Stress absorption matrix

An apparatus for interfacing materials and absorbing disparate thermal expansions thereof utilizes a woven wire mesh to support a predetermined thickness of a first soft solder which absorbs expansions, and utilizes a second soft solder having a lower melting point than the first to coat the surfaces of the wire mesh/first soft solder combination so that the materials can be bonded thereto.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates generally to interfaces between dissimilar 
materials, and more particularly to interfaces in microelectronic circuits 
between substrates and metal surfaces possessing disparate temperature 
coefficients of expansion. 
2. Description of the Prior Art 
Large substrates comprising more than one square inch of surface area have 
conventionally, as in the microelectronics domain, been affixed to metal 
surfaces via epoxies, solders, or alloys. A substrate, such as alumina or 
beryllia, may possess a different temperature coefficient of expansion 
than the metal to which it is bonded. Accordingly, when the combination is 
subjected to thermal variations, the materials expand at disparate rates, 
often precipitating shearing of the bonding material or fracturing of the 
substrate. To ameliorate this result, industrial practice normally entails 
partitioning of large substrates into smaller substrates having surface 
areas less than one square inch. 
Thus, there is a need for an apparatus that allows larges substrates to be 
mounted on metal surfaces without shearing of the interfaces and 
jeopardizing of the substrates, upon exposure to varying temperatures. 
SUMMARY OF THE INVENTION 
The present invention provides an apparatus for interfacing materials and 
absorbing disparate thermal expansions of the materials. The invention 
comprises means for absorbing disparate thermal expansions of the 
materials, and means for supporting a predetermined thickness of the 
absorbing means. Means for bonding the combination of supporting and 
absorbing means to the materials is affixed to surface areas of the 
combination. 
In a preferred embodiment of the invention, the supporting means comprises 
a woven copper wire mesh having uniform spacing, having a wire diameter 
not less than 0.005 inches, and having between 25 and 75 wires per linear 
inch. The absorbing means comprises a first soft solder, preferably an 
indium-lead solder having a melting point not less than 220.degree. C. The 
bonding means comprises a second soft solder, preferably tin-lead or 
tin-lead-silver eutectic solder, having a lower melting point than the 
first. 
The invention can also be utilized to drain heat from the materials, 
particularly when the wire mesh comprises thermally conductive wire such 
as copper. 
When one of the materials comprises a substrate having an electrically 
conductive surface, and another material comprises a ground plane, the 
invention may additionally be utilized as a ground, by wrapping edges of 
the wire mesh/solder combination around the substrate in electrical 
contact with the conductive surface. Such use of the invention eliminates 
the need for wrap-around ground planes whose processing requires stringent 
controls and radius substrates in order to prevent metal discontinuities.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The invention comprises a stress absorption matrix which functions as an 
interface between materials possessing different temperature coefficients 
of expansion, such as a substrate of aluminia or beryllia and a metal 
plate in a microelectronic circuit. The matrix bonds the one material to 
the other, while precluding damage that might otherwise result from 
disparate expansions of the materials due to temperature variations. 
Referring to FIG. 1, a preferred embodiment of the invention comprises a 
woven mesh of wires. The wires are woven with longitudinal wires, such as 
a wire 10, interlaced between lateral wires such as wires 11, 12, and 13. 
Preferably, the longitudinal wires are disposed substantially parallel to 
one another, the lateral wires are disposed substantially parallel to one 
another, the longitudinal wires are disposed substantially perpendicular 
to the lateral wires, the distances between adjacent parallel wires are 
substantially equal, and the diameters of the wires are substantially 
equal. The diameter of the wire is desirably at least 0.005 inches, with 
0.008 inches being preferable, whereby the woven mesh is 0.016 inches 
thick. From 25 to 75 wires per linear inch is desirable, with 50 per 
linear inch being preferred. Fewer than 25 wires per linear inch may pose 
difficulties in filling the relatively large gaps between wires with 
solder. Preferably, the wire comprises copper. The spaces surrounding the 
wire mesh are filled with a soft solder 14, preferably forming two planar 
surfaces 15 and 16 which are tangent to the wire mesh. The soft solder 14 
is disposed by plating and/or solder dipping the wire mesh. The soft 
filler solder 14 preferably comprises a high temperature 
(.gtoreq.220.degree. C.) lead-indium solder. One such solder comprises 75% 
lead and 25% indium, is solid at 250.degree. C., plastic between 
250.degree. C. and 264.degree. C., and liquid at 264.degree. C. Another 
such solder comprises 81% lead and 19% indium, is solid at 270.degree. C., 
plastic between 270.degree. C. and 280.degree. C., and liquid at 
280.degree. C. The surfaces 15 and 16 of the wire mesh filled with the 
soft solder 14 are coated with a soft solder 17. Preferably, the soft 
coating solder 17 comprises a solder possessing a lower melting point than 
the soft filler solder 14. Standard tin-lead or tin-lead-silver eutectic 
solders may serve as the soft coating solder 17. The lower melting point 
of the soft coating solder 17 permits it to be applied to the surfaces of 
the wire mesh/soft filler solder14 combination without damaging the 
combination by melting the soft filler solder 14. 
Referring to FIG. 2, with continuing reference to FIG. 1, a matrix 21 
resulting from the combination of the wire mesh, the soft filler solder 
14, and the soft coating solder 17 is bonded, via the soft coating solder 
17, between two materials, 22 and 23, possessing different temperature 
coefficients of expansion. For example, in a microelectronic circuit, the 
material 22 may comprise a copper plate and the material 23 may comprise 
an aluminia or beryllia substrate. The melting point of the soft coating 
solder 17 being lower than that of the soft filler solder 14 entails 
additional advantages: the matrix 21 can be bonded to the materials 22 and 
23 via the soft coating solder 17 without disrrupting the matrix 21 by 
melting the soft filler solder 14. Removal of the matrix 21 from the 
mateirals 22 and 23, and repair of the matrix 21 can be achieved by 
melting the soft coating solder 17 without affecting the soft filler 
solder 14. In microelectronic circuits, the matrix 21 preferably extends 
at least 0.010 inches beyond the perimeter of a substrate to ensure that 
the entire surface of the substrate is in contact with the matrix 21, and 
to facilitate the alignment of the substrate relative to the matrix 21. 
When the materials 22 and 23 expand at different rates due to temperature 
variations, the matrix 21 which is bonded therebetween absorbs the 
disparate expansions, preventing shearing of the interface and fracturing 
of the materials 22 and 23. In microelectronic circuits, the matrix 21 
eliminates fractures of substrates which are bonded, via the matrix 21, to 
metal plates. Specifically, upon temperature variation, some of the 
resulting disparate expansion of the materials 22 and 23 is absorbed by 
the soft coating solder 17 which bonds the matrix 21 between the materials 
22 and 23; but, the preponderance of such expansion is absorbed by the 
relatively thick volume of the soft filler solder 14. Accordingly, the 
matrix 21 allows interfacing of two or more dissimilar materials having 
extremely different temperature coefficients of expansion. For example, 
the following pairs of materials can be bonded together with the matrix 
21: aluminia/copper, beryllia/copper, aluminia/aluminum, aluminia/nickel, 
and beryllia/nickel. Gold in the materials 22 and 23 to which the matrix 
21 is bonded, such as gold in the printed circuit on a substrate, may 
migrate into the matrix 21, embrittling the solders 14 and 17. 
Accordingly, the gold content of the solder 17 and particularly the solder 
14 should be kept below 2% to ensure the solders' compliancy. 
If the woven mesh comprises a thermally conductive wire, such as copper, 
the ability of the matrix 21 to drain heat from the materials 21 and 22 is 
enhanced. As such, the matrix 21 comprising copper wire serves 
additionally as a heat sink for a substrate such as aluminia or beryllia 
in a microelectronic circuit. To reduce thermal resistance of the matrix 
21, flaws and voids in the soft coating solder 17 and particularly in the 
soft filler solder 14 should be avoided. 
Generally, the wire comprising the woven mesh of the matrix 21 should be 
solderable, in order to bond with the soft filler solder 14, and the soft 
coating solder 17. The wire should not oxidize, and should not harbor 
alkalis which may jeopardize components in a microelectronic circuit. That 
is, the wire should be non-corrosive. The wire should comprise no 
encapsulant, such as teflon or plastic coatings, which would affect the 
bonding of solder thereto and the transfer of heat thereby. The mesh of 
the wire should be uniform, to facilitate the voidless filling of the 
spaces between the wires with solder. 
The woven wire mesh serves as a framework for supporting the soft filler 
solder 14 at a predetermined thickness, and as a heat sink, particularly 
when the mesh comprises thermally conductive wire such as copper. The soft 
filler solder 14 serves as a compliant medium for absorping disparate 
thermal expansions of the materials 22 and 23 between which the matrix 21 
is bonded. The soft coating solder 17 serves primarly to bond the matrix 
21 to the materials 22 and 23, but serves additionally to absorb some of 
the disparate thermal expansion of the materials 22 and 23. 
The matrix 21 can be utilized as an interface between more than two 
dissimilar materials. For example, several materials in one plane may be 
bonded to several materials in another plane via the matrix, such that, 
more than one material in one plane is interfaced with a single material 
in the other plane. 
A stress absorption matrix can also be utilized as a ground. For example, 
referring to FIG. 3, a stress absorption matrix 30 is bonded between a 
substrate 31, having an electrically conductive surface 32, and a ground 
plane 33. The edges of the matrix 30 are wrapped around the substrate 31 
making electrical contact with the electrically conductive surface 32 of 
the substrate 31. In this fashion, the matrix 30 serves not only to absorp 
disparate thermal expansions of the ground plane 33 and the substrate 31, 
but also to ground the substrate 31, conveying current from the conductive 
surface 32 of the substrate 31 to the ground plane 33. 
While the invention has been described in its preferred embodiments, it is 
to be understood that the words which have been used are words of 
description rather than limitation and that changes within the purview of 
the appended claims may be made without departing from the true scope and 
spirit of the invention in its broader aspects.