Patent application number | Description | Published |
20100038617 | SEMICONDUCTOR MEMORY DEVICE - A semiconductor memory device having a first wiring layer which is provided on a first insulator, and which extends in a first direction, and a non-volatile memory cell which is provided in a pillar shape on the first wiring layer, and which includes a non-ohmic element and variable resistance element connected in series. The resistance value of the variable resistance element changes in accordance with a voltage or current applied thereto. A barrier layer is provided on the memory cell and is configured in an in-plane direction. A conductive layer is provided on the barrier layer and is configured in an in-plane direction. A second insulator is provided on the first insulator and covers side surfaces of the memory cell, the barrier layer, and the conductive layer. A second wiring layer is provided on the conductive layer and extends in a second direction. | 02-18-2010 |
20100295013 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SAME - A semiconductor device according to an embodiment includes: a semiconductor substrate; a resistance element of a first conductivity type formed in one region of the semiconductor substrate; a field effect transistor of a second conductivity type formed in another region of the semiconductor substrate; and a field effect transistor of the first conductivity type formed in still another region of the semiconductor substrate. The resistance element includes: an insulating film formed in an upper layer portion of the semiconductor substrate; and a well of the first conductivity type formed immediately below the insulating film, an impurity concentration at an arbitrary depth position in the well of the first conductivity is lower than an impurity concentration at the same depth position in a channel region of the field effect transistor of the second conductivity type. | 11-25-2010 |
20110062509 | SEMICONDUCTOR DEVICE HAVING UPPER LAYER PORTION OF SEMICONDUCTOR SUBSTRATE DIVIDED INTO A PLURALITY OF ACTIVE AREAS - A semiconductor memory device includes: a semiconductor substrate; a plurality of element isolation insulators disposed in parts of an upper layer portion of the semiconductor substrate and dividing the upper layer portion into a plurality of active areas extended in one direction; tunnel insulating films provided on the active areas: charge storage members provided on the tunnel insulating films; and control gate electrodes provided on the charge storage members. A width of a middle portion of one of the active areas in the up-to-down direction being smaller than a width of a portion of the active areas upper of the middle portion and a width of a portion of the active areas below the middle portion. | 03-17-2011 |
20110062527 | SEMICONDUCTOR APPARATUS AND METHOD FOR MANUFACTURING SAME - In one embodiment, a semiconductor apparatus is disclosed. The apparatus includes: an element-isolation insulating film formed on a major surface of a semiconductor layer, the element-isolation insulating film having a first opening and a second opening; an n-type MOSFET provided in the first opening; and a p-type MOSFET provided in the first opening. An upper face of a portion of the element-isolation insulating film adjacent to a source/drain region of the n-type MOSFET is positioned below an upper face of the source/drain region of the n-type MOSFET. An upper face of a portion of the element-isolation insulating film adjacent to a source/drain region of the p-type MOSFET is positioned above an upper face of the source/drain region of the p-type MOSFET. | 03-17-2011 |
20110096600 | SEMICONDUCTOR MEMORY DEVICE REDUCING RESISTANCE FLUCTUATION OF DATA TRANSFER LINE - According to one embodiment, a semiconductor memory device includes first and second memory cell blocks and an interconnect rerouting unit provided therebetween. The first memory cell block includes first interconnects and second interconnects provided in each space between the first interconnects. The second memory cell block includes a plurality of third interconnects provided on lines extending from the first interconnects and a plurality of fourth interconnects provided on lines extending from the second interconnects. A width and a thickness of the second and fourth interconnects are smaller than a width and a thickness of the first and second interconnects. Each of the first to fourth interconnects is connected to one end of first to fourth cell units including memory cells. The interconnect rerouting unit connects one of the fourth interconnects to one of the first interconnects and connects one of the third interconnects to the second interconnects. | 04-28-2011 |
20110215473 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SAME - According to one embodiment, a semiconductor device includes a first contact, a second contact, and an intermediate interconnection. The first contact is made of a first conductive material. The second contact is made of a second conductive material. A lower end portion of the second contact is connected to an upper end portion of the first contact. The intermediate interconnection is made of a third conductive material and isolated from the first contact and the second contact. A lower face of the intermediate interconnection is positioned higher than a lower face of the first contact. An upper face of the intermediate interconnection is positioned lower than an upper face of the second contact. A diffusion coefficient of the first conductive material with respect to the second conductive material is lower than a diffusion coefficient of the third conductive material with respect to the second conductive material. | 09-08-2011 |
20110228583 | SEMICONDUCTOR MEMORY DEVICE - According to one embodiment, a semiconductor memory device includes a memory cell array, a first sense amplifier circuit, and a second sense amplifier circuit. The memory cell array includes a plurality of first memory cell units, a plurality of second memory cell units, a plurality of first interconnects, and a plurality of second interconnects. The first sense amplifier circuit is connected to the plurality of first interconnects. The second sense amplifier circuit is connected to the plurality of second interconnects. Heights of upper surfaces of interconnects are equal. At least one of a width of each of the plurality of second interconnects along a second direction perpendicular to the first direction and a thickness of each of the plurality of second interconnects along a third direction perpendicular to the first direction and the second direction is set smaller than each of the plurality of first interconnects, and the first sense amplifier circuit and the second sense amplifier circuit are disposed to face each other across the memory cell array. | 09-22-2011 |
20120236619 | SEMICONDUCTOR MEMORY DEVICE - According to one embodiment, a semiconductor memory device includes a memory array and a peripheral circuit. The memory array has a plurality of memory cells, word lines, and bit lines, in which a first, second, and third blocks are set in the order along the bit line. The peripheral circuit has a transistor group. The transistor group includes a first transfer transistor belonging to the first block, a second transfer transistor belonging to the second block, and a third transfer transistor belonging to the third block. The first, second, and third transfer transistors share the other of a source and a drain of each. With regard to a direction in which either of the source and the drain is connected to the other in each of the first, second, and third transfer transistors, the directions of the adjacent transfer transistors are different from each other by 90° or 180°. | 09-20-2012 |
Patent application number | Description | Published |
20080268639 | Method of Manufacturing A Semiconductor Integrated Circuit Device - In forming five trenches buried with an intermediate conductive layer for connecting transfer MISFETs and driving MISFETs with vertical MISFETs formed thereover, in which the second and third trenches, and the first, fourth, and fifth trenches are formed separately by twice etching using first and second photoresist films as a mask. Since all the trenches can be formed at a good accuracy even in a case where the shortest distance between the first trench and the second or third trench, and the shortest distance between the second or third trench and the fourth trench is smaller than the resolution limit for the exposure light, the distance between each of the five trenches arranged in one identical memory cell can be reduced to be smaller than resolution limit for the exposure light. | 10-30-2008 |
20090140342 | SEMICONDUCTOR MEMORY DEVICE AND A METHOD OF MANUFACTURING THE SAME, A METHOD OF MANUFACTURING A VERTICAL MISFET AND A VERTICAL MISFET, AND A METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE AND A SEMICONDUCTOR DEVICE - Vertical MISFETs are formed over drive MISFETs and transfer MISFETs. The vertical MISFETs comprise rectangular pillar laminated bodies each formed by laminating a lower semiconductor layer (drain), an intermediate semiconductor layer, and an upper semiconductor layer (source), and gate electrodes formed on corresponding side walls of the laminated bodies with gate insulating films interposed therebetween. In each vertical MISFET, the lower semiconductor layer constitutes a drain, the intermediate semiconductor layer constitutes a substrate (channel region), and the upper semiconductor layer constitutes a source. The lower semiconductor layer, the intermediate semiconductor layer and the upper semiconductor layer are each comprised of a silicon film. The lower semiconductor layer and the upper semiconductor layer are doped with a p type and constituted of a p type silicon film. | 06-04-2009 |
20090275193 | METHOD OF MANUFACTURING A SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE - In forming five trenches buried with an intermediate conductive layer for connecting transfer MISFETs and driving MISFETs with vertical MISFETs formed thereover, in which the second and third trenches, and the first, fourth, and fifth trenches are formed separately by twice etching using first and second photoresist films as a mask. Since all the trenches can be formed at a good accuracy even in a case where the shortest distance between the first trench and the second or third trench, and the shortest distance between the second or third trench and the fourth trench is smaller than the resolution limit for the exposure light, the distance between each of the five trenches arranged in one identical memory cell can be reduced to be smaller than resolution limit for the exposure light. | 11-05-2009 |
20100136778 | Semiconductor Memory Device and a Method of Manufacturing the Same, A Method of Manufacturing a Vertical MISFET and a Vertical MISFET, and a Method of Manufacturing a Semiconductor Device and a Semiconductor Device - Vertical MISFETs are formed over drive MISFETs and transfer MISFETs. The vertical MISFETs comprise rectangular pillar laminated bodies each formed by laminating a lower semiconductor layer (drain), an intermediate semiconductor layer, and an upper semiconductor layer (source), and gate electrodes formed on corresponding side walls of the laminated bodies with gate insulating films interposed therebetween. In each vertical MISFET, the lower semiconductor layer constitutes a drain, the intermediate semiconductor layer constitutes a substrate (channel region), and the upper semiconductor layer constitutes a source. The lower semiconductor layer, the intermediate semiconductor layer and the upper semiconductor layer are each comprised of a silicon film. The lower semiconductor layer and the upper semiconductor layer are doped with a p type and constituted of a p type silicon film. | 06-03-2010 |
20110021022 | METHOD OF MANUFACTURING A SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE - In forming five trenches buried with an intermediate conductive layer for connecting transfer MISFETs and driving MISFETs with vertical MISFETs formed thereover, in which the second and third trenches, and the first, fourth, and fifth trenches are formed separately by twice etching using first and second photoresist films as a mask. Since all the trenches can be formed at a good accuracy even in a case where the shortest distance between the first trench and the second or third trench, and the shortest distance between the second or third trench and the fourth trench is smaller than the resolution limit for the exposure light, the distance between each of the five trenches arranged in one identical memory cell can be reduced to be smaller than resolution limit for the exposure light. | 01-27-2011 |
20110230041 | SEMICONDUCTOR MEMORY DEVICE AND A METHOD OF MANUFACTURING THE SAME, A METHOD OF MANUFACTURING A VERTICAL MISFET AND A VERTICAL MISFET, AND A METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE AND A SEMICONDUCTOR DEVICE - Vertical MISFETs are formed over drive MISFETs and transfer MISFETs. The vertical MISFETs comprise rectangular pillar laminated bodies each formed by laminating a lower semiconductor layer (drain), an intermediate semiconductor layer, and an upper semiconductor layer (source), and gate electrodes formed on corresponding side walls of the laminated bodies with gate insulating films interposed therebetween. In each vertical MISFET, the lower semiconductor layer constitutes a drain, the intermediate semiconductor layer constitutes a substrate (channel region), and the upper semiconductor layer constitutes a source. The lower semiconductor layer, the intermediate semiconductor layer and the upper semiconductor layer are each comprised of a silicon film. The lower semiconductor layer and the upper semiconductor layer are doped with a p type and constituted of a p type silicon film. | 09-22-2011 |
20110250752 | METHOD OF MANUFACTURING A SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE - In forming five trenches buried with an intermediate conductive layer for connecting transfer MISFETs and driving MISFETs with vertical MISFETs formed thereover, in which the second and third trenches, and the first, fourth, and fifth trenches are formed separately by twice etching using first and second photoresist films as a mask. Since all the trenches can be formed at a good accuracy even in a case where the shortest distance between the first trench and the second or third trench, and the shortest distance between the second or third trench and the fourth trench is smaller than the resolution limit for the exposure light, the distance between each of the five trenches arranged in one identical memory cell can be reduced to be smaller than resolution limit for the exposure light. | 10-13-2011 |
Patent application number | Description | Published |
20090267136 | SEMICONDUCTOR MEMORY DEVICE AND METHOD OF MANUFACTURING THE SAME - A semiconductor memory device having a memory cell region and a peripheral circuit region, and a method of manufacturing such a semiconductor memory device, are proposed, in which trench grooves are formed to be shallow in the memory cell region in order to improve the yield, and trench grooves are formed to be deep in the high voltage transistor region of the peripheral circuit region, in particular in a high voltage transistor region thereof, in order to improve the element isolation withstand voltage. A plurality of memory cell transistors having an ONO layer | 10-29-2009 |
20130221422 | MEMORY DEVICE AND METHOD OF MANUFACTURE THEREOF - A memory device is provided with a floating gate electrode film formed in a memory cell region, a first inter-electrode insulating film formed on the floating gate electrode film, a control gate electrode film formed on the first inter-electrode insulating film, a lower conductive film formed in a peripheral circuit region, a second inter-electrode insulating film formed on the lower conductive film, an upper conductive film formed on the second inter-electrode insulating film, and a pair of contacts that is separated from each other, is connected to the lower conductive film from the upper side, and is not connected to the upper conductive film. Materials of the lower conductive film and the floating gate electrode film are the same. Materials of the second inter-electrode insulating film and the first inter-electrode insulating film are the same. Materials of the upper conductive film and the control gate electrode film are the same. | 08-29-2013 |
20140242767 | METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE - After forming a first film over the main surface of a semiconductor substrate, the first film is patterned, thereby forming a control gate electrode for a non-volatile memory, a dummy gate electrode, and a first film pattern. Subsequently, a memory gate electrode for the non-volatile memory adjacent to the control gate electrode is formed. Then, the first film pattern is patterned thereby forming a gate electrode and a dummy gate electrode. | 08-28-2014 |
20140286103 | NON-VOLATILE SEMICONDUCTOR MEMORY DEVICE - A non-volatile semiconductor memory device includes a memory cell configured to allow electrical writing and erasing, a bit line configured to transmit a potential corresponding to data stored in the memory cell in a column direction, a sense amplifier circuit configured to detect a potential of the bit line, and a bit line coupling circuit coupled between the bit line and the sense amplifier circuit. The bit line coupling circuit includes a first bit line coupling transistor in an outer layout area of the bit line coupling circuit and a second bit line coupling transistor in an inner layout area of the bit line coupling circuit. The first bit line coupling transistor has a longer distance in a channel length direction or in a channel width direction between an impurity diffused layer coupled to the bit line and an element isolation area than the second bit line coupling transistor. | 09-25-2014 |
20150076625 | SEMICONDUCTOR DEVICE - A semiconductor device according to an embodiment includes a gate wire including a laminated film in which a polysilicon film, a barrier conductive film, and a metal film are laminated in this order; a first contact plug/upper layer wire arranged above the source or the drain; a second upper layer wire arranged above an element isolation region; a second contact plug arranged apart from the second upper layer wire and connecting the metal film and the polysilicon film above a channel region; and a third contact plug formed apart from the polysilicon film in the element isolation region and connecting the second upper layer wire and the metal film. The second contact plug includes a barrier metal in contact with the polysilicon film and the barrier conductive film is made of WN, TaN, or Ta and the barrier metal is made of Ti or TiN. | 03-19-2015 |