JPS6329938A - Semiconductor device - Google Patents

Abstract

PURPOSE:To lengthen the lifetime of creep rupture due to the load of tensile stress generated by a temperature cycle by using a specific copper alloy inhibiting recrystallization as a bonding wire for a semiconductor element. CONSTITUTION:In a semiconductor device in which wire bondings 4 are used for connection with a semiconductor chip, a wire material, which contains one kind or two kinds or more of elements of 20-440ppm selected from Sc, Y, La and Ce or contains one kind or two kinds or more of elements of 25-250ppm selected from Sb, P, Li, Sn, Pb and Cd or one kind or two kinds or more of elements of 25-250ppm selected from Sb, P, Li, Sn, Pb and Cd and the remainder of which consists of Cu, is employed as a wire bonding raw material. Accordingly, performance stable for a prolonged term to a temperature change is displayed by using a copper wire having excellent creep strength and superior bonding properties.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a semiconductor device in which a semiconductor chip electrode and an inner lead portion of an external lead frame 21 are wire-bonded.

(Prior Art) In general, semiconductor devices such as transistors, ICs (integrated circuits), and LSIs (large-scale integrated circuits) are
The structure shown in the figure is known.

It is formed by die-bonding a pellet 2, which is a semiconductor chip, onto a die frame, electrically connecting the electrode of this pellet 2 and a lead frame 3 with a bonding wire 4, and then molding them with a resin 5. .

The bonding wire has a diameter of 20 to 10 mm and is bonded by thermocompression bonding or ultrasonic thermocompression bonding.
0μm gold, φ25~ bonded by ultrasonic method
50- aluminum alloy (e.g. AQ-1%SL, A
Ω-1%Mg) and high purity aluminum (99.9Q% or more) with a diameter of 100 to 500μ.

Currently, gold wire is used for popular type ICs and LSIs, and aluminum wire is used for cerdip type or power transistors.

Recently, the cost of gold wire cannot be ignored due to the trend toward increasing the number of pins as the degree of integration increases.

Therefore, consideration is being given to changing the bonding wire from expensive gold to relatively inexpensive copper. In addition, copper has significantly lower material resistance than gold, has high conductivity, can be made into thin wires, is less likely to form intermetallic compounds with aluminum electrodes, and has excellent high-temperature strength at joints. It has characteristics.

Bonding using copper wire involves melting the copper wire into a ball by discharging it with an electric torch or heating it with an oxyhydrogen flame in a reducing gas atmosphere such as argon, nitrogen, or hydrogen, and then attaching this ball to an aluminum electrode using a capillary. Weld while applying ultrasonic waves. At this time, the surface of the copper ball is oxidized by the invading air, and the formed ball is too hard compared to gold or aluminum balls, which may cause damage to the semiconductor chip or peeling of the wire due to insufficient bonding strength. . Therefore, S, O, and Se make copper hard.

High purity copper wire with reduced impurity elements such as Te (99%)
.

Also transistors wired by copper wire.

ICs and LSIs are generally used after being encapsulated with resin (for example, epoxy resin or silicone resin), which is superior in terms of economy and mass production. However, in the resin-sealed cord, the bonding wire is directly wrapped in resin, so tensile stress is applied to the bonding wire due to the heat generated during operation a.

This is mold resin (epoxy resin: 22~30X10
-'/'C) and bonding wire (copper: 17
x 10-'/℃) and lead frame (42 alloy:
This is because the thermal expansion coefficients of 4.5X 1o" (7℃) are significantly different, and in a high-temperature atmosphere, tensile stress is applied to the bonding wire due to the difference in thermal expansion between them. This is due to the repetitive stress caused by heat generation and cooling during operation. When tensile stress acts on the high-purity copper bonding wire for a long period of time, cracks occur at the grain boundaries directly above the copper ball bonded to the aluminum electrode, resulting in creep rupture.

There is also contact with an aluminum electrode.

(Problems to be Solved by the Invention) The present invention has been made to solve these problems, and provides a highly reliable semiconductor device using copper wire with good creep strength and excellent bonding properties. The purpose is to provide.

[Structure of the invention]

(Means for Solving the Problems) Therefore, as a result of intensive studies on the above-mentioned problems, the present inventors have found that grain boundary rupture due to creep of copper wires is caused by high temperatures associated with recrystallization of steel wires. The main reason for the decrease in strength, and one of the causes of hardening of copper balls, is that copper oxide (C
U, 0) was formed, and the present invention was unsuccessful.In other words, the present invention provides a semiconductor device using wire bonding for connection with a semiconductor chip, in which the wire bonding material is used as the wire bonding material. , Sc, Y, La and Ca at 20 to 440p of one or more elements selected from
Contains pm (wt PPI!l, below), and sb,
p.

25 to 250 ppm of one or more elements selected from Si, Sn, Pb and Cd, or Sb,
P, Li, Sn.

This semiconductor device is characterized by using a wire material containing 25 to 250 ppm of one or more elements selected from Pb and Cd, and the remainder being Cu.

(Function) Next, the effects of each element defined in the present invention and the reason for limiting the number of elements included will be explained.

When added in small amounts, Sc, Y, La, and Ce have the effect of delaying dislocation recovery and grain boundary movement during recrystallization, increasing the reconsolidation temperature, and preventing grain boundary fracture in copper wire, but if too much is added, It forms a solid solution or precipitates in copper, significantly increasing its strength.
The copper balls harden and damage the semiconductor chip, and the bonding strength decreases, making it easier for the copper balls to peel off. Therefore, the amount added was 20 to 440 ppm.

Further, Sb, Li, Sn, Pb, and Cd react with the oxygen that invades during the formation of the copper ball to produce oxides, which evaporate from the copper ball, thereby having the effect of softening the copper ball. In order to fully obtain the effect, it is necessary to add more than 25 ppm, but adding 250 ppm will leave unreacted elements in the copper ball, increasing the ball hardness and reducing the ball deformability. The range was 250 ppm.

Furthermore, As, Zn, K, Sr, Mg, Ca, and T] are vaporized from the steel during the formation of the copper ball, and have the effect of preventing oxygen from entering the ball, thereby preventing the ball from hardening. In order to fully obtain the effect, it is necessary to add more than 10 ppm, but adding 650 ppm will leave unreacted elements in the copper ball, increasing the ball hardness and reducing the ball deformability. The range was set at 650 Pρ.

Furthermore, in the present invention, in order to improve bonding properties, it is effective to reduce S and otan contained as impurities in copper. S and Q in copper are concentrated and segregated on the surface of the ball formed as shown in Figure 1.
This leads to deterioration of bonding properties. Therefore, S≦ippm,
O≦2 ppm.

(Example) The present invention will be described below based on specific examples.

Purity 99.999w obtained by zone melting method
As shown in Table 1, using high purity copper of t,% as the raw material,
Samples with a purity of 99.9 wt% or more and to which various elements were added were prepared by vacuum melting. Each ingot of φ20 was sold at 100 yen, cold drawn to 1 rra, and then annealed at 400°C for 1 hour.

Furthermore, it was made into a thin wire with a diameter of 25 mm by drawing processing. Next, the wire rod was subjected to isothermal annealing at 300' and used as a sample.

Using the obtained sample, a ball was formed by electric arc in a mixed reducing gas atmosphere of argon and hydrogen, and after bonding was performed to an aluminum electrode on a semiconductor chip and a copper lead frame plated with Ag, the electrode part was The bonding strength was measured using the Butsch test. In addition, the electrode surface from which the wire was removed was etched with hydrochloric acid, and the presence or absence of chip damage was examined using an optical microscope. These results are shown in Table 2.

By the way, samples for the comparative examples shown in Table 1 were prepared in the same manner as in the examples, and tests corresponding to the inventive examples were conducted.

As is clear from the results in Table 2, the examples of the present invention had higher bonding strength than the comparative examples, and no chip damage occurred, confirming that they had excellent bonding properties. .

Next, the wired semiconductor elements are sealed with resin, and a high temperature storage test (
200°C x 500hr) and temperature cycle test (-65
'CX30m1n→25℃X 5m1n→200℃X
100 cycles of 30 m1n) were carried out. The results are shown in Table 2.

As is clear from this table, wire peeling and wire breakage were not observed in the 9 examples of the present invention, and it was confirmed that they had excellent bonding properties and creep strength.

(Margin below) Table 1■ Table 1■ Margin below Table 2 (1) 1) Average value of 50 samples 2) The number of samples for each test is 50 per type. Table 2■ ■) Average value of 50 samples 2) The number of samples for each test above was 50 per type.

Margins below [Effects of the Invention] As explained above, the present invention uses a copper alloy that suppresses recrystallization as a bonding wire for a semiconductor element.
The rupture life of creep due to the loading of tensile stress generated by temperature cycling is greatly improved. Also, there is no oxide mixed into the ball.

Since a soft ball can be formed, bonding strength can be improved and chip damage can be prevented. Thus, according to the present invention,
It is possible to provide a semiconductor device that exhibits stable performance over a long period of time against temperature changes and has good bonding properties.

[Brief explanation of the drawing]

Figure 1 is an impurity distribution curve diagram from the surface of the copper ball. FIG. 2 is a schematic cross-sectional view showing a resin-sealed IC. 2... Pellet 3... Rad frame 4
...Bonding wire agent Patent attorney Nori Chika Yudo Kikuo Takehana

Claims (2)

[Claims] (1) In a semiconductor device using wire bonding for connection with a semiconductor chip, the wire bonding material contains 20 to 440 ppm of one or more elements selected from Sc, Y, La, and Ce. , and 10 to 650 ppm of one or more elements selected from As, Zn, K, Sr, Mg, Ca, and Tl.
Or, a semiconductor device characterized by using a wire material containing 25 to 250 ppm of one or more elements selected from Sb, P, Li, Sn, Pb, and Cd, with the remainder being Cu. (2) The semiconductor device according to claim 1, wherein the wire material as the wire bonding material further contains S at 1 ppm or less and O at 2 ppm or less.