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A silicon carbide umosfet device with integrated tjbs

A silicon carbide and device technology, used in semiconductor devices, semiconductor/solid-state device manufacturing, electrical components, etc., can solve the problem of weak internal freewheeling capability of silicon carbide UMOSFET devices, increasing the complexity and cost of circuit systems, and incapable of device freewheeling. and other problems, to achieve the effect of improving the avalanche resistance, improving the breakdown characteristics, and improving the performance of the device

Active Publication Date: 2021-10-08
芜湖西晶微电子科技有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, due to the large bandgap of silicon carbide materials, the turn-on voltage of the parasitic PiN diodes integrated in silicon carbide UMOSFET devices is mostly around 3V, which cannot provide freewheeling for the device itself, resulting in the internal freewheeling capability of silicon carbide UMOSFET devices. weaker
Therefore, in power electronic system applications such as full bridges, an additional Schottky diode is often used in antiparallel as a freewheeling diode, which greatly increases the complexity and cost of the circuit system.
In addition, in the blocking mode, a series of reliability problems will be caused due to the strong electric field of the gate oxide at the corner of the trench

Method used

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  • A silicon carbide umosfet device with integrated tjbs
  • A silicon carbide umosfet device with integrated tjbs
  • A silicon carbide umosfet device with integrated tjbs

Examples

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Embodiment 1

[0036] See figure 1 , figure 1 It is a schematic structural diagram of a silicon carbide UMOSFET device integrating TJBS (Trenched Junction Barrier schottky) provided by an embodiment of the present invention. As shown in the figure, the silicon carbide UMOSFET device integrating TJBS in this embodiment includes:

[0037] N+ substrate region 1;

[0038] The N- epitaxial region 2 is arranged on the N+ substrate region 1;

[0039] The P-well region 3 is arranged on the N-epitaxial region 2;

[0040] The N+ injection region 4 is arranged on the P-well region 3;

[0041] The first P+ implantation region 5 is located inside the N- epitaxial region 2, and the first P+ implantation region 5 is provided with a first trench 6;

[0042] The second P+ implantation region 7 is located inside the N- epitaxial region 2 and is spaced apart from the first P+ implantation region 5, and a second trench 8 is arranged in the second P+ implantation region 7;

[0043] The gate is arranged adj...

Embodiment 2

[0066] See Figure 2a-Figure 2i , Figure 2a-Figure 2i It is a process schematic diagram of a silicon carbide UMOSFET device integrating TJBS provided by an embodiment of the present invention, and the preparation method includes the following steps:

[0067] Step a: Form N- epitaxial region 2 on N+ substrate region 1 by means of epitaxial growth, such as Figure 2a shown.

[0068] First, the thickness is 350 μm, and the doping concentration is 5×10 18 cm -3 The SiC substrate was cleaned by RCA standard, and then epitaxially grown on the N+ substrate region 1 with a thickness of 10 μm and a doping concentration of 6×10 15 cm -3 N-Epi region 2.

[0069] Step b: Etching to form a thinner N-epitaxial region 2, such as Figure 2b shown.

[0070] A mask layer is deposited on the upper surface of the N- epitaxial region 2, and a mask pattern is formed by a photolithography etching process, and then etched by an ICP etching method such as Figure 2b The N-epitaxial region 2 ...

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Abstract

The invention relates to a silicon carbide UMOSFET device integrating TJBS, comprising: N+ substrate region, N-epitaxy region, P-well region, N+ injection region, first P+ injection region, second P+ injection region, gate, source electrode and drain, wherein the second P+ implantation region is spaced from the first P+ implantation region and has the same depth, the first P+ implantation region is provided with a first trench, and the second P+ implantation region is provided with a second trench, The depth of the gate is greater than the depth of the P-well region and less than the depth of the first P+ implantation region, and the interface between the source and the P-well region, the N+ implantation region, the first P+ implantation region, and the second P+ implantation region is an ohmic contact, The interface between the source and the N-epi region is a Schottky contact. In the device of the present invention, a trench structure is introduced into the Schottky diode structure integrated in the device, so that the depths of the first P+ implantation region and the second P+ implantation region are increased, and the thinner N-epitaxy formed by etching P+ implantation is carried out on the surface of the region, which makes the depth of the P+ implantation region larger and improves the avalanche resistance of the device.

Description

technical field [0001] The invention belongs to the technical field of semiconductors, and in particular relates to a silicon carbide UMOSFET device integrating TJBS. Background technique [0002] In recent years, with the continuous development of power electronic systems, higher requirements have been placed on the power devices in the system. Silicon (Si)-based power electronic devices have been unable to meet the requirements of system applications due to the limitations of the material itself. As a representative of the third-generation semiconductor material, silicon carbide (SiC) materials are far better than silicon materials in many characteristics. Silicon carbide MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor, Metal-Oxide-Semiconductor Field-Effect Transistor) device, as a commercialized device in recent years, has an alternative in terms of on-resistance, switching time, switching loss and heat dissipation performance. The huge potential of the existi...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H01L29/78H01L21/336H01L29/06H01L29/16H01L29/423
CPCH01L29/0603H01L29/0684H01L29/1608H01L29/4236H01L29/66068H01L29/7827H01L29/7839
Inventor 汤晓燕余意何艳静袁昊宋庆文张玉明
Owner 芜湖西晶微电子科技有限公司
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