| Shanghai Institute of Microsystem and Information Technology Chinese Academy of Sciences Patent applications |
| Patent application number | Title | Published |
|---|
| 20120129320 | METHOD OF NISIGE EPITAXIAL GROWTH BY INTRODUCING AL INTERLAYER - The present invention discloses a method of NiSiGe epitaxial growth by introducing Al interlayer, comprising the deposition of an Al thin film on the surface of SiGe layer, subsequent deposition of a Ni layer on Al thin film and then the annealing process for the reaction between Ni layer and SiGe material of SiGe layer to form NiSiGe material. Due to the barrier effect of Al interlayer, NiSiGe layer features a single crystal structure, a flat interface with SiGe substrate and a thickness of up to 0.3 nm, significantly enhancing interface performance. | 05-24-2012 |
| 20120021569 | MANUFACTURING METHOD OF SOI HIGH-VOLTAGE POWER DEVICE - The present invention relates to a manufacturing method of SOI devices, and in particular, to a manufacturing method of SOI high-voltage power devices. The method comprises steps of: forming a first oxide layer in a section on the surface of the SOI substrate; removing the first oxide layer to form a depressed area in the corresponding section of the upper surface of the SOI substrate; forming a second oxide layer, the upper surface of which is as high as the that of the SOI substrate, in the depressed area formed in step (B); performing photoetching and doping processes to form a P-type region, an N-type region and a gate region on the thus-formed structure where the second oxide layer is formed; forming a third oxide layer by deposition on the drift region of the structure after P-type and N-type regions are formed; wherein the total thickness of the third oxide layer and the second oxide layer approximates to the thickness of the buried oxide layer in the SOI substrate; and forming metal sub-regions, which are respectively in contact with the P-type region, the N-type region and the gate region, on the structure where the third oxide layer is formed, thereby forming a high-voltage power device. | 01-26-2012 |
| 20110248354 | HYBRID MATERIAL INVERSION MODE GAA CMOSFET - A Ge and Si hybrid material inversion mode GAA (Gate-All-Around) CMOSFET includes a PMOS region having a first channel, an NMOS region having a second channel and a gate region. The first channel and the second channel have a racetrack-shaped cross section and are formed of n-type Ge and p-type Si, respectively; the surfaces of the first channel and the second channel are substantially surrounded by the gate region; a buried oxide layer is disposed between the PMOS region and the NMOS region and between the PMOS or NMOS region and the Si substrate to isolate them from one another. In an inversion mode, the devices have hybrid material, GAA structure with the racetrack-shaped, high-k gate dielectric layer and metal gate, so as to achieve high carrier mobility, prevent polysilicon gate depletion and short channel effects. | 10-13-2011 |
