ACTIVE EDGE STRUCTURES PROVIDING UNIFORM CURRENT FLOW IN INSULATED GATE TURN-OFF THYRISTORS

US 20140034995A1
Filed: 07/29/2013
Published: 02/06/2014
Est. Priority Date: 08/02/2012
Status: Active Grant

First Claim

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1. An insulated gate turn-off thyristor formed as a die comprising:

a first semiconductor layer of a first conductivity type;

a second semiconductor layer of a second conductivity type;

a third semiconductor layer of the first conductivity type;

a matrix of cells comprising inner cells and edge cells, wherein each of the inner cells and each of the edge cells comprises a plurality of insulated gate regions within trenches formed at least within the third semiconductor layer;

wherein, in the inner cells, a fourth semiconductor layer of the second conductivity type is formed in first areas between the gate regions near a top surface of the third semiconductor layer, the fourth semiconductor layer having a first concentration profile of dopants of the second conductivity type, wherein a vertical structure of NPN and PNP transistors is formed, and conduction between the first semiconductor layer and the fourth semiconductor layer is controlled by a voltage applied to the gate regions; and

wherein, in at least some of the edge cells, the fourth semiconductor layer having the first concentration profile of dopants of the second conductivity type is not formed in a second area between the gate regions nearest to an outer edge of the edge cells, so as to reduce a current flow near the outer edge of the edge cells.

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Abstract

An insulated gate turn-off thyristor, formed as a die, has a layered structure including a p+ layer (e.g., a substrate), an n− layer, a p-well, vertical insulated gate regions formed in the p-well, and n+ regions between the gate regions, so that vertical NPN and PNP transistors are formed. The thyristor is formed of a matrix of cells. Due to the discontinuity along the edge cells, a relatively large number of holes are injected into the n− epi layer and drift into the edge p-well, normally creating a higher current along the edge and lowering the breakover voltage of the thyristor. To counter this effect, the dopant concentration of the n+ region(s) near the edge is reduced to reduce the NPN transistor beta and current along the edge, thus increasing the breakover voltage. Alternatively, a deep trench may circumscribe the edge cells to provide isolation from the injected holes.

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21 Claims

1. An insulated gate turn-off thyristor formed as a die comprising:
- a first semiconductor layer of a first conductivity type;
  
  a second semiconductor layer of a second conductivity type;
  
  a third semiconductor layer of the first conductivity type;
  
  a matrix of cells comprising inner cells and edge cells, wherein each of the inner cells and each of the edge cells comprises a plurality of insulated gate regions within trenches formed at least within the third semiconductor layer;
  
  wherein, in the inner cells, a fourth semiconductor layer of the second conductivity type is formed in first areas between the gate regions near a top surface of the third semiconductor layer, the fourth semiconductor layer having a first concentration profile of dopants of the second conductivity type, wherein a vertical structure of NPN and PNP transistors is formed, and conduction between the first semiconductor layer and the fourth semiconductor layer is controlled by a voltage applied to the gate regions; and
  
  wherein, in at least some of the edge cells, the fourth semiconductor layer having the first concentration profile of dopants of the second conductivity type is not formed in a second area between the gate regions nearest to an outer edge of the edge cells, so as to reduce a current flow near the outer edge of the edge cells.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
- - 2. The thyristor of claim 1 wherein the second area contains a second concentration profile of dopants of the second conductivity type, and wherein the second concentration profile is less than the first concentration profile but greater than zero.
  - 3. The thyristor of claim 1 wherein the second area is the first conductivity type and has a dopant concentration profile higher than a dopant concentration profile in the third semiconductor layer.
  - 4. The thyristor of claim 1 wherein the gate regions do not extend below the third semiconductor layer.
  - 5. The thyristor of claim 1 wherein the first semiconductor layer is a substrate.
  - 6. The thyristor of claim 1 wherein the third semiconductor layer is a well.
  - 7. The thyristor of claim 1 where the second area is a first conductivity type within at least one of the first areas of the second conductivity type.
  - 8. The thyristor of claim 1 wherein, in at least some of the inner cells, the fourth semiconductor layer having the first concentration profile of dopants of the second conductivity type is not formed at least in a third area between the gate regions, so as to reduce a current flow through the at least some of the inner cells.
  - 9. The thyristor of claim 1 wherein the first semiconductor layer acts as an emitter for the PNP transistor, the second semiconductor layer acts as a base for the PNP transistor and a collector for the NPN transistor, the third semiconductor layer acts as a base for the NPN transistor and a collector for the PNP transistor, and the fourth semiconductor layer acts as an emitter for the NPN transistor.

10. An insulated gate turn-off thyristor formed as a die comprising:
- a first semiconductor layer of a first conductivity type;
  
  a second semiconductor layer of a second conductivity type;
  
  a third semiconductor layer of the first conductivity type;
  
  a matrix of cells comprising inner cells and edge cells, wherein each of the inner cells and each of the edge cells comprises a plurality of insulated gate regions within trenches formed at least within the third semiconductor layer;
  
  wherein, in the inner cells and the edge cells, a fourth semiconductor layer of the second conductivity type is formed in first areas between the gate regions near a top surface of the third semiconductor layer, wherein a vertical structure of NPN and PNP transistors is formed, and conduction between the first semiconductor layer and the fourth semiconductor layer is controlled by a voltage applied to the gate regions; and
  
  an electrically insulating first trench extending down to the first semiconductor layer between an outer gate region in the edge cells so as to circumscribe the gate regions in the matrix of cells.
- View Dependent Claims (11, 12, 13, 14)
- - 11. The thyristor of claim 10 wherein the first trench cuts through a portion of the third semiconductor layer.
  - 12. The thyristor of claim 10 wherein the first trench circumscribes the third semiconductor layer.
  - 13. The thyristor of claim 10 wherein the first semiconductor layer acts as an emitter for the PNP transistor, the second semiconductor layer acts as a base for the PNP transistor and a collector for the NPN transistor, the third semiconductor layer acts as a base for the NPN transistor and a collector for the PNP transistor, and the fourth semiconductor layer acts as an emitter for the NPN transistor.
  - 14. The thyristor of claim 10 wherein the gate regions do not extend below the third semiconductor layer.

15. An insulated gate turn-off thyristor formed as a die comprising:
- a first semiconductor layer of a first conductivity type;
  
  a second semiconductor layer of a second conductivity type;
  
  a third semiconductor layer of the first conductivity type;
  
  a matrix of cells comprising inner cells and edge cells, wherein each of the inner cells and each of the edge cells comprises a plurality of insulated gate regions within trenches formed at least within the third semiconductor layer;
  
  wherein, in the inner cells and the edge cells, a fourth semiconductor layer of the second conductivity type is formed in first areas between the gate regions near a top surface of the third semiconductor layer, wherein a vertical structure of NPN and PNP transistors is formed, and conduction between the first semiconductor layer and the fourth semiconductor layer is controlled by a voltage applied to the gate regions;
  
  wherein, in at least some of the cells, at least one second area between the gate regions is not a second conductivity type but is part of the third semiconductor layer of the first conductivity type; and
  
  a metal electrode electrically contacting the fourth semiconductor layer in the first areas and the third semiconductor layer in the second area to short the first areas to the second area.

16. The thyristor of claim 16 wherein the at least some of the cells comprises the edge cells.
- View Dependent Claims (17, 18, 19, 20, 21)
- - 17. The thyristor of claim 16 wherein the at least some of the cells comprises the inner cells.
  - 18. The thyristor of claim 16 wherein the second area is additionally doped with first conductivity type dopants to improve electrical contact between the third semiconductor layer and the metal electrode.
  - 19. The thyrisor of claim 16 wherein the at least some of the cells comprises cells distributed over the thyristor.
  - 20. The thyristor of claim 16 wherein the first semiconductor layer acts as an emitter for the PNP transistor, the second semiconductor layer acts as a base for the PNP transistor and a collector for the NPN transistor, the third semiconductor layer acts as a base for the NPN transistor and a collector for the PNP transistor, and the fourth semiconductor layer acts as an emitter for the NPN transistor.
  - 21. The thyristor of claim 16 wherein the gate regions do not extend below the third semiconductor layer.

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Current Assignee
Pakal Technologies, Inc.
Original Assignee
Pakal Technologies, LLC
Inventors
Akiyama, Hidenori, Blanchard, Richard A., Tworzydlo, Woytek

Granted Patent

US 8,878,237 B2
Time in Patent Office

Days
Field of Search
US Class Current

257/119
CPC Class Codes

H01L 29/0619 with a supplementary region...

H01L 29/7455 produced by an insulated ga...

ACTIVE EDGE STRUCTURES PROVIDING UNIFORM CURRENT FLOW IN INSULATED GATE TURN-OFF THYRISTORS

First Claim

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Abstract

12 Citations

21 Claims

Specification

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ACTIVE EDGE STRUCTURES PROVIDING UNIFORM CURRENT FLOW IN INSULATED GATE TURN-OFF THYRISTORS

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

12 Citations

21 Claims

Specification

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Use Cases

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