Vertical junction field effect power transistor
A semiconductor vertical junction field effect power transistor formed by a semiconductor structure having top and bottom surfaces and including a plurality of semiconductor layers with predetermined doping concentrations and thicknesses and comprising at least a bottom layer as drain layer, a middle layer as blocking and channel layer, a top layer as source layer. A plurality of laterally spaced U-shaped trenches with highly vertical side walls defines a plurality of laterally spaced mesas. The mesas are surrounded on the four sides by U-shaped semiconductor regions having conductivity type opposite to that of the mesas forming U-shaped pn junctions and defining a plurality of laterally spaced long and vertical channels with a highly uniform channel opening dimension. A source contact is formed on the top source layer and a drain contact is formed on the bottom drain layer. A gate contact is formed on the bottom of the U-shaped trenches for the purpose of creating and interrupting the vertical channels so as to turn on and turn off the transistor.
This invention relates to the creation and design of power semiconductor switches. More specifically, this invention relates to vertical junction field-effect power transistors with long vertical channels all having a highly uniform channel opening dimension defined and controlled by highly vertical p+n junctions.
BACKGROUND OF THE INVENTION SiC power devices have been intensively investigated for the past 13 years. High power SiC vertical junction field effect-transistors (VJFETs) have attracted great attention for high temperature applications because VJFETs do not suffer from the low channel mobility problem of SiC MOSFETs. One SiC VJFET attempt, U.S. Pat. No. 6,107,649 to J. H. Zhao entitled Field-controlled high-power semiconductor devices, the disclosure of which is hereby incorporated as reference, solves the problem of high electric field in the gate oxide of SiC MOSFETs by using lateral FETs to control the conduction of vertical channels without the need of epitaxial regrowth.
Purely vertical JFETs without the lateral JFETs have also been attempted but mostly in the forms of static induction transistors (SITs) which do not have long and highly uniform opening vertical channels defined and controlled by vertical pn junction gates. One attempt, as shown in
Therefore, it is obvious to those skilled in the art that pure vertical JFETs with gate junctions formed by normal incident ion implantation without long vertical channels of a highly uniform channel opening dimension are not desirable for the implementation of normally-off operation. It is also obvious to those skilled in the art that pure vertical JFETs can not offer optimum normally-on operation when the gate junctions are formed by normal incident ion implantation without long vertical channels of a highly uniform channel opening dimension because an excessive negative gate bias is needed to create a barrier with enough depth to block desired voltages.
There is, therefore, a clear need to design a better performing SiC VJFET with long vertical channels all having a highly uniform channel opening dimension defined and controlled by highly vertical gate p+n junctions so that higher power capability can be achieved with lower device resistance for either normally-off or normally-on operation.
SUMMARY OF THE INVENTIONThis invention provides new designs and implementations of pure vertical JFETs (VJFEETs) ideally suited for realization in wide bandgap semiconductors such as SiC, GaN, diamond and the more traditional semiconductors such as silicon and GaAs as well as any other semiconductors suitable for high power and high frequency applications. The device includes a large number of paralleled cells fabricated on wafers with an n+-n−-n-n++ structure, where the n++ is the top source layer for the source ohmic contact and for defining the boundary of the vertical p+n junction gates remote from the top surface. The n− layer forms the drift or blocking layer. The n layer is the channel layer used to form the vertical mesas and vertical channels. The n− layer is for the blocking layer. The n+ region is the bottom drain layer or substrate upon which the n− blocking layer, the n channel layer n and the n++ source layer are grown. Each cell contains a highly vertical mesa defined by deep U-shaped trenches in the semiconductor with the center region of each mesa forming the long vertical channel of the cell. On each of the four side walls of a mesa, a U-shaped gate p+n junction is formed by angled or titled ion implantation of acceptors whose energy controls the vertical channel opening dimension, resulting in a highly uniform vertical channel opening. Gate ohmic contacts are placed on the bottom of the U-shaped trenches on p++ region selectively formed by ion implantation on the bottom of the U-shaped p+n junction. The trenches are planarized by a standard planarization technique such as spin-coating of polyimide. Source ohmic contacts are placed on the mesa surface of the n++ top source layer. Drain ohmic contact is formed on the n+ bottom surface of the bottom drain layer. The n− blocking layer and the n channel layer can be combined into a single n layer when separate optimization of the blocking and channel layers are not required.
BRIEF DESCRIPTION OF THE DRAWINGS
Now referring to
In order to experimentally achieve the highly vertical channel with a highly uniform opening dimension throughout the entire vertical channel region and the entire wafer, it is critically important to use a heavily doped thick n++ source layer 60, thick enough so that (i) self-aligned (by using metal on mesa as implantation mask) and tilted or angled implantation can be used to create p+ vertical side walls without converting any part of the top source layer 60 from n-type to p-type (as illustrated by
In the blocking mode, the VJFET of
Referring now to
While the preferred embodiments and specific examples are described herein those skilled in the arts would appreciate the fact that other variations are possible based on the invention. For example, the vertical channels can be formed by epitaxial refilling of p+ SiC into the U-shaped trench regions to define the desired vertical channels with a highly uniform channel opening dimension. As another example, the conductivity type of each
LIST OF REFERENCE ATTACHED
- 1. J. H. Zhao, U.S. Pat. No. 6,107,649 entitled Field-controlled high-power semiconductor devices.
2. K. Asano et al. in IEEE ISPSD-2002, pp. 61-64, entitled 5 kV 4H-SiC SEJFET with low RonS of 69 mΩ cm2.
- 3. R. R. Siergiej et al., U.S. Pat. No. 5,903,020, entitled Silicon Carbide static induction transistor structure.
- 4. J. Nishizawa et al. in IEEE Transactions on Electron Devices, Vol. 4, No. 2, February 2000, pp. 482-487, entitled The 2.45 GHz 36 W CW Si recessed gate type SIT with high gain and high voltage operation.
- 5. H. Onose, et al. in Materials Science Forum, Vols. 389-393, 2002, pp. 1227-1230, entitled 2 kV 4H-SiC junction FETs.
- 6. J. H. Zhao et al., in IEEE ISPSD-2003, pp. 50-52, entitled 3.6 mΩ cm2, 1,726V 4H-SiC normally-off trenched-and-implanted vertical JFETs.
- 7. J. H. Zhao et al., in IEE Electronics Letters, Vol. 39, No. 3, Feb. 6, 2003, pp. 321-323 entitled demonstration of a high performance 4H-SiC vertical junction field effect transistor without epitaxial regrowth.
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FIG. 1 shows prior art in the design of SiCVJFETs. -
FIG. 2 shows prior art in the design of SiC VJFETs. -
FIG. 3 shows prior art in the design of SiC static induction transistors (SITs). -
FIG. 4 shows prior art in another design of SiC static induction transistors (SITs). -
FIG. 5 shows prior art in yet another design of SiC static induction transistors (SITs). -
FIG. 6 shows prior art in the design of Si SITs. -
FIG. 7 shows prior art in the design of long vertical channel and high voltage SiC VJFETs. -
FIG. 8 shows cross sectional view embodying one form of the invention. -
FIG. 9 shows cross sectional view of formation of a long vertical channel with a highly uniform channel opening dimension by titled ion implantation of acceptors using thick and heavily doped n++ source layer by a self-aligned process. -
FIG. 10 shows cross sectional view embodying another form of the invention. -
FIG. 11 shows the cross sectional view of a 4H-SiC VJFET designed and fabricated according to the invention using a single 7×1015cm−3 doped n-type layer for the drift layer as well as the vertical channel n layer. -
FIG. 12 shows the experimental room temperature I-V curves for the fabricated 4H-SiC VJFET. -
FIG. 13 shows the cross sectional view of a design for a 14 kV SiC VJFET. -
FIG. 14 shows the simulated I-V curves for the 14 kV Sic VJFET designed.
Claims
1. A semiconductor vertical junction field-effect power transistor formed by a semiconductor structure having top and bottom surfaces and including a plurality of semiconductor layers with predetermined doping concentrations and thicknesses and comprising
- (a) At least a bottom layer as drain layer of said transistor, a middle layer as blocking and channel layer of said transistor, a top layer as source layer of said transistor;
- (b) a plurality of laterally spaced U-shaped trenches with highly vertical side walls defining a plurality of laterally spaced mesas in said semiconductor structure;
- (c) said highly vertical side walls making an angle of β with respect to the said top surface of said semiconductor structure;
- (d) said mesas surrounded on the four sides perpendicular to said top surface by U-shaped semiconductor regions; said U-shaped semiconductor regions having conductivity type opposite to the conductivity type of said mesas, forming U-shaped pn junctions;
- (e) said U-shaped pn junctions having selectively and heavily doped regions formed on the bottom of said U-shaped pn junctions for the formation of gate ohmic contacts; said selectively and heavily doped regions having same conductivity type as said U-shaped semiconductor regions;
- (f) said U-shaped junctions defining a plurality of laterally spaced vertical channel of length LVC in said mesas with a uniform channel opening dimension of d0 along the vertical channel;
- (g) said top surface having ohmic contact forming the source of said transistor;
- (h) said U-shaped junctions having ohmic contacts to the bottom of said U-shaped junctions forming the gate of said transistor;
- (i) said semiconductor structure having ohmic contact on said bottom surface of said structure forming the drain of said transistor;
- (j) said semiconductor structure having a top source layer more heavily doped than the doping densities of both sides of the vertical part of said U-shaped junctions;
2. A vertical junction field-effect power transistor according to claim 1 wherein
- (a) said angle β is 90°;
- (b) said angle β is within the range of 90°±5°;
- (c) said angle β is within the range of 90°±10°;
- (d) said angle β is within the range of 90°±20°;
- (e) said angle β is within the range of 90°±30°;
- (f) said channel opening dimension d0 is constant along and within said vertical channel;
- (g) said channel opening dimension d0 is within the range of d0±5% d0 along and within said vertical channel;
- (h) said channel opening dimension d0 is within the range of d0±10% d0 do along and within said vertical channel;
- (i) said channel opening dimension d0 is within the range of d020% d0 along and within said vertical channel;
- (j) said channel opening dimension d0 is within the range of d0±30% d0 along and within said vertical channel;
- (k) said channel length LVC is in the range of 0.5 to 1.5um;
- (l) said channel length LVC is in the range of 1.5 to 2.5um;
- (m) said channel length LVC is in the range of 2.5 to 3.5um;
- (n) said top source layer thickness is within the range of 0.2 to 2um;
- (o) said top source layer thickness is within the range of 0.2 to 4um.
3. A vertical junction field-effect power transistor according to claim 2 wherein said plurality semiconductor layers including a first layer of first conductivity type for drain ohmic contact, a second layer of first conductivity type on top of said first layer as blocking and channel layer, a third layer of first conductivity type as top source layer.
4. A vertical junction field-effect power transistor according to claim 2 wherein said plurality semiconductor layers including a first layer of first conductivity type for drain ohmic contact, a second layer of first conductivity type on top of said first layer as blocking layer, a third layer of first conductivity type on top of said second layer as channel layer, and a fourth layer of first conductivity type on top of said third layer as top source layer.
5. A vertical junction field-effect power transistor according to claim 2 wherein said plurality semiconductor layers including a first layer of first conductivity type for drain ohmic contact, a second layer of first conductivity type on top of said first layer as buffer layer, a third layer of first conductivity type on top of said second layer as blocking and channel layer, a fourth layer of first conductivity type on top of said third layer as top source layer.
6. A vertical junction field-effect power transistor according to claim 2 wherein said plurality semiconductor layers including a first layer of first conductivity type for drain ohmic contact, a second layer of first conductivity type on top of said first layer as buffer layer, a third layer of first conductivity type on top of said second layer as blocking layer, a fourth layer of first conductivity type on top of said third layer as channel layer, and a fifth layer of first conductivity type on top of said fourth layer as top source layer.
7. A bipolar vertical junction field-effect power transistor according to claim 2 wherein said bottom drain layer having conductivity type opposite to the conductivity type of said blocking and channel layer and said top source layer.
8. A vertical junction field-effect transistor according to claim 7 wherein said plurality semiconductor layers including a first layer of second conductivity type for drain ohmic contact, a second layer of first conductivity type on top of said first layer as blocking and channel layer, a third layer of first conductivity type on top of said second layer as top source layer.
9. A vertical junction field-effect power transistor according to claim 7 wherein said plurality semiconductor layers including a first layer of second conductivity type for drain ohmic contact, a second layer of first conductivity type on top of said first layer as blocking layer, a third layer of first conductivity type on top of said second layer as channel layer, and a fourth layer of first conductivity type on top of said third layer as top source layer.
10. A vertical junction field-effect power transistor according to claim 7 wherein said plurality semiconductor layers including a first layer of second conductivity type for drain ohmic contact, a second layer of second conductivity type on top of said first layer as buffer layer, a third layer of first conductivity type on top of said second layer as blocking and channel layer, a fourth layer of first conductivity type on top of said third layer as top source layer.
11. A vertical junction field-effect power transistor according to claim 7 wherein said plurality semiconductor layers including a first layer of second conductivity type for drain ohmic contact, a second layer of second conductivity type on top of said first layer as buffer layer, a third layer of first conductivity type on top of said second layer as blocking layer, a fourth layer of first conductivity type on top of said third layer as channel layer, and a fifth layer of first conductivity type on top of said fourth layer as top source layer.
Type: Application
Filed: Sep 25, 2003
Publication Date: Mar 31, 2005
Inventor: Jian Zhao (North Brunswick, NJ)
Application Number: 10/671,233