Patent application number | Description | Published |
20090047756 | DUAL PORT GAIN CELL WITH SIDE AND TOP GATED READ TRANSISTOR - A DRAM memory cell and process sequence for fabricating a dense (20 or 18 square) layout is fabricated with silicon-on-insulator (SOI) CMOS technology. Specifically, the present invention provides a dense, high-performance SRAM cell replacement that is compatible with existing SOI CMOS technologies. Various gain cell layouts are known in the art. The present invention improves on the state of the art by providing a dense layout that is fabricated with SOI CMOS. In general terms, the memory cell includes a first transistor provided with a gate, a source, and a drain respectively; a second transistor having a first gate, a second gate, a source, and a drain respectively; and a capacitor having a first terminal, wherein the first terminal of said capacitor and the second gate of said second transistor comprise a single entity. | 02-19-2009 |
20090079030 | Forming SOI Trench Memory with Single-Sided Buried Strap - A method of forming a trench memory cell includes forming a trench capacitor within a substrate material, the trench capacitor including a node dielectric layer formed within a trench and a conductive capacitor electrode material formed within the trench in contact with the node dielectric layer; forming a strap mask so as cover one side of the trench and removing one or more materials from an uncovered opposite side of the trench; and forming a conductive buried strap material within the trench; wherein the strap mask is patterned in a manner such that a single-sided buried strap is defined within the trench, the single-sided buried strap configured in a manner such that the deep trench capacitor is electrically accessible at only one side of the trench. | 03-26-2009 |
20090108356 | INTEGRATION SCHEME FOR MULTIPLE METAL GATE WORK FUNCTION STRUCTURES - A metal gate stack containing a metal layer having a mid-band-gap work function is formed on a high-k gate dielectric layer. A threshold voltage adjustment oxide layer is formed over a portion of the high-k gate dielectric layer to provide devices having a work function near a first band gap edge, while another portion of the high-k dielectric layer remains free of the threshold voltage adjustment oxide layer. A gate stack containing a semiconductor oxide based gate dielectric and a doped polycrystalline semiconductor material may also be formed to provide a gate stack having a yet another work function located near a second band gap edge which is the opposite of the first band gap edge. A dense circuit containing transistors of p-type and n-type with the mid-band-gap work function are formed in the region containing the threshold voltage adjustment oxide layer. | 04-30-2009 |
20090152638 | DUAL OXIDE STRESS LINER - A transistor structure includes a first type of transistor (e.g., P-type) positioned in a first area of the substrate, and a second type of transistor (e.g., N-type) positioned in a second area of the substrate. A first type of stressing layer (compressive conformal nitride) is positioned above the first type of transistor and a second type of stressing layer (compressive tensile nitride) is positioned above the second type of transistor. In addition, another first type of stressing layer (compressive oxide) is positioned above the first type of transistor. Further, another second type of stressing layer (compressive oxide) is positioned above the second type of transistor. | 06-18-2009 |
20090154258 | FLOATING BODY CONTROL IN SOI DRAM - A system including a DRAM memory device on an integrated circuit (IC) using a control logic device to initiate a body refresh operation to provide a means for maintaining a low voltage at a floating body and discourage data loss, and a design structure including the DRAM memory device embodied in a machine readable medium is provided. A plurality of DRAM cells are connected to a first word line circuit and a first bit line circuit. The control logic device is coupled to the DRAM memory device and the IC for initiating the body refresh cycle. The control logic communicates with a first bit line and word line circuits and communicates with a reference word line and bit line circuits. A sense amplifier circuit and signal is provided for amplifying the voltage at the first bit line and the reference bit line. The body refresh cycle includes deactivating the first word line voltage while the first bit line and reference bit line voltages continue. | 06-18-2009 |
20090174031 | DRAM HAVING DEEP TRENCH CAPACITORS WITH LIGHTLY DOPED BURIED PLATES - By controlling buried plate doping level and bias condition, different capacitances can be obtained from capacitors on the same chip with the same layout and deep trench process. The capacitors may be storage capacitors of DRAM/eDRAM cells. The doping concentration may be less than 3E19cm−3, a voltage difference between the biases of the buried electrodes may be at least 0.5V, and a capacitance of one capacitor may be at least 1.2 times, such as 2.0 times the capacitance of another capacitor. | 07-09-2009 |
20090176339 | Method of multi-port memory fabrication with parallel connected trench capacitors in a cell - A method is provided for fabricating a multi-port memory in which a plurality of parallel connected capacitors are in a cell. A plurality of trench capacitors are formed which have capacitor dielectric layers extending along walls of the plurality of trenches, the plurality of trench capacitors having first capacitor plates and second capacitor plates opposite the capacitor dielectric layers from the first capacitor plates. The first capacitor plates are conductively tied together and the second capacitor plates are conductively tied together. In this way, the first capacitor plates are adapted to receive a same variable voltage and the second capacitor plates are adapted to receive a same fixed voltage. | 07-09-2009 |
20090268510 | DYNAMIC RANDOM ACCESS MEMORY CIRCUIT, DESIGN STRUCTURE AND METHOD - Disclosed is a DRAM circuit that incorporates an improved reference cell, has half the capacitance of the memory cell, does not require a particular reference voltage, and can be formed using the same fabrication processes as the memory cell. This DRAM circuit comprises a memory cell with a single trench capacitor and a reference cell having two trench capacitors. The two reference cell trench capacitors are connected in series through a merged buried capacitor plate such that they provide half the capacitance of the memory cell trench capacitor. Additionally, the reference cell trench capacitors have essentially the same structure as the memory cell trench capacitor so that they can be formed in conjunction with the memory cell trench capacitor. Also disclosed are a design structure for the above-described memory circuit and a method for forming the above-described memory circuit. | 10-29-2009 |
20090289291 | SOI DEEP TRENCH CAPACITOR EMPLOYING A NON-CONFORMAL INNER SPACER - A bottle shaped trench for an SOI capacitor is formed by a simple processing sequence. A non-conformal dielectric layer with an optional conformal dielectric diffusion barrier layer underneath is formed on sidewalls of a deep trench. Employing an isotropic etch, the non-conformal dielectric layer is removed from a bottom portion of the deep trench, leaving a dielectric spacer covering sidewalls of the buried insulator layer and the top semiconductor layer. The bottom portion of the deep trench is expanded to form a bottle shaped trench, and a buried plated is formed underneath the buried insulator layer. The dielectric spacer may be recessed during formation of a buried strap to form a graded thickness dielectric collar around the upper portion of an inner electrode. Alternately, the dielectric spacer may be removed prior to formation of a buried strap. | 11-26-2009 |
20090315124 | WORK FUNCTION ENGINEERING FOR EDRAM MOSFETS - Embedded DRAM MOSFETs including an array NFET having a gate stack comprising a high-K dielectric layer upon which is deposited a first metal oxide layer (CD | 12-24-2009 |
20100032742 | INTEGRATED CIRCUITS COMPRISING AN ACTIVE TRANSISTOR ELECTRICALLY CONNECTED TO A TRENCH CAPACITOR BY AN OVERLYING CONTACT AND METHODS OF MAKING - A method of forming an integrated circuit comprises: providing a semiconductor topography comprising an active transistor laterally adjacent to a trench capacitor formed in a semiconductor substrate, the active transistor comprising a source junction and a drain junction, wherein a barrier layer is disposed along a periphery of the trench capacitor for isolating the trench capacitor; forming an interlevel dielectric across the semiconductor topography; concurrently etching (i) a first opening through the interlevel dielectric to the drain junction of the active transistor and the trench capacitor, and (ii) a second opening through the interlevel dielectric to the source junction of the active transistor; and filling the first opening and the second opening with a conductive material to form a strap for electrically connecting the trench capacitor to the drain junction of the active transistor and to also form a contact for electrically connecting the source junction to an overlying level of the integrated circuit. | 02-11-2010 |
20100200949 | METHOD FOR TUNING THE THRESHOLD VOLTAGE OF A METAL GATE AND HIGH-K DEVICE - A method of forming a deep trench capacitor includes providing a wafer. Devices are formed on a front side of the wafer. A through-silicon-via is formed on a substrate of the wafer. Deep trenches are formed on a back side of the wafer. A deep trench capacitor is formed in the deep trench. The through-silicon-via connects the deep trench capacitor to the devices. | 08-12-2010 |
20100203732 | FIN AND FINFET FORMATION BY ANGLED ION IMPLANTATION - A semiconductor device is formed by providing a substrate and forming a semiconductor-containing layer atop the substrate. A mask having a plurality of openings is then formed atop the semiconductor-containing layer, wherein adjacent openings of the plurality of openings of the mask are separated by a minimum feature dimension. Thereafter, an angled ion implantation is performed to introduce dopants to a first portion of the semiconductor-containing layer, wherein a remaining portion that is substantially free of dopants is present beneath the mask. The first portion of the semiconductor-containing layer containing the dopants is removed selective to the remaining portion of semiconductor-containing layer that is substantially free of the dopants to provide a pattern of sublithographic dimension, and the pattern is transferred into the substrate to provide a fin structure of sublithographic dimension. | 08-12-2010 |
20100237417 | Through-Gate Implant for Body Dopant - The present invention, provides a semiconductor device including a substrate including a semiconductor layer overlying an insulating layer, wherein a back gate structure is present underlying the insulating layer and a front gate structure on the semiconductor layer; a channel dopant region underlying the front gate structure of the substrate, wherein the channel dopant region has a first concentration present at an interface of the semiconductor layer and the insulating layer and at least a second concentration present at the interface of the front gate structure and the semiconductor layer, wherein the first concentration is greater than the second concentration; and a source region and drain region present in the semiconductor layer of the substrate. | 09-23-2010 |
20100283093 | Structure and Method to Form EDRAM on SOI Substrate - A memory device is provided that in one embodiment includes a trench capacitor located in a semiconductor substrate including an outer electrode provided by the semiconductor substrate, an inner electrode provided by a conductive fill material, and a node dielectric layer located between the outer electrode and the inner electrode; and a semiconductor device positioned centrally over the trench capacitor. The semiconductor device includes a source region, a drain region, and a gate structure, in which the semiconductor device is formed on a semiconductor layer that is separated from the semiconductor substrate by a dielectric layer. A first contact is present extending from an upper surface of the semiconductor layer into electrical contact with the semiconductor substrate, and a second contact from the drain region of the semiconductor device in electrical contact to the conductive material within the at least one trench. | 11-11-2010 |
20110180883 | METHOD AND STRUCTURE TO IMPROVE BODY EFFECT AND JUNCTION CAPACITANCE - A method and structure implant a first-type impurity within a substrate to form a channel region within the substrate adjacent a top surface of the substrate; form a gate stack on the top surface of the substrate above the channel region; and implant a second-type impurity within the substrate to form source and drain regions within the substrate adjacent the top surface. The channel region is positioned between the source and drain regions. The second-type impurity has an opposite polarity with respect to the first-type impurity. The method and structure implant a greater concentration of the first-type impurity, relative to a concentration of the first-type impurity within the channel region, to form a primary body doping region within the substrate below (relative to the top surface) the channel region; and to form secondary body doping regions within the substrate below (relative to the top surface) the source and drain regions. | 07-28-2011 |
20110248326 | STRUCTURE AND METHOD TO INTEGRATE EMBEDDED DRAM WITH FINFET - A transistor includes a first fin structure and at least a second fin structure formed on a substrate. A deep trench area is formed between the first and second fin structures. The deep trench area extends through an insulator layer of the substrate and a semiconductor layer of the substrate. A high-k metal gate is formed within the deep trench area. A polysilicon layer is formed within the deep trench area adjacent to the metal layer. The polysilicon layer and the high-k metal layer are recessed below a top surface of the insulator layer. A poly strap in the deep trench area is formed on top of the high-k metal gate and the polysilicon material. The poly strap is dimensioned to be below a top surface of the first and second fin structures. The first fin structure and the second fin structure are electrically coupled to the poly strap. | 10-13-2011 |
20110272702 | ENHANCED CAPACITANCE DEEP TRENCH CAPACITOR FOR EDRAM - A substrate including a stack of a handle substrate, an optional lower insulator layer, a doped polycrystalline semiconductor layer, an upper insulator layer, and a top semiconductor layer is provided. A deep trench is formed through the top semiconductor layer, the upper insulator layer, and the doped polycrystalline semiconductor layer. Exposed vertical surfaces of the polycrystalline semiconductor layer are crystallographically etched to form random facets in the deep trench, thereby increasing the total exposed surface area of the polycrystalline semiconductor layer in the deep trench. A node dielectric and at least one conductive material are deposited to fill the trench and to form a buried strap portion, which constitute a capacitor of an eDRAM. Access transistors and other logic devices can be formed. | 11-10-2011 |
20110272762 | EMBEDDED DRAM FOR EXTREMELY THIN SEMICONDUCTOR-ON-INSULATOR - A node dielectric and a conductive trench fill region filling a deep trench are recessed to a depth that is substantially coplanar with a top surface of a semiconductor-on-insulator (SOI) layer. A shallow trench isolation portion is formed on one side of an upper portion of the deep trench, while the other side of the upper portion of the deep trench provides an exposed surface of a semiconductor material of the conductive fill region. A selective epitaxy process is performed to deposit a raised source region and a raised strap region. The raised source region is formed directly on a planar source region within the SOI layer, and the raised strap region is formed directly on the conductive fill region. The raised strap region contacts the raised source region to provide an electrically conductive path between the planar source region and the conductive fill region. | 11-10-2011 |
20110291169 | REDUCED CORNER LEAKAGE IN SOI STRUCTURE AND METHOD - A structural alternative to retro doping to reduce transistor leakage is provided by providing a liner in a trench, undercutting a conduction channel region in an active semiconductor layer, etching a side, corner and/or bottom of the conduction channel where the undercut exposes semiconductor material in the active layer and replacing the removed portion of the conduction channel with insulator. This shaping of the conduction channel increases the distance to adjacent circuit elements which, if charged, could otherwise induce a voltage and cause a change in back-channel threshold in regions of the conduction channel and narrows and reduces cross-sectional area of the channel where the conduction in the channel is not well-controlled; both of which effects significantly reduce leakage of the transistor. | 12-01-2011 |
20110316061 | STRUCTURE AND METHOD TO CONTROL BOTTOM CORNER THRESHOLD IN AN SOI DEVICE - Semiconductor structures and methods to control bottom corner threshold in a silicon-on-insulator (SOI) device. A method includes doping a corner region of a semiconductor-on-insulator (SOI) island. The doping includes tailoring a localized doping of the corner region to reduce capacitive coupling of the SOI island with an adjacent structure. | 12-29-2011 |
20120064694 | FORMING IMPLANTED PLATES FOR HIGH ASPECT RATIO TRENCHES USING STAGED SACRIFICIAL LAYER REMOVAL - A method of forming a deep trench structure for a semiconductor device includes forming a mask layer over a semiconductor substrate. An opening in the mask layer is formed by patterning the mask layer, and a deep trench is formed in the semiconductor substrate using the patterned opening in the mask layer. A sacrificial fill material is formed over the mask layer and into the deep trench. A first portion of the sacrificial fill material is recessed from the deep trench and a first dopant implant forms a first doped region in the semiconductor substrate. A second portion of the sacrificial fill material is recessed from the deep trench and a second dopant implant forms a second doped region in the semiconductor substrate, wherein the second doped region is formed underneath the first doped region such that the second doped region and the first doped region are contiguous with each other. | 03-15-2012 |
20120068237 | SELF-ALIGNED STRAP FOR EMBEDDED CAPACITOR AND REPLACEMENT GATE DEVICES - After forming a planarization dielectric layer in a replacement gate integration scheme, disposable gate structures are removed and a stack of a gate dielectric layer and a gate electrode layer is formed within recessed gate regions. Each gate electrode structure is then recessed below a topmost surface of the gate dielectric layer. A dielectric metal oxide portion is formed above each gate electrode by planarization. The dielectric metal oxide portions and gate spacers are employed as a self-aligning etch mask in combination with a patterned photoresist to expose and metalize semiconductor surfaces of a source region and an inner electrode in each embedded memory cell structure. The metalized semiconductor portions form metal semiconductor alloy straps that provide a conductive path between the inner electrode of a capacitor and the source of an access transistor. | 03-22-2012 |
20120083092 | STRUCTURE AND METHOD OF FORMING ENHANCED ARRAY DEVICE ISOLATION FOR IMPLANTED PLATE EDRAM - A method for forming a memory device in a semiconductor on insulator substrate is provided, in which a protective oxide that is present on the sidewalls of the trench protects the first semiconductor layer, i.e., SOI layer, of the semiconductor on insulator substrate during bottle etching of the trench. In one embodiment, the protective oxide reduces back channel effects of the transistors to the memory devices in the trench that are formed in the semiconductor on insulator substrate. In another embodiment, a thermal oxidation process increases the thickness of the buried dielectric layer of a bonded semiconductor on insulator substrate by oxidizing the bonded interface between the buried dielectric layer and at least one semiconductor layers of the semiconductor on insulator substrate. The increased thickness of the buried dielectric layer may reduce back channel effects in devices formed on the substrate having trench memory structures. | 04-05-2012 |
20120122315 | SELF-ALIGNED DEVICES AND METHODS OF MANUFACTURE - A method includes forming patterned lines on a substrate having a predetermined pitch. The method further includes forming spacer sidewalls on sidewalls of the patterned lines. The method further includes forming material in a space between the spacer sidewalls of adjacent patterned lines. The method further includes forming another patterned line from the material by protecting the material in the space between the spacer sidewalls of adjacent patterned lines while removing the spacer sidewalls. The method further includes transferring a pattern of the patterned lines and the another patterned line to the substrate. | 05-17-2012 |
20120139080 | METHOD OF FORMING SUBSTRATE CONTACT FOR SEMICONDUCTOR ON INSULATOR (SOI) SUBSTRATE - A semiconductor structure is provided that includes a material stack including an epitaxially grown semiconductor layer on a base semiconductor layer, a dielectric layer on the epitaxially grown semiconductor layer, and an upper semiconductor layer present on the dielectric layer. A capacitor is present extending from the upper semiconductor layer through the dielectric layer into contact with the epitaxially grown semiconductor layer. The capacitor includes a node dielectric present on the sidewalls of the trench and an upper electrode filling at least a portion of the trench. A substrate contact is present in a contact trench extending from the upper semiconductor layer through the dielectric layer and the epitaxially semiconductor layer to a doped region of the base semiconductor layer. A substrate contact is also provided that contacts the base semiconductor layer through the sidewall of a trench. Methods for forming the above-described structures are also provided. | 06-07-2012 |
20120139085 | Structure and Method for Topography Free SOI Integration - A semiconductor structure is provided that includes a semiconductor oxide layer having features. The semiconductor oxide layer having the features is located between an active semiconductor layer and a handle substrate. The semiconductor structure includes a planarized top surface of the active semiconductor layer such that the semiconductor oxide layer is beneath the planarized top surface. The features within the semiconductor oxide layer are mated with a surface of the active semiconductor layer. | 06-07-2012 |
20120171827 | STRUCTURE AND METHOD TO FORM EDRAM ON SOI SUBSTRATE - A memory device is provided that in one embodiment includes a trench capacitor located in a semiconductor substrate including an outer electrode provided by the semiconductor substrate, an inner electrode provided by a conductive fill material, and a node dielectric layer located between the outer electrode and the inner electrode; and a semiconductor device positioned centrally over the trench capacitor. The semiconductor device includes a source region, a drain region, and a gate structure, in which the semiconductor device is formed on a semiconductor layer that is separated from the semiconductor substrate by a dielectric layer. A first contact is present extending from an upper surface of the semiconductor layer into electrical contact with the semiconductor substrate, and a second contact from the drain region of the semiconductor device in electrical contact to the conductive material within the at least one trench. | 07-05-2012 |
20120175694 | STRUCTURE AND METHOD OF FORMING ENHANCED ARRAY DEVICE ISOLATION FOR IMPLANTED PLATE EDRAM - A memory device is provided including a semiconductor on insulator (SOI) substrate including a first semiconductor layer atop a buried dielectric layer, wherein the buried dielectric layer is overlying a second semiconductor layer. A capacitor is present in a trench, wherein the trench extends from an upper surface of the first semiconductor layer through the buried dielectric layer and extends into the second semiconductor layer. A protective oxide is present in a void that lies adjacent the first semiconductor layer, and a pass transistor is present atop the semiconductor on insulator substrate in electrical communication with the capacitor. | 07-12-2012 |
20120181661 | METHOD FOR TUNING THE TRHESHOLD VOLTAGE OF A METAL GATE AND HIGH-K DEVICE - A method of forming a deep trench capacitor includes providing a wafer. Devices are formed on a front side of the wafer. A through-silicon-via is formed on a substrate of the wafer. Deep trenches are formed on a back side of the wafer. A deep trench capacitor is formed in the deep trench. The through-silicon-via connects the deep trench capacitor to the devices. | 07-19-2012 |
20120187490 | FET STRUCTURES WITH TRENCH IMPLANTATION TO IMPROVE BACK CHANNEL LEAKAGE AND BODY RESISTANCE - A field effect transistor (FET) structure on a semiconductor substrate which includes a gate structure having a spacer on a semiconductor substrate; an extension implant underneath the gate structure; a recessed source and a recessed drain filled with a doped epitaxial material; halo implanted regions adjacent a bottom of the recessed source and drain and being underneath the gate stack. In an exemplary embodiment, there is implanted junction butting underneath the bottom of each of the recessed source and drain, the junction butting being separate and distinct from the halo implanted regions. In another exemplary embodiment, the doped epitaxial material is graded from a lower dopant concentration at a side of the recessed source and drain to a higher dopant concentration at a center of the recessed source and drain. In a further exemplary embodiment, the semiconductor substrate is a semiconductor on insulator substrate. | 07-26-2012 |
20120196413 | METHOD AND STRUCTURE TO IMPROVE BODY EFFECT AND JUNCTION CAPACITANCE - A method and structure implant a first-type impurity within a substrate to form a channel region within the substrate adjacent a top surface of the substrate; form a gate stack on the top surface of the substrate above the channel region; and implant a second-type impurity within the substrate to form source and drain regions within the substrate adjacent the top surface. The channel region is positioned between the source and drain regions. The second-type impurity has an opposite polarity with respect to the first-type impurity. The method and structure implant a greater concentration of the first-type impurity, relative to a concentration of the first-type impurity within the channel region, to form a primary body doping region within the substrate below (relative to the top surface) the channel region; and to form secondary body doping regions within the substrate below (relative to the top surface) the source and drain regions. | 08-02-2012 |
20120205732 | INTEGRATED CIRCUITS COMPRISING AN ACTIVE TRANSISTOR ELECTRICALLY CONNECTED TO A TRENCH CAPACITOR BY AN OVERLYING CONTACT - An integrated circuit includes an active transistor laterally adjacent to a trench capacitor formed in a semiconductor substrate, the active transistor comprising a source junction and a drain junction, wherein a barrier layer is disposed along a periphery of the trench capacitor for isolating the trench capacitor; a passive transistor laterally spaced from the active transistor, wherein at least a portion of the trench capacitor is interposed between the active and passive transistors; an interlevel dielectric disposed upon the active and passive transistors; and a first conductive contact extending through the interlevel dielectric to the drain junction of the active transistor and the at least a portion of the trench capacitor between the active and passive transistors, wherein the first conductive contact electrically connects the trench capacitor to the drain junction of the active transistor. | 08-16-2012 |
20120286392 | SUPPRESSION OF DIFFUSION IN EPITAXIAL BURIED PLATE FOR DEEP TRENCHES - Dopants of a first conductivity type are implanted into a top portion of a semiconductor substrate having a doping of the first conductivity type to increase the dopant concentration in the top portion, which is a first-conductivity-type semiconductor layer. A semiconductor material layer having a doping of the second conductivity type, a buried insulator layer, and a top semiconductor layer are formed thereupon. Deep trenches having a narrow width have a bottom surface within the second-conductivity-type semiconductor layer, which functions as a buried plate. Deep trenches having a wider width are etched into the first-conductivity-type layer underneath, and can be used to form an isolation structure. The additional dopants in the first-conductivity-type semiconductor layer provide a counterdoping against downward diffusion of dopants of the second conductivity type to enhance electrical isolation. | 11-15-2012 |
20120305998 | HIGH DENSITY MEMORY CELLS USING LATERAL EPITAXY - In a vertical dynamic memory cell, monocrystalline semiconductor material of improved quality is provided for the channel of an access transistor by lateral epitaxial growth over an insulator material (which complements the capacitor dielectric in completely surrounding the storage node except at a contact connection structure, preferably of metal, from the access transistor to the storage node electrode) and etching away a region of the lateral epitaxial growth including a location where crystal lattice dislocations are most likely to occur; both of which features serve to reduce or avoid leakage of charge from the storage node. An isolation structure can be provided in the etched region such that space is provided for connections to various portions of a memory cell array. | 12-06-2012 |
20120306049 | METAL TRENCH CAPACITOR AND IMPROVED ISOLATION AND METHODS OF MANUFACTURE - A high-k dielectric metal trench capacitor and improved isolation and methods of manufacturing the same is provided. The method includes forming at least one deep trench in a substrate, and filling the deep trench with sacrificial fill material and a poly material. The method further includes continuing with CMOS processes, comprising forming at least one transistor and back end of line (BEOL) layer. The method further includes removing the sacrificial fill material from the deep trenches to expose sidewalls, and forming a capacitor plate on the exposed sidewalls of the deep trench. The method further includes lining the capacitor plate with a high-k dielectric material and filling remaining portions of the deep trench with a metal material, over the high-k dielectric material. The method further includes providing a passivation layer on the deep trench filled with the metal material and the high-k dielectric material. | 12-06-2012 |
20120326233 | METHOD TO REDUCE THRESHOLD VOLTAGE VARIABILITY WITH THROUGH GATE WELL IMPLANT - The present disclosure provides a semiconductor device that may include a substrate including a semiconductor layer overlying an insulating layer. A gate structure that is present on a channel portion of the semiconductor layer. A first dopant region is present in the channel portion of the semiconductor layer, in which the peak concentration of the first dopant region is present within the lower portion of the gate conductor and the upper portion of the semiconductor layer. A second dopant region is present in the channel portion of the semiconductor layer, in which the peak concentration of the second dopant region is present within the lower portion of the semiconductor layer. | 12-27-2012 |
20130005129 | STRUCTURE AND METHOD TO INTEGRATE EMBEDDED DRAM WITH FINFET - Various embodiment integrate embedded dynamic random access memory with fin field effect transistors. In one embodiment, a first fin structure and at least a second fin structure are formed on a substrate. A deep trench area is formed between the first and second fin structures. A high-k metal gate is formed within the deep trench area. The high-k metal gate includes a high-k dielectric layer and a metal layer. A polysilicon material is deposited within the deep trench area adjacent to the metal layer. The high-k metal gate and the polysilicon material are recessed and etched to an area below a top surface of a substrate insulator layer. A poly strap is formed in the deep trench area. The poly strap is dimensioned to be below a top surface of the first and second fin structures. The first and second fin structures are electrically coupled to the poly strap. | 01-03-2013 |
20130032859 | EPITAXIAL EXTENSION CMOS TRANSISTOR - A pair of horizontal-step-including trenches are formed in a semiconductor layer by forming a pair of first trenches having a first depth around a gate structure on the semiconductor layer, forming a disposable spacer around the gate structure to cover proximal portions of the first trenches, and by forming a pair of second trenches to a second depth greater than the first depth. The disposable spacer is removed, and selective epitaxy is performed to form an integrated epitaxial source and source extension region and an integrated epitaxial drain and drain extension region. A replacement gate structure can be formed after deposition and planarization of a planarization dielectric layer and subsequent removal of the gate structure and laterally expand the gate cavity over expitaxial source and drain extension regions. Alternately, a contact-level dielectric layer can be deposited directly on the integrated epitaxial regions and contact via structures can be formed therein. | 02-07-2013 |
20130105898 | Recessed Single Crystalline Source and Drain For Semiconductor-On-Insulator Devices | 05-02-2013 |
20130134490 | LOW RESISTANCE EMBEDDED STRAP FOR A TRENCH CAPACITOR - A trench is formed in a semiconductor substrate, and is filled with a node dielectric layer and at least one conductive material fill portion that functions as an inner electrode. The at least one conductive material fill portion includes a doped polycrystalline semiconductor fill portion. A gate stack for an access transistor is formed on the semiconductor substrate, and a gate spacer is formed around the gate stack. A source/drain trench is formed between an outer sidewall of the gate spacer and a sidewall of the doped polycrystalline semiconductor fill portion. An epitaxial source region and a polycrystalline semiconductor material portion are simultaneously formed by a selective epitaxy process such that the epitaxial source region and the polycrystalline semiconductor material portion contact each other without a gap therebetween. The polycrystalline semiconductor material portion provides a robust low resistance conductive path between the source region and the inner electrode. | 05-30-2013 |
20130134491 | POLYSILICON/METAL CONTACT RESISTANCE IN DEEP TRENCH - A method of forming a trench structure that includes forming a metal containing layer on at least the sidewalls of a trench, and forming an undoped semiconductor fill material within the trench. The undoped semiconductor fill material and the metal containing layer are recessed to a first depth within the trench with a first etch. The undoped semiconductor fill material is then recessed to a second depth within the trench that is greater than a first depth with a second etch. The second etch exposes at least a sidewall portion of the metal containing layer. The trench is filled with a doped semiconductor containing material fill, wherein the doped semiconductor material fill is in direct contact with the at least the sidewall portion of the metal containing layer. | 05-30-2013 |
20130134527 | STRUCTURE AND METHOD TO FABRICATE A BODY CONTACT - A structure and method to fabricate a body contact on a transistor is disclosed. The method comprises forming a semiconductor structure with a transistor on a handle wafer. The structure is then inverted, and the handle wafer is removed. A silicided body contact is then formed on the transistor in the inverted position. The body contact may be connected to neighboring vias to connect the body contact to other structures or levels to form an integrated circuit. | 05-30-2013 |
20130146957 | EMBEDDED DYNAMIC RANDOM ACCESS MEMORY DEVICE FORMED IN AN EXTREMELY THIN SEMICONDUCTOR ON INSULATOR (ETSOI) SUBSTRATE - A memory device including an SOI substrate with a buried dielectric layer having a thickness of less than 30 nm, and a trench extending through an SOI layer and the buried dielectric layer into the base semiconductor layer of the SOI substrate. A capacitor is present in a lower portion of the trench. A dielectric spacer is present on the sidewalls of an upper portion of the trench. The dielectric spacer is present on the portions of the trench where the sidewalls are provided by the SOI layer and the buried dielectric layer. A conductive material fill is present in the upper portion of the trench. A semiconductor device is present on the SOI layer that is adjacent to the trench. The semiconductor device is in electrical communication with the capacitor through the conductive material fill. | 06-13-2013 |
20130147007 | DEEP ISOLATION TRENCH STRUCTURE AND DEEP TRENCH CAPACITOR ON A SEMICONDUCTOR-ON-INSULATOR SUBSTRATE - Two trenches having different widths are formed in a semiconductor-on-insulator (SOI) substrate. An oxygen-impermeable layer and a fill material layer are formed in the trenches. The fill material layer and the oxygen-impermeable layer are removed from within a first trench. A thermal oxidation is performed to convert semiconductor materials underneath sidewalls of the first trench into an upper thermal oxide portion and a lower thermal oxide portion, while the remaining oxygen-impermeable layer on sidewalls of a second trench prevents oxidation of the semiconductor materials. After formation of a node dielectric on sidewalls of the second trench, a conductive material is deposited to fill the trenches, thereby forming a conductive trench fill portion and an inner electrode, respectively. The upper and lower thermal oxide portions function as components of dielectric material portions that electrically isolate two device regions. | 06-13-2013 |
20130154007 | RARE-EARTH OXIDE ISOLATED SEMICONDUCTOR FIN - A dielectric template layer is deposited on a substrate. Line trenches are formed within the dielectric template layer by an anisotropic etch that employs a patterned mask layer. The patterned mask layer can be a patterned photoresist layer, or a patterned hard mask layer that is formed by other image transfer methods. A lower portion of each line trench is filled with an epitaxial rare-earth oxide material by a selective rare-earth oxide epitaxy process. An upper portion of each line trench is filled with an epitaxial semiconductor material by a selective semiconductor epitaxy process. The dielectric template layer is recessed to form a dielectric material layer that provides lateral electrical isolation among fin structures, each of which includes a stack of a rare-earth oxide fin portion and a semiconductor fin portion. | 06-20-2013 |
20130171794 | EPITAXIAL EXTENSION CMOS TRANSISTOR - A pair of horizontal-step-including trenches are formed in a semiconductor layer by forming a pair of first trenches having a first depth around a gate structure on the semiconductor layer, forming a disposable spacer around the gate structure to cover proximal portions of the first trenches, and by forming a pair of second trenches to a second depth greater than the first depth. The disposable spacer is removed, and selective epitaxy is performed to form an integrated epitaxial source and source extension region and an integrated epitaxial drain and drain extension region. A replacement gate structure can be formed after deposition and planarization of a planarization dielectric layer and subsequent removal of the gate structure and laterally expand the gate cavity over expitaxial source and drain extension regions. Alternately, a contact-level dielectric layer can be deposited directly on the integrated epitaxial regions and contact via structures can be formed therein. | 07-04-2013 |
20130181326 | MULTILAYER MIM CAPACITOR - An improved semiconductor capacitor and method of fabrication is disclosed. A MIM stack, comprising alternating first-type and second-type metal layers (each separated by dielectric) is formed in a deep cavity. The entire stack can be planarized, and then patterned to expose a first area, and selectively etched to recess all first metal layers within the first area. A second selective etch is performed to recess all second metal layers within a second area. The etched recesses can be backfilled with dielectric. Separate electrodes can be formed; a first electrode formed in said first area and contacting all of said second-type metal layers and none of said first-type metal layers, and a second electrode formed in said second area and contacting all of said first-type metal layers and none of said second-type metal layers. | 07-18-2013 |
20130183806 | High Density Memory Cells Using Lateral Epitaxy - In a vertical dynamic memory cell, monocrystalline semiconductor material of improved quality is provided for the channel of an access transistor by lateral epitaxial growth over an insulator material (which complements the capacitor dielectric in completely surrounding the storage node except at a contact connection structure, preferably of metal, from the access transistor to the storage node electrode) and etching away a region of the lateral epitaxial growth including a location where crystal lattice dislocations are most likely to occur; both of which features serve to reduce or avoid leakage of charge from the storage node. An isolation structure can be provided in the etched region such that space is provided for connections to various portions of a memory cell array. | 07-18-2013 |
20130193562 | STRUCTURE AND METHOD FOR TOPOGRAPHY FREE SOI INTEGRATION - A semiconductor structure is provided that includes a semiconductor oxide layer having features. The semiconductor oxide layer having the features is located between an active semiconductor layer and a handle substrate. The semiconductor structure includes a planarized top surface of the active semiconductor layer such that the semiconductor oxide layer is beneath the planarized top surface. The features within the semiconductor oxide layer are mated with a surface of the active semiconductor layer. | 08-01-2013 |
20130193563 | TRENCH CAPACITOR WITH SPACER-LESS FABRICATION PROCESS - A trench capacitor and method of fabrication are disclosed. The SOI region is doped such that a selective isotropic etch used for trench widening does not cause appreciable pullback of the SOI region, and no spacers are needed in the upper portion of the trench. | 08-01-2013 |
20130207188 | JUNCTION BUTTING ON SOI BY RAISED EPITAXIAL STRUCTURE AND METHOD - A method of forming a semiconductor device including forming well trenches on opposing sides of a gate structure by removing portions of a semiconductor on insulator (SOI) layer of an semiconductor on insulator (SOI) substrate, wherein the base of the well trenches is provided by a surface of a buried dielectric layer of the SOI substrate and sidewalls of the well trenches are provided by a remaining portion of the SOI layer. Forming a dielectric fill material at the base of the well trenches, wherein the dielectric fill material is in contact with the sidewalls of the well trenches and at least a portion of the surface of the buried dielectric layer that provides the base of the well trenches. Forming a source region and a drain region in the well trenches with an in-situ doped epitaxial semiconductor material. | 08-15-2013 |
20130214382 | METHOD OF FORMING SUBSTRATE CONTACT FOR SEMICONDUCTOR ON INSULATOR (SOI) SUBSTRATE - A semiconductor structure is provided that includes a material stack including an epitaxially grown semiconductor layer on a base semiconductor layer, a dielectric layer on the epitaxially grown semiconductor layer, and an upper semiconductor layer present on the dielectric layer. A capacitor is present extending from the upper semiconductor layer through the dielectric layer into contact with the epitaxially grown semiconductor layer. The capacitor includes a node dielectric present on the sidewalls of the trench and an upper electrode filling at least a portion of the trench. A substrate contact is present in a contact trench extending from the upper semiconductor layer through the dielectric layer and the epitaxially semiconductor layer to a doped region of the base semiconductor layer. A substrate contact is also provided that contacts the base semiconductor layer through the sidewall of a trench. Methods for forming the above-described structures are also provided. | 08-22-2013 |
20130230949 | EMBEDDED DRAM FOR EXTREMELY THIN SEMICONDUCTOR-ON-INSULATOR - A node dielectric and a conductive trench fill region filling a deep trench are recessed to a depth that is substantially coplanar with a top surface of a semiconductor-on-insulator (SOI) layer. A shallow trench isolation portion is formed on one side of an upper portion of the deep trench, while the other side of the upper portion of the deep trench provides an exposed surface of a semiconductor material of the conductive fill region. A selective epitaxy process is performed to deposit a raised source region and a raised strap region. The raised source region is formed directly on a planar source region within the SOI layer, and the raised strap region is formed directly on the conductive fill region. The raised strap region contacts the raised source region to provide an electrically conductive path between the planar source region and the conductive fill region. | 09-05-2013 |
20130260520 | LOW RESISTANCE EMBEDDED STRAP FOR A TRENCH CAPACITOR - A trench is formed in a semiconductor substrate, and is filled with a node dielectric layer and at least one conductive material fill portion that functions as an inner electrode. The at least one conductive material fill portion includes a doped polycrystalline semiconductor fill portion. A gate stack for an access transistor is formed on the semiconductor substrate, and a gate spacer is formed around the gate stack. A source/drain trench is formed between an outer sidewall of the gate spacer and a sidewall of the doped polycrystalline semiconductor fill portion. An epitaxial source region and a polycrystalline semiconductor material portion are simultaneously formed by a selective epitaxy process such that the epitaxial source region and the polycrystalline semiconductor material portion contact each other without a gap therebetween. The polycrystalline semiconductor material portion provides a robust low resistance conductive path between the source region and the inner electrode. | 10-03-2013 |
20130267071 | SELF-ALIGNED STRAP FOR EMBEDDED CAPACITOR AND REPLACEMENT GATE DEVICES - After forming a planarization dielectric layer in a replacement gate integration scheme, disposable gate structures are removed and a stack of a gate dielectric layer and a gate electrode layer is formed within recessed gate regions. Each gate electrode structure is then recessed below a topmost surface of the gate dielectric layer. A dielectric metal oxide portion is formed above each gate electrode by planarization. The dielectric metal oxide portions and gate spacers are employed as a self-aligning etch mask in combination with a patterned photoresist to expose and metalize semiconductor surfaces of a source region and an inner electrode in each embedded memory cell structure. The metalized semiconductor portions form metal semiconductor alloy straps that provide a conductive path between the inner electrode of a capacitor and the source of an access transistor. | 10-10-2013 |
20130328157 | SPACER ISOLATION IN DEEP TRENCH - A method of forming improved spacer isolation in deep trench including recessing a node dielectric, a first conductive layer, and a second conductive layer each deposited within a deep trench formed in a silicon-on-insulator (SOI) substrate, to a level below a buried oxide layer of the SOI substrate, and creating an opening having a bottom surface in the deep trench. Further including depositing a spacer along a sidewall of the deep trench and the bottom surface of the opening, and removing the spacer from the bottom surface of the opening. Performing at least one of an ion implantation and an ion bombardment in one direction at an angle into an upper portion of the spacer. Removing the upper portion of the spacer from the sidewall of the deep trench. Depositing a third conductive layer within the opening. | 12-12-2013 |
20130328161 | SPACER ISOLATION IN DEEP TRENCH - A method of forming improved spacer isolation in deep trench including recessing a node dielectric, a first conductive layer, and a second conductive layer each deposited within a deep trench formed in a silicon-on-insulator (SOI) substrate, to a level below a buried oxide layer of the SOI substrate, and creating an opening having a bottom surface in the deep trench. Further including depositing a spacer along a sidewall of the deep trench and the bottom surface of the opening, and removing the spacer from the bottom surface of the opening. Performing at least one of an ion implantation and an ion bombardment in one direction at an angle into an upper portion of the spacer. Removing the upper portion of the spacer from the sidewall of the deep trench. Depositing a third conductive layer within the opening. | 12-12-2013 |
20140054664 | POLYSILICON/METAL CONTACT RESISTANCE IN DEEP TRENCH - A method of forming a trench structure that includes forming a metal containing layer on at least the sidewalls of a trench, and forming an undoped semiconductor fill material within the trench. The undoped semiconductor fill material and the metal containing layer are recessed to a first depth within the trench with a first etch. The undoped semiconductor fill material is then recessed to a second depth within the trench that is greater than a first depth with a second etch. The second etch exposes at least a sidewall portion of the metal containing layer. The trench is filled with a doped semiconductor containing material fill, wherein the doped semiconductor material fill is in direct contact with the at least the sidewall portion of the metal containing layer. | 02-27-2014 |
20140061793 | SUBLITHOGRAPHIC WIDTH FINFET EMPLOYING SOLID PHASE EPITAXY - A dielectric mandrel structure is formed on a single crystalline semiconductor layer. An amorphous semiconductor material layer is deposited on the physically exposed surfaces of the single crystalline semiconductor layer and surfaces of the mandrel structure. Optionally, the amorphous semiconductor material layer can be implanted with at least one different semiconductor material. Solid phase epitaxy is performed on the amorphous semiconductor material layer employing the single crystalline semiconductor layer as a seed layer, thereby forming an epitaxial semiconductor material layer with uniform thickness. Remaining portions of the epitaxial semiconductor material layer are single crystalline semiconductor fins and thickness of these fins are sublithographic. After removal of the dielectric mandrel structure, the single crystalline semiconductor fins can be employed to form a semiconductor device. | 03-06-2014 |
20140070292 | DEEP TRENCH CAPACITOR - A method of forming a deep trench capacitor in a semiconductor-on-insulator substrate is provided. The method may include providing a pad layer positioned above a bulk substrate, etching a deep trench into the pad layer and the bulk substrate extending from a top surface of the pad layer down to a location within the bulk substrate, and doping a portion of the bulk substrate to form a buried plate. The method further including depositing a node dielectric, an inner electrode, and a dielectric cap substantially filling the deep trench, the node dielectric being located between the buried plate and the inner electrode, the dielectric cap being located at a top of the deep trench, removing the pad layer, growing an insulator layer on top of the bulk substrate, and growing a semiconductor-on-insulator layer on top of the insulator layer. | 03-13-2014 |
20140073092 | RECESSED SINGLE CRYSTALLINE SOURCE AND DRAIN FOR SEMICONDUCTOR-ON-INSULATOR DEVICES - After formation of a gate stack, regions in which a source and a drain are to be formed are recessed through the top semiconductor layer and into an upper portion of a buried single crystalline rare earth oxide layer of a semiconductor-on-insulator (SOI) substrate so that a source trench and drain trench are formed. An embedded single crystalline semiconductor portion epitaxially aligned to the buried single crystalline rare earth oxide layer is formed in each of the source trench and the drain trench to form a recessed source and a recessed drain, respectively. Protrusion of the recessed source and recessed drain above the bottom surface of a gate dielectric can be minimized to reduce parasitic capacitive coupling with a gate electrode, while providing low source resistance and drain resistance through the increased thickness of the recessed source and recessed drain relative to the thickness of the top semiconductor layer. | 03-13-2014 |
20140120688 | DEEP ISOLATION TRENCH STRUCTURE AND DEEP TRENCH CAPACITOR ON A SEMICONDUCTOR-ON-INSULATOR SUBSTRATE - Two trenches having different widths are formed in a semiconductor-on-insulator (SOI) substrate. An oxygen-impermeable layer and a fill material layer are formed in the trenches. The fill material layer and the oxygen-impermeable layer are removed from within a first trench. A thermal oxidation is performed to convert semiconductor materials underneath sidewalls of the first trench into an upper thermal oxide portion and a lower thermal oxide portion, while the remaining oxygen-impermeable layer on sidewalls of a second trench prevents oxidation of the semiconductor materials. After formation of a node dielectric on sidewalls of the second trench, a conductive material is deposited to fill the trenches, thereby forming a conductive trench fill portion and an inner electrode, respectively. The upper and lower thermal oxide portions function as components of dielectric material portions that electrically isolate two device regions. | 05-01-2014 |
20140131782 | SEMICONDUCTOR DEVICE HAVING DIFFUSION BARRIER TO REDUCE BACK CHANNEL LEAKAGE - A semiconductor-on-insulator (SOI) substrate comprises a bulk semiconductor substrate, a buried insulator layer formed on the bulk substrate and an active semiconductor layer formed on the buried insulator layer. Impurities are implanted near the interface of the buried insulator layer and the active semiconductor layer. A diffusion barrier layer is formed between the impurities and an upper surface of the active semiconductor layer. The diffusion barrier layer prevents the impurities from diffusing therethrough. | 05-15-2014 |
20140154849 | METHOD OF FORMING SUBSTRATE CONTACT FOR SEMICONDUCTOR ON INSULATOR (SOI) SUBSTRATE - A semiconductor structure is provided that includes a material stack including an epitaxially grown semiconductor layer on a base semiconductor layer, a dielectric layer on the epitaxially grown semiconductor layer, and an upper semiconductor layer present on the dielectric layer. A capacitor is present extending from the upper semiconductor layer through the dielectric layer into contact with the epitaxially grown semiconductor layer. The capacitor includes a node dielectric present on the sidewalls of the trench and an upper electrode filling at least a portion of the trench. A substrate contact is present in a contact trench extending from the upper semiconductor layer through the dielectric layer and the epitaxially semiconductor layer to a doped region of the base semiconductor layer. A substrate contact is also provided that contacts the base semiconductor layer through the sidewall of a trench. Methods for forming the above-described structures are also provided. | 06-05-2014 |
20140170854 | SELF-ALIGNED DEVICES AND METHODS OF MANUFACTURE - A method includes forming patterned lines on a substrate having a predetermined pitch. The method further includes forming spacer sidewalls on sidewalls of the patterned lines. The method further includes forming material in a space between the spacer sidewalls of adjacent patterned lines. The method further includes forming another patterned line from the material by protecting the material in the space between the spacer sidewalls of adjacent patterned lines while removing the spacer sidewalls. The method further includes transferring a pattern of the patterned lines and the patterned line to the substrate. | 06-19-2014 |
20140319600 | TSV Structure With A Built-In U-Shaped FET Transistor For Improved Characterization - A through-the silicon via (TSV) structure providing a built-in TSV U-shaped FET that includes an annular gate shaped as a TSV partially embedded in a substrate, the annular gate having an inner and an outer surface bound by an oxide layer; a drain formed on an isolated epitaxial layer on top of the substrate conformally connecting the gate oxide layer surrounding the inner annular surface of the TSV; a source partially contacting said gate oxide layer conformally contacting gate oxide layer surrounding the outer surface of the TSV. | 10-30-2014 |
20150014814 | METAL TRENCH CAPACITOR AND IMPROVED ISOLATION AND METHODS OF MANUFACTURE - A high-k dielectric metal trench capacitor and improved isolation and methods of manufacturing the same is provided. The method includes forming at least one deep trench in a substrate, and filling the deep trench with sacrificial fill material and a poly material. The method further includes continuing with CMOS processes, comprising forming at least one transistor and back end of line (BEOL) layer. The method further includes removing the sacrificial fill material from the deep trenches to expose sidewalls, and forming a capacitor plate on the exposed sidewalls of the deep trench. The method further includes lining the capacitor plate with a high-k dielectric material and filling remaining portions of the deep trench with a metal material, over the high-k dielectric material. The method further includes providing a passivation layer on the deep trench filled with the metal material and the high-k dielectric material. | 01-15-2015 |
20150037939 | RARE-EARTH OXIDE ISOLATED SEMICONDUCTOR FIN - A dielectric template layer is deposited on a substrate. Line trenches are formed within the dielectric template layer by an anisotropic etch that employs a patterned mask layer. The patterned mask layer can be a patterned photoresist layer, or a patterned hard mask layer that is formed by other image transfer methods. A lower portion of each line trench is filled with an epitaxial rare-earth oxide material by a selective rare-earth oxide epitaxy process. An upper portion of each line trench is filled with an epitaxial semiconductor material by a selective semiconductor epitaxy process. The dielectric template layer is recessed to form a dielectric material layer that provides lateral electrical isolation among fin structures, each of which includes a stack of a rare-earth oxide fin portion and a semiconductor fin portion. | 02-05-2015 |
20150054130 | MULTILAYER MIM CAPACITOR - An improved semiconductor capacitor and method of fabrication is disclosed. A MIM stack, comprising alternating first-type and second-type metal layers (each separated by dielectric) is formed in a deep cavity. The entire stack can be planarized, and then patterned to expose a first area, and selectively etched to recess all first metal layers within the first area. A second selective etch is performed to recess all second metal layers within a second area. The etched recesses can be backfilled with dielectric. Separate electrodes can be formed; a first electrode formed in said first area and contacting all of said second-type metal layers and none of said first-type metal layers, and a second electrode formed in said second area and contacting all of said first-type metal layers and none of said second-type metal layers. | 02-26-2015 |
20150056760 | SEMICONDUCTOR DEVICE HAVING DIFFUSION BARRIER TO REDUCE BACK CHANNEL LEAKAGE - A semiconductor-on-insulator (SOI) substrate comprises a bulk semiconductor substrate, a buried insulator layer formed on the bulk substrate and an active semiconductor layer formed on the buried insulator layer. Impurities are implanted near the interface of the buried insulator layer and the active semiconductor layer. A diffusion barrier layer is formed between the impurities and an upper surface of the active semiconductor layer. The diffusion barrier layer prevents the impurities from diffusing therethrough. | 02-26-2015 |