A three-dimensional semiconductor wafer relates to a semiconductor wafer, including a raw semiconductor wafer, at least one connection layer, a conduction layer and a protection layer, wherein the protection layer is arranged on the conduction layer; the connection layer is inserted into a bottom surface or/and a top surface of the raw semiconductor wafer; and the conduction layer is arranged on the bottom surface of the raw semiconductor wafer.

CROSS REFERENCE OF RELATED APPLICATION

BACKGROUND OF THE PRESENT INVENTION

Field of Invention

The present invention relates to the field of semiconductor wafers. More particularly, the present invention relates to three-dimensional semiconductor wafers.

Description of Related Arts

Generally, the wafer material applied in the production of semiconductor chips is mainly a single crystal epitaxial wafer or a single crystal polished wafer. The epitaxial wafer is obtained through forming an epitaxial layer on the single crystal polished wafer. The single crystal polished wafer serves as a substrate layer to support the epitaxial layer, and the epitaxial layer is used to support the blocking voltage of power semiconductor devices.

In order to make a breakthrough to the silicon limit and achieve huge improvement for the design of high blocking voltage power devices with reduced specific on-resistance or conduction loss, superjunction (SJ) power devices with a voltage sustaining layer composed of alternating p and n doped region become popular. In order to form a three-dimensional sustaining layer, the methods of multiple epitaxy and deep trench are used. However, these manufacture processes of a SJ sustaining layer are complicated and expensive.

SUMMARY OF THE PRESENT INVENTION

An object of the present invention is to provide a three-dimensional semiconductor wafer.

The three-dimensional semiconductor wafer comprises a raw semiconductor wafer, at least one connection layer, a conduction layer and a protection layer. The protection layer is arranged on the conduction layer. The connection layer is inserted into a bottom surface or/and a top surface of the raw semiconductor wafer. The conduction layer is arranged on the bottom surface of the raw semiconductor wafer.

Preferably, the raw semiconductor wafer is cylindrical.

Preferably, the connection layer comprises a plurality of connection parts. A first end of each connection part is inserted into the raw semiconductor wafer, and a second end of each connection part is level with the bottom surface or the top surface of the raw semiconductor wafer.

Preferably, the connection parts are prismatic, cylindrical, spherical or ellipsoidal, and the connection parts are arranged inside the raw semiconductor wafer in a form of array.

Preferably, the protection layer is arranged on an outer surface of the conduction layer.

Through adopting the above technical solutions, the present invention has following beneficial effects.

The present invention provides the three-dimensional semiconductor wafer, comprising the raw semiconductor wafer, the connection layer, the conduction layer and the protection layer. The three-dimensional semiconductor wafer provided by the present invention can not only replace two-dimensional semiconductor wafer materials such as a single crystal epitaxial wafer, but also provide a design basis for high performance semiconductor devices.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

A three-dimensional semiconductor wafer comprises a raw semiconductor wafer1, at least one connection layer, a conduction layer3and a protection layer4, wherein: the protection layer4is arranged on the conduction layer3; the connection layer is inserted into a bottom surface or/and a top surface of the raw semiconductor wafer1; the conduction layer is arranged on the bottom surface of the raw semiconductor wafer1; the raw semiconductor wafer1is cylindrical; the connection layer comprises a plurality of connection parts2; a first end of each connection part2is inserted into the raw semiconductor wafer1, and a second end of each connection part2is level with the bottom surface or the top surface of the raw semiconductor wafer1; the connection parts2are prismatic, cylindrical, spherical or ellipsoidal; the connection parts2are arranged inside the raw semiconductor wafer1in a form of array; and the protection layer4is arranged on an outer surface of the conduction layer3.

For the three-dimensional semiconductor wafer provided by the present invention, according to types of semiconductors of different power, a conduction type of the raw semiconductor wafer1, the connection layer, and the conduction layer3can be respectively selected as N-type or P-type, wherein the bottom surface of the raw semiconductor wafer1can be produced according to requirements of a chip.

First Preferred Embodiment

As shown inFIG. 2, the raw semiconductor wafer1is a lightly doped N-type region, namely an N−region; the connection layer is a heavily doped N-type region, namely an N+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped N-type region, namely the N+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1.

Second Preferred Embodiment

As shown inFIG. 3, the raw semiconductor wafer1is a lightly doped N-type region, namely an N−region; the connection layer is a heavily doped P-type region, namely a P+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped P-type region, namely the P+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1.

Third Preferred Embodiment

As shown inFIG. 4, the raw semiconductor wafer1is a lightly doped N-type region, namely an N−region; the connection layer is a heavily doped N-type region, namely an N+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped P-type region, namely a P+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1.

Fourth Preferred Embodiment

As shown inFIG. 5, the raw semiconductor wafer1is a lightly doped N-type region, namely an N−region; the connection layer is a heavily doped P-type region, namely a P+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped N-type region, namely an N+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1. The above three-dimensional semiconductor wafer is mainly applicable in production of N-channel enhancement mode metal-oxide-semiconductor field-effect transistor (MOSFET) and fast recovery diode (FRD) chip.

Fifth Preferred Embodiment

As shown inFIG. 6, the raw semiconductor wafer1is a lightly doped P-type region, namely a P−region; the connection layer is a heavily doped P-type region, namely a P+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped P-type region, namely the P+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1. The above three-dimensional semiconductor wafer is mainly applicable in production of P-channel enhancement mode MOSFET and giant transistor (GTR).

Sixth Preferred Embodiment

As shown inFIG. 7, the raw semiconductor wafer1is a lightly doped P-type region, namely a P−region; the connection layer is a heavily doped N-type region, namely an N+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped N-type region, namely the N+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1.

Seventh Preferred Embodiment

As shown inFIG. 8, the raw semiconductor wafer1is a lightly doped N-type region, namely an N−region; the connection layer is a heavily doped P-type region, namely a P+region; for the array-distributed connection parts2, the first ends are inserted into the raw semiconductor wafer1, and the second ends are level with the top surface of the raw semiconductor wafer1; the conduction layer3is a heavily doped N-type region, namely an N+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1.

Eighth Preferred Embodiment

As shown inFIG. 9, the raw semiconductor wafer1is a lightly doped N-type region, namely an N−region; a first connection layer at the top surface of the raw semiconductor wafer is a heavily doped P-type region, namely a P+region, and the array-distributed connection parts2of the first connection layer have the first ends inserted into the raw semiconductor wafer1and the second ends level with the top surface of the raw semiconductor wafer1; a second connection layer at the bottom surface of the raw semiconductor wafer1is a heavily doped N-type region, namely an N+region, and the array-distributed connection parts2of the second connection layer have the first ends inserted into the raw semiconductor wafer1and the second ends connected to each other on the bottom surface of the raw semiconductor wafer1through the conduction layer3; the conduction layer3is a heavily doped N-type region, namely the N+region; and the protection layer4is arranged on the conduction layer3at the bottom surface of the raw semiconductor wafer1.