Patent application number | Description | Published |
20110221002 | MOS-TYPE ESD PROTECTION DEVICE IN SOI AND MANUFACTURING METHOD THEREOF - The present invention discloses a MOS ESD protection device for SOI technology and a manufacturing method for the device. The MOS ESD protection device comprises: an epitaxial silicon layer grown on top of an SOI substrate; a first side-wall spacer disposed on both sides of the epitaxial silicon layer so as to isolate the ESD protection device from the intrinsic active structures; a source region and a drain region disposed respectively on two sides of the epitaxial silicon layer; a poly silicon gate and a gate dielectric formed on top of the epitaxial silicon layer; and a second side-wall spacer disposed on both sides of the poly silicon gate of . ESD leakage current passes down to the SOI substrate for protection. Because ESD protection device and intrinsic MOS transistor are located in the same plane, this fabrication process can be inserted in the current MOS process flow. | 09-15-2011 |
20110233727 | VERTICAL SOI BIPOLAR JUNCTION TRANSISTOR AND MANUFACTURING METHOD THEREOF - The present invention discloses a vertical SOI bipolar junction transistor and a manufacturing method thereof. The bipolar junction transistor includes an SOI substrate from down to up including a body region, a buried oxide layer and a top silicon film; an active region located in the top silicon film formed by STI process; a collector region located in the active region deep close to the buried oxide layer formed by ion implantation; a base region located in the active region deep close to the top silicon film formed by ion implantation; an emitter and a base electrode both located over the base region; a side-wall spacer located around the emitter and the base electrode. The present invention utilizing a simple double poly silicon technology not only can improve the performance of the transistor, but also can reduce the area of the active region in order to increase the integration density. Furthermore, the present invention utilizes side-wall spacer process to improve the compatibility of SOI BJT and SOI CMOS, which simplifies the SOI BiCMOS process and thus reduce the cost. | 09-29-2011 |
20110291191 | MOS Structure with Suppressed SOI Floating Body Effect and Manufacturing Method thereof - The present invention discloses a MOS structure with suppressed floating body effect including a substrate, a buried insulation layer provided on the substrate, and an active area provided on the buried insulation layer comprising a body region, a first conductive type source region and a first conductive type drain region provided on both sides of the body region respectively and a gate region provide on top of the body region, wherein the active area further comprises a highly doped second conductive type region between the first conductive type source region and the buried insulation layer. For manufacturing this structure, implant ions into a first conductive type source region via a mask having an opening thereon forming a highly doped second conductive type region under the first conductive type source region and above the buried insulation layer. The present invention will not increase chip area and is compatible with conventional CMOS process. | 12-01-2011 |
20120009741 | SOI MOS DEVICE HAVING A SOURCE/BODY OHMIC CONTACT AND MANUFACTURING METHOD THEREOF - The present invention discloses a manufacturing method of SOI MOS device having a source/body ohmic contact. The manufacturing method comprises steps of: firstly creating a gate region, then performing high dose source and drain light doping to form the lightly doped N-type source region and lightly doped N-type drain region; forming an insulation spacer surrounding the gate region; performing large tilt heavily-doped P ion implantation in an inclined direction via a mask with an opening at the position of the N type Si source region and implanting P ions into the space between the N type Si source region and the N type drain region to form a heavily-doped P-type region; finally forming a metal layer on the N type Si source region, then allowing the reaction between the metal layer and the remained Si material underneath to form silicide by heat treatment. In the device prepared by the method of the present invention, an ohmic contact is formed between the silicide and the heavily-doped P-type region nearby in order to release the holes accumulated in body region of the SOI MOS device and eliminate floating body effects thereof. Besides, the device of the present invention also has following advantages, such as limited chip area, simplified fabricating process and great compatibility with traditional CMOS technology. | 01-12-2012 |
20120012931 | SOI MOS DEVICE HAVING BTS STRUCTURE AND MANUFACTURING METHOD THEREOF - The present invention discloses a SOI MOS device having BTS structure and manufacturing method thereof. The source region of the SOI MOS device comprises: two heavily doped N-type regions, a heavily doped P-type region formed between the two heavily doped N-type regions, a silicide formed above the heavily doped N-type regions and the heavily doped P-type region, and a shallow N-type region which is contact to the silicide; an ohmic contact is formed between the heavily doped P-type region and the silicide thereon to release the holes accumulated in body region of the SOI MOS device and eliminate floating body effects thereof without increasing the chip area and also overcome the disadvantages such as decreased effective channel width of the devices in the BTS structure of the prior art. The manufacturing method comprises steps of: forming a heavily doped P-type region via ion implantation, forming a metal layer above the source region and forming a silicide via the heat treatment between the metal layer and the Si underneath. The device in the present invention could be fabricated via simplified fabricating process with great compatibility with traditional CMOS technology. | 01-19-2012 |
20120021571 | Method of Reducing Floating Body Effect of SOI MOS Device Via a Large Tilt Ion Implantation - The present invention discloses a method of reducing floating body effect of SOI MOS device via a large tilt ion implantation including a step of: (a) implanting ions in an inclined direction into an NMOS with a buried insulation layer forming a highly doped P region under a source region of the NMOS and above the buried insulation layer, wherein the angle between a longitudinal line of the NMOS and the inclined direction is ranging from 15 to 45 degrees. Through this method, the highly doped P region under the source region and a highly doped N region form a tunnel junction so as to reduce the floating body effect. Furthermore, the chip area will not be increased, manufacturing process is simple and the method is compatible with conventional CMOS process. | 01-26-2012 |
20120115287 | MANUFACTURING METHOD OF SOI MOS DEVICE ELIMINATING FLOATING BODY EFFECTS - The present invention discloses a manufacturing method of SOI MOS device eliminating floating body effects. The active area of the SOI MOS structure according to the present invention includes a body region, a N-type source region, a N-type drain region, a heavily doped P-type region, wherein the N-type source region comprises a silicide and a buried insulation region and the heavily doped P-type region is located between the silicide and the buried insulation region. The heavily doped P-type region contacts to the silicide, the body region, the buried insulation layer and the shallow trench isolation (STI) structure respectively. The manufacturing method of the device comprises steps of forming a heavily doped P-type region via ion implantation method, forming a metal layer on a part of the surface of the source region, then obtaining a silicide by the heat treatment of the metal layer and the Si material below. The present invention utilizes the silicide and the heavily doped P-type region to form an ohmic contact in order to release the holes accumulated in the body region of SOI MOS device and eliminate SOI MOS floating body effects. Besides, the manufacturing process is simple and can be easily implement. Further, the manufacturing process according to the present invention will not increase chip area and is compatible with conventional CMOS process. | 05-10-2012 |
20120205743 | PD SOI DEVICE WITH A BODY CONTACT STRUCTURE - The present invention discloses a PD SOI device with a body contact structure. The active region of the PD SOI device includes: a body region; a gate region, which is inverted-L shaped, formed on the body region; a N-type source region and a N-type drain region, formed respectively at the two opposite sides of the anterior part the body region; a body contact region, formed at one side of the posterior part of the body region, which is side-by-side with the N-type source region; and a first silicide layer, formed on the body contact region and the N-type source region, which is contact to both of the body contact region and the N-type source region. The body contact region of the device is formed on the border of the source region and the leading-out terminal of the gate electrode. It can suppress floating body effect of the PD SOI device meanwhile not increasing the chip area, thereby overcoming the shortcoming in the prior art that the chip area is enlarged when the traditional body contact structure is employed. Furthermore, the fabrication process provided herein is simple and compatible to the CMOS technology. | 08-16-2012 |
20130054209 | Modeling Method of SPICE Model Series of SOI FET - The present invention provides a modeling method of a SPICE model series of a Silicon On Insulator (SOI) Field Effect Transistor (FET), where auxiliary devices are designed and fabricated, electrical property data is measured, intermediate data is obtained, model parameters are extracted based on the intermediate data, a SPICE model of an SOI FET of a floating structure is established, model parameters are extracted by using the intermediate data and data of the auxiliary devices, a macro model is complied, and a SPICE model of an SOI FET of a body leading-out structure is established. The modeling method provided in the present invention takes an influence of a parasitic transistor of a leading-out part in a body leading-out structure into consideration, and model series established by using the method can more accurately reflect actual operating conditions and electrical properties of the SOI FET of a body leading-out structure and the SOI FET of a floating structure, thereby improving fitting effects of the models. | 02-28-2013 |
20130054210 | Method for Determining BSIMSOI4 DC Model Parameters - The present invention provides a method for determining BSIMSOI4 Direct Current (DC) model parameters, where a plurality of Metal Oxide Semiconductor Field Effect Transistor (MOSFET) devices of a body leading-out structure and of different sizes, and a plurality of MOSFET devices of a floating structure and of different sizes are provided; Id-Vg-Vp, Id/Ip-Vd-Vg, Ig-Vg-Vd, Ig-Vp, Ip-Vg-vd, Is/Id-Vp, and Id/Ip-Vp-Vd properties of all the MOSFET devices of a body leading-out structure, and Id-Vg-Vp, Id-Vd-Vg, and Ig-Vg-Vd properties of all the MOSFET devices of a floating structure are measured; electrical property curves without a self-heating effect of each MOSFET device of a body leading-out structure and each MOSFET device of a floating structure are obtained; and then DC parameters of a BSIMSOI4 model are successively extracted according to specific steps. In the present invention, proper test curves are successively selected according to model equations, and various kinds of parameters are successively determined, thereby accurately and effectively extracting the DC parameters of the BSIMSOI4 model. | 02-28-2013 |
20130054219 | Equivalent Electrical Model of SOI FET of Body Leading-Out Structure, and Modeling Method Thereof - The present invention provides an equivalent electrical model of a Silicon On Insulator (SOI) Field Effect Transistor (FET) of a body leading-out structure, and a modeling method thereof. The equivalent electrical model is formed by an internal FET and an external FET connected in parallel, where the SOI FET of a body leading-out structure is divided into a body leading-out part and a main body part, the internal FET represents a parasitic transistor of the body leading-out part, and the external FET represents a normal transistor of the main body part. The equivalent electrical model provided in the present invention completely includes the influence of parts of a physical structure of the SOIMOSFET device of a body leading-out structure, that is, the body leading-out part and the main body part, on the electrical properties, thereby improving a fitting effect of the model on the electrical properties of the device. | 02-28-2013 |
20130152033 | TCAD Emulation Calibration Method of SOI Field Effect Transistor - The present invention provides a Technology Computer Aided Design (TCAD) emulation calibration method of a Silicon On Insulator (SOI) field effect transistor, where process emulation Metal Oxide Semiconductor (MOS) device structures with different channel lengths Lgate are obtained by establishing a TCAD process emulation program; based on the process emulation MOS device structures, the process emulation MOS device structures are calibrated according to a Transmission Electron Microscope (TEM) test result, a secondary ion mass spectrometer (SIMS) test result, a Capacitor Voltage (CV) test result, a WAT test result, and a square resistance test result of an actual device, so as to complete TCAD emulation calibration of key electrical parameters of an SOI field effect transistor. Through the calibration method consistent with the present invention, in the same SOI process, TCAD emulation results of key parameters Vt and Idsat of MOSFETs of different sizes all meet a high-precision requirement that an error is less than 10%; moreover, accurate and effective pretest can be implement in the case of multiple splits, thereby providing effective guidance for research, development and optimization of a new process flow. | 06-13-2013 |