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    • 专利摘要:
    There is disclosed a lead-free Au-Sn-Ag-based high-temperature solder alloy which is excellent in sealing ability, bonding safety and wettability and which can be stored at a high quality level for a long period of time and can be provided at a relatively low cost. The lead-free Au-Sn-Ag based brazing alloy contains at least 27.5 mass%, but less than 33.0 mass% of Sn, at least 8.0 mass%, but less than 14.5 mass% of Ag, the remainder Au excluding elements which inevitably occur during production. In the case of a plate-like or band-like shape, the Au-Sn-Ag-based solder alloy has a surface whose L *, a * and b * in a L * a * b * color system according to JIS Z8781-4 at least 41.1 to at most 57.1 , be at least -1.48 to at most 0.52 or at least -4.8 to at most 9.2. In the case of a spherical shape, the Au-Sn-Ag-based solder alloy has a surface whose L *, a * and b * in a L * a * b * color system according to JIS Z8781-4 is at least 63.9 to at most 75.9, at least 0.05 to a maximum of 0.65 or at least 1.3 to a maximum of 11.3.
    公开号:CH710360A2
    申请号:CH01418/15
    申请日:2015-09-30
    公开日:2016-05-13
    发明作者:Lseki Takashi
    申请人:Sumitomo Metal Mining Co;
    IPC主号:
    专利说明:

    Technical area
    The present invention relates to a high-temperature lead-free solder alloy mainly containing Au, an electronic component sealed or bonded using the solder alloy, and an electronic device equipped with the electronic component.
    State of the art
    In recent years, restrictions on environmentally harmful chemical substances have become increasingly strict, and solder materials which are used for connecting an electronic component or the like to a substrate are not exempt from these restrictions. Lead (Pb) was used as a main component of solder materials in the past, but has now been specified as a prohibited substance in the RoHS directives, for example. Accordingly, there has been an active development of solder materials that do not contain lead (also referred to here as Pb-free solders).
    Solders that are used to connect an electronic component to a substrate can be roughly divided into high-temperature solders (approximately 260 ° C to 400 ° C) and low and medium-temperature solders (approximately 140 ° C to 230 ° C), depending on their application temperature limits ° C). In the case of the low and medium temperature solders, lead-free solders, which mainly contain Sn, have already been introduced for practical use. For example, JP 11-077 366 A, as a low and medium temperature lead-free solder material, discloses a lead-free solder alloy composition which contains Sn as a main component, 1.0 to 4.0 mass% of Ag, at most 2.0 mass% of Cu, at most 1.0 mass% of Ni and contains no more than 0.2 mass% of P. JP 8-215 880 A discloses a lead-free solder alloy composition which contains 0.5 to 3.5 mass% of Ag, 0.5 to 2.0 mass% of Cu, the balance being Sn.
    On the other hand, Pb-free high-temperature solders have also been investigated and developed by various organizations. For example, JP 2002-160 089 discloses a Bi / Ag solder material which contains 30 to 80 at% of Bi and has a melting temperature of 350 to 500 ° C. JP 2008-161 913 A discloses a solder alloy which is obtained by adding a binary eutectic alloy to a Bi-containing eutectic alloy with further addition of an additive element. JP 2008-161 913 A states that although this solder alloy is a multi-component solder of quaternary or higher order, its liquidus line temperature can be adjusted and its variations can be reduced.
    As an expensive Pb-free high-temperature solder material mainly containing Au, an Au-Sn- is used in electronic parts including an electronic component such as a crystal part, a SAW filter or a MEMS (microelectromechanical system). Alloy or an Au-Ge alloy is used. The eutectic composition of the Au-Sn alloy is Au-20 mass% Sn (which means a composition containing 80 mass% of Au and 20 mass% of Sn, analogous to that below), and its melting point is 280 ° C. The eutectic composition of the Au-Ge alloy is Au-12.5 mass% Ge and its melting point is 356 ° C.
    For the respective use, the selection of either the Au-Sn alloy or the Au-Ge alloy depends mainly on the difference in their melting points. More specifically, the Au-Sn alloy is used for joining at a relatively low application temperature within an application temperature range of high temperature solders, while the Au-Ge alloy is used for joining at a relatively high application temperature within the application temperature range. However, these Au-based alloys are much harder than Pb- or Sn-based solders. In particular, the Au-Ge alloy contains Ge, which is a semimetal, and accordingly it is very difficult to work it into a sheet shape or the like. As a result, it is difficult to increase productivity or yield, and accordingly the product cost will increase.
    The Au-Sn alloy is also difficult to process, albeit not to the same extent as the Au-Ge alloy mentioned above. In particular, when the Au-Sn alloy is processed into a preform or the like, productivity or yield tends to be low. The reasons for this are that even if Au-20 mass% Sn is a eutectic composition, the Au-20 mass% Sn alloy consists only of an intermetallic compound and accordingly, dislocation is difficult to move. Accordingly, it becomes difficult to deform the Au-20 mass% Sn alloy, and accordingly, cracks or burrs are likely to develop during rolling or press punching. In addition, the material costs for the Au-20 mass% Sn alloy are orders of magnitude higher than for other solder materials. Accordingly, there is a fact that the Au-20 mass% Sn alloy is mainly used for sealing crystal members or the like which require particularly high reliability.
    In order to reduce the cost of the Au-Sn alloy as much as possible and to make the Au-Sn alloy easier to use, Au-Sn-Ag-based solder alloys have been developed. For example, JP 2008-155 221 A discloses a technique using a solder material to provide an inexpensive solder material having a relatively low melting point and a piezoelectric component using the solder material, the solder material having the properties of easy handling and excellent strength as well as excellent adhesiveness having. When the composition ratio of the solder material is expressed as (Au, Ag, Sn) in mass%, the solder material has a composition ratio within an area ranging from a point A1 (41.8, 7.6, 50.5), a point A2 (62.6, 3.4, 34.0), a point A3 (75.7, 3.2, 21.1), a point A4 (53.6, 22.1, 24.3), and a point A5 (30.3, 33.2, 36.6) in the ternary composition diagram is surrounded by Au, Ag, and Sn.
    In addition, Japanese Patent No. 4,305,511 discloses a technique to provide a high temperature lead-free solder alloy for melt sealing which contains 2 to 12 mass% of Ag, 40 to 55 mass% of Au and the balance Sn . This technique is aimed at providing a lead-free high-temperature solder which has a lower Au content than that of a conventional electrical Au-Sn alloy and at the same time has a solidus line temperature of at least 270 ° C, or to provide a package that has excellent heat cycle resistance or mechanical strength of the joint between a container and its cover member.
    In addition, Japanese Patent No. 2,670,098 discloses a technique to prepare a solder material prepared by adding 20 to 50% by weight of Au and 10 to 20% by weight of Ge or 20 to 40% by weight. -% of Sn to Ag is obtained to be attached to a pin tip of a lead frame. This technique is aimed at providing a lead frame with a solder material with a low melting point such that the solder material flows as desired to stabilize the strength of the connection without making an Fe-Ni alloy lead frame brittle and without reducing the corrosion resistance of the lead frame .
    Other high-temperature lead-free solder materials than those disclosed in the documents cited above have also been developed by various organizations, but an inexpensive general-purpose solder material has not yet been found. More specifically, an electronic component or a substrate generally uses a material having a relatively low upper temperature limit such as a thermoplastic resin or a thermosetting resin, and accordingly the working temperature must be lower than 400 ° C, desirably 370 ° C or less. The Bi / Ag solder material disclosed in JP 2002-160 089 A, however, has a liquidus line temperature which can be 400 to 700 ° C., and accordingly it can be assumed that the working temperature during the connection is also 400 to 700 ° C. or higher. Accordingly, the working temperature exceeds the upper temperature limit of an electronic component or substrate to be connected.
    Au-Sn-based solder or Au-Ge-based solder uses very expensive Au in large quantities and is accordingly much more expensive than the general-purpose Pb- or -Sn-based solder. Although Au-Sn-based solder or Au-Ge-based solder has found practical use, its field of application for soldering is limited to electronic components that require particularly high reliability, for example crystal components, SAW filters or MEMS. In addition, Au-based solder is very hard and difficult to process. Accordingly, it takes longer to process Au-based solder into a sheet shape by rolling, or it is necessary to use rollers made of a special scratch-resistant material, thus increasing the production cost. In addition, when press-molding Au-based solder, it is expected that scratches or burrs will form due to its hard and brittle nature, resulting in a considerable reduction in yield compared to other common solders that are press-formed. Processing Au-based solder into a wire shape also involves a similar serious problem. That is, even if an extruder which allows extrusion at a very high pressure is used, the extrusion rate of Au-based solder is low because of its hardness, and accordingly the related productivity is only about several hundredths of that when Pb- based solder is processed into a wire shape.
    In order to solve this problem of poor workability of Au-based solder, efforts have been made to develop an Au-based solder paste. However, the Au-based solder paste may have other problems such as pore formation or an additional increase in cost. The Au-Sn-Ag-based solder alloys disclosed in JP 2008-155 221 A, Japanese Patent No. 4,305,511 and Japanese Patent No. 2,670,098 have been developed to solve various problems of the Au-based solder, including the to solve the above-described problems of melting point, processability and cost. However, it is considered difficult to achieve the desired properties to a similar extent in the entire surface area which - as described in JP 2008-155 221 A - is surrounded by points A1 to A5, because this surface area has an extremely large range of compositions covers.
    For example, the difference in the Au content between the point A3 and the point A5 is a considerable 45.4 mass%. If the compositions of these two solder alloys differ to this extent, the intermetallic compounds to be formed are very different from one another, and thus the liquidus line temperatures or solidus line temperatures are significantly different from one another. In addition, if the difference in the Au content, which prevents oxidation, is as large as 45.4 mass%, the wettability of the solder alloys differ significantly from one another. As can be seen from the ternary phase diagram of Au-Sn-Ag shown in Fig. 1, the Au-Sn-Ag intermetallic compound varies significantly when the composition of Au, Sn, and Ag vary. That is, when the composition of Au, Sn and Ag varies, the kind or ratio of an intermetallic compound formed upon joining also varies significantly. Accordingly, similarly excellent workability and stress relaxation properties are unlikely to be achieved in such a broad composition range as described in JP 2008-155 221 A.
    In Japanese Patent No. 4,305,511, the Ag content is 2 to 12 mass% and the Au content is 40 to 55 mass%, and accordingly the balance is Sn at 33 to 58 mass% . A solder alloy with such a high Sn content can be easily oxidized, which can lead to insufficient wettability. Due to the fact that the Au-20 mass% Sn alloy is used practically with no problem, there is a possibility that the wettability can be ensured as long as the Sn content is around 30 mass%. However, it may be difficult to ensure wettability if the Sn content exceeds 40 mass%. A solder alloy with an Sn content exceeding 40 mass% is not a eutectic alloy, and accordingly it is considered difficult to achieve excellent connection security because crystal grains become coarse or because of a large difference between the liquidus line temperature and the solidus line temperature. Temperature during bonding, a separate melting phenomenon occurs.
    In Japanese Patent No. 2,670,098, the Au content is at most 50 mass%, which means a significant reduction in the amount of Au used as a raw material. In addition, the wettability can be ensured to a certain extent by the fact that the Sn content is at most 40 mass% (or less than 40 mass%). The object of the present invention is to stabilize the strength of the connection by a well-flowing solder and thereby avoid the brittleness of a connection frame made of an Fe-Ni alloy without reducing the corrosion resistance of the connection frame. Japanese Patent No. 2,670,098 is therefore not directed to providing a solder material having the properties necessary for connecting a semiconductor element, which include relieving the stresses caused by temperature changes due to expansion and contraction.
    The solder material within the composition range described in Japanese Patent No. 2,670,098 is not a eutectic alloy, and accordingly, it is considered difficult to achieve excellent connection security because its crystal grains are coarse or because of a significant difference between liquidus lines. Temperature and solidus line temperature, a separate melting phenomenon occurs during bonding. In addition, the brazing material disclosed in Japanese Patent No. 2,670,098 is intended for Fe-Ni alloy application, and accordingly is not intended to be an alloy suitable for bonding to the metallic layer of a semiconductor element or a substrate made of Cu or the like form.
    SUMMARY
    In view of the above-mentioned circumstances, it is an object of the present invention to provide a comparatively inexpensive lead-free Au-Sn-Ag-based high-temperature solder alloy, which is characterized in terms of sealing ability, connection security and wettability and which has a high level of quality over a long period Period of time can be stored with small temporal changes in its various properties and which can be used in a suitable manner for a highly reliable electronic component with an electronic component such as a crystal component, a SAW filter or a MEMS.
    In order to achieve the above-mentioned object, a first aspect of the present invention relates to a plate or strip-shaped Au-Sn-Ag-based solder alloy containing at least 27.5 mass% but less than 33.0 mass% of Sn, at least 8.0 Mass% but less than 14.5 mass% of Ag, and the remainder Au with the exception of elements that inevitably arise during production, the Au-Sn-Ag-based solder alloy having a surface whose L *, a * and b * in an L * a * b * color system according to JIS Z8781-4 at least 41.1 to at most 57.1, at least –1.48 to at most 0.52 or at least –4.8 to at most 9.2.
    A second aspect of the present invention relates to a spherical Au-Sn-Ag-based solder alloy containing at least 27.5 mass% but less than 33.0 mass% of Sn, at least 8.0 mass% but less than 14.5 mass% Ag, and the remainder Au with the exception of elements that inevitably arise during production, the Au-Sn-Ag-based solder alloy having a surface whose L *, a * and b * in an L * a * b * color system according to JIS Z8781-4 at least 63.9 to at most 75.9, at least 0.05 to at most 0.65 or at least 1.3 to at most 11.3.
    According to the present invention, it is possible at a relatively low cost to provide a lead-free Au-Sn-Ag-based high-temperature solder alloy, which is characterized in terms of sealing ability, connection security and wettability and which has a high level of quality over a long period of time small changes over time in their various properties can be stored. This makes it possible to provide a solder alloy more cost-effectively than with conventional Au-based solders, which can be used for electronic components that require particularly high reliability, such as electronic components with a crystal component, SAW filter, MEMS or the like, as well as for electronic components of this type Electronic devices equipped with components.
    BRIEF DESCRIPTION OF THE DRAWINGS
    Fig. 1 is an Au-Sn-Ag ternary phase diagram; Fig. 2 is a sectional view of an arrangement in which a Si chip is connected to a Ni-plated Cu substrate by means of a solder alloy; Fig. 3 is a sectional view of an arrangement in which a solder alloy is bonded to a Ni-plated Cu substrate; 4 is a view illustrating a longer diameter (X1) and a shorter diameter (X2) which are used to define an aspect ratio and which correspond to the maximum and minimum lengths of the wetted solder, respectively, and FIG. 5 Fig. 13 is a cross-sectional view of a sealing canister sealed with a ball.
    DETAILED DESCRIPTION
    The present inventor intensively studied a lead-free solder alloy mainly containing Au, and as a result, found that an Au-Sn-Ag-based solder alloy having a basic composition close to the composition at the ternary electrical point of Au-Sn-Ag (the "Point e1" shown in the ternary phase diagram of Au-Sn-Ag in FIG. 1) has various particularly advantageous properties as lead-free Au-based solder. That is, the Au-Sn-Ag-based alloy is absolutely softer than an Au-Sn alloy if the Au-Sn-Ag-based alloy has a composition within a composition range close to the composition at the ternary eutectic point of Au, Sn and Ag in their ternary phase diagram. Accordingly, such an Au-Sn-Ag-based alloy has excellent workability or stress relaxation behavior, and can be used as a solder alloy having sufficient wettability from a practical point of view. In addition, by replacing part of the expensive Au with Sn and Ag, the Au content of the solder alloy can be significantly reduced, which enables the cost of the solder alloy to be reduced.
    More precisely, the Au-Sn-Ag-based solder alloy has, as a basic composition, a composition according to the ternary eutectic point of Au-Sn-Ag, namely Au = 57.2% by mass, Sn = 30.8% by mass, Ag = 12.0 Mass%) (Au = 43.9 at%, Sn = 39.3 at%, Ag = 16.8 at% in terms of atomic%), and accordingly, their crystal grains are fine and their crystal structure is lamellar, so that their workability and stress relaxation behavior are significantly improved . In addition, the Au-Sn-Ag-based solder alloy has a high Sn content and a high Ag content, and accordingly its Au content can be reduced, so that a high cost-reduction effect can be obtained. In addition, the Au-Sn-Ag-based solder alloy contains a large amount of Ag, which is reactive and difficult to be oxidized, and accordingly excellent wettability or connectivity can be achieved. In order to keep the properties of the surface of the solder at the preferred level, it is also important to understand and control the conditions of the solder surface. Accordingly, the surface condition of the solder alloy is specified by L *, a * and b * in an L * a * b * color system according to JIS Z8781-4.
    More precisely, the Au-Sn-Ag-based solder alloy according to the invention has a composition containing at least 27.5 mass% but less than 33.0 mass% of Sn, at least 8.0 mass% but less than 14.5 mass% of Ag, and the remainder Au with the exception of elements that inevitably arise during manufacture. In the case of a plate or strip shape, the solder alloy has a surface whose L *, a * and b * in an L * a * b * color system according to JIS Z8781-4 at least 41.1 to at most 57.1, at least -1.48 to at most 0.52 or at least –4.8 to a maximum of 9.2. In the case of a spherical shape, the solder alloy has a surface whose L *, a * and b * in an L * a * b * color system according to JIS Z8781-4 at least 63.9 to at most 75.9, at least 0.05 to at most 0.65 or at least 1.3 to not exceed 11.3. The L *, a * and b * in the L * a * b * color system and the essential elements of an embodiment of the Au-Sn-Ag-based solder alloy according to the invention are described in detail below.
    <L *, a *. b *>
    It is desirable that the surface state of the solder is always kept constant in order to keep the wettability or connectivity of the solder stable without variations. In general, the surface of a solder alloy is coated with an oxide film and impurities are weakly attached to it. Such oxide film and impurities are inevitably present, and accordingly, it is desirable to clearly understand how they are from the point of quality control. One way of doing this, for example, is to measure the oxide layer, the amount of carbon, or the components of the solder near the surface of the solder with a field emission Auger electron spectrometer or the like. However, the installation of such a measuring device in a production line is too expensive to implement. In order to keep the quality of the solder alloy constantly at a high level, it is therefore important that the surface condition of the solder can be measured in a simple manner.
    The present inventor has found that the surface of a solder alloy, which greatly affects wettability or connectivity, can be easily understood and handled by understanding and controlling the color (lightness, hue, and color saturation) on the surface of the solder alloy can. More specifically, the present inventor has found that in the case of a plate or ribbon shape of the Au-Sn-Ag-based solder alloy of the present invention, L * as indicators of lightness and a * and b * as indicators of hue and color saturation in one in JIS Z8781-4 specified L * a * b * color system should be at least 41.1 to at most 57.1, at least -1.48 to at most 0.52 or at least -4.8 to at most 9.2, and that in the case of a spherical shape of the Au-Sn-Ag-based solder alloy according to the invention L *, a * and b * in the above-mentioned L * a * b * color system should be at least 63.9 to a maximum of 75, at least 0.05 to a maximum of 0.65 or at least 1.3 to a maximum of 11.3, creating an oxide layer and impurities on the surface layer of the solder alloy, which affect the wettability or connectivity unfavorably, can be indirectly controlled in order to reduce the harmful effects caused by them in one keep acceptable range. As a result, excellent wettability or connectivity can be achieved, making it possible to achieve high connection security.
    As described above, the definition of L *, a * and b * of the Au-Sn-Ag-based solder alloy makes it possible to ensure substantially uniformly good conditions for almost the entire surface of the solder alloy, which allows to distribute a molten solder alloy evenly over an object to be connected wet and to form a uniformly solidified solder alloy that connects the object and also suppresses the formation of pores. Accordingly, high connection security can be achieved. Since the quality of the Au-Sn-Ag-based solder alloy can be stably maintained at a high level in this way, a cost advantage can be obtained due to an increase in yield or productivity.
    In addition, the surface of the Au-Sn-Ag-based solder alloy can be made clean to some extent by controlling the oxide film and the impurities on the surface, and accordingly, oxidation or corrosion is less likely to proceed Au-Sn-Ag-based solder alloy also has excellent storage stability or corrosion resistance. In other words, if the surface of the solder continues to oxidize, or if large amounts of contaminants from an earlier manufacturing stage adhere to the surface of the solder, the oxidation or corrosion is likely to proceed thereafter, significantly changing various properties of the solder alloy over time so that the storage stability of the solder alloy deteriorates. On the other hand, if the amount of an oxide film on the surface of the solder is very small and there is little impurity on the surface of the solder, oxidation or corrosion proceeds very slowly.
    If the L *, a * and b * of the Au-Sn-Ag-based solder alloy are outside the above-mentioned range, the thickness of an oxide layer is large or impurities are present in amounts exceeding the acceptable limit. As a result, the wettability or connectivity becomes poor, and hence the reliability inevitably becomes poor, which is undesirable. Each of the elements of the Au-Sn-Ag-based solder alloy of the present invention will be described below.
    <Au>
    Au is a main component of the solder alloy according to the invention and is an essential element. Au is difficult to be oxidized, and accordingly, it is the most suitable element in view of its properties as a solder for joining or sealing electronic components which require high reliability. Au-based solder is therefore often used to seal a crystal component or a SAW filter. The present invention provides a similar solder alloy containing Au as a main component, so that it is mainly used in a technical field which requires high reliability.
    Since Au is a very expensive metal, Au should be used in the smallest possible amount from the point of view of cost. Therefore, Au is rarely used in electronic components that require a general level of reliability. In contrast, the solder alloy according to the invention has a composition close to the composition at the ternary eutectic point of an Au-Sn-Ag system, which enables excellent flexibility or processability of the solder alloy and at the same time ensures properties such as wettability or connectivity that are comparable to or superior to those of Au -20 mass% Sn solder or Au-12.5 mass% Ge solder. In addition, the solder alloy according to the invention has the lowest possible Au content in order to reduce costs.
    <Sn>
    Sn is a basic element of the solder alloy according to the invention and is an essential element. A conventional Au-Sn solder alloy has a composition close to the composition at its eutectic point, that is, a composition close to Au-20 mass% Sn. Such an Au-Sn solder alloy has a solidus line temperature of 280 ° C. and fine crystal grains, and therefore can have a relatively high flexibility. Although the Au-20 mass% Sn alloy is a eutectic alloy, the Au-20 mass% Sn alloy is composed of an Au1Sn1 intermetallic compound and an Au5Sn1 intermetallic compound, and is therefore hard and of a brittle nature and difficult to process. For example, when the Au-20 mass% Sn alloy is worked into a sheet shape by rolling, the thickness thereof needs to be gradually reduced, and accordingly, productivity cannot be increased. If the processing speed is forcibly increased, numerous cracks may occur during rolling, which undesirably leads to a low yield. Although the hard and brittle nature of the intermetallic compound cannot be changed in general, the intermetallic compound is used for applications which require high reliability because the intermetallic compound is difficult to be oxidized and has excellent wettability or reliability.
    The solder alloy according to the invention has a basic composition close to the composition at its eutectic point and is composed of an intermetallic Au1Sn1 compound and a ζ phase in such a way that the advantageous properties of the intermetallic Au1Sn1 compound are effectively brought about. It should be noted that the ζ phase is an intermetallic Au-Sn-Ag compound and its composition ratio in at% is defined by Au: Sn: Ag = 30.1: 16.1: 53.8 (reference literature: Ternary Alloys, A Comprehensive Compen -dium of Evaluated Constitutional Data and Phase Diagrams, Edited by G. Petzow and Effenberg, VCH).
    The solder alloy according to the invention has properties of the ζ phase of relatively high flexibility as well as those of the basic composition close to the composition at the eutectic point, which forms a lamellar structure, and accordingly the solder alloy achieves excellent workability and stress relaxation behavior. Such a composition of the solder alloy makes it possible to reduce the melting point of the solder alloy, and accordingly the solder alloy can have a eutectic temperature of 370 ° C., which is not much different from that of an Au-Ge alloy. Such a melting point which is suitable for a high-temperature solder alloy is one of the advantages of the solder alloy according to the invention.
    The Sn content of the solder alloy according to the invention is at least 27.5 mass% up to at most 33.0 mass%, particularly preferably at least 29.0 mass% up to at most 32.0 mass%. If the Sn content is less than 27.5 mass%, the crystal grains become coarser, so that the effect of improving flexibility or workability is not sufficiently exhibited and the difference between the liquidus line temperature and the solidus line temperature becomes too large, whereby a separate melting phenomenon occurs and the cost reduction effect is limited because of the increased Au content of the solder alloy. On the other hand, if the Sn content is 33.0 mass% or more, the composition of the solder alloy largely deviates from the composition at the eutectic point, causing problems such as coarsening of crystal grains or an increase in the difference between the liquidus line temperature and the solidus line temperature. Temperature. In addition, when the Sn content becomes too large, the solder alloy is more likely to be oxidized and lose the excellent wettability characteristic of Au-based solders, and accordingly high connection security is difficult to achieve. It is particularly preferable if the Sn content is at least 29.0 mass% to at most 32.0 mass% because then the composition of the solder alloy comes closer to the composition at the eutectic point, which can produce an effect of refining the crystal grains and is less likely makes a separate melting phenomenon occur.
    <Ag>
    Ag is an element which is indispensable for the ternary eutectic alloy and is an essential element of the solder alloy according to the invention. The solder alloy of the present invention has a composition close to the composition at the ternary eutectic point of Au-Sn-Ag, and therefore the solder alloy can have excellent flexibility, workability, and stress relaxation properties, and moreover, the solder alloy can have an appropriate melting point. In addition, the Au content can be significantly reduced, whereby a high cost reduction effect can be achieved. In addition, since Ag is reactive with Cu or Ni used in the uppermost surface of a substrate or the like, it has an effect of improving wettability. Ag is excellent in reactivity with Ag or a metallized Au layer, so it is often used in the connection surface of a semiconductor element.
    The content of Ag with such excellent effects is at least 8.0 mass% to at most 14.5 mass%. If the Ag content is less than 8.0 mass%, the composition of the solder alloy deviates too much from the composition at the eutectic point. As a result, the liquidus line temperature of the solder alloy becomes too high, or the crystal grains coarsen, making it difficult to achieve excellent connectivity. On the other hand, when the Ag content exceeds 14.5 mass%, problems such as occurrence of a separate melting phenomenon due to an increase in liquidus line temperature or coarsening of crystal grains arise. It should be noted that the Ag content is preferably at least 10.0 mass% to at most 14.0 mass% because this makes the composition of the solder alloy closer to the composition at the eutectic point and accordingly the effect of adding Ag becomes more pronounced.
    Examples
    Au, Sn and Ag each having a purity of at least 99.99 mass% were produced as raw materials, and Ge having a purity of at least 99.99 mass% was produced as a raw material for comparative examples. Large flakes or pieces of the raw materials were cut or pulverized into small pieces of 3 mm or less, taking care that the composition of the molten alloy was uniform and without variation from sample to sample. Then, predetermined amounts of these raw materials were weighed out and placed in a graphite crucible for a high frequency melting furnace.
    The crucible containing the raw materials was placed in a high frequency melting furnace, and nitrogen was flowed over it at a flow rate of at least 0.7 L / min per kg of the raw material to suppress the oxidation. In this state, the melting furnace was turned on to heat and melt the raw materials. After the start of the melting process, the raw materials were mixed well by stirring with a mixing rod in order to bring about a uniform composition of the molten metal without local variations. After the complete melting of the raw materials was confirmed, the high frequency melting furnace was turned off and the crucible was immediately taken out of the melting furnace, and the molten metal was poured from the crucible into molds for master solder alloys. For the production of master solder alloys, a mold with a casting cavity with a size of width 45 mm * thickness 6 mm * length 250 mm was used with a view to carrying out a rolling and pressing process for the production of stamped products, as well as a mold with a casting cavity with a Size of diameter 20 mm * length 200 mm used with a view to carrying out an atomization process for the production of spheres. Accordingly, Samples 1 to 19 and 39 to 50 of the punched products were made using the die for making punched products, and Samples 20 to 38 and 51 to 62 of the balls were made using the die for making balls.
    Master solder alloys of Samples 1 to 62, which differ in the mixing ratio of the raw materials, were produced in this way. The composition of each of the thus obtained master solder alloys of Samples 1 to 62 was analyzed by means of an ICP emission spectrometer (SHIMAZU S-8100). The results of the compositional analysis obtained are shown in Tables 1 and 2 below together with the colors (SCE) described later.
    Subsequently, each of the master solder alloys of samples 1 to 19 and 39 to 50 was further processed into a sheet shape with the aid of a roller device and then punched out with the aid of a pressing device in order to produce square punched products of 5.0 mm * 5.0 mm in a manner which is described below. The L *, a * and b * of the punched product were then measured with the aid of a spectrocolorimeter. In addition, a substrate and a chip were bonded to each other using the punched product to form an array to examine the connectivity (measurement of the void ratio) and storage stability (constant temperature and constant humidity test).
    On the other hand, each of the master solder alloys of Samples 20 to 38 and 51 to 62 was used to prepare a spherical sample having a diameter of 0.25 mm by a sputtering method which will be described later. Then L *, a * and b * of each spherical sample were measured. In addition, the wettability of the spherical sample was examined (measurement of aspect ratio), and an article sealed with the spherical sample was prepared to test the sealing ability of the spherical sample (leakage inspection). In the following, the treatment carried out to vary the surface condition from sample to sample and a method for measuring L *, a * and b * are described in detail. In addition, a method for producing punched products or balls and various test methods are described in detail.
    <Surface condition of solder alloy>
    The punched products and spherical samples of samples 1 to 62 were heat-treated in a reducing hydrogen atmosphere at various temperatures in the range from 80 to 250 ° C for various times in the range from 0.1 to 5.0 hours to reduce the degree of oxidation or the metal structure of the surface of the solder alloy from sample to sample. Increasing the temperature and / or increasing the duration of the heat treatment decreases L *, but increases a * and b *. The L *, a * and b * of each solder alloy sample of Samples 1 to 62 whose surface condition was adjusted in this way were measured.
    <Method of making punched products>
    Each of the master solder alloys of Samples 1 to 19 and 39 to 50 shown in the table above was rolled to a thickness of 50 μm with the aid of a rolling device. In carrying out the rolling processing, the following points were observed. First, the samples were rolled into a sheet with an appropriate amount of lubricating oil added if necessary to prevent the sample from sticking to the rollers. The formation of an oil film in this way between the rollers and the sheet or between the surfaces of the sheet makes it possible to prevent the roller and sheet or sheet surfaces from sticking together. In addition, the feed rate of the sample should also be taken into account. If the feeding speed is too high, sticking between the surfaces of the sheet is likely to occur or the sample will break due to the application of an excessively high tension. On the other hand, if the feeding speed is too low, a deflection occurs, so that the sheet is woven when the sheet is wound, or a sheet with a uniform thickness cannot be obtained.
    Each of the sheets thus obtained was further processed by means of a roller, whereby the punched products were obtained. More specifically, each sheet was placed in a press machine and then punched out with the addition of lubricating oil to produce the punched products. The die cut products were collected in a container filled with organic solvent. Each of the punched products had a square shape of 5.0 mm x 5.0 mm. Subsequently, the punched products were washed with an organic solvent and dried for 2 hours by vacuuming in a vacuum dryer, whereby the test samples were obtained.
    <Method of Making Balls>
    Each of the master alloys (20 mm in diameter) prepared as Samples 20 to 38 and 51 to 62 was placed in a nozzle of a liquid phase atomizing device, and the nozzle was set on the tip of a quartz tube which was heated to 320 ° C Oil contained (i.e. in a high frequency melting coil). The master alloy was heated to 650 ° C. in the nozzle by high frequency and held there for 5 minutes, and thereafter atomization was carried out by applying pressure to the nozzle with an inert gas, thereby producing balls of the solder alloy. It should be noted that the diameter of the nozzle tip was set in advance such that the median value of the diameter of the balls was 0.25 mm. Subsequently, the balls obtained with the aid of the above-mentioned method were sorted with the aid of a twin screw classifier in order to obtain balls with a diameter in the range of 0.25 ± 0.015 mm. In this way, spherical specimens with a diameter of 0.25 mm were produced and used as test specimens.
    <Measurement of L *, a * and b *>
    The surface of each punched product (with a square shape of 5.0 mm * 5.0 mm) of samples 1 to 19 and 39 to 50 and the surface of each ball with a diameter of 0.25 mm of samples 20 to 38 and 51 to 62 were measured using a spectrocolorimeter (manufactured by KONICA MINOLTA OPTICS, INC., Model: CM-5) to determine L *, a * and b *. First, the device was corrected using a standardized light source. Subsequently, each of the samples was placed on a measuring table, the lid was closed, and the measurement was carried out automatically. The measurement was carried out by removing specular reflection (in the case of the present device, this is the type of measurement SCE, which is a measurement method in which the specular reflection is removed). The measurement results of each of the samples are shown in Tables 1 and 2 listed above.
    <Investigation of the connectivity (measurement of the porosity)>
    The void ratio was measured using the punched product to examine connectivity. More specifically, a laser soldering machine (manufactured by Apollo Seiko Ltd.) was started, and a nitrogen gas flow was set at a flow rate of 50 L / min. A Cu substrate 1 (thickness: 0.3 mm) with a Ni coating layer 2 (thickness: 3.0 μm) was then automatically transferred into a laser irradiation area. The spherical sample (solder alloy 3) was then fed in and arranged on the Ni-coated Cu substrate 1 and heated and melted by means of laser irradiation for 0.3 seconds. Shortly thereafter, a Si chip 4 was placed on the solder alloy 3 and scrubbed for 3 seconds. After completion of the scrubbing process, the Si chip arrangement was automatically transferred from the laser irradiation area to a transfer area, cooled and stored under a nitrogen atmosphere. After sufficient cooling, the Si chip arrangement was removed and exposed to the atmosphere (see FIG. 2).
    In order to examine the wettability, the void ratio of the Si chip assembly was measured using an X-ray inspection system (manufactured by TOSHIBA CORPORATION, TOSMICRON-6125). The X-rays emitted above the Si chip were vertically passed through the joint in the arrangement with which the Si chip is connected to the Cu substrate provided with the sample (solder alloy), and the void ratio was determined using the following calculation formula 2 calculated. [Calculation formula 2]Pore proportion = pore area (pore area + area of the connection between solder and Cu substrate) x 100 (%)
    <Investigation of storage stability (constant temperature and constant humidity test)>
    Changes in the surface state of a solder alloy sample as a result of corrosion or oxidation of the surface of the solder during long-term storage lead to a reduction in wettability or connectivity, as a result of which a good connection of the solder alloy sample is prevented. In addition, changes in the surface of the solder over time lead to variations in the state of the connection. Accordingly, in order to achieve a successful connection, it is important that the surroundings do not change the surface of the solder. In order to examine the storage stability, a test was carried out under constant temperature and constant humidity conditions. More specifically, the punched product was placed in a constant temperature, constant humidity chamber (manufactured by Yamato Scientific Co., Ltd., Model: IW242) and subjected to a test at 85 ° C and 85% RH for 1000 hours.
    Of each sample, the thickness of the oxide film before and after the constant temperature and constant humidity test was examined by comparison with the thickness of an oxide film of Sample 1 before the constant temperature and constant humidity test, which was defined as 100%. The thickness of the oxide film was defined as a depth (distance) from the surface of the solder to the point where the oxygen concentration measured in a depth direction from the surface of the solder material was reduced to 50% when the maximum oxygen concentration was near the surface of the solder alloy was defined as 100%. The thickness of the oxide layer near the surface of the solder alloy was measured with a field emission type Auger electron spectrometer (manufactured by ULVAC-PHI, Model: SAM-4300).
    <Investigation of wettability (measurement of aspect ratio)>
    Each ball of Samples 20 to 38 and 51 to 62 was bonded to a substrate to form an array, and the aspect ratio of the wetted solder alloy was measured to determine wettability. More specifically, a laser soldering machine (manufactured by Apollo Seiko Ltd.) was started, and a nitrogen gas flow was set at a flow rate of 50 L / min. A Cu substrate 1 (thickness: 0.3 mm) with a Ni coating layer 2 (thickness: 3.0 μm) was then automatically transferred into a laser irradiation area. The spherical sample was then fed in and positioned on the Ni-coated Cu substrate 1 and heated and melted by means of laser irradiation for 0.3 seconds. The Cu substrate 1 was then automatically transferred from the laser irradiation area to a transfer area, cooled and stored under a nitrogen atmosphere. After being cooled sufficiently, the Cu substrate 1 was exposed to the atmosphere.
    The aspect ratio of the wetted solder alloy in the arrangement thus obtained, in which the solder alloy 3 is bonded to the Ni coating layer 2 of the Cu substrate 1 as shown in FIG. 3, was determined. More specifically, the maximum and minimum lengths of the wetted solder shown in FIG. 4 were measured as a longer diameter (X1) and a shorter diameter (X2), respectively, and the aspect ratio of the wetted solder was calculated using Calculation Formula 1 below. The closer the aspect ratio calculated with the aid of calculation formula 1 is to 1, the more pronounced the solder wets a circular shape on the substrate, and accordingly the wettability can be assessed as better. If the aspect ratio is greater than 1, the shape of the wetted solder deviates more from a circle the more the aspect ratio increases. In this case, variations occur in the displacement distance of the molten solder material, and accordingly uneven reaction takes place, so that the thickness or composition of the alloy layer greatly varies and uniform and successful joining cannot be achieved. In addition, a large amount of solder flows and spreads in a certain direction, and accordingly there is an area in which the amount of solder is too high and an area in which the solder is not present, so that in certain areas the The soldering process is bad or the connection does not succeed. [Calculation formula 1]Aspect ratio = longer diameter + shorter diameter
    <Examination of stability (checking for leaks)>
    A sealing container 5 having the shape shown in Fig. 5 was sealed with a spherical solder alloy 3 of each of Samples 20 to 38 and 51 to 62 by means of a laser bonding machine to determine the sealing ability of the solder alloy. The solder alloy was bonded in the same manner as in the wettability test, except that a sealing container was selected as the object to be bonded with the solder alloy. Each of the objects produced in this way was immersed in water for 2 hours, after which it was removed from the water and disassembled to check for leaks. If there was water in the disassembled sealed object, it was concluded that a leak had occurred. In this case, the sealing ability was rated as “poor”. If such a leak did not occur, the sealing performance was rated as "good". The results of the tests on the sealing ability are shown in Tables 3 and 4 below, together with the results of the above-mentioned tests on connectivity (proportion of pores in a Si chip arrangement), storage stability and wettability (aspect ratio of the solder alloy).
    As can be seen from Tables 3 and 4 listed above, the inventive Au-Sn-Ag-based solder alloys of samples 1 to 38 gave good results for all examined criteria of connectivity, storage stability, wettability and sealing capacity. Specifically, the investigation of the connectivity revealed a void ratio of 0%, which means that no pores were formed in all cases of the samples in these examples, and in the investigation of the storage stability, the thickness of the oxide film was hardly changed before and after the test, that is that the surface of the solder alloy was difficult to change, and accordingly the storage stability was excellent. In addition, when the wettability was examined, the aspect ratio was 1.02 or less, and the solder alloy showed a uniform wetting distribution, and accordingly the wettability was excellent. In addition, when the sealing performance was examined, there was no leak at all. The reason why such excellent results were obtained is considered to be that the solder alloy of the present invention has L *, a * and b * in their appropriate ranges and has a composition within the appropriate range.
    On the other hand, each of the solder alloys of Samples 39 to 62 as comparative examples gave poor results in various tests because L *, a * and b * were not within their respective appropriate ranges, and the content of any of Au, Sn, and, respectively Ag was not in the appropriate range. In particular, it was the case that in the investigation of the connectivity the pore proportion was at least 8%, in the investigation of the storage stability the thickness of the oxide film had increased sharply after the test, in the investigation of the wettability the aspect ratio was at least 1.2 and in the investigation of the Sealing ability in the samples in all cases leaks were found.
    Modifications of the Au-Sn-Ag-based solder alloy according to the present invention have been described with reference to examples, but the present invention is not limited to these examples or configurations, and various configurations can be implemented without departing from the scope of the present invention. That is, the technical scope of the present invention is defined by the claims and their equivalents. In addition, the present invention is based on Japanese Patent Application No. 2014-200478 filed on Sep. 30, 2014, the disclosure of which is hereby incorporated by reference.
    权利要求:
    Claims (12)
    [1]
    1. A plate or tape-shaped Au-Sn-Ag-based solder alloy comprising at least 27.5 mass% but less than 33.0 mass% of Sn, at least 8.0 mass% but less than 14.5 mass% of Ag, the balance Au with Exception of elements which are inevitably produced during production, the Au-Sn-Ag-based solder alloy having a surface whose L *, a * and b * in a L * a * b * color system according to JIS Z8781-4 at least 41.1 up to a maximum of 57.1, at least -1.48 to a maximum of 0.52 or at least -4.8 to a maximum of 9.2.
    [2]
    2. Au-Sn-Ag-based solder alloy according to claim 1, containing at least 29.0% by mass to at most 32.0% by mass of Sn.
    [3]
    3. Au-Sn-Ag-based solder alloy according to claim 1, containing at least 10.0 mass% to at most 14.0 mass% of Ag.
    [4]
    4. Au-Sn-Ag-based solder alloy according to claim 1, containing at least 29.0 mass% to at most 32.0 mass% of Sn and at least 10.0 mass% to at most 14.0 mass% of Ag.
    [5]
    5. An electronic component sealed with the Au-Sn-Ag-based solder alloy according to claim 1.
    [6]
    6. Electronic device which is equipped with the electronic component according to claim 5.
    [7]
    7. Spherical Au-Sn-Ag-based solder alloy comprising at least 27.5 mass% but less than 33.0 mass% of Sn, at least 8.0 mass% but less than 14.5 mass% of Ag, the remainder Au excluding elements, which inevitably occur during production, the Au-Sn-Ag-based solder alloy having a surface whose L *, a * and b * in a L * a * b * color system according to JIS Z8781-4 at least 63.9 to at most 75.9, at least 0.05 to a maximum of 0.65 or at least 1.3 to a maximum of 11.3.
    [8]
    8. Au-Sn-Ag-based solder alloy according to claim 7, containing at least 29.0 mass% to at most 32.0 mass% of Sn.
    [9]
    9. Au-Sn-Ag-based solder alloy according to claim 7, containing at least 10.0% by mass) to at most 14.0% by mass of Ag.
    [10]
    10. Au-Sn-Ag-based solder alloy according to claim 7, containing at least 29.0% by mass to at most 32.0% by mass of Sn and at least 10.0% by mass) to at most 14.0% by mass of Ag.
    [11]
    11. An electronic component sealed with the Au-Sn-Ag-based solder alloy according to claim 1.
    [12]
    12. Electronic device which is equipped with the electronic component according to claim 11.
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    同族专利:
    公开号 | 公开日
    US20160089752A1|2016-03-31|
    JP2016068123A|2016-05-09|
    US9796054B2|2017-10-24|
    TW201619399A|2016-06-01|
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    法律状态:
    2018-10-31| AZW| Rejection (application)|
    优先权:
    申请号 | 申请日 | 专利标题
    JP2014200478A|JP2016068123A|2014-09-30|2014-09-30|Au-Sn-Ag-BASED SOLDER ALLOY, SEALED OR JOINED ELECTRONIC EQUIPMENT USING THE SAME AND ELECTRONIC DEVICE MOUNTING THE ELECTRONIC EQUIPMENT|
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