P-channel silicon carbide MOSFET
First Claim
1. A p-channel silicon carbide MOSFET comprising:
- a silicon carbide semiconductor substrate;
a high-concentration p-type layer containing silicon carbide semiconductor provided on one principal surface of the silicon carbide semiconductor substrate;
a low-concentration p-type base layer containing silicon carbide semiconductor provided on the high-concentration p-type layer;
an n-type base layer containing silicon carbide semiconductor provided on the low-concentration p-type base layer;
p-type source regions selectively formed on a surface layer of the n-type base layer;
first trenches extending from the p-type source regions, passing through the n-type base layer and reaching the p-type base layer;
control electrodes packed through gate insulating films on surfaces of the p-type base layer exposed from inner surfaces of the first trenches;
second trenches extending from the surface of the n-type base layer, passing through the n-type base layer and reaching the p-type base layer;
source electrodes in contact with inner surfaces of the second trenches while being in contact with the n-type base layer and the p-type source layer as contact regions located in the substrate surface around opening portions of the second trenches; and
a drain electrode in contact with the other principal surface of the silicon carbide semiconductor substrate,wherein a plane pattern of the first trenches has a wide-interval first trench pattern portion where the second trench and the contact region are disposed between the first trenches, and a narrow-interval first trench pattern portion where the second trench and the contact region are not disposed between the first trenches;
wherein each second trench has a depth not smaller than each first trench;
wherein a distance between center lines of the first trench and the second trench is not larger than 10 μ
m;
wherein each of the source electrodes has a Schottky junction between the source electrode and a surface of the p-type base layer in a bottom portion of the second trench;
wherein third trenches are provided so as to extend from the other principal surface of the silicon carbide semiconductor substrate and reach the high-concentration p-type layer; and
wherein the drain electrode is in contact with p-type layer surface-containing inner surfaces of bottom portions of the third trenches.
2 Assignments
0 Petitions
Accused Products
Abstract
A second trench in each source electrode portion (Schottky diode portion) is formed to have a depth equal to or larger than the depth of a first trench in each gate electrode portion. The distance between the first and second trenches is set to be not longer than 10 μm. A source electrode is formed in the second trench and a Schottky junction is formed in the bottom portion of the second trench. In this manner, it is possible to provide a wide band gap semiconductor device which is small-sized, which has low on-resistance and low loss characteristic, in which electric field concentration into a gate insulating film is relaxed to suppress reduction of a withstand voltage, and which has high avalanche breakdown tolerance at turn-off time.
-
Citations
2 Claims
-
1. A p-channel silicon carbide MOSFET comprising:
-
a silicon carbide semiconductor substrate; a high-concentration p-type layer containing silicon carbide semiconductor provided on one principal surface of the silicon carbide semiconductor substrate; a low-concentration p-type base layer containing silicon carbide semiconductor provided on the high-concentration p-type layer; an n-type base layer containing silicon carbide semiconductor provided on the low-concentration p-type base layer; p-type source regions selectively formed on a surface layer of the n-type base layer; first trenches extending from the p-type source regions, passing through the n-type base layer and reaching the p-type base layer; control electrodes packed through gate insulating films on surfaces of the p-type base layer exposed from inner surfaces of the first trenches; second trenches extending from the surface of the n-type base layer, passing through the n-type base layer and reaching the p-type base layer; source electrodes in contact with inner surfaces of the second trenches while being in contact with the n-type base layer and the p-type source layer as contact regions located in the substrate surface around opening portions of the second trenches; and a drain electrode in contact with the other principal surface of the silicon carbide semiconductor substrate, wherein a plane pattern of the first trenches has a wide-interval first trench pattern portion where the second trench and the contact region are disposed between the first trenches, and a narrow-interval first trench pattern portion where the second trench and the contact region are not disposed between the first trenches; wherein each second trench has a depth not smaller than each first trench; wherein a distance between center lines of the first trench and the second trench is not larger than 10 μ
m;wherein each of the source electrodes has a Schottky junction between the source electrode and a surface of the p-type base layer in a bottom portion of the second trench; wherein third trenches are provided so as to extend from the other principal surface of the silicon carbide semiconductor substrate and reach the high-concentration p-type layer; and wherein the drain electrode is in contact with p-type layer surface-containing inner surfaces of bottom portions of the third trenches.
-
-
2. A p-channel silicon carbide MOSFET comprising:
-
a silicon carbide semiconductor substrate; a high-concentration p-type layer containing silicon carbide semiconductor provided on one principal surface of the silicon carbide semiconductor substrate; a low-concentration p-type base layer containing silicon carbide semiconductor provided on the high-concentration p-type layer; an n-type base layer containing silicon carbide semiconductor provided on the low-concentration p-type base layer; p-type source regions selectively formed on a surface layer of the n-type base layer; first trenches extending from the p-type source regions, passing through the n-type base layer and reaching the p-type base layer; control electrodes packed through gate insulating films on surfaces of the p-type base layer exposed from inner surfaces of the first trenches; second trenches extending from the surface of the n-type base layer, passing through the n-type base layer and reaching the p-type base layer; source electrodes being in contact with inner surfaces of the second trenches while being in contact with the n-type base layer and the p-type source layer as contact regions located in the substrate surface around opening portions of the second trenches; and a drain electrode being in contact with the other principal surface of the silicon carbide semiconductor substrate; wherein a plane pattern of the first trenches has a wide-interval first trench pattern portion where the second trench and the contact region are disposed between the first trenches, and a narrow-interval first trench pattern portion where the second trench and the contact region are not disposed between the first trenches; wherein each second trench has a depth not smaller than each first trench; wherein a distance between center lines of the first trench and the second trench is not larger than 10 μ
m;wherein each of the source electrodes has a Schottky junction between the source electrode and a surface of the p-type base layer in a bottom portion of the second trench; and wherein the silicon carbide semiconductor substrate is of a p type as its conductivity type and has a specific resistance not larger than 0.1 Ω
cm.
-
Specification