Insulated gate semiconductor device

Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode

Reexamination Certificate

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C257S341000

Reexamination Certificate

active

06664591

ABSTRACT:

CROSS-REFERENCE TO RELATED APPLICATIONS
This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2001-316824, filed on Oct. 15, 2001, the entire contents of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to an insulated gate semiconductor device.
2. Related Background Art
FIG. 10A
shows a partial cross-sectional view of a non-punch-through-type and vertical-type IGBT (insulated gate bipolar transistor) taken as a prior art of insulated gate semiconductor device. This IGBT
10
includes an n-type base layer
13
, and a p-type base layer
14
formed on the base layer
13
. The p-type base layer
14
includes an ne-type source layer (cathode)
15
formed in a selective top surface region thereof. A p
+
-type drain layer (anode)
11
underlies the bottom surface of the base layer
13
opposite from the top surface thereof. A gate electrode
16
is formed in the base layer
13
so that the gate electrode
16
makes a channel in the p-type base layer
14
for electrical conduction between the source layer
15
and the base layer
13
. The gate electrode
16
is insulated from the base layer
13
, source layer
15
and p-type base layer
14
by an insulating layer
17
.
In IGBT
10
, the base layer
13
must be relatively thick, or relatively low in specific resistance to prevent that the depletion layer from the p-type base layer
14
reaches the anode when it is turned OFF. As a result, the tail current during turnoff period undesirably increases. Therefore, to attain a high-speed turnoff property, injection efficiency of hole current from the anode is reduced by lifetime control. Typically, lifetime control is carried out by annealing the wafer by irradiating an electron beam after completion of the wafer process.
This process of lifetime control, however, invites a decrease of the carrier concentration in the high-resistance n

-type base layer
13
, and thereby undesirably increases the ON voltage. If nothing is done for shortening the lifetime, the ON voltage will be maintained low, but the turnoff time will be elongated. That is, the ON voltage and the turnoff time are related to trade off relation.
FIG. 10B
shows a partial cross-sectional view of a punch-through type and vertical type IGBT taken as another prior art. This IGBT
20
is different from IGBT
10
in including an n
+
-type buffer layer
23
interposed between the n

-type base layer
13
and the p
+
-type drain layer
11
.
Because of the existence of the n
+
-type buffer layer
23
, the depletion layer from the p-type base layer
14
does not reach the anode even when the n

-type base layer
13
is relatively thin or has a relatively high resistance. Therefore, IGBT
20
can maintain a resistivity to voltage even if the n

-type base layer
13
is thinner or lower in resistance than IGBT
10
.
Additionally, injection efficiency of hole current in IGBT
20
is controlled by thickness or concentration of the p
+
-type drain layer
11
. Therefore, IGBT
20
has been improved toward higher switching speed without lifetime control.
Another type of IGBT operative at a switching speed as high as approximately 150 kHz has become known recently. However, any of high-switching-speed IGBTs including the above-mentioned IGBT
20
suffer a tail current that increase under high temperatures. Tail current becomes switching loss, and the switching loss disturbs high-speed switching of IGBT.
FIG. 11
shows changes of current and voltage characteristics of L (inductance) loaded IGBT
20
in response to the time during turnoff period of IGBT
20
. When the gate voltage V
G
decreases and the electron current flowing to the channel decreases, opposite-electromotive force is generated across opposite ends of the L load. The opposite-electromotive force is applied between the anode and the cathode, and the drain voltage V
D
rises (seethe portion from time t
1
to time t
2
).
With the drain voltage V
D
, a depletion layer (not shown) is generated from the junction between the high-resistance n

-type base layer
13
and the p-type base layer
14
. The depletion layer permits electrons heretofore accumulated in the high-resistance n

-type base layer to be supplied to the electron current from the channel. As a result, IGBT
20
behaves to have a constant drain current I
D
to flow. Therefore, a substantially constant hole current flows from the p
+
-type drain layer
11
. That is, in the period from time t
1
to time t
2
, the drain current ID is maintained approximately constant.
Electrons having accumulated in the n

-type base layer are exhausted eventually. Accordingly, the hole current from the p
+
-type drain layer also decreases. That is, the drain current I
D
gradually decreases in the period from time t
2
to time t
3
.
The drain current I
D
flowing in the period after t
3
is called tail current.
As such, waste of power (shaded portion in
FIG. 11
) occurs in the period from time t
1
to time t
3
. The waste of power is a switching loss of IGBT. Further, the waste of power due to the tail current flowing after time t
3
becomes large when the tail current flows for a long time even if the tail current is small.
Let the time t
3
be the end point of the fall time of the drain current I
D
. The fall time of the drain current I
D
is the period beginning from the point of time where the drain current I
D
is 90% of its full value in the ON state of IGBT to the point of time where the drain current I
D
is 10% of the same. In
FIG. 11
, the period from time t
2
to time t
3
is the fall time.
Furthermore, IGBT maintains its breakdown voltage because of having the n
+
-type buffer layer
23
.
However, for attaining a higher breakdown voltage of IGBT, the n

-type base layer
13
needs a larger thickness. For example, in case the IGBT
20
is an element having the breakdown voltage of 600V, that is, in case its base layer
13
is 60 &mgr;m thick, the n

-type base layer
13
must be thicker to increase the breakdown voltage to 600V or more.
Therefore, there is a demand for insulated gate semiconductor devices having low switching loss during turnoff period while being capable of maintaining a lower ON resistance.
There is also a demand for insulated gate semiconductor devices having relatively higher breakdown voltage while maintaining a thin n

-type base layer.
BRIEF SUMMARY OF THE INVENTION
An insulated gate semiconductor device according to an embodiment of the invention comprises: a first base layer of a first conduction type; a second base layer of a second conduction type formed on a first surface of the first base layer; a source layer of the first conduction type selectively formed in a surface region of the second base layer; a drain layer of the second conduction type formed on a second surface of the first base layer opposite from said first surface; and a gate electrode insulated from the source layer, the first base layer and the second base layer and forming in the first base layer a channel electrically connecting the source layer and the second base layer, wherein the injection efficiency of hole current from said drain layer is 0.27 in maximum.
An insulated gate semiconductor device according to a further embodiment of the invention comprises: a first base layer of a first conduction type; a second base layer of a second conduction type formed on a first surface of the first base layer;
a source layer of the first conduction type selectively formed in a surface region of the second base layer; a drain layer of the second conduction type formed on a second surface of the first base layer opposite from said first surface; and a gate electrode insulated from the source layer, the first base layer and the second base layer and forming in the first base layer a channel electrically connecting the source layer and the second base layer, wherein the voltage transiently applied to

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