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A kind of bidirectional igbt device and manufacturing method thereof

A device and N-type technology, applied in the field of insulated gate bipolar transistors and bidirectional trench gate insulated gate bipolar transistors, can solve the problems of poor reliability of devices, deterioration of short-circuit safe working area, and increase of saturation current density. Achieve the effects of improving carrier concentration distribution, improving short-circuit safe working area, and reducing saturation current density

Inactive Publication Date: 2018-10-02
UNIV OF ELECTRONICS SCI & TECH OF CHINA
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, for this bidirectional IGBT structure, when the forward or reverse IGBT works, the breakdown voltage of the device is significantly higher due to the higher doping concentration of the carrier storage layer and the existence of a certain thickness of the N-type layer 8 or 28. Reduce, in order to effectively shield the adverse effects of the N-type layer as the carrier storage layer and obtain a certain device withstand voltage, it is necessary to adopt: 1) deep trench gate depth, so that the depth of the trench gate is greater than the N-type layer 8 or 28 junction depth, but the deep trench gate depth not only increases the gate-emitter capacitance but also increases the gate-collector capacitance when working in either direction, thus reducing the switching speed of the device and increasing The switching loss of the device affects the compromise characteristics of the conduction voltage drop and switching loss of the device; 2) The small cell width makes the distance between the trench gates as small as possible, however, when working in any direction, the high The dense trench MOS structure not only increases the gate capacitance of the device, reduces the switching speed of the device, increases the switching loss of the device, and affects the compromise characteristics of the conduction voltage drop and switching loss of the device, but also, high The dense trench MOS structure increases the saturation current density of the device, making the short-circuit safe working area of ​​the device worse
Additionally, for figure 1 and 2 In the bidirectional IGBT structure shown, the gate oxide layer is formed in the trench by one thermal oxidation. In order to ensure a certain threshold voltage, the thickness of the entire gate oxide layer is small. Since the MOS capacitance is inversely proportional to the thickness of the oxide layer, traditional The small gate oxide thickness in the bidirectional IGBT structure greatly increases the gate capacitance of the device
In addition, the small gate oxide thickness concentrates the electric field at the bottom of the trench, making the device less reliable

Method used

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  • A kind of bidirectional igbt device and manufacturing method thereof
  • A kind of bidirectional igbt device and manufacturing method thereof
  • A kind of bidirectional igbt device and manufacturing method thereof

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0041] A bidirectional IGBT device with a cell structure such as image 3 As shown, it includes two N-channel MOS structures symmetrically arranged on both sides of the N-type drift region 10; the front MOS structure includes a front metal electrode 1, a front N+ emitter region 5, a front P+ emitter region 6, and a front P-type Base region 7, front N-type layer 8 and front trench gate structure; the front P-type base region 7 is located on the upper surface of the front N-type layer 8, and the front N+ emitter region 5 and the front P+ emitter region 6 are located side by side on the front P-type base region. The upper surface of the region 7; the upper surfaces of the front N+ emission region 5 and the front P+ emission region 6 are connected to the front metal electrode 1; the back MOS structure includes a back metal electrode 21, a back N+ emission region 25, a back P+ emission region 26, The P-type base region 27, the back N-type layer 28 and the back trench gate structure...

Embodiment 2

[0047] A bidirectional IGBT device in this example, its cell structure is as follows Figure 4 As shown, on the basis of Embodiment 1, the width of the front bottom electrode 13 is greater than the width of the total trench gate structure on it and extends into the N-type layer 8, so that the front trench gate structure is in an inverted "T" shape ; The backside MOS structure is connected and arranged mirror-symmetrically with the front side MOS structure along the centerline of the N-type drift region 10 up and down. The width of the composite trench structure substructure extending into the N-type layer 8 / 28 is about 1 / 4-3 / 4 of the width of the p-type base region 7 / 27. The lower layer structure extending into the N-type layer 8 / 28 further reduces the extraction area of ​​minority carriers, further improves the carrier injection enhancement effect of the emitter terminal, and can obtain better forward voltage drop of the device The compromise between switching loss and switc...

Embodiment 3

[0049] A bidirectional IGBT device in this example, its cell structure is as follows Figure 5 As shown, on the basis of Example 2, there is also a layer of N+ layer 14 / 214 in the partial area between the lower layer structure of the front / back composite trench structure and the p-type base region 7 / 27, and the N+ layer The concentration of 14 / 214 is greater than the concentration of N-type layer 8 / 28 and its sidewall is connected to the composite trench structure; one side of the N+ layer 14 / 214 is connected to the front N-type layer 8 / 28, and the N+ layer 14 / 214 The other side and bottom of the N+ layer are connected to the trench gate structure, and the upper surface of the N+ layer 14 / 214 is connected to the lower surface of the P-type base region 7 / 27; the width of the formed N+ layer 9 / 29 is smaller than that extended into the N-type The width of the underlying structure of the composite trench structure in layer 8 / 28. The formed N+ layer 14 / 214 further reduces the resi...

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Abstract

A bidirectional IGBT device and a manufacturing method thereof belong to the technical field of power semiconductor devices. The present invention adopts a wide trench width on the front and back of the device and introduces an electrode connected to the metal electrode at the bottom of the gate electrode in the trench, without affecting the threshold voltage and turn-on of the IGBT device. The reverse characteristic improves the forward and reverse switching speed of the bidirectional IGBT device, reduces the switching loss of the device; improves the carrier concentration distribution in the entire N-type drift region, and improves the compromise between the forward conduction voltage drop and switching loss The saturation current density of the device is reduced, the short-circuit safe working area of ​​the device is improved, the concentration of the electric field at the bottom of the trench is improved, the breakdown voltage of the device is improved, and the reliability of the device is further improved; the manufacturing method provided by the invention The trench is filled by two electrode filling processes, the process difficulty is small, and it is compatible with the traditional bidirectional IGBT manufacturing method.

Description

technical field [0001] The invention belongs to the technical field of power semiconductor devices, and relates to an insulated gate bipolar transistor (IGBT), in particular to a bidirectional trench gate insulated gate bipolar transistor (Bi-directional trench IGBT). Background technique [0002] Insulated Gate Bipolar Transistor (IGBT) is a new type of power electronic device combining MOS field effect and bipolar transistor. It not only has the advantages of easy driving and simple control of MOSFET, but also has the advantages of low conduction voltage of power transistor, large on-state current and small loss. It has become one of the core electronic components in modern power electronic circuits and is widely used in Various fields of the national economy such as communications, energy, transportation, industry, medicine, household appliances and aerospace. The application of IGBT plays an extremely important role in improving the performance of power electronic syste...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H01L29/739H01L29/423H01L21/331
CPCH01L29/42312H01L29/66325H01L29/7395
Inventor 张金平刘竞秀李泽宏任敏张波李肇基
Owner UNIV OF ELECTRONICS SCI & TECH OF CHINA
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