DE2930779A1 - Contact layer for semiconductor chip - consists of three or four metal layers giving firm bond and including gold-germanium alloy layer for soldering - Google Patents

Abstract

Semiconductor device has a chip pad and related semiconductor element, with three consecutive metal layers, consisting of (I) V, Al, Ti, Cr, Mo or No-Cr alloy, (II) Cu (alloy) or Ni (alloy) and (III) Au-Ge (based) alloy, which acts as solder and fixes the element to the chip pad. Exact positioning is facilitated by using an extremely small amt. of Au-Ge alloy instead of Au foil and the amt. of Au needed is reduced. Reliability is increased by the strong bond formed between the Si and Au-Ge alloy by the intermediate layers.

Description

Haible iter device

Description The invention relates to a semiconductor device according to the preamble of claim 1. In particular, it relates to a semiconductor device with an improved ability to attach the semiconductor elements to the Chip mounting or connection parts (paths).

Fig. 1 illustrates part of a known semiconductor device, in which a semiconductor element 1 made of silicon (hereinafter "silicon chip" called) on a chip mounting part 2 such as a lead frame and a stem is attached. The collector area of the silicon chip 1 is with the chip mounting part 2 connected. The base and emitter areas of the chip 1 are secured by means of fastening wires 3 connected to line pieces 4.

Various methods are known to produce a silicon chip on a To attach chip mounting part. Of these methods, the following are provided in the Generally applied: a) It is applied between a silicon chip and a chip mounting part a gold foil or a gold alloy foil about 10 µm thick is inserted. then the chip and the fastening part with the intermediate film on one Heated temperature higher than the eutectic temperature of gold-silicon, d. H. higher than 373 ° C. This is used between the chip and the mounting plate a gold-silicon alloy is formed and thereby the silicon chip on the chip mounting part attached.

b) Between a silicon chip and a die attach part a eutectic gold-silicon layer is formed by adding a gold or gold alloy layer on the Siliciuincüip is heated. Between the table layer and the chip mounting part gold foil or gold alloy foil is inserted - the chip, the fastening part, the cutectic layer w ~ o the foil are put together and then on one Temperature above the eutectic temperature 1 of gold-silicon heated, whereby the c? #tp is attached to all the mounting part.

c) A gold-silicon alloy layer is formed on a surface of a silicon substrate a suitable thickness. The silicon substrate is then cut into chips. Using the alloy layer as solder, the respective silicon chip attached to the chip mounting part.

d) A gold-germanium alloy layer or a gold-antimony alloy layer appropriate thickness is formed on a surface of a silicon substrate.

The silicon substrate is then cut into chips.

Using the alloy layer as a solder, the silicon chip is made attached to the chip mounting part.

Procedure a) has shortcomings in the following respects: 1) Since the foil is much larger than the silicon chip, the accuracy of the positioning is lower of the chip bad. This inevitably causes trouble in the subsequent ones Manufacturing processes of the semiconductor device.

2) To attach the film to the chip mounting part, a High accuracy device required.

3) It takes a large amount of gold, which is very expensive.

4) It is difficult to have a strong enough bond between the Manufacture chip and the fastening part.

The adhesive strength varies from semiconductor device to semiconductor device different. The products are therefore not sufficiently reliable.

Process (b) is advantageous over process a) in that there is stronger adhesion between the silicon chip and the chip mounting part enables.

The defects specified under 1) to 3) are also liable to him at.

The method according to c) makes it possible to reduce the cost of the semiconductor device as it does not use gold foil. Because of this, it also needs no device for positioning a film on the die attach part. It is extremely difficult with this method, a good division of the Silicon substrate in cubes. Because the eutectic gold-silicon layer a jim or thicker, the substrate is diced along cube lines from the surface cut out on which the eutectic layer is formed, as is done in Japanese Patent publication 13 27 78/77 is described. In practice, however, it is extremely difficult to cut the substrate exactly along the cube lines.

In most cases the substrate is cut along a line, 100 am or more from the dice line.

The method d) has deficiencies in that the bond between the alloy layer and the silicon substrate are not sufficiently thick. as As a result, there is a risk that the alloy layer will break down during dicing separates from the substrate. If the alloy layer does not come off the substrate, it is the product obtained as a result of the poor bond between the alloy layer and the silicon substrate unreliable.

The object of this invention is a semiconductor device in which the semiconductor element is positioned on the chip mounting part e ::: iJ-t, that with low cost can be made and that a strong bond between the semiconductor element and the die attach part.

The invention is characterized by the features of claim 1. Advantageous refinements of the invention can be found in the subclaims.

The invention is illustrated by exemplary embodiments on the basis of 5 figures explained in more detail. 1 shows a perspective view of part of a known semiconductor device in which a silicon chip is mounted on a lead frame is attached; Fig. 2 is a cross-sectional view of a silicon substrate according to this Invention; 3 is a cross-sectional view of a semiconductor device according to this Invention in which a silicon chip is mounted on a chip mounting part; Fig. 4 is a diagram showing the distribution of thermal resistance in an inventive Shows semiconductor device; and Fig. 5 is a cross-sectional view of another Silicon substrate according to this invention.

A semiconductor device according to this invention includes a die attach part and a semiconductor element having three metal layers interposed between the fixing part and the element are inserted. The first metal layer is on a surface of the semiconductor element applied and made of a metal that consists of the Vanadium, aluminum, titanium, chromium, molybdenum and nickel-chromium alloy group are selected is. The second metal layer, which is applied to the first metal layer, is made of a metal belonging to the group copper, copper-based alloy, Nickel and nickel-based alloy is selected. The third layer of metal that is applied to the second metal layer is made of a gold-germanium alloy or made from an alloy based on gold-germanium. The third Metal layer acts as a solder that attaches the semiconductor element to the die attach part attached.

The first and second metal layers reinforce the Bond between the semiconductor element and the third metal layer.

The third metal layer may be oxidized as it is formed will. If this happens, the bond strength between the third metal layer will be reduced and the chip attaching part lowered. To such a decrease in bond strength To avoid this, the third metal layer can be covered with a fourth metal layer that will come from the Group gold, silver and platinum is selected.

As a copper-based alloy and a nickel-based alloy, i. H. as the material of the second metal layer, a copper-nickel alloy and a nickel-chromium alloy can be used. As an alloy based on gold-germanium, d. H. A gold-germanium-antimony alloy can be used as the material of the third metal layer or a gold-germarium-gallium alloy can be used. The antimony in the Gold-germanium-antimony alloy serves to reduce the collector-emitter saturation voltage Decrease Vces of the semiconductor device.

Is a gold-germanium-antlmon alloy on a nickel layer or a nickel-based alloy layer is then deposited first Antimony deposited because the vapor pressure of antimony is higher than that of gold or Is germanium. The precipitated antimony reacts with nickel in such a way that it causes an increase in the thermal resistance Rth of the semiconductor device. In order to avoid this reaction between nickel and antimony, between the nickel layer or the alloy layer based on nickel and the gold-germanium-antimony layer Gold, germanium or a gold-germanium alloy can be formed.

Furthermore, between the third and the fourth metal layer Likewise a gold-germanium layer can be formed.

The germanium content is preferably in the gold-germanium alloy in the range between 4 and 20% by weight. If the germanium content is less than 4% by weight, then the alloy becomes so soft that it is difficult to cut into cubes. Exceeds if the proportion is 20% by weight, the third metal layer cannot bond sufficiently establish more between the semiconductor element and the die attach part. Preferably the germanium content should be in the range between 6 and 12% by weight. Most beneficial it is when it is 12% by weight, so that a gold-germanium eutectic is formed will. The antimony content of the gold-germanium-antimony alloy is preferably in the range between 0.005 and 1.0 wt% based on the amount of gold germanium. It is most advantageous if the antimony content is in the range between 0.03 to 0.2 wt. T. The first metal layer should be 50 to 2,000 Å thick, the second Metal layer 300 to 5,000 Å, the third metal layer 0.8 to 3.5 tim and the fourth metal layer 500 to 5,000 Å. There are now several Examples of this invention illustrated.

Example 1 As shown in Fig. 2, a first metal layer was formed 12th of about 300 Å thick of saaadium, and therefore suitable of a silicon layer on a surface of a silicon substrate 11, in which pNP transistor chips 11a, 11b, 11c and 11d were formed, from the gas phase deposited. A second metal layer 13 was placed on the first metal layer 12 vapor deposited, which was made of nickel and had a thickness of about 1,000 Å. A third metal layer 14 was vapor-deposited on the second metal layer 13 or deposited from the gas phase, which consists of a gold-germanium alloy (germanium content: 12% by weight) and had a thickness of about 1 µm. The silicon substrate 11 was then scribed on the other surface with a diamond cutter. Thereafter, the substrate 11 was divided into chips. Each chip was plated on a silver Leadframe 2 attached as shown in Fig. 3, the third metal layer 14 served as soldering material. In this way, semiconductor devices were made of which each containing a semiconductor chip.

The yield was greater than that of those produced by known processes Products. In addition, the devices exhibited a lower collector-emitter saturation voltage Vces and a lower thermal resistance Rth than those obtained by known methods manufactured semiconductor devices. More precisely, Vces of the devices lay between 0.15 and 0.20 volts, while V ces of semiconductor devices made by known methods was between 0.2 and 0.3 volts. Fig. 4 shows the distribution of thermal resistance in the semiconductor devices A1 and A2 manufactured by known methods as well as in the semiconductor device B according to Example 1. As shown in FIG shows was the thermal resistance of the semiconductor devices according to Example 1 low and varied little from device to device compared to the known semiconductor devices.

Example 2 In the same manner as in Example 1, semiconductor devices were manufactured manufactured except that NPN transistor chips are formed in the silicon substrate and the first metal layer, the second metal layer and the third metal layer made of titanium, copper or a gold-germanium-antimony alloy (antimony content: 0.1 Wt .-% based on the amount of gold germanium) were produced.

The yield was higher than that produced by known processes Products. Similar to Example 1, the semiconductor devices exhibited a smaller collector-emitter saturation voltage Vces and a smaller thermal one resistance Rth than those made by known methods Semiconductor devices. The thermal resistance Rth varied only a little from Device to device.

As a result of the proportion of antimony in the gold-germanium-antimony alloy the voltage Vces was lower than that of the semiconductor devices of the example 1.

Example 3 In the same manner as in Example 1, semiconductor devices were manufactured except that, as shown in Fig. 5, on the third metal layer 14 a fourth metal layer 15 made of gold, the thickness of which was 500 Å, vapor deposited became. The fourth metal layer 15 prevented oxidation of the third metal layer 14. The bond between the third metal layer 14 and the lead frame 2 has been established therefore not so badly affected.

The yield was higher than that produced by known processes Products. Similar to Example 1, the semiconductor devices exhibited a lower collector-emitter saturation voltage Vces and a lower thermal Resistance Rth than the semiconductor devices manufactured by known methods. The thermal resistance R th varied little from device to device.

Example 4 In the same manner as in Example 2, semiconductor devices were manufactured except that, as shown in Fig. 5, on the third metal layer 14 a fourth metal layer 15 made of gold, which had a thickness of 500 Å, was deposited became. The fourth metal layer 15 prevented oxidation of the third metal layer 14th

The bond between the third metallic layer 14 and the lead frame 2 was therefore not adversely affected.

The yield was higher than that produced by known processes Products. As in Example 1, the semiconductor w devices showed a lower one Collector-emitter saturation voltage Vces and a lower thermal resistance Rth than the semiconductor devices manufactured by known methods. Of the thermal resistance Rth varied only slightly from device to device. As a result of the antimony content in the gold-germanium-antimony alloy, the voltage V was lower than the semiconductor devices manufactured according to Beices 1 and 3.

The semiconductor device according to the invention has the following advantages on: 1) There instead of a gold foil an extremely small amount of a gold-germanium alloy is used to mount the silicon chips on the chip mounting hardware, the chips are positioned so precisely that there are no difficulties in attaching the wires develop.

2) Since no gold foil is used, the process step is one To place gold foil on a die attach part or a device for It is not necessary to carry out this process.

3) As the amount of gold, which is a very expensive metal and which one is used in the invention in the form of a gold-germanium alloy, extraordinarily is small, the device can be manufactured at a low cost.

4) Because between a silicon substrate and a gold-germanium alloy layer Metal layers are inserted that good with both silicon and can also be connected to the gold-germanium alloy, one will be sufficient strong bond between the silicon chip and the chip mounting part achieved, whereby the reliability of the device is improved.

5) Since a gold-germanium alloy instead of a Gold-silicon alloy is used, the silicon substrate can be easily can be divided into chips and the silicon substrate can be longitudinally on the upper surface Cube lines are marked, not on the alloy layers. The usage The gold-germanium alloy makes it easier to break the silicon substrate into chips for the following reason. The silicon content in the eutectic gold-silicon compound is 2.85 wt .-%, while the germanium content in the eutectic gold-germanium compound Is 12% by weight. The specific densities of gold, silicon and germanium are 19.3; 2.42 and 5.46, respectively. Thus, silicon takes up 19% by volume of the gold-silicon eutectic alloy while germanium makes up 33% of the gold-germanium alloy. Apparently is thus the gold content in volume terms in the eutectic gold-germanium alloy much smaller than in the eutectic gold-silicon alloy.

6) In general, the metal is released from the gas phase under pressure from 10 1 to 10 2 Torr.

deposited. The temperature at which gold produces such a vapor or gas pressure, is almost equal to the temperature at which germanium has a has such vapor pressure. In other words, they are the vapor pressures of gold and germanium at a temperature suitable for the vapor deposition of gold and germanium almost the same size. Unlike gold-silicon or gold-antimony, gold-germanium can easily vaporized without fractional evaporation.

For example, the vapor pressure of gold and germanium has the value at 2000 K. 5.5 x 10 Torr (see RCA Review, June 1969, pp. 292 and 293). The vapor pressure of Silicon has a value of 3.0 x 10 Torr at 2000 K.

Claims (8)

Semiconductor device Patent claims Semiconductor device with a Chip mounting part and a semiconductor element mounted thereon, thereby characterized in that the semiconductor element has the following layers: a first applied to a surface of the semiconductor element made of a metal layer Metal from the group vanadium, aluminum, titanium, chromium, molybdenum and a nickel-chromium alloy; a second applied to the first metal layer Metal layer from a metal from the group of copper, copper-based alloy, nickel and alloy nickel based; and a third metal layer applied to the second metal layer made of a gold-germanium alloy or an alloy based on gold-germanium number which acts as a solder material and the semiconductor element on the die attach part attached. 2. Semiconductor device according to claim 1, characterized in that that the germanium content of the gold-germanium alloy is 4 to 20% by weight. 3. Semiconductor device according to claim 1, characterized in that that the alloy based on gold-germanium is a gold-germanium-antimony alloy in which the germanium content and the antimony content are 4 to 20% by weight and 0.005, respectively up to 1.0% by weight based on the total weight of gold and germanium. 4. Semiconductor device according to claim 1, characterized in that that the alloy based on gold-germanium is a gold-germanium-Gailiurn alloy in which the germanium content and the gallium content are 4 to 20% by weight and 0.005, respectively up to 1.0% by weight based on the total weight of gold and germanium be. 5. Semiconductor device according to claim 3 or 4, characterized in that that the semiconductor element has a further metal layer placed on the second metal layer has, which consists of a metal from the group gold, germanium and a gold-germanium alloy is selected. 6. Semiconductor device according to one of claims 1 to 3, characterized characterized in that the semiconductor element is placed on the third metal layer has fourth metal layer, which consists of a metal from the group gold, silver and platinum is made. 7. semiconductor device according to claim 1, characterized in that that the first metal layer has a thickness of 50 to 2,000 Å, the second metal layer a thickness of 300 to 5,000 Å and the third metal layer a thickness of 0.8 to 3.5 µm. 8. The semiconductor device according to claim 4, characterized in that that the four metal layer is one Has a thickness of 500 to 5,000 Å.