DE1207507B - Process for the production of a planar alloy transistor consisting of germanium or silicon - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

HOIl

German KL: 21g -11/02

Number: 1207 507

File number: S 48077 VIII c / 21 g

Filing date: March 23, 1956

Opening day: December 23, 1965

The invention is concerned with a method for the production of a planar, from germanium or silicon alloy transistor with two resting on the surface of the semiconductor Electrodes, which are made of metallic, closely spaced and in the manner of two combs of interlocking wires exist, the wire ends each having a comb opposite sides are connected to each other, and with one on the opposite Surface of the semiconductor body lying electrode. The small distance between the emitter and The base electrode and its dimensions are known to be a prerequisite for applicability of the transistor for particularly high frequencies. However, the alloying processes known up to now did not work only minimum clearances, which are in the order of one or half a millimeter lay. For example, it is known to use a grid-like arrangement of parallel wires, which are coated with the same doping material and opposite in the alloying process Generate conductivity as it has the semiconductor body. On the other hand, it is known to use high frequency transistors produced by emitter and base side by side on one side of the crystal in a small, for example 25 μ distance, are vapor deposited while the collector is on the opposite side of the platelet.

The invention now provides a way of how by combining these known measures an ultra-high frequency power transistor is achieved which is easy to manufacture. According to the invention For the production of the two electrodes, a tension grid known from tube technology is made from alternately used wires sheathed with different material, the wires with the same material on one side to form a comb-like electrode and the wires cut with the other material on the same side and the two comb-like electrodes generate the base and emitter electrodes, and the collector electrode on the opposite one Surface or made inside the semiconductor body.

Opposite a transistor that has the emitter and base vapor-deposited on one side of the crystal the semiconductor arrangement according to the invention a great advantage in production, since not afterwards Contacts must be made, in any case with extremely small vapor-deposited Layers are very difficult to implement.

Process for the production of a two-dimensional,
made of germanium or silicon
Alloy transistor

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,

Munich 2, Witteisbacherplatz 2

Named as inventor:

Dr. Karl Siebertz, Munich

The mutual electrode distances that can be achieved in this way are of the order of magnitude from about 6 to 30 µ; the individual wire thicknesses are roughly in the same order of magnitude. The wire material expediently consists of the material customary in tensioning grids for electron tubes, z. B. molybdenum or tungsten. The coating with alloy material is expedient by sputtering, vapor deposition, immersion in a melt and / or by galvanic means. as The base material is gold, silver or another precious metal in a known manner.

By dimensioning the jacket thickness and / or alloy duration and temperature and / or selection of the doping material and, if necessary, a subsequent thermal treatment leaves it achieve that desired doping gradients arise, which, for example, a hook or Cause drift effect.

With reference to the drawing, in which some embodiments according to the invention, for example are shown, the idea of the invention is explained in more detail.

F i g. Fig. 1 shows a tension grid made in a manner known per se with spars 1 and 2, above which, according to the invention, two separate sheathed wires are wound up alternately. The drawn one Wire 3 has a gold-antimony jacket, while wire 4, shown in dashed lines, has a is provided with a sheath made of indium. The core material of both wires consists of molybdenum.

According to FIG. 2 is one side of the grid on a semiconductor single crystal made of germanium, silicon or placed one of the known alloys and heated together with this so high and long that the wires become embedded in the semiconductor surface

509 759/423

alloy. The emitter wires are on the left and the semiconductor crystal on the right cut the base wires and removed this from the one on that side Bracket of the spar 1 or 2 separately. In this state the FIG. 2 drawn, which two into each other shows chimney-like entangled systems of base and emitter wires, of which the emitter wires 4 are connected to one another by the spar and the base wires 3 by the spar 2.

F i g. 3 shows a cross section through the alloy transistor produced in this way. The cross-sections marked with E through the wires of the tensioning grid are the emitter wires 4, while the cross-sections marked with B belong to the base wires 3. The inner circle in cross-sections E and B indicates the molybdenum wire core, while the hatched zone below the large circles indicates the alloy zone which the gold or indium formed with the semiconductor material. On the opposite side of the semiconductor crystal, a flat collector C is made of indium in the usual way, which is provided with a feed 6 which is attached to the collector C or otherwise with it in a manner known per se. The collector C shown is also made by alloying. It is also possible to create the collector p-n junction before alloying the tension grid close to the upper surface of the crystal by diffusing in or otherwise introducing impurities.

An exemplary embodiment is shown in FIG. according to which the tensioning grid with the spars 1 and 2 has a considerable length, so that several semiconductor crystals 5, 5 ', 5 ", 5"' etc. can be covered by it at the same time and the alloying can be done for a number of transistors simultaneously. In appropriate Way can optionally also the other side of the grille later or at the same time can be used for alloying into a semiconductor crystal or a large number of semiconductor crystals.

45

Claims (5)

Patent claims: 1. Process for the production of a planar, consisting of germanium or silicon Alloy transistor with two resting on a surface of the semiconductor body Electrodes, which are made of metallic, closely spaced and after Kind of consist of two combs of interlocking wires, the wire ends depending of a comb are connected to each other on opposite sides, and with one on the opposite surface of the semiconductor body lying electrode, characterized in that that for the production of the two electrodes a tension grid known from tube technology alternating with different ones Material sheathed wires is used, the wires with the same material combined on one side to form a comb-like electrode and the wires with the cut through another material on the same side and the two comb-like Electrodes create the base and emitter electrodes, and the collector electrode on the opposite surface or in the interior of the semiconductor body is produced. 2. The method according to claim 1, characterized in that the sheathing with alloy material is carried out by dusting, vapor deposition and / or by galvanic means. 3. The method according to any one of claims 1 and 2, characterized by such a dimensioning the jacket thickness and / or alloy duration or temperature and / or selection of the alloy material as well as by, if necessary subsequent thermal treatment that the desired doping gradients arise for example cause a hook or drift effect. 4. The method according to any one of claims 1 to 3, characterized in that the wires a long tension grid can be alloyed onto several separate semiconductor crystals at the same time. 5. The method according to any one of claims 1 to 4, characterized in that the mutual Distances between the wires and possibly also the individual wire thicknesses of an order of magnitude from 6 to 30 μ can be selected. Considered publications:
German Patent No. 137,800;
Austrian Patent No. 181629;
U.S. Patent Nos. 2597028, 2721965;
Proc. IRE, 40, 1952, pp. 1512 to 1518;
Bell System techn. Journ., 35, 1956, pp. 23 to 34. 1 sheet of drawings 509 759/423 12.65 ® Bundesdruckerei Berlin