Patent application number | Description | Published |
20100123171 | Multi-level Lateral Floating Coupled Capacitor Transistor Structures - A semiconductor device includes a source region, a drain region, a gate region, and a drift region. The drift region further includes an active drift region and inactive floating charge control (FCC) regions. The active drift region conducts current between the source region and the drain region when voltage is applied to the gate region. The inactive FCC regions, which field-shape the active drift region to improve breakdown voltage, are vertically stacked in the drift region and are separated by the active drift region. Vertically stacking the inactive FCC regions reduce on-resistance while maintaining higher breakdown voltages. | 05-20-2010 |
20120091516 | Lateral Floating Coupled Capacitor Device Termination Structures - Voltage termination structures include one or more capacitively coupled trenches, which can be similar to the trenches in the drift regions of the active transistor. The capacitively coupled trenches in the termination regions are arranged with an orientation that is either parallel or perpendicular to the trenches in the active device drift region. The Voltage termination structures can also include capacitively segmented trench structures having dielectric lined regions filled with conducting material and completely surrounded by a silicon mesa region. The Voltage termination structures can further include continuous regions composed entirely of an electrically insulating layer extending a finite distance vertically from the device surface. | 04-19-2012 |
20120211834 | MULTI-LEVEL LATERAL FLOATING COUPLED CAPACITOR TRANSISTOR STRUCTURES - A semiconductor device includes an active region having a first floating charge control structure and a termination region having a second floating charge control structure. The second floating charge control structure is at least twice as long as the first floating control structure. | 08-23-2012 |
20130221429 | METHOD AND APPARATUS RELATED TO A JUNCTION FIELD-EFFECT TRANSISTOR - In a general aspect, a semiconductor device can include a gate having a first trench portion disposed within a first trench of a junction field-effect transistor device, a second trench portion disposed within a second trench of the junction field-effect transistor device, and a top portion coupled to both the first trench portion and to the second trench portion. The semiconductor device can include a mesa region disposed between the first trench and the second trench, and including a single PN junction defined by an interface between a substrate dopant region having a first dopant type and a channel dopant region having a second dopant type. | 08-29-2013 |
20140145245 | DEVICE ARCHITECTURE AND METHOD FOR IMPROVED PACKING OF VERTICAL FIELD EFFECT DEVICES - A semiconductor field-effect device is disclosed that utilizes an octagonal or inverse-octagonal deep trench super-junction in combination with an octagonal or inverse-octagonal gate trench. The field-effect device achieves improved packing density, improved current density, and improved on resistance, while at the same time maintaining compatibility with the multiple-of-45°-angles of native photomask processing and having well characterized (010), (100) and (110) (and their equivalent) silicon sidewall surfaces for selective epitaxial refill and gate oxidation, resulting in improved scalability. By varying the relative length of each sidewall surface, devices with differing threshold voltages can be achieved without additional processing steps. Mixing trenches with varying sidewall lengths also allows for stress balancing during selective epitaxial refill. | 05-29-2014 |
20150340454 | DEVICE ARCHITECTURE AND METHOD FOR IMPROVED PACKING OF VERTICAL FIELD EFFECT DEVICES - A semiconductor field-effect device is disclosed that utilizes an octagonal or inverse-octagonal deep trench super-junction in combination with an octagonal or inverse-octagonal gate trench. The field-effect device achieves improved packing density, improved current density, and improved on resistance, while at the same time maintaining compatibility with the multiple-of-45°-angles of native photomask processing and having well characterized (010), (100) and (110) (and their equivalent) silicon sidewall surfaces for selective epitaxial refill and gate oxidation, resulting in improved scalability. By varying the relative length of each sidewall surface, devices with differing threshold voltages can be achieved without additional processing steps. Mixing trenches with varying sidewall lengths also allows for stress balancing during selective epitaxial refill. | 11-26-2015 |
Patent application number | Description | Published |
20090003082 | Method of making memory cell with voltage modulated sidewall poly resistor - A method of making a two terminal nonvolatile memory cell includes forming a first electrode, forming a charge storage medium, forming a resistive element, and forming a second electrode. The charge storage medium and the resistive element are connected in parallel between the first and the second electrodes, and a presence or absence of charge being stored in the charge storage medium affects a resistivity of the resistive element. | 01-01-2009 |
20090003083 | Memory cell with voltage modulated sidewall poly resistor - A two terminal nonvolatile memory cell includes a first electrode, a second electrode, a charge storage medium, and a resistive element. The charge storage medium and the resistive element are connected in parallel between the first and the second electrodes. A presence or absence of charge being stored in the charge storage medium affects a resistivity of the resistive element. | 01-01-2009 |
20090140299 | MEMORY WITH HIGH DIELECTRIC CONSTANT ANTIFUSES ADAPTED FOR USE AT LOW VOLTAGE - A memory array having memory cells comprising a diode and an antifuse can be made smaller and programmed at lower voltage by using an antifuse material having a higher dielectric constant and a higher acceleration factor than those of silicon dioxide, and by using a diode having a lower band gap than that of silicon. Such memory arrays can be made to have long operating lifetimes by using the high acceleration factor and lower band gap materials. Antifuse materials having dielectric constants between 5 and 27, for example, hafnium silicon oxynitride or hafnium silicon oxide, are particularly effective. Diode materials with band gaps lower than that of silicon, such as germanium or a silicon-germanium alloy, are particularly effective. | 06-04-2009 |
20090141535 | METHODS INVOLVING MEMORY WITH HIGH DIELECTRIC CONSTANT ANTIFUSES ADAPTED FOR USE AT LOW VOLTAGE - Methods involve using a memory array having memory cells comprising a diode and an antifuse, in which the antifuse is made smaller and programmed at lower voltage by using an antifuse material having a higher dielectric constant and a higher acceleration factor than those of silicon dioxide, and in which the diode is made of a material having a lower band gap than that of silicon. Such memory arrays can be made to have long operating lifetimes by using the high acceleration factor and lower band gap materials. Antifuse materials having dielectric constants between 5 and 27, for example, hafnium silicon oxynitride or hafnium silicon oxide, are particularly effective. Diode materials with band gaps lower than that of silicon, such as germanium or a silicon-germanium alloy, are particularly effective. | 06-04-2009 |
20100276660 | MEMORY WITH HIGH DIELECTRIC CONSTANT ANTIFUSES ADAPTED FOR USE AT LOW VOLTAGE - A memory cell is provided that includes a diode and a resistance-switching material layer coupled in series with the diode. The resistance-switching material layer: (a) has a dielectric constant in the range of about 5 to about 27, and (b) includes a material from the family consisting of X | 11-04-2010 |
20110062563 | NON-VOLATILE MEMORY WITH REDUCED MOBILE ION DIFFUSION - Mobile ion diffusion causes a shift in the threshold voltage of non-volatile storage elements in a memory chip, such as during an assembly process of the memory chip. To reduce or avoid such shifts, a coating can be applied to a printed circuit board substrate or a leader frame to which the memory chip is surface mounted. An acrylic resin coating having a thickness of about 10 μm may be used. A memory chip is attached to the coating using an adhesive film. Stacked chips may be used as well. Another approach provides metal barrier traces over copper traces of the printed circuit board, within a solder mask layer. The metal barrier traces are fabricated in the same pattern as the copper traces but are wider so that they at least partially envelop and surround the copper traces. Corresponding apparatuses and fabrication processes are provided. | 03-17-2011 |
20110075482 | MAINTAINING INTEGRITY OF PRELOADED CONTENT IN NON-VOLATILE MEMORY DURING SURFACE MOUNTING - A non-volatile memory chip package is prepared for surface mounting to a substrate in a solder reflow process by programming erased blocks to higher threshold voltage levels, to improve data retention for blocks which are preloaded with content, such as by an electronic device manufacturer. Following the surface mounting, the previously-erased blocks are returned to the erased state. The threshold voltage of storage elements of the preloaded blocks can change during the surface mounting process due to a global charge effect phenomenon. The effect is most prominent for higher state storage elements which are surrounded by erased blocks, in a chip for which the wafer backside was thinned and polished. The erased blocks can be programmed using a single program pulse without performing a verify operation, as a wide threshold voltage distribution is acceptable. | 03-31-2011 |
20130314971 | METHODS INVOLVING MEMORY WITH HIGH DIELECTRIC CONSTANT ANTIFUSES ADAPTED FOR USE AT LOW VOLTAGE - Methods involve using a memory array having memory cells comprising a diode and an antifuse, in which the antifuse is made smaller and programmed at lower voltage by using an antifuse material having a higher dielectric constant and a higher acceleration factor than those of silicon dioxide, and in which the diode is made of a material having a lower band gap than that of silicon. Such memory arrays can be made to have long operating lifetimes by using the high acceleration factor and lower band gap materials. Antifuse materials having dielectric constants between 5 and 27, for example, hafnium silicon oxynitride or hafnium silicon oxide, are particularly effective. Diode materials with band gaps lower than that of silicon, such as germanium or a silicon-germanium alloy, are particularly effective. | 11-28-2013 |