RU160937U1 - INTEGRATED SCHOTKI p-n DIODE - Google Patents

Abstract

The Schottky integrated pn diode, consisting of an epitaxial structure, the working side of which is covered with a dielectric layer, a guard ring made by diffusion, the type of conductivity opposite to the type of conductivity of the epitaxial structure, the contact window of the anode in the dielectric layer, distributed rows of bands of local pn junctions made simultaneously with security ring, and Schottky junctions made in the recesses in the contact window of the anode, characterized in that the local pn junctions are made on the protrusions, formed in the contact window of the anode of height h, selected from the ratio of 0.15x≤h≤0.5x, where x is the diffusion depth of the guard ring.

Description

The utility model relates to the field of electronic technology, namely, to the design of creating high-voltage semiconductor diodes, and can be used to create integrated Schottky p-n diodes.

Schottky barrier diodes have the advantage of being able to block a large reverse voltage at a relatively high level of doping of the base, and a high level of doping, in turn, provides little resistance in the forward direction. Technical solutions in the manufacture of Schottky diodes (DS) by various manufacturers are largely similar. Integrated systems of the JBS type (Junction Barrier Schottky diode, JBS diode) in which local pn junctions are interspersed with Schottky contacts (see, for example, SJ Kim, S. Kim, S.C. Kim , IH Kang, KH Leeand, T. Matsuoka // MaterialsScienseForum. Vol. 556-557, 2007, p. 869 and U.S. Patent No. WO 2006122252, class H01L 29/872, publ. 11.16.06).

When the diode is turned on in direct bias, a current of high density flows through it. When applying reverse voltage, the charge carriers that are in the base of the diode can be pulled together in cords. The current density in the cords can significantly exceed the working density, which leads to a local temperature increase and burnout of the diode. To prevent thermal damage, strips of p + regions are introduced over the entire area of the Schottky diode. These areas are made in the form of continuous concentric or linear strips alternating with Schottky contact strips. With increasing temperature, the resistance of doped semiconductors between p + regions increases to degeneracy. Since the resistance of the portion where the current cord passes increases, the amount of current in the cord decreases. That is, there is a negative feedback between local current lacing and the resistance of the lacing portion. And thus, the diode resistance to high current densities and high switching speeds is significantly increased. To increase the ultimate energy of avalanche breakdown, several thousand of these p + bands are introduced. p + bands divide the reverse current cord into many small ones. This reduces the instantaneous temperature of the semiconductor and increases the resistance to secondary breakdown.

The distances between the pn junctions are selected based on the depth of the pn junction. For example, at a pn junction depth of 5 μm, the distance between the pn junction bands can be from 8 μm to 19 μm so as to provide the necessary resistance to the effect of avalanche breakdown energy at reverse bias, see U.S. Patent 7,071,525 B2 U.S. C.L. 257/471 from 07/07/06

The disadvantage of these devices is the increased voltage drop when the diodes work in the forward direction due to a decrease in the effective Schottky contact area and damage to the Schottky contact when welding flexible leads to its metallization.

The closest to the proposed utility model in technical generality and the achieved result is the device according to the patent of the Republic of Belarus BY 18137, class H01L 29/872, which describes an integrated Schottky pn diode consisting of an epitaxial structure, the working side of which is covered with a layer of dielectric, guard ring, made by diffusion, the type of conductivity opposite to the type of conductivity of the epitaxial structure, the contact window of the anode in the dielectric layer, the distributed rows of bands of local planar pn junction s made simultaneously with the guard ring, and Schottky transitions made in the recesses in the contact window of the anode.

The disadvantages of the previous analogues in the prototype were partially eliminated, however, when forming rows of bands of local planar p-n junctions to reduce the series resistance in the integrated Schottky p-n diode, their linear dimensions in the Schottky contact plane should be minimal. The minimum size is determined by the resolution of photolithography and lateral diffusion of p-impurities during the formation of p-n junctions. Lateral diffusion increases the minimum size. This effect is especially pronounced in the p-n junctions of integrated Schottky p-n diodes at operating voltages up to 100-120 V.

The purpose of the utility model is to increase the effective Schottky contact area to reduce direct voltage drop.

This goal is achieved in that, in contrast to the known device in the proposed utility model of an integrated Schottky pn diode consisting of an epitaxial structure, the working side of which is coated with a dielectric layer, a protection ring made by diffusion, the type of conductivity opposite to the type of conductivity of the epitaxial structure, the contact window of the anode in the dielectric layer, distributed rows of bands of local planar pn junctions made simultaneously with the guard ring, and Schottky junctions made in recesses in the contact window of the anode, local planar pn junctions are performed on the protrusions formed in the contact window of the anode with a height h selected from the relation 0.15x _j ≤h≤0.5x _j , where x _j is the diffusion depth of the guard ring.

New in the proposed utility model is that local planar pn junctions are made on the protrusions formed in the contact window of the anode with a height h selected from the relation 0.15x _j ≤h≤0.5x _j , where x _j is the diffusion depth of the guard ring .

In the manufacture of Schottky integrated p-d diodes with local planar p-n junctions made on protrusions, the influence of lateral diffusion of the p-impurity during the formation of p-n junctions is insignificant, and the minimum dimensions are determined only by the resolution of photolithography.

The minimum height of the projections due to the fact that almost 90% of the dopant in the surface portion is thick 0,15x _j. At a lower height of the protrusions, the influence of the lateral diffusion of the p-impurity on the series resistance in the integrated Schottky pn diode is enhanced and the effect is not achieved.

The greatest height of the protrusions is due to the fact that with a greater height of the protrusion, the efficiency of the integrated Schottky p-n diodes decreases with the reverse bias supplied to the diode, which leads to an increase in reverse currents.

The essence of the proposed utility model is illustrated by figures. In FIG. 1 shows a section of the proposed integrated Schottky p-n diode. In FIG. 2 shows an enlarged image of the pn junction on the protrusion.

With reference to FIG. 1, 2 are indicated:

1 - substrate of n ⁺ type conductivity;

2 - epitaxial film of n-type conductivity;

3 - a guard ring;

4 - a protective layer of SiO ₂ ;

5 - protrusions;

6 - local p-n junctions (JBS structures);

7 - contact window of the anode;

8 - recesses in the contact window of the anode;

9 - Schottky molybdenum contact;

10 - a layer of aluminum metallization;

11 - metallization of the cathode;

12 is a p-n junction configuration of an integrated Schottky p-n diode made by diffusion into the planar part of the anode;

A is the minimum resolution of photolithography.

The device and manufacturing process of the proposed semiconductor device is described below.

On an epitaxial n ⁺ substrate 1 (see Fig. 1) doped with arsenic up to a resistivity of 0.003 Ω · cm, an n-type epitaxial film 2 of 10 μm thickness with a resistance of 2 Ω · cm is formed. Then the surface of the epitaxial film is doped with boron with a dose of 10 ¹⁴ cm ^-2 and an energy of 40 keV by ion implantation. Next, an operation is performed to mask the areas of the guard rings 3 and local pn junctions 6, for example, using photoresist and isotropic etching in a plasma to a depth of 0.3 μm. Then the surface of the plate is oxidized at a temperature of 1100 ° C for 100 minutes. In this case, the formation of a protective layer of SiO ₂ 4 with a thickness of 0.3 μm and local diffusion of the regions of the guard rings 3 and local pn junctions 6 to a depth of x _j 1.7 μm. Then open the contact window of the anode 7 to the epitaxial layer with pn junctions. Next, a layer of molybdenum 9 with a thickness of 0.15 μm and a layer of aluminum 10 with a thickness of 2.5 μm are applied by electron beam spraying. Then photolithography on metal is carried out to form the metallization of the anode and Schottky contact and heat treatment at a temperature of 450 ° C in argon. Local pn junctions of the Schottky contact are localized on the protrusions 5, and in the recesses 8 a Schottky silicon-molybdenum contact is formed. The metallization of the cathode 11 is formed by sequential sputtering of titanium with a thickness of 0.1 μm, nickel with a thickness of 0.5 μm and silver or gold with a thickness of 0.5 μm.

In FIG. 2 shows an enlarged image of the local pn junction region on the protrusion. When using positive photoresist, the local transition region is masked by opaque areas with size A, which is determined by the minimum resolution of photolithography. For example, in contact photolithography using unfiltered radiation from a mercury lamp, size A is about 2.5 microns. Then, when etching the recesses 8, the size of the protrusion 5 doped with boron decreases due to lateral etching by an amount of the order of 0.6-0.9 μm, and when conducting diffusion of boron, the region of the local pn junction decreases in width due to the walls of the protrusion 5. For comparison, in FIG. Figure 2 shows the configuration of the local pn junction 12 into the flat surface of the epitaxial layer. As can be seen from figure 2, when carrying out technological operations in the above modes, the width of the local transition on the protrusion will be approximately 1.6-1.9 microns, and when diffused into the flat surface of the epitaxial layer - 5-5.2 microns.

Thus, the effective Schottky contact area will increase due to a decrease in the size of local pn junctions.

Table 1 shows the experimental data for determining the influence of the height of the protrusion on the residual voltage of the integrated Schottky pn diodes, the design of which is described above. Anode area (including JBS-structure) was 1 mm ^2, the current density - 1 A / mm ^2.

As can be seen from the table, the optimal parameters of the diode for U _ost and I _{arr are} achieved with a protrusion height of 0.24-0.85 microns.

It should be noted that the formation of depressions in the anode contact can be carried out not only by etching, but also by local oxidation with masking with silicon nitride of the guard ring sections and local p-n junctions inside the Schottky contact.

Claims (1)

An integrated Schottky pn diode consisting of an epitaxial structure, the working side of which is coated with a dielectric layer, a guard ring made by diffusion, the type of conductivity opposite to the type of conductivity of the epitaxial structure, the contact window of the anode in the dielectric layer, distributed rows of local pn junction bands made simultaneously with security ring, and Schottky transitions made in the recesses in the contact window of the anode, characterized in that the local pn junctions are made on the protrusions, formed h anode contact window height h, the ratio selected from 0,15x _j ≤h≤0,5x _j, where x _j - diffusion depth of the guard ring.

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