Patent application number | Description | Published |
20080272394 | JUNCTION FIELD EFFECT TRANSISTORS IN GERMANIUM AND SILICON-GERMANIUM ALLOYS AND METHOD FOR MAKING AND USING - Junction field effect transistors (JFET) formed in substrates containing germanium. JFETs having polycrystalline semiconductor surface contacts with self-aligned silicide formed thereon and self-aligned source, drain and gate regions formed by thermal drive-in of impurities from surface contacts into the substrate, and implanted link regions. Others have a polycrystalline semiconductor gate surface contact and metal back gate, source and drain contacts and a metal surface contact to the gate surface contact with implanted source and drains and a self-aligned gate region. JFETs having a polycrystalline semiconductor gate surface contact and metal back gate, source and drain contacts and a metal surface contact to the gate surface contact with implanted source and drains and a self-aligned gate region and silicide formed on the top of the source, drain and back gate contacts and on top of the gate polycrystalline semiconductor gate contact to which the metal surface contacts make electrical contact. | 11-06-2008 |
20080272408 | ACTIVE AREA JUNCTION ISOLATION STRUCTURE AND JUNCTION ISOLATED TRANSISTORS INCLUDING IGFET, JFET AND MOS TRANSISTORS AND METHOD FOR MAKING - Integrated active area isolation structure for transistor to replace larger and more expensive Shallow Trench Isolation or field oxide to isolate transistors. Multiple well implant is formed with PN junctions between wells and with surface contacts to substrate and wells so bias voltages applied to reverse bias PN junctions to isolate active areas. Insulating layer is formed on top surface of substrate and interconnect channels are etched in insulating layer which do not go down to the semiconductor substrate. Contact openings for surface contacts to wells and substrate are etched in insulating layer down to semiconductor layer. Doped silicon or metal is formed in contact openings for surface contacts and to form interconnects in channels. Silicide may be formed on top of polycrystalline silicon contacts and interconnect lines to lower resistivity. Any JFET or MOS transistor may be integrated into the resulting junction isolated active area. | 11-06-2008 |
20080272439 | SMALL GEOMETRY MOS TRANSISTOR WITH THIN POLYCRYSTALLINE SURFACE CONTACTS AND METHOD FOR MAKING - Process for fabrication of MOS semiconductor structures and transistors such as CMOS structures and transistors with thin gate oxide, polysilicon surface contacts having thickness on the order of 500 Angstroms or less and with photo-lithographically determined distances between the gate surface contact and the source and drain contacts. Semiconductor devices having polysilicon surface contacts wherein the ratio of the vertical height to the horizontal dimension is approximately unity. Small geometry Metal-Oxide-Semiconductor (MOS) transistor with thin polycrystalline surface contacts and method and process for making the MOS transistor. MOS and CMOS transistors and process for making. Process for making transistors using Silicon Nitride layer to achieve strained Silicon substrate. Strained Silicon devices and transistors wherein fabrication starts with strained Silicon substrate. Strained Silicon devices which use a Silicon Nitride film applied to the substrate at high temperature and which use differential thermal contraction rates during cooling to achieve strained Silicon. | 11-06-2008 |
20090039407 | Vertically integrated flash EPROM for greater density and lower cost - A nonvolative memory in the form of a vertical flash EPROM with high density and low cost. A vertical MOS transistor is formed in well etched into a semiconductor substrate, the substrate having source, body and drain regions formed by ion implantation. A thin gate oxide or oxide-nitride-oxide (ONO) layer is formed in the well and a self-aligned floating gate of polysilicon is formed over the gate oxide in the well to overlie the body region. An anisotropic etch is used to form the self aligned floating gate so as to remove all horizontal components and leave no portion of said floating gate extending beyond the perimeter of said well such that its lateral extents are determined by the anisotropic etch and not photolithography. L | 02-12-2009 |
20090075435 | JFET With Built In Back Gate in Either SOI or Bulk Silicon - A process for manufacturing a Junction Field-Effect Transistor, comprises doping a semiconductor material formed on an insulating substrate with impurities of a first conductivity type to form a well region. The process continues by implanting impurities of a second conductivity type into said well region to form a channel region, and by implanting impurities of the first conductivity type in said well region to form a back gate region. The process continues by forming a trench to expose at least one sidewall of said channel region, wherein the trench extends far enough along the sidewall to expose at least a portion of said back gate region. The process continues by depositing polysilicon to fill said trench along the at least one sidewall of said channel region and at least a portion of said back gate region, wherein at least a portion of the polysilicon will form a gate contact. The polysilicon is then doped with impurities of a first conductivity type. The process concludes by annealing the polysilicon to activate the doped impurities and to cause the doped impurities to diffuse along the at least one sidewall of said channel region so as to form a top gate region. The top gate region extends far enough to make electrical contact with said back gate region. | 03-19-2009 |
20090142889 | Oxide Isolated Metal Silicon-Gate JFET - A JFET structure with self-aligned metal source, drain and gate contacts with very low resistivity and very small feature sizes. Small source, drain and gate openings are etched in a thin dielectric layer which has a thickness set according to the desired source, gate and drain opening sizes, said dielectric layer having a nitride top layer. Metal is deposited on top of said dielectric layer to fill said openings and the metal is polished back to the top of the dielectric layer to achieve thin source, drain and gate contacts. Some embodiments include an anti-leakage poly-silicon layer lining the contact holes and all embodiments where spiking may occur include a barrier metal layer. | 06-04-2009 |
20090164963 | SYSTEM AND METHOD FOR ROUTING CONNECTIONS - A method for modeling a circuit includes receiving a netlist that defines a plurality of connections between a plurality of circuit elements and identifying a subset of the connections. The method also includes routing the identified connections with a first group of wires having a first wire width and routing at least a portion of the remaining connections with a second wire width. The second wire width is smaller than the first wire width. The method further includes replacing the first group of wires with a third group of wires having the second wire width. | 06-25-2009 |
20090204935 | Semiconductor device, design method and structure - A semiconductor device can include at least a first diffusion region formed by doping a semiconductor substrate and at least a second diffusion region formed by doping the semiconductor substrate that is separated from the first diffusion region by an isolation region. At least a first conductive line can comprise a semiconductor material formed over and in contact with the first diffusion region and the second diffusion region. A portion of the first conductive line in contact with the first diffusion region is doped to an opposite conductivity type as the first diffusion region. At least a second conductive line comprising a semiconductor material is formed in parallel with the first conductive line and over and in contact with the first diffusion region and the second diffusion region. A portion of the second conductive line can be in contact with the first diffusion region and doped to a same conductivity type as the first diffusion region. A portion of the second conductive line in contact with the second diffusion region can be doped to a same conductivity type as the second diffusion region. | 08-13-2009 |
20090215234 | Semiconductor device, design method and structure - A semiconductor device can include at least a first diffusion region formed by doping a semiconductor substrate and at least a second diffusion region formed by doping the semiconductor substrate that is separated from the first diffusion region by an isolation region. At least a first conductive line can comprise a semiconductor material formed over and in contact with the first diffusion region and the second diffusion region. A portion of the first conductive line in contact with the first diffusion region is doped to an opposite conductivity type as the first diffusion region. At least a second conductive line comprising a semiconductor material is formed in parallel with the first conductive line and over and in contact with the first diffusion region and the second diffusion region. A portion of the second conductive line can be in contact with the first diffusion region and doped to a same conductivity type as the first diffusion region. A portion of the second conductive line in contact with the second diffusion region can be doped to a same conductivity type as the second diffusion region. | 08-27-2009 |
20090282382 | SYSTEM AND METHOD FOR ROUTING CONNECTIONS WITH IMPROVED INTERCONNECT THICKNESS - A method for modeling a circuit includes generating a circuit model based on a netlist that defines a plurality of connections between a plurality of circuit elements. The circuit model includes a model of one or more of the circuit elements. The method further includes determining a wire width associated with at least a selected connection based, at least in part, on design rules associated with the netlist. Additionally, the method includes determining a wire thickness associated with the selected connection based, at least in part, on a signal delay associated with the wire thickness. Furthermore, the method also includes routing the selected connection in the circuit model using a wire having a width substantially equal to the wire width calculated for the connection and a thickness equal to the wire thickness calculated for the connection and storing the circuit model in an electronic storage media. | 11-12-2009 |
20090295427 | Programmable switch circuit and method, method of manufacture, and devices and systems including the same - A switching circuit can include a logic circuit having a logic circuit input and a logic circuit output and at least three input transistors coupled to provide three separate paths between three input/output (I/O) nodes and the logic circuit input. The switching circuit can further include at least three output transistors coupled to provide three separate paths between the three I/O nodes and the logic circuit output. Methods of fabricating such switch circuits and devices and/or systems including such switching circuits are also disclosed. | 12-03-2009 |
20100019289 | Junction Field Effect Transistor Using Silicide Connection Regions and Method of Fabrication - A junction field effect transistor comprises a semiconductor substrate and a well region formed in the substrate. A source region of a first conductivity type is formed in the well region. A drain region of the first conductivity type is formed in the well region and spaced apart from the source region. A channel region of the first conductivity type is located between the source region and the drain region and formed in the well region. A gate region of a second conductivity type is formed in the well region. The transistor further includes first, second, and third connection regions. The first connection region is in ohmic contact with the source region and formed of silicide. The second connection region is in ohmic contact with the drain region and formed of silicide. The third connection region in ohmic contact with the gate region. | 01-28-2010 |
20120061856 | Apparatus and Methods for High-Density Chip Connectivity - An electronic circuit and method may include a first chip including first electronics and a first connector including multiple self-alignment features and conductive pads. A second chip may include second electronics and a second connector including multiple self-alignment features and conductive pads. The first chip and second chip may be indirectly horizontally aligned with one another and in electrical communication with one another via the first and second connectors. | 03-15-2012 |