| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 257297000 | With means for preventing charge leakage due to minority carrier generation (e.g., alpha generated soft error protection or "dark current" leakage protection) | 11 |
| 20080251825 | PILLAR-TYPE FIELD EFFECT TRANSISTOR HAVING LOW LEAKAGE CURRENT - A pillar-type field effect transistor having low leakage current is provided. The pillar-type field effect transistor includes a semiconductor pillar, a gate insulating layer formed on a portion of a surface of the semiconductor pillar, a gate electrode formed on the gate insulating layer, and source/drain regions formed on portions of the semiconductor pillar where the gate electrode is not formed, in which the gate electrode includes a first gate electrode, a second gate electrode, and an inter-gate insulating layer, in which the first gate electrode has a work function higher than that of the second gate electrode, in which the inter-gate insulating layer is formed between the first gate electrode and the second gate electrode, and in which the first gate electrode and the second gate electrode are electrically connected by a contact or a metal interconnection line. A portion of the second gate electrode having the work function lower than that of the first gate electrode is overlapped by the drain region. Accordingly, the gate electrode of the pillar-type FET is formed using a material having a high work function, so that the threshold voltage can be increased and the work function of the portion of the gate electrode overlapped by the drain region can be decreased. Therefore, gate induced drain leakage is reduced, so that off-state leakage current can likewise be greatly reduced. | 10-16-2008 |
| 20090050950 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - A semiconductor device includes a first MOS type capacitor having a first insulating film and a first electrode that are formed on a semiconductor substrate, and a second MOS type capacitor having a second insulating film and a second electrode that are formed on the semiconductor substrate. The first electrode has a first concentration difference as a difference when an impurity concentration in an interface region with the first insulating film is subtracted from an impurity concentration in a top portion of the first electrode. The second electrode has a second concentration difference as a difference when an impurity concentration in an interface region with the second insulating film is subtracted from an impurity concentration in a top portion of the second electrode. The second concentration difference is larger than the first concentration difference. | 02-26-2009 |
| 20090085082 | CONTROLLED INTERMIXING OF HFO2 AND ZRO2 DIELECTRICS ENABLING HIGHER DIELECTRIC CONSTANT AND REDUCED GATE LEAKAGE - Controlled deposition of HfO | 04-02-2009 |
| 20090085083 | Semiconductor memory device and method of forming the same - Provided may be a semiconductor memory device and a method of forming the semiconductor memory device. The memory device of example embodiments may include a bit line structure including a bit line on a semiconductor substrate, and a buried contact plug structure including a buried contact pad and a buried contact plug that extends in a lower portion of the bit line from one side of the bit line and connected to the buried contact pad. A width of the buried contact plug near a top surface of the buried contact pad may be greater than a width of the buried contact plug adjacent to the bit line. | 04-02-2009 |
| 20090166700 | SINGLE TRANSISTOR MEMORY CELL WITH REDUCED RECOMBINATION RATES - A semiconductor fabrication method includes forming a semiconductor structure including source/drain regions disposed on either side of a channel body wherein the source/drain regions include a first semiconductor material and wherein the channel body includes a migration barrier of a second semiconductor material. A gate dielectric overlies the semiconductor structure and a gate module overlies the gate dielectric. An offset in the majority carrier potential energy level between the first and second semiconductor materials creates a potential well for majority carriers in the channel body. The migration barrier may be a layer of the second semiconductor material over a first layer of the first semiconductor material and under a capping layer of the first semiconductor material. In a one dimensional migration barrier, the migration barrier extends laterally through the source/drain regions while, in a two dimensional barrier, the barrier terminates laterally at boundaries defined by the gate module. | 07-02-2009 |
| 20090189209 | SEMICONDUCTOR MEMORY DEVICE - In a full CMOS SRAM having a lateral type cell (memory cell having three partitioned wells arranged side by side in a word line extending direction and longer in the word line direction than in the bit line direction) including first and second driver MOS transistors, first and second load MOS transistors and first and second access MOS transistors, two capacitors are arranged spaced apart from each other on embedded interconnections to be storage nodes, with lower and upper cell plates cross-coupled to each other. | 07-30-2009 |
| 20090206380 | APPARATUS AND METHOD FOR USING A WELL CURRENT SOURCE TO EFFECT A DYNAMIC THRESHOLD VOLTAGE OF A MOS TRANSISTOR - Deep submicron wells of MOS transistors, implemented over an ungrounded well, exhibit two modes of operation: a current sink mode and a current source mode. While operation as a current sink is well understood and successfully controlled, it is also necessary to control the current provided in the current source mode of the well. A Schottky diode is connected between the well and the gate, the Schottky diode having a smaller barrier height than that of the PN junction of the well-to-source. For an NMOS transistor, current flows through the PN junction when the gate is high. When the gate is low, current flows through the Schottky diode. This difference of current flow results in a difference in transistor threshold, thereby achieving a dynamic threshold voltage using the current from the well when operating at the current source mode. | 08-20-2009 |
| 20120074478 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - As for a bypass capacitor, a first capacitor insulating film, together with a tunnel insulating film of a storage element, is formed of a first insulating film, a first electrode being a lower electrode, together with floating gate electrodes of the storage element, is formed of a doped·amorphous silicon film (a crystallized one), a second capacitor insulating film, together with a gate insulating film of transistors of 5 V in a peripheral circuit, is formed of a second insulating film, and a second electrode being an upper electrode, together with control gate electrodes of the storage element and gate electrodes of the transistors in the peripheral circuit, is formed of a polycrystalline silicon film. | 03-29-2012 |
| 20140299927 | Digital Circuit Having Correcting Circuit and Electronic Apparatus Thereof - Provided is a digital circuit ( | 10-09-2014 |
| 20150294974 | DYNAMIC MEMORY STRUCTURE - A dynamic memory structure is disclosed. The dynamic memory structure includes: a substrate; a first strip semiconductor material disposed on the substrate and extending along a first direction; a gate standing astride the first strip semiconductor material, extending along a second direction and dividing the first strip semiconductor material into a first source terminal, a first drain terminal and a first channel region; a first dielectric layer sandwiched between the gate and the first strip semiconductor material; a first capacitor unit disposed on the substrate and comprising the first source terminal serving as a bottom electrode, a second dielectric layer covering the first source terminal to serve as a capacitor dielectric layer and a capacitor metal layer covering the second dielectric layer to serve as a top electrode. Preferably, the first source terminal and the first drain terminal have asymmetric shapes. | 10-15-2015 |
| 20160118376 | SEMICONDUCTOR INTEGRATED CIRCUIT - A first power line configured to receive a first voltage, a second power line configured to receive a second voltage which is lower than the first voltage, a first clamping unit configured to be connected to the first power line, a second clamping unit configured to be connected between the first clamping unit and the second power line, and a discharging unit configured to, when an abnormal voltage introduced through the first power line or the second power line is applied, discharge the abnormal voltage by coupling with the first clamping unit or the second clamping unit are included. | 04-28-2016 |
