and a pellicle manufactured by the method of any of clauses 1-48 and configured to protect the patterning device. 68. A lithographic apparatus including: a patterning device configured to impart a pattern to a beam of radiation; and the pellicle or any of clauses 49-66 configured to protect the patterning device. 69. A device manufacturing method including using the lithographic apparatus or clause 67 or 68 to manufacture a device using lithography. 70. A pellicle available or obtained by the manufacturing method or any of clauses 1 to 48. 71. A pellicle comprising a membrane bonded to a membrane support, wherein: the membrane comprises a graphene layer; and the membrane is bonded to and created on the membrane support with a thin film deposition process. 72. The pellicle of clause 71, the bond is an intrinsic bond between the membrane and the membrane support induced by the thin film deposition process or the membrane onto the membrane support. 73. The pellicle of clause 72, the intrinsic bonding has a bonding strength such that the membrane remains bonded to the membrane support under a gravity force acting on the membrane. 74. The pellicle of any of clauses 71 to 73, the thin film deposition process is a chemical vapor deposition process. 75. A device manufacturing method including: using a patterning device to impart a pattern to a beam of radiation; using a pellicle including at least one graphene layer forming a freestanding membrane to protect the patterning device; and passing an electrical current through the at least one graphene layer to heat the at least one graphene layer. 76. The method of clause 75, which is the least one graphene layer is heated to a temperature at which conversion of carbon to single or multilayer graphene is thermally activated. 77. The method of clause 75 or 76, the least one graphene layer is heated to above 800K. 78. The method of any of clauses 75-77, further including applying a flow or material including a source or carbon onto the pellicle. 79. An apparatus for processing a pellicle, the pellicle including at least one graphene layer forming a freestanding membrane, the apparatus including: a current driving apparatus for driving an electrical current through the freestanding membrane to heat the freestanding membrane. 80. The apparatus of clause 79, further including a supply port for applying a flow or material including a source or carbon onto the pellicle. 81. The apparatus of clause 80, further including an enclosure for containing the pellicle during processing of the pellicle, the supply port is configured to convey the flow of material including the source of carbon from the outside of the enclosure to the inside of the enclosure. 82. The apparatus of any of clauses 79-81, where the pellicle is available or obtained by the manufacturing method or any of clauses 1 to 48. 83. A method of processing a pellicle, the pellicle including at least one graphene layer forming a freestanding membrane, the method including driving an electrical current through the freestanding membrane to heat the freestanding membrane. 84. The method of clause 83, further including applying a flow of material including a source of carbon onto the pellicle during the heating of the freestanding membrane by the electrical current. 85. The method of clause 83 or 84, wherein the pellicle is available or obtained by the manufacturing method or any of clauses 1 to 48. 86. A method of processing a pellicle, the pellicle including at least one graphene layer forming a freestanding membrane , the method including using electrochemical deposition to apply carbon to the least one graphene layer. 87. A pellicle comprising a freestanding membrane, the freestanding membrane comprising at least one layer of a two-dimensional material other than graphene. 88. A pellicle according to clause 87, the freestanding membrane is supported by a planar surface or a portion of a substrate on which the freestanding membrane was grown, said planar surface being located outside of the freestanding membrane when viewed in a direction perpendicular to the planar surface. 89. A pellicle according to clause 87, the freestanding membrane is bonded to a membrane support, the freestanding membrane is bonded to and created on the membrane support with a thin film deposition process. 90. The pellicle of clause 87 to 89, containing the least one layer of a two-dimensional material other than graphene comprising least layer of one or more of the following: graphyne, borophene, silicene, stanene, phosphorene, molybdenite, graphane, h-BN, germanane, an MXene, a transition metal dichalcogenide, MOS2, MoSe2, WSe2. 91. A method of manufacturing a pellicle for a lithographic apparatus, including: depositing at least one layer of a two-dimensional material on a planar surface of a substrate, containing the substrate comprising a first substrate portion and a second substrate portion; and removing the first substrate portion to form a freestanding membrane from the at least one layer of a two-dimensional material, the freestanding membrane being supported by the second substrate portion. 92. A pellicle assembly suitable for use in a lithographic process, the pellicle assembly including: a pellicle according to any one of clauses 49 to 66 or 87 to 90; and a frame configured to support the pellicle. 93. A mask assembly suitable for use in a lithographic process, including the mask assembly: a patterning device; a pellicle according to any one or clauses 49 to 66 or 87 to 90; and a frame configured to support the pellicle.
权利要求:
Claims (1) [1] A lithography device comprising: an exposure device adapted to provide a radiation beam; a carrier constructed to support a patterning device, the patterning device being capable of applying a pattern in a section of the radiation beam to form a patterned radiation beam; a substrate table constructed to support a substrate; and a projection device adapted to project the patterned radiation beam onto a target area of the substrate, characterized in that the substrate table is adapted to position the target area of the substrate in a focal plane of the projection device.
类似技术:
公开号 | 公开日 | 专利标题 US20190056654A1|2019-02-21|Method of manufacturing a pellicle for a lithographic apparatus, a pellicle for a lithographic apparatus, a lithographic apparatus, a device manufacturing method, an apparatus for processing a pellicle, and a method for processing a pellicle JP2018531426A6|2018-12-13|Method for manufacturing a pellicle for a lithographic apparatus, pellicle for a lithographic apparatus, lithographic apparatus, device manufacturing method, apparatus for processing a pellicle, and method for processing a pellicle JP6253641B2|2017-12-27|Reflector, pellicle, lithography mask, film, spectral purity filter, and apparatus EP2465012B1|2012-12-12|Lithographic apparatus and method CN108351586B|2022-01-14|Method for manufacturing a diaphragm assembly US20210311385A1|2021-10-07|Method for manufacturing a membrane assembly JP5727590B2|2015-06-03|Spectral purity filter JP2013526044A5|2014-04-10| Nam et al.2021|Fabrication of extreme ultraviolet lithography pellicle with nanometer-thick graphite film by sublimation of camphor supporting layer
同族专利:
公开号 | 公开日 JP2018531426A|2018-10-25| KR20180072786A|2018-06-29| CN108431693A|2018-08-21| TW201725178A|2017-07-16| US20190056654A1|2019-02-21| EP3365730A2|2018-08-29| CN108431693B|2021-10-01| JP6784757B2|2020-11-11| WO2017067813A3|2017-06-01| WO2017067813A2|2017-04-27| CA3002702A1|2017-04-27|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题 US2502533A|1943-05-10|1950-04-04|Quercia Marcel|Ignition device for lighters and like apparatus| US7449133B2|2006-06-13|2008-11-11|Unidym, Inc.|Graphene film as transparent and electrically conducting material| US20110200787A1|2010-01-26|2011-08-18|The Regents Of The University Of California|Suspended Thin Film Structures| US8494119B2|2010-06-18|2013-07-23|Oxford Instruments Analytical Oy|Radiation window, and a method for its manufacturing| WO2011160861A1|2010-06-25|2011-12-29|Asml Netherlands B.V.|Lithographic apparatus and method| JP6116128B2|2011-04-11|2017-04-19|エーエスエムエル ネザーランズ ビー.ブイ.|Lithographic apparatus and method| KR20130088565A|2012-01-31|2013-08-08|주식회사 에프에스티|Euv pellicle uging graphene and manufacturing method of the same| US20130250260A1|2012-03-23|2013-09-26|Globalfoundries Inc.|Pellicles for use during euv photolithography processes| KR102040720B1|2012-05-21|2019-11-05|에이에스엠엘 네델란즈 비.브이.|Lithographic apparatus| DE102012107342B4|2012-08-09|2019-10-10|Ketek Gmbh|X-ray transmission window for a radiation detector, radiation detector with such an X-ray transmission window and method for producing an X-ray transmission window| JP5711703B2|2012-09-03|2015-05-07|信越化学工業株式会社|EUV pellicle| WO2014202585A2|2013-06-18|2014-12-24|Asml Netherlands B.V.|Lithographic method| TWI658321B|2013-12-05|2019-05-01|荷蘭商Asml荷蘭公司|Apparatus and method for manufacturing a pellicle, and a pellicle| US9140975B2|2013-12-13|2015-09-22|Globalfoundries Inc.|EUV pellicle frame with holes and method of forming| KR102251999B1|2015-01-09|2021-05-17|삼성전자주식회사|Pellicle and method of manufacturing the same| EP3291006A4|2015-04-27|2019-01-23|Mitsui Chemicals, Inc.|Pellicle manufacturing method and method for manufacturing photomask with pellicle| US20170090278A1|2015-09-30|2017-03-30|G-Force Nanotechnology Ltd.|Euv pellicle film and manufacturing method thereof|US10217819B2|2015-05-20|2019-02-26|Samsung Electronics Co., Ltd.|Semiconductor device including metal-2 dimensional material-semiconductor contact| KR101813185B1|2016-06-30|2018-01-30|삼성전자주식회사|Pellicle for photomask and exposure apparatus including the pellicle| KR101813186B1|2016-11-30|2017-12-28|삼성전자주식회사|Pellicle for photomask, reticle including the same and exposure apparatus for lithography| KR102330943B1|2017-03-10|2021-11-25|삼성전자주식회사|Pellicle for photomask, reticle including the same and exposure apparatus for lithography| US10996556B2|2017-07-31|2021-05-04|Samsung Electronics Co., Ltd.|Pellicles for photomasks, reticles including the photomasks, and methods of manufacturing the pellicles| EP3662324A1|2017-08-03|2020-06-10|ASML Netherlands B.V.|Simultaneous double-side coating of multilayer graphene pellicle by local thermal processing| US10636614B2|2018-01-08|2020-04-28|Moxtek, Inc.|Boron x-ray window| KR102264112B1|2018-11-28|2021-06-11|성균관대학교산학협력단|Pellicle structure and method of manufacturing the pellicle structure| EP3671342B1|2018-12-20|2021-03-17|IMEC vzw|Induced stress for euv pellicle tensioning| WO2020126950A1|2018-12-20|2020-06-25|Asml Netherlands B.V.|Method of manufacturing a membrane assembly| CN109830381B|2019-04-04|2021-01-19|兰州理工大学|MXene/MoS for supercapacitor electrodes2Method for preparing composite material| WO2021007004A2|2019-06-26|2021-01-14|Northwestern University|Borophene-based two-dimensional heterostructures, fabricating methods and applications of same| WO2021018777A1|2019-07-30|2021-02-04|Asml Netherlands B.V.|Pellicle membrane| KR20210119055A|2020-03-24|2021-10-05|한국전자기술연구원|Graphene-metal composite pellicle and manufacturing method thereof| KR102247692B1|2020-08-19|2021-04-30|성균관대학교산학협력단|Pellicle structure and method of manufacturing the pellicle structure| CN112023702B|2020-09-07|2022-02-08|湖北中烟工业有限责任公司|Hydroxylated boron nitride composite film and preparation method and application thereof| KR102282184B1|2020-11-11|2021-07-28|한국전자기술연구원|Multilayer graphene direct growth method and method for manufacturing pellicle for extreme ultraviolet lithography using the same|
法律状态:
优先权:
[返回顶部]
申请号 | 申请日 | 专利标题 EP15191052|2015-10-22| EP16156637|2016-02-22| EP16170384|2016-05-19| EP16186851|2016-09-01| 相关专利
Sulfonates, polymers, resist compositions and patterning process
Washing machine
Washing machine
Device for fixture finishing and tension adjusting of membrane
Structure for Equipping Band in a Plane Cathode Ray Tube
Process for preparation of 7 alpha-carboxyl 9, 11-epoxy steroids and intermediates useful therein an
国家/地区
|