Method of cooling a semiconductor device with a cooling unit, using metal sherbet between the device and the cooling unit

A method of cooling a device with a cooling unit, using a metal sherbet, which is metal being in a state of a two-phase composition consisting of a liquid phase and a solid phase, as a heat conducting body put between the cooling unit and the heat generating device for transferring heat generated in the device to the cooling unit. The metal sherbet is metal, such as an In-Ga binary system, in which solids of an In-Ga solid solution are dispersed in an In and Ga liquid at a temperature obtained under normal operations of the device and the cooling unit.

BACKGROUND OF THE INVENTION 
The present invention relates to a method for heat transfer such as cooling 
method for a semiconductor device, and more particularly, to a cooling 
method of using a metal sherbet, consisting of metal being in the state of 
a mixed phase or two-phase mixture of a liquid phase and a solid phase, as 
a heat conducting body disposed between a cooling unit and the heat source 
for transferring heat generated by the device to the cooling unit in high 
cooling efficiency. 
Recently, to improve processing ability of an information processing 
system, respective sizes of the transistor devices used in the system have 
become extremely miniaturized. Accordingly, the size of each element of 
the semiconductor device is extremely miniaturized. In other words, a 
number of electronic elements mounted on the semiconductor device is 
tremendously increased as seen in an advanced semiconductor device such as 
an LSI (Large Scale Integration) device and a VLSI (Very Large Scale 
Integration) device. However, realizing a further reduction in size of the 
semiconductor device. In other words, realizing a higher packing density 
of the semiconductor device results in generating a large amount of heat 
from the semiconductor device. Accordingly, it has become impossible to 
keep an operating temperature of the semiconductor device in a maximum 
allowable in use, as long as a conventional air cooling method is used for 
cooling the semiconductor device. For example, the heating value per 
second of an LSI device is about 4 watts even in a maximum, and it 
increases up to as much as 10 watts in the case of a VLSI device. 
Therefore, to cool the semiconductor device, it has become necessary to 
employ a liquid cooling method in place of the conventional air cooling 
method. 
Many kinds of liquid cooling units or structure have been practically used. 
For instance, FIG. 1 is a liquid cooling unit used for a flat package type 
semiconductor device, and FIG. 2 is liquid cooling structure used for a 
flip chip type semiconductor device. These liquid cooling unit and 
structure may be applied to any other types of semiconductor devices. 
FIG. 1 indicates a mounting state of a liquid cooling unit 6 onto a flat 
package type semiconductor device 2 through an elastic heat conducing body 
4 and a heat transferring plate 3 (made of, for example, alumina) equipped 
with the flat package type semiconductor device 2. The liquid cooling unit 
6 comprises a cooling body 1, a bellows 5 made of metal or plastic, a heat 
conducting plate 9 connected to the bellows 5, a nozzle 7 and a water 
drain port 8. The heat conducting plate 9 is thermally connected with the 
heat transferring plate 3 through the elastic heat conducting body 4. 
In FIG. 1, the nozzle 7 injects cooling water into a chamber formed by the 
bellows 5 for cooling the heat conducting plate 9 so that heat generated 
by the flat package type semiconductor device 2 is transferred to the 
cooling body 1, then the cooling water flows out from the water drain port 
8 transferring heat from the heat conducting plate 9. Usually, the cooling 
temperature can be controlled by changing the temperature of the cooling 
water. 
The elastic heat conducting body 4 is made of silicon rubber, in which a 
ceramic powder is mixed, for making the elastic heat conducting body 4 
have an excellent heat conducting characteristic and good contact with 
both the heat conducting plate 9 and the heat transferring plate 3, using 
a pressure due to the elasticity of the bellows 5. 
FIG. 2 indicates the structure for cooling a flip chip type semiconductor 
device 10 by utilizing a metal block (made of, for example, aluminum) 11 
cooled by a cooling unit 13 which is also cooled by coolant flowing 
through a plurality of pipes 12 passing through the cooling unit 13. The 
cooing unit 13 has a recessed portion into which the metal block 11 is 
inserted pushing a coil spring 14. The metal block 11 has high heat 
conductivity and a smooth surface for making good contact with an inner 
wall surface of the recessed portion. The coil spring 14 is used to allow 
the metal block 11 to be placed in sufficient contact with the 
semiconductor device 10, with uniform pressure. The heat generated by the 
semiconductor device 10 is transferred to the cooling unit 13 through the 
metal block 11 The heat resistance appearing in gaps between the 
semiconductor device 10 and metal block 11 and between the metal block 11 
and inner wall surface of the cooling unit 13 is reduced by using gas, 
such as helium, having good heat conduction, filled in the gaps and a 
space 20. 
Many kinds of liquid cooling units have been used elsewhere, however 
considerably high heat resistance appears between the semiconductor device 
and the liquid cooing unit. Accordingly, in the prior art, the following 
methods have been proposed to lower the heat resistance: 
1) depositing a soft metal (for example, indium or an indium alloy) into a 
contact portion intended to be thermally contacted, with pressure; 
2) providing a liquid metal (for example, mercury) to the contact portion; 
and 
3) soldering the contact portion. 
However, in method 1), high thermal conductivity is difficult to achieve 
because the air layer always exists at a gap appearing in the contact 
portion. In method 2), there is always the danger of a short-circuit 
caused by flow of the liquid metal, because the liquid metal has low 
viscosity. In method 3), stress due to the difference in thermal expansion 
between the solder, the semiconductor device and the liquid cooling unit 
occurs, so that connecting structure around the contact portion is easily 
cracked when in operation and cooling is frequently performed. 
Thus, the liquid cooling method is effective for cooling the semiconductor 
device, compared with the air cooling method. However, there is still a 
problem that a sufficient cooling effect is hard to be obtained because of 
large heat resistance appearing between the semiconductor device and the 
cooling unit, which has been a problem in the prior art. 
A satellite flying in space is in a high vacuum, so that the temperature at 
the side of the satellite, facing the sun and that not facing the sun are 
quite different from each other. Therefore, making the temperature in the 
satellite uniform is very important for making components mounted in the 
satellite operate stably. As a result, the heat generated at the side 
facing the sun must be transferred to another side away from the sun. 
Furthermore, the components themselves generate heat respectively, so that 
such heat must be transferred to other places for keeping the temperatures 
of the components within allowable values. Usually, the heat of the 
components is transferred within the satellite and radiated into space, 
not directed toward the sun and the earth. 
The satellite is fabricated by combining many structures, so that there are 
many fixed and rotatable mechanical joints in the construction of the 
structure. In these mechanical joints, the heat transfer which is carried 
out through these mechanical joints is very important, because the heat 
transferred through the structure is lost mostly at these mechanical 
joints. Therefore, how to reduce the heat transfer loss at the mechanical 
joints is a big problem in the manufacturing and operating of the 
satellite. To reduce the heat transfer loss at the mechanical joints, an 
organic material, such as silicon grease, optionally including metal and 
ceramic powder has been used. However, the organic material has the defect 
of being easily evaporated and changed in quality in a high vacuum so that 
the heat transfer loss of the material itself and at the contact to the 
mechanical structure increases. 
SUMMARY OF THE INVENTION 
An object of the present invention is to improve cooling effect of a 
semiconductor device such as an LSI and a VLSI device. 
Another object of the present invention is to increase the packing density 
of a semiconductor device for realizing further accelerated development of 
the semiconductor devices. 
Another object of the present invention is to contribute to realizing 
higher operating reliability of the semiconductor devices. 
Still another object of the present invention is to provide a more 
efficient means for heat transfer in devices such as space satellites 
which are exposed to high radiant heat levels on one side and to extreme 
cold on another side. 
The above objects of the present invention can be attained by employing a 
cooling method in which "metal sherbet" is used for a heat conducting body 
located between a cooling unit and the heat source, wherein, the metal 
sherbet is a metal being in a mixing state (two-phase state) of a solid 
phase and a liquid phase, such as, a mixture consisting of indium (In) and 
gallium (Ga). 
In case of a binary system of Ga and In, when the weight percent of In is 
within a particular range, a two-phase mixture exists in a state of a 
highly viscous sherbet in which solids are dispersed in a liquid. In the 
present invention, such a two-phase mixture is used as the heat conducting 
body. 
In accordance with applying the metal sherbet to the heat conducting body, 
a sufficient thermal contact between the semiconductor device and the 
cooling unit can be realized without using much pressure, and a very high 
cooling efficiency can be obtained because heat conductivity of the metal 
sherbet is excellent. That is, the heat resistance of the prior art 
(2.5.degree. C./watt), in which the silicon rubber has been used, is 
improved to one-half that value by applying the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The present invention is adopted to cool a flip chip type semiconductor 
device as shown in FIG. 2. 
FIG. 3(a) is a phase diagram of an In-Ga binary system. As indicated in the 
diagram, the melting point of In is approximately 156.degree. C. and the 
melting point of Ga is approximately 29.degree. C. In this system, a mixed 
phase, related to the present invention, of a liquid phase and a solid 
phase lies within a range of 24.5%-88% (weight percent) or 16.3%-81.7% 
(atomic percent) of In. Namely, the mixed phase region, in other words, a 
metal sherbet region in this disclosure, corresponds to a region enclosed 
by a liquidus line 15 and a solidus line 16. This metal sherbet region is 
well known to those skilled in the art, and particularly in academia, as 
the "two-phase field of liquid and solid." For instance, when the In-Ga 
binary system includes 50 weight percent of In under 40.degree. C. of the 
temperature of the system, a point P is obtained in the sherbet region, 
points Q and R are obtained respectively by intersecting an X coordinate 
of 40.degree. C. with the lines 15 and 16. Wherein, the point P indicates 
a total composition, R indicates the composition of a solid of In-Ga solid 
solution (which will be called simply "solid solution" hereinafter) and Q 
indicates the composition of an In and Ga liquid. From such points, P, Q 
and R, it can be said that this system has a component ratio of a solid to 
a liquid is equal to a ratio of length P-Q to P-R. When the semiconductor 
device normally operates under a normally cooled condition, the metal 
sherbet has a temperature at which the metal sherbet is in a state that 
the In-Ga solid solution is dispersed in an In and Ga liquid. A ratio of 
the In-Ga solid solution to the In and Ga liquid depends on a component 
ratio of In to Ga and the temperature of the In-Ga binary system, and a 
composition ratio of In to Ga in the In-Ga solid solution depends on the 
temperature. For instance, in FIG. 3(a), when the In weight percent 
decreases, an amount of dispersed In-Ga solid solution decreases. In other 
words, an amount of the In and Ga liquid increases. 
When considering the temperature rise of a semiconductor device which 
normally operates under a normally cooled condition, a temperature range 
from 40.degree. C. to 90.degree. C. is enough for obtaining the metal 
sherbet in the In-Ga binary system. Incidentally, in FIG. 3(a), the line 
of 40.degree. C. intersects with the lines 15 and 16 at the points Q and R 
respectively as mentioned before, and the In weight percent at the point Q 
is 32% and that at the point R is 93%. 
FIG. 4 shows the relationship between the In weight percent and an In 
viscosity (units are centipoise or cP) in the In-Ga binary system at the 
temperature of 40.degree. C. The viscosity is measured by a B type 
viscosimeter. From this figure, it will be understood that the viscosity 
is 3,000 cP or more when more than 50% weight percent In is present in the 
In-Ga binary system. 
To achieve the present invention, it is preferable that the viscosity of 
the metal sherbet is more than 3,000 cP to avoid the metal sherbet flying 
out due to, for example, mechanical vibration. 
Generally, the temperature of the semiconductor device rises to more than 
40.degree. C. in normal operation, so that, as shown in FIG. 4, the weight 
percent of In must be more than 50 for obtaining a viscosity of greater 
than 3,000 cP. Since the maximum allowable temperature of semiconductor 
device is approximately 80.degree. C. when in operation, the weight 
percent of In must be less than 94, as shown in FIG. 4. From the above, 
for forming the mixture of the In-Ga solid solution and the In and Ga 
liquid, it can be concluded that the composition of In in the In-Ga binary 
system for this use is within 50 to 94 weight percents. 
FIG. 5(a) is a sectional view of a flip chip type semiconductor device 
using the metal sherbet of the present invention as the heat conducting 
body. The FIG. 5(a) corresponds to the prior art cooling structure shown 
in FIG. 2, and the same reference numerals as in FIG. 2 designate the same 
device or parts as in FIG. 2. 
In FIG. 5(a), the semiconductor device 10 and the metal block 11 are 
thermally connected through a metal sherbet 18 having a high viscosity at 
a temperature obtained under normal operation of the semiconductor device 
10 and the cooling unit 11. In this embodiment, the In-Ga binary system, 
having 80% weight percent of In, is used as the metal sherbet. The above 
In-Ga binary system shows a two-phase (solid and liquid phases) mixture in 
a temperature range of 15.7.degree. C.-88.degree. C. Applying such metal 
sherbet 18 to the heat conducting body, a sufficient heat connection can 
be obtained and there is no fear of a short circuit due to the lowered 
viscosity of a heat conducting body. Furthermore, lowering the thermal 
resistance can be realized in the same way as that performed by 
conventional soldering. 
FIG. 5(b) is a sectional view where a flat package type semiconductor 
device 2 is cooled by using a liquid cooling unit 6 connected to the 
device 2 through a metal sherbet 18 of the present invention as the heat 
conducting body. This structure corresponds to the conventional structure 
indicated in FIG. 1, and the same reference numerals as in FIG. 1 
designate the same unit or parts as in FIG. 1. 
In FIG. 5(b), the connection between the heat transfer plate 3 attached to 
the flat package type semiconductor device 2 and the heat conducting plate 
9 of the liquid cooling unit 6 having the bellows 5 is realized by using a 
metal sherbet 18 having a high viscosity at an operating temperature of 
the semiconductor device 2. The heat connection between the heat 
transferring plate 3 and the heat conducting plate 9 by the metal sherbet 
18 can be perfectly performed as stated in the explanation referring to 
FIG. 5(a), so that there is no fear of a short-circuit due to the flow or 
leak from a heat conducting body having a low viscosity, and the thermal 
resistance also can be lowered. 
As another embodiment, a Ga-Sn binary system can be used as a heat 
conducting body. In the Ga-Sn binary system, when the weight percent of Sn 
is designated to 20%-60%, the same effect as that obtained in case of the 
In-Ga binary system can be obtained. 
FIG. 3(b) is a phase diagram of the Ga-Sn binary system. As indicated in 
the figure, the melting point of Sn is approximately 232.degree. C. and 
the melting point of Ga is approximately 29.degree. C. In FIG. 3(b), the 
region enclosed by the liquidus line 15 and the solidus line 16 is the 
metal sherbet region. In this metal sherbet region, the solids of Ga-Sn 
solid solution (which will be called "Ga-Sn solid solution" hereinafter) 
are dispersed in a Ga and Sn liquid so that a ratio of the Ga-Sn solid 
solution to the Ga and Sn liquid and the composition ratio of Ga to Sn 
depend on the component ratio of Ga to Sn in the metal sherbet and the 
temperature of the metal sherbet. 
The relationship between weight percent of Sn and the viscosity (cP), which 
is measured using a B type viscosimeter, in the Ga-Sn binary system can be 
obtained similarly to the case of the In-Ga binary system shown in FIG. 4. 
When the weight percent of Sn is 20%-60% (more desirably 30%-45%) and that 
of Ga is 80%-40% (more desirably 70%-55%), the same effect as obtained in 
case of the In-Ga binary system can be obtained. That is, if the weight 
percent of Sn is less than 20%, the temperature range for allowing the 
Ga-Sn binary system to have a state of the mixture phase becomes narrow, 
and if the weight percent on Sn is more than 60%, the viscosity of the 
Ga-Sn binary system (metal sherbet) becomes so large that it would be hard 
to form the metal sherbet so as to uniformly attach to the metal block 11 
and the semiconductor device 10 in case of cooling the flip chip type 
semiconductor device 10 as shown in FIG. 5(a) and to the heat transferring 
plate 3 and the heat conducting plate 9 in case of cooling flat package 
type semiconductor device as shown in FIG. 5(b). 
In each of the phase diagrams [FIGS. 3(a) and 3(b)], it is preferable that 
a temperature difference between the liquidus line and the solidus line is 
large, because, in such case, the usable temperature range for the heat 
conducting body can be widened. 
In FIGS. 5(a) and 5(b), the metal sherbet for the heat conducting body 18 
is formed by the following steps, when, for example, the In-Ga binary 
system is applied to the heat conducting body 18: 1) providing a first 
In-Ga solid solution having, for example, 75.5% (weight) of Ga and 24.5% 
(weight) of In; wherein, the first In-Ga solid solution is in a liquid 
phase at a room temperature; 2) wetting the surfaces, to be connected, of 
the semiconductor device and the cooling unit with the first In-Ga solid 
solution; 3) providing a second In-Ga solid solution according to this 
invention and which is in a state of mixed phase when its temperature 
rises up to, for example, 40.degree. C.; wherein, the temperature 
40.degree. C. is selected by considering the desired cooling condition of 
the semiconductor device; 4) putting the semiconductor device and the 
cooling unit in an atmosphere having a temperature of 40.degree. C.; 5) 
dropping a proper amount of the second In-Ga solid solution on the wet 
surfaces of the semiconductor device and the cooling unit, so that the 
drop of the invented In-Ga solid solution is naturally spread over the 
surfaces; 6) connecting the surfaces to each other; and 7) taking the 
semiconductor device and the cooling unit, connected to each other, out 
from the heated atmosphere and putting them in a normal atmosphere which 
is at room temperature. 
Thus, the In-Ga and Ga-Sn binary systems may be used as the metal sherbet. 
However, other multinary metal systems such as a ternary system 
substantially including respectively In and Ga or Ga and Sn can also be 
used as the metal sherbet. 
Not only to the flat package type semiconductor device or the flip chip 
type one but also to other type semiconductor devices, the cooling method 
of the present invention can be applied as long as a liquid cooling unit 
is used. The cooling method of the present invention can also be applied 
to other liquid cooling systems for cooling devices other than the 
semiconductor devices, which is illustrated by explaining the metal 
sherbet as applied to the heat transfer structure used in a space 
satellite, in reference to FIGS. 6(a) to 6(d), 7(a) and 7(b). 
In this embodiment, the present invention is used as the heat conductive 
body (metal sherbet) of an In-Ga or Sn-Ga alloy in a state of metal 
sherbet, that is, in a state of a two-phase field of liquid and solid 
uniformly throughout the body, in the mechanical joints instead of the 
usual organic material, e.g., silicon grease. Because the metal sherbet 
has the features of having a very small heat resistance, an excellent 
mechanical contact with the mechanical structure so as to have very small 
heat loss and a very low vapor pressure (less than 10.sup.-32 Torr when 
the metal sherbet is made of In and Ga and less than 10.sup.-36 Torr when 
the metal sherbet is made of Sn and Ga). In particular, the feature of 
having a very low vapor pressure is very important for using the metal 
sherbet in an orbiting satellite. In the above, whether the heat 
conductive body is in the state of a metal sherbet or not depends on the 
temperature of the heat conductive body. As is well known, the temperature 
of a substance in space is extremely low when the substance is in a shadow 
of the sun. However, the temperature of the heat conducting body can be 
kept in a proper value for maintaining the heat conducting body in the 
sherbet state even though the body is in space, because the temperature of 
the heat conducting body is raised by the heat source to which the heat 
conducting body is attached, and if necessary, the temperature can be 
raised for by using another heating means automatically if it is required, 
in the satellite. 
FIGS. 6(a) to 6(d) show the application of the metal sherbet to rotatable 
mechanical joints used in the satellite. Through FIGS. 6(a) to 6(d), the 
same number designates the same unit or part. FIGS. 6(a) and 6(b) show the 
perspective views of a heat radiation unit 61 respectively, for radiating 
heat generated from a heat source 62 such as electric devices located in 
the heat radiation unit 61. In FIGS. 6(a) and 6(b), thick solid lines 
indicate heat pipes 631, 632 and 633 forming three square frames in which 
heat radiation panels 641, 642 and 643 are provided respectively. In the 
heat radiation unit 61, the heat radiation panel 641 only mechanically 
touches the heat source 62 as shown in FIG. 6(b). Therefore, the heat 
transferred to the panel 641 from the heat source 62 is radiated to space 
by the panel 641. However, the satellite must be fabricated to be compact, 
so that the heat radiation panel is usually divided and the divided panels 
are folded out when the satellite is set in space. In this embodiment, the 
heat radiation panel is divided into three panels 641, 642 and 643 as 
described above, and the three panels are folded out as shown in FIG. 
6(b). When the three panels are folded out thusly, two rotatable 
mechanical joints 651 and 652 are needed and the heat must be transferred 
from the heat pipe 631 to the heat pipes 632 and 633 through the rotatable 
mechanical joints 651 and 652 respectively, as shown in FIG. 6(b). The 
details of the rotatable mechanical joints 651 (or 652) is shown in FIGS. 
6(c) and 6(d) respectively. In FIGS. 6(c) and 6(d), a unit or part having 
the same number as in FIGS. 6(a) and 6(b) designates the same unit or part 
as in FIGS. 6(a) and 6(b). FIG. 6(c) shows a plan view of the rotatable 
mechanical joint 651 for mechanically connecting the heat pipes 631 and 
632 so as to have good heat contact between them. FIG. 6(d) is a sectional 
side view at a line X1-Y1 in FIG. 6(c). As shown in FIG. 6(d ), the joint 
651 is constructed by joining an upper block 66 and a lower block 67 using 
fasteners 68, holding the heat pipes 631 and 632 separately, inserting a 
metal sherbet 69 between the heat pipes (631 and 632) of the rotatable 
mechanical joint 651, respectively. Inserting the metal sherbet 69, the 
heat at the pipe 631 can be transferred to the heat pipe 632 through the 
metal sherbet 69 and the rotatable mechanical joint 651, and the heat at 
the heat pipe 632 is radiated to space from the radiation panel 642 
attached to the heat pipe 632 as shown in FIG. 6(b). 
FIGS. 7(a) and 7(b) show another embodiment of he present invention, 
wherein the metal sherbet is applied in a fixed mechanical joint, in the 
satellite. The fixed mechanical joint is used to connect a heat block, 
including a heat source such as an electric part, with a metal chassis 
used as a heat sink. FIG. 7(a) is a plan view of a heat block 71 mounted 
on a meal chassis 72. FIG. 7(b) is a sectional side view at a line X2-Y2 
in FIG. 7(a). As shown in FIG. 7(b), the heat block 71 is mounted on the 
metal chassis 72 by fasteners 73, through a metal sherbet 74. By using the 
metal sherbet 74, the heat resistance at the mechanical joint between the 
heat block 71 and the metal chassis 72 can be reduced significantly and 
the heat transfer can be performed effectively, even in a perfect vacuum.