Patent application number | Description | Published |
20080246032 | TEST STRUCTURE FOR DETECTING VIA CONTACT SHORTING IN SHALLOW TRENCH ISOLATION REGIONS - A test structure for detecting void formation in semiconductor device layers includes a plurality of active device areas formed in a substrate, a plurality of shallow trench isolation (STI) regions separating the active device areas, a plurality of gate electrode structures formed across the active device areas and the STI regions, and a matrix of vias formed over the active device areas and between the gate electrode structures. At least one edge of each of a pair of vias at opposite ends of a given one of the STI regions extends at least out to an edge of the associated active device area. | 10-09-2008 |
20120168874 | STRUCTURE AND METHOD TO IMPROVE THRESHOLD VOLTAGE OF MOSFETS INCLUDING A HIGH K DIELECTRIC - Threshold voltage controlled semiconductor structures are provided in which a conformal nitride-containing liner is located on at least exposed sidewalls of a patterned gate dielectric material having a dielectric constant of greater than silicon oxide. The conformal nitride-containing liner is a thin layer that is formed using a low temperature (less than 500° C.) nitridation process. | 07-05-2012 |
20130154005 | SOI FINFET WITH RECESSED MERGED FINS AND LINER FOR ENHANCED STRESS COUPLING - FinFETS and methods for making FinFETs with a recessed stress liner. A method includes providing an SW substrate with fins, forming a gate over the fins, forming an off-set spacer on the gate, epitaxially growing a film to merge the fins, depositing a dummy spacer around the gate, and recessing the merged epi film. Silicide is then formed on the recessed merged epi film followed by deposition of a stress liner film over the FinFET. By using a recessed merged epi process, a MOSFET with a vertical silicide (i.e. perpendicular to the substrate) can be formed. The perpendicular silicide improves spreading resistance. | 06-20-2013 |
20130161744 | FINFET WITH MERGED FINS AND VERTICAL SILICIDE - A finFET device is provided. The finFET device includes a BOX layer, fin structures located over the BOX layer, a gate stack located over the fin structures, gate spacers located on vertical sidewalls of the gate stack, an epi layer covering the fin structures, source and drain regions located in the semiconductor layers of the fin structures, and silicide regions abutting the source and drain regions. The fin structures each comprise a semiconductor layer and extend in a first direction, and the gate stack extends in a second direction that is perpendicular. The gate stack comprises a high-K dielectric layer and a metal gate, and the epi layer merges the fin structures together. The silicide regions each include a vertical portion located on the vertical sidewall of the source or drain region. | 06-27-2013 |
20130164890 | METHOD FOR FABRICATING FINFET WITH MERGED FINS AND VERTICAL SILICIDE - A method is provided for fabricating a finFET device. Fin structures are formed over a BOX layer. The fin structures include a semiconductor layer and extend in a first direction. A gate stack is formed on the BOX layer over the fin structures and extending in a second direction. The gate stack includes a high-K dielectric layer and a metal gate. Gate spacers are formed on sidewalls of the gate stack, and an epi layer is deposited to merge the fin structures. Ions are implanted to form source and drain regions, and dummy spacers are formed on sidewalls of the gate spacers. The dummy spacers are used as a mask to recess or completely remove an exposed portion of the epi layer. Silicidation forms silicide regions that abut the source and drain regions and each include a vertical portion located on the vertical sidewall of the source or drain region. | 06-27-2013 |
20130193445 | SOI STRUCTURES INCLUDING A BURIED BORON NITRIDE DIELECTRIC - Boron nitride is used as a buried dielectric of an SOI structure including an SOI layer and a handle substrate. The boron nitride is located between an SOI layer and a handle substrate. Boron nitride has a dielectric constant and a thermal expansion coefficient close to silicon dioxide. Yet, boron nitride has a wet as well as a dry etch resistance that is much better than silicon dioxide. In the SOI structure, there is a reduced material loss of boron nitride during multiple wet and dry etches so that the topography and/or bridging are not an obstacle for device integration. Boron nitride has a low dielectric constant so that devices built in SOI active regions do not suffer from a charging effect. | 08-01-2013 |
20130193513 | Multi-Gate Field Effect Transistor with a Tapered Gate Profile - A multi-gate field effect transistor apparatus and method for making same. The apparatus includes a source terminal, a drain terminal, and a gate terminal which includes a tapered-gate profile. A method for designing a multi-gate field effect transistor includes arranging a source terminal, a drain terminal and a gate terminal with a tapered-gate profile to create a wider gate width on a bottom of a fin. | 08-01-2013 |
20130196483 | SOI STRUCTURES INCLUDING A BURIED BORON NITRIDE DIELECTRIC - Boron nitride is used as a buried dielectric of an SOI structure including an SOI layer and a handle substrate. The boron nitride is located between an SOI layer and a handle substrate. Boron nitride has a dielectric constant and a thermal expansion coefficient close to silicon dioxide. Yet, boron nitride has a wet as well as a dry etch resistance that is much better than silicon dioxide. In the SOI structure, there is a reduced material loss of boron nitride during multiple wet and dry etches so that the topography and/or bridging are not an obstacle for device integration. Boron nitride has a low dielectric constant so that devices built in SOI active regions do not suffer from a charging effect. | 08-01-2013 |
20130198695 | Multi-Gate Field Effect Transistor with A Tapered Gate Profile - A multi-gate field effect transistor apparatus and method for making same. The apparatus includes a source terminal, a drain terminal, and a gate terminal which includes a tapered-gate profile. A method for designing a multi-gate field effect transistor includes arranging a source terminal, a drain terminal and a gate terminal with a tapered-gate profile to create a wider gate width on a bottom of a fin. | 08-01-2013 |
20130264612 | DEVICE AND METHOD FOR FORMING SHARP EXTENSION REGION WITH CONTROLLABLE JUNCTION DEPTH AND LATERAL OVERLAP - A method for forming a semiconductor device includes forming a gate stack on a monocrystalline substrate. A surface of the substrate adjacent to the gate stack and below a portion of the gate stack is amorphorized. The surface is etched to selectively remove a thickness of amorphorized portions to form undercuts below the gate stack. A layer is epitaxially grown in the thickness and the undercuts to form an extension region for the semiconductor device. Devices are also provided. | 10-10-2013 |
20130264614 | DEVICE AND METHOD FOR FORMING SHARP EXTENSION REGION WITH CONTROLLABLE JUNCTION DEPTH AND LATERAL OVERLAP - A method for forming a semiconductor device includes forming a gate stack on a monocrystalline substrate. A surface of the substrate adjacent to the gate stack and below a portion of the gate stack is amorphorized. The surface is etched to selectively remove a thickness of amorphorized portions to form undercuts below the gate stack. A layer is epitaxially grown in the thickness and the undercuts to form an extension region for the semiconductor device. Devices are also provided. | 10-10-2013 |
20130307121 | RETROGRADE SUBSTRATE FOR DEEP TRENCH CAPACITORS - A semiconductor device includes a substrate having a first doped portion to a first depth and a second doped portion below the first depth. A deep trench capacitor is formed in the substrate and extends below the first depth. The deep trench capacitor has a buried plate that includes a dopant type forming an electrically conductive connection with second doped portion of the substrate and being electrically insulated from the first doped portion. | 11-21-2013 |
20130309835 | RETROGRADE SUBSTRATE FOR DEEP TRENCH CAPACITORS - A method for forming a semiconductor device includes forming a deep trench in a substrate having a first doped portion to a first depth and a second doped portion below the first depth, the deep trench extending below the first depth. A region around the deep trench is doped to form a buried plate where the buried plate includes a dopant type forming an electrically conductive connection with the second doped portion of the substrate and being electrically insulated from the first doped portion. A deep trench capacitor is formed in the deep trench using the buried plate as one electrode of the capacitor. An access transistor is formed to charge or discharge the deep trench capacitor. A well is formed in the first doped portion. | 11-21-2013 |
20130313649 | FIN ISOLATION FOR MULTIGATE TRANSISTORS - Multigate transistor devices and methods of their fabrication are disclosed. One such device includes a plurality of semiconductor fins that have source and drain regions and a gate structure overlaying the fins. The device further includes a dielectric layer that is beneath the gate structure and the fins. Here, the dielectric layer includes first dielectric regions that are disposed beneath the fins and second dielectric regions that are disposed between the fins. In addition, the first dielectric regions have a density that is greater than a density of the second dielectric regions. | 11-28-2013 |
20130316513 | FIN ISOLATION FOR MULTIGATE TRANSISTORS - Multigate transistor devices and methods of their fabrication are disclosed. In one method, a substrate including a semiconductor upper layer and a lower layer beneath the upper layer is provided. The lower layer has a rate of transformation into a dielectric that is higher than a rate of transformation into a dielectric of the upper layer when the upper and lower layers are subjected to dielectric transformation conditions. Fins are formed in the upper layer, and the lower layer beneath the fins is transformed into a dielectric material to electrically isolate the fins. In addition, a gate structure is formed over the fins to complete the multigate transistor device. | 11-28-2013 |
20140021523 | DRAM WITH DUAL LEVEL WORD LINES - A top semiconductor layer and conductive cap structures over deep trench capacitors are simultaneously patterned by an etch. Each patterned portion of the conductive cap structures constitutes a conductive cap structure, which laterally contacts a semiconductor material portion that is one of patterned remaining portions of the top semiconductor layer. Gate electrodes are formed as discrete structures that are not interconnected. After formation and planarization of a contact-level dielectric layer, passing gate lines are formed above the contact-level dielectric layer in a line level to provide electrical connections to the gate electrodes. Gate electrodes and passing gate lines that are electrically connected among one another constitute a gate line that is present across two levels. | 01-23-2014 |
20140061734 | FINFET WITH REDUCED PARASITIC CAPACITANCE - A gate dielectric and a gate electrode are formed over a plurality of semiconductor fins. An inner gate spacer is formed and source/drain extension regions are epitaxially formed on physically exposed surface of the semiconductor fins as discrete components that are not merged. An outer gate spacer is subsequently formed. A merged source region and a merged drain region are formed on the source extension regions and the drain extension regions, respectively. The increased lateral spacing between the merged source/drain regions and the gate electrode through the outer gate spacer reduces parasitic capacitance for the fin field effect transistor. | 03-06-2014 |
20140065777 | DRAM WITH DUAL LEVEL WORD LINES - A top semiconductor layer and conductive cap structures over deep trench capacitors are simultaneously patterned by an etch. Each patterned portion of the conductive cap structures constitutes a conductive cap structure, which laterally contacts a semiconductor material portion that is one of patterned remaining portions of the top semiconductor layer. Gate electrodes are formed as discrete structures that are not interconnected. After formation and planarization of a contact-level dielectric layer, passing gate lines are formed above the contact-level dielectric layer in a line level to provide electrical connections to the gate electrodes. Gate electrodes and passing gate lines that are electrically connected among one another constitute a gate line that is present across two levels. | 03-06-2014 |
20140084301 | LATERAL SILICON-ON-INSULATOR BIPOLAR JUNCTION TRANSISTOR RADIATION DOSIMETER - A radiation dosimeter includes a semiconductor substrate and a buried insulator layer disposed on the semiconductor substrate. The buried insulator layer has a plurality of charge traps. A semiconductor layer is disposed on the buried insulator layer. The semiconductor layer has an emitter, an intrinsic base, and a collector laterally arranged with respect to one another. In response to radiation exposure by the radiation dosimeter, positive charges are trapped in the plurality of charge traps in the buried insulator layer, the amount of positive charge trapped being used to determine the amount of radiation exposure. A method for radiation dosimetry includes providing a radiation dosimeter, where the radiation dosimeter includes a lateral silicon-on-insulator bipolar junction transistor having a buried insulator layer; exposing the radiation dosimeter to ionizing radiation; determining a change in one of the collector current and current gain of the radiation dosimeter; and determining an amount of the radiation dose based on the change in one of the collector current and current gain. | 03-27-2014 |
20140088401 | Method For Radiation Monitoring - A radiation dosimeter includes a semiconductor substrate and a buried insulator layer disposed on the semiconductor substrate. The buried insulator layer has a plurality of charge traps. A semiconductor layer is disposed on the buried insulator layer. The semiconductor layer has an emitter, an intrinsic base, and a collector laterally arranged with respect to one another. In response to radiation exposure by the radiation dosimeter, positive charges are trapped in the plurality of charge traps in the buried insulator layer, the amount of positive charge trapped being used to determine the amount of radiation exposure. A method for radiation dosimetry includes providing a radiation dosimeter, where the radiation dosimeter includes a lateral silicon-on-insulator bipolar junction transistor having a buried insulator layer; exposing the radiation dosimeter to ionizing radiation; determining a change in one of the collector current and current gain of the radiation dosimeter; and determining an amount of the radiation dose based on the change in one of the collector current and current gain. | 03-27-2014 |
20140103435 | VERTICAL SOURCE/DRAIN JUNCTIONS FOR A FINFET INCLUDING A PLURALITY OF FINS - Fin-defining mask structures are formed over a semiconductor material layer. A semiconductor material portion is formed by patterning the semiconductor material layer, and a disposable gate structure is formed over the fin-defining mask structures. After formation of a disposable template layer, the disposable gate structure is removed. A plurality of semiconductor fins are formed by etching center portions of the semiconductor material portion employing the combination of the disposable template layer and the fin-defining mask structures as an etch mask. A first pad region and a second pad region laterally contact the plurality of semiconductor fins. A replacement gate structure is formed on the plurality of semiconductor fins. The disposable template layer is removed, and the first pad region and the second pad regions are vertically recessed. Vertical source/drain junctions can be formed by introducing dopants through vertical sidewalls of the recessed source and second pad regions. | 04-17-2014 |
20140148003 | REPLACEMENT METAL GATE TRANSISTORS USING BI-LAYER HARDMASK - Methods of fabricating replacement metal gate transistors using bi-layer a hardmask are disclosed. By utilizing a bi-layer hardmask comprised of a first layer of nitride, followed by a second layer of oxide, the topography issues caused by transition regions of gates are mitigated, which simplifies downstream processing steps and improves yield. | 05-29-2014 |
20140151773 | FINFET eDRAM STRAP CONNECTION STRUCTURE - A method of forming a strap connection structure for connecting an embedded dynamic random access memory (eDRAM) to a transistor comprises forming a buried oxide layer in a substrate, the buried oxide layer defining an SOI layer on a surface of the substrate; forming a deep trench through the SOI layer and the buried oxide layer in the substrate; forming a storage capacitor in a lower portion of the deep trench; conformally doping a sidewall of an upper portion of the deep trench; depositing a metal strap on the conformally doped sidewall and on the storage capacitor; forming at least one fin in the SOI layer, the fin being in communication with the metal strap; forming a spacer over the metal strap and over a juncture of the fin and the metal strap; and depositing a passive word line on the spacer. | 06-05-2014 |
20140159166 | Preventing FIN Erosion and Limiting Epi Overburden in FinFET Structures by Composite Hardmask - A FinFET structure is formed by forming a hardmask layer on a substrate including a silicon-containing layer on an insulating layer. The hardmask layer includes first, second and third layers on the silicon-containing layer. An array of fins is formed from the hardmask layer and the silicon-containing layer. A gate is formed covering a portion but not all of a length of each of the array of fins. The portion covers each of the fins in the array. The gate defines source/drain regions on either side of the gate. A spacer is formed on each side of the gate, the forming of the spacer performed to remove the third layer from portions of the fins in the source/drain regions. The second layer of the hardmask layer is removed from the portions of the fins in the source/drain regions, and the fins in the source/drain regions are merged. | 06-12-2014 |
20140159167 | PREVENTING FIN EROSION AND LIMITING EPI OVERBURDEN IN FINFET STRUCTURES BY COMPOSITE HARDMASK - A FinFET structure is formed by forming a hardmask layer on a substrate including a silicon-containing layer on an insulating layer. The hardmask layer includes first, second and third layers on the silicon-containing layer. An array of fins is formed from the hardmask layer and the silicon-containing layer. A gate is formed covering a portion but not all of a length of each of the array of fins. The portion covers each of the fins in the array. The gate defines source/drain regions on either side of the gate. A spacer is formed on each side of the gate, the forming of the spacer performed to remove the third layer from portions of the fins in the source/drain regions. The second layer of the hardmask layer is removed from the portions of the fins in the source/drain regions, and the fins in the source/drain regions are merged. | 06-12-2014 |
20140167202 | ELECTROSTATIC DISCHARGE RESISTANT DIODES - A diode and a method for an electrostatic discharge resistant diode. The method includes, for example, receiving a wafer. The wafer includes a silicon layer electrically isolated from a silicon substrate by a buried oxide (BOX) layer. The BOX layer is in physical contact with the silicon layer and the silicon substrate. An N-type well is implanted in the silicon substrate. Furthermore, a vertical column of P+ doped epitaxial silicon and a vertical column of N+ doped epitaxial silicon are formed over the N-type well and extend through the BOX layer and the silicon layer. Both vertical columns may form electrical junctions with the N-type well. | 06-19-2014 |
20140167203 | ELECTROSTATIC DISCHARGE RESISTANT DIODES - A diode and a method for an electrostatic discharge resistant diode. The method includes, for example, receiving a wafer. The wafer includes a silicon layer electrically isolated from a silicon substrate by a buried oxide (BOX) layer. The BOX layer is in physical contact with the silicon layer and the silicon substrate. An N-type well is implanted in the silicon substrate. Furthermore, a vertical column of P+ doped epitaxial silicon and a vertical column of N+ doped epitaxial silicon are formed over the N-type well and extend through the BOX layer and the silicon layer. Both vertical columns may form electrical junctions with the N-type well. | 06-19-2014 |
20140210004 | SELF-ADJUSTING GATE HARD MASK - A method provides an intermediate semiconductor device structure and includes providing a water having first dummy gate plugs and second dummy gate plugs embedded in a first layer having a non planar wafer surface topography due at least to a presence of the fist dummy gate plugs; depositing at least one second layer over the first layer, the at least one second layer comprising a hard mask material; and removing at least a portion of the second layer to form a substantially planar wafer surface topography over the first dummy gate plugs and the second dummy gate plugs prior to gate conductor deposition. | 07-31-2014 |
20140210005 | SELF-ADJUSTING GATE HARD MASK - An intermediate wafer includes a substrate having a surface and a first dummy gate plug disposed upon a structure, e.g., a FIN, supported by the substrate surface; a second dummy gate plug disposed upon the substrate surface; and a first layer in which the first dummy gate plug and the second dummy gate plug are embedded. The first layer exhibits a non-planar surface topography characterized by a depression due at least to a presence of the first dummy gate plug. The structure further includes a second layer that fills the depression to the surface of the first layer, and a third layer that overlies the first layer and the second layer. The third layer is formed of a hard mask material and has a substantially planar surface topography over the first and second dummy gate plugs and over the depression that is filled with the material of the second layer. | 07-31-2014 |
20140231890 | MIM CAPACITOR IN FINFET STRUCTURE - A method of forming a FinFET structure having a metal-insulator-metal capacitor. Silicon fins are formed on a semiconductor substrate followed by formation of the metal-insulator-metal capacitor on the silicon fins by depositing sequential layers of a first layer of titanium nitride, a dielectric layer and a second layer of titanium nitride. A polysilicon layer is deposited over the metal-insulator-metal capacitor followed by etching back the polysilicon layer and the metal-insulator-metal capacitor layers from ends of the silicon fins so that the first and second ends of the silicon fins protrude from the polysilicon layer. A spacer may be formed on surfaces facing the ends of the silicon fins followed by the formation of epitaxial silicon over the ends of the silicon fins. Also disclosed is a FinFET structure having a metal-insulator-metal capacitor. | 08-21-2014 |
20140231891 | MIM CAPACITOR IN FINFET STRUCTURE - A FinFET structure which includes: silicon fins on a semiconductor substrate, each silicon fin having two sides and a horizontal surface; sequential layers of a first layer of titanium nitride, a dielectric layer and a second layer of titanium nitride on the sides and horizontal surface of the silicon fins; a polysilicon gate layer over the second layer of titanium nitride on the silicon fins and over the semiconductor substrate such that first and second ends of the silicon fins protrude from the polysilicon layer; spacers adjacent to the polysilicon gate layer; epitaxial silicon over the first and second ends of the silicon fins to form sources and drains, wherein the combination of the first layer of titanium nitride, dielectric layer and second layer of titanium nitride forms a metal-insulator-metal capacitor situated between each silicon fin and the polysilicon layer. | 08-21-2014 |
20140231913 | Trilayer SIT Process with Transfer Layer for FINFET Patterning - Improved sidewall image transfer (SIT) techniques are provided. In one aspect, a SIT method includes the following steps. An oxide layer is formed on a substrate. A transfer layer is formed on a side of the oxide layer opposite the substrate. A mandrel layer is formed on a side of the transfer layer opposite the oxide layer. The mandrel layer is patterned to form at least one mandrel. Sidewall spacers are formed on opposite sides of the at least one mandrel. The at least one mandrel is removed, wherein the transfer layer covers and protects the substrate during removal of the at least one mandrel. The transfer layer is etched using the sidewall spacers as a hardmask to form a patterned transfer layer. The oxide layer and the sidewall spacers are removed from the substrate. The substrate is etched using the patterned transfer layer as a hardmask. | 08-21-2014 |
20140231915 | Trilayer SIT Process with Transfer Layer for FINFET Patterning - Improved sidewall image transfer (SIT) techniques are provided. In one aspect, a SIT method includes the following steps. An oxide layer is formed on a substrate. A transfer layer is formed on a side of the oxide layer opposite the substrate. A mandrel layer is formed on a side of the transfer layer opposite the oxide layer. The mandrel layer is patterned to form at least one mandrel. Sidewall spacers are formed on opposite sides of the at least one mandrel. The at least one mandrel is removed, wherein the transfer layer covers and protects the substrate during removal of the at least one mandrel. The transfer layer is etched using the sidewall spacers as a hardmask to form a patterned transfer layer. The oxide layer and the sidewall spacers are removed from the substrate. The substrate is etched using the patterned transfer layer as a hardmask. | 08-21-2014 |
20140264522 | SEMICONDUCTOR STRUCTURES WITH DEEP TRENCH CAPACITOR AND METHODS OF MANUFACTURE - An integrated FinFET and deep trench capacitor structure and methods of manufacture are disclosed. The method includes forming at least one deep trench capacitor in a silicon on insulator (SOI) substrate. The method further includes simultaneously forming polysilicon fins from material of the at least one deep trench capacitor and SOI fins from the SOI substrate. The method further includes forming an insulator layer on the polysilicon fins. The method further includes forming gate structures over the SOI fins and the insulator layer on the polysilicon fins. | 09-18-2014 |
20140306274 | SELF-ALIGNED STRUCTURE FOR BULK FinFET - A FinFET structure which includes a bulk semiconductor substrate; semiconductor fins extending from the bulk semiconductor substrate, each of the semiconductor fins having a top portion and a bottom portion such that the bottom portion of the semiconductor fins is doped and the top portion of the semiconductor fins is undoped; a portion of the bulk semiconductor substrate directly underneath the plurality of semiconductor fins being doped to form an n+ or p+ well; and an oxide formed between the bottom portions of the fins. | 10-16-2014 |
20140306289 | SELF-ALIGNED STRUCTURE FOR BULK FinFET - A FinFET structure which includes a bulk semiconductor substrate; semiconductor fins extending from the bulk semiconductor substrate, each of the semiconductor fins having a top portion and a bottom portion such that the bottom portion of the semiconductor fins is doped and the top portion of the semiconductor fins is undoped; a portion of the bulk semiconductor substrate directly underneath the plurality of semiconductor fins being doped to form an n+ or p+ well; and an oxide formed between the bottom portions of the fins. Also disclosed is a method for forming a FinFET device. | 10-16-2014 |
20140308781 | DUAL EPITAXIAL INTEGRATION FOR FinFETS - A dual epitaxial integration process for FinFET devices. First and second pluralities of fins and gates are formed, with some of the fins and gates being for NFETs and some of the fins and gates being for PFETs. A first layer of a hard mask material selected from the group consisting of titanium nitride, tungsten nitride, tantalum nitride, amorphous carbon and titanium carbide is deposited over the NFETs and PFETs. The hard mask material is removed from one of the NFETs and PFETs and a first source and drain material is epitaxially deposited on the fins. A second layer of the hard mask material is deposited over the NFETs and PFETs. The first and second layers of the hard mask material are removed from the other of the NFETs and PFETs and a second source and drain material is deposited on the fins. | 10-16-2014 |
20140327044 | METHOD TO MAKE DUAL MATERIAL FINFET ON SAME SUBSTRATE - A method of fabricating a semiconductor device including proving a substrate having a germanium containing layer that is present on a dielectric layer, and etching the germanium containing layer of the substrate to provide a first region including a germanium containing fin structure and a second region including a mandrel structure. A first gate structure may be formed on the germanium containing fin structures. A III-V fin structure may then be formed on the sidewalls of the mandrel structure. The mandrel structure may be removed. A second gate structure may be formed on the III-V fin structure. | 11-06-2014 |
20140327045 | METHOD TO MAKE DUAL MATERIAL FINFET ON SAME SUBSTRATE - A method of fabricating a semiconductor device including proving a substrate having a germanium containing layer that is present on a dielectric layer, and etching the germanium containing layer of the substrate to provide a first region including a germanium containing fin structure and a second region including a mandrel structure. A first gate structure may be formed on the germanium containing fin structures. A III-V fin structure may then be formed on the sidewalls of the mandrel structure. The mandrel structure may be removed. A second gate structure may be formed on the III-V fin structure. | 11-06-2014 |
20140377925 | SELECTIVE LASER ANNEAL ON SEMICONDUCTOR MATERIAL - A method of forming a semiconductor device including providing a substrate having a first region of a first semiconductor material and a second region of a second semiconductor material and forming a first gate structure in a first region of the semiconductor material and a second gate structure in a second region of the substrate. A first source region and a first drain region is implanted in the first region of the substrate. The dopant for the first source region and the first drain region is not implanted into the second region. The first source region and the first drain region are then activated with a laser anneal. A second source region and a second drain region are implanted in the second region of the substrate after activating the first source region and the first drain region. The second source region and the first source region may then be activated. | 12-25-2014 |
20150021610 | SEMICONDUCTOR STRUCTURES WITH DEEP TRENCH CAPACITOR AND METHODS OF MANUFACTURE - An integrated FinFET and deep trench capacitor structure and methods of manufacture are disclosed. The method includes forming at least one deep trench capacitor in a silicon on insulator (SOI) substrate. The method further includes simultaneously forming polysilicon fins from material of the at least one deep trench capacitor and SOI fins from the SOI substrate. The method further includes forming an insulator layer on the polysilicon fins. The method further includes forming gate structures over the SOI fins and the insulator layer on the polysilicon fins. | 01-22-2015 |
Patent application number | Description | Published |
20140015054 | FIELD EFFECT TRANSISTOR DEVICES HAVING THICK GATE DIELECTRIC LAYERS AND THIN GATE DIELECTRIC LAYERS - A semiconductor device includes a substrate, a fin arranged on the substrate, a first field effect transistor (FET) comprising a first gate stack disposed over the a portion of the fin, the first gate stack including a polysilicon layer and a silicide material disposed on the polysilicon layer, and an epitaxial material disposed over portions of the fin, the epitaxial material defining source and drain regions of the first FET, and a second effect transistor (FET) comprising a second gate stack disposed over the a portion of the fin, the second gate stack including a metal gate material layer, and an epitaxial material disposed over portions of the fin, the epitaxial material defining source and drain regions of the second FET. | 01-16-2014 |
20140197370 | OVERLAP CAPACITANCE NANOWIRE - A device and method for fabricating a nanowire include patterning a first set of structures on a substrate. A dummy structure is formed over portions of the substrate and the first set of structures. Exposed portions of the substrate are etched to provide an unetched raised portion. First spacers are formed about a periphery of the dummy structure and the unetched raised portion. The substrate is etched to form controlled undercut etched portions around a portion of the substrate below the dummy structure. Second spacers are formed in the controlled undercut etched portions. Source/drain regions are formed with interlayer dielectric regions formed thereon. The dummy structure is removed. The substrate is etched to release the first set of structures. Gate structures are formed including a top gate formed above the first set of structures and a bottom gate formed below the first set of structures to provide a nanowire. | 07-17-2014 |
20140197371 | OVERLAP CAPACITANCE NANOWIRE - A device and method for fabricating a nanowire include patterning a first set of structures on a substrate. A dummy structure is formed over portions of the substrate and the first set of structures. Exposed portions of the substrate are etched to provide an unetched raised portion. First spacers are formed about a periphery of the dummy structure and the unetched raised portion. The substrate is etched to form controlled undercut etched portions around a portion of the substrate below the dummy structure. Second spacers are formed in the controlled undercut etched portions. Source/drain regions are formed with interlayer dielectic regions formed thereon. The dummy structure is removed. The substrate is etched to release the first set of structures. Gate structures are formed including a top gate formed above the first set of structures and a bottom gate formed below the first set of structures to provide a nanowire. | 07-17-2014 |
20140339507 | STACKED SEMICONDUCTOR NANOWIRES WITH TUNNEL SPACERS - A structure is provided that includes at least one multilayered stacked semiconductor material structure located on a semiconductor substrate and at least one sacrificial gate material structure straddles a portion of the at least one multilayered stacked semiconductor structure. The at least one multilayered stacked semiconductor material structure includes alternating layers of sacrificial semiconductor material and semiconductor nanowire template material. End segments of each layer of sacrificial semiconductor material are then removed and filled with a dielectric spacer. Source/drain regions are formed from exposed sidewalls of each layer of semiconductor nanowire template material, and thereafter the at least one sacrificial gate material structure and remaining portions of the sacrificial semiconductor material are removed suspending each semiconductor material. A gate structure is formed within the areas previously occupied by the at least one sacrificial gate material structure and remaining portions of the sacrificial semiconductor material. | 11-20-2014 |
20140339611 | STACKED SEMICONDUCTOR NANOWIRES WITH TUNNEL SPACERS - A structure is provided that includes at least one multilayered stacked semiconductor material structure located on a semiconductor substrate and at least one sacrificial gate material structure straddles a portion of the at least one multilayered stacked semiconductor structure. The at least one multilayered stacked semiconductor material structure includes alternating layers of sacrificial semiconductor material and semiconductor nanowire template material. End segments of each layer of sacrificial semiconductor material are then removed and filled with a dielectric spacer. Source/drain regions are formed from exposed sidewalls of each layer of semiconductor nanowire template material, and thereafter the at least one sacrificial gate material structure and remaining portions of the sacrificial semiconductor material are removed suspending each semiconductor material. A gate structure is formed within the areas previously occupied by the at least one sacrificial gate material structure and remaining portions of the sacrificial semiconductor material. | 11-20-2014 |
20140353796 | Fin eFuse Formed by Trench Silicide Process - A semiconductor structure and method of manufacturing the same are provided. The semiconductor device includes an enhanced performance electrical fuse formed in a polysilicon fin using a trench silicide process. In one embodiment, at least one semiconductor fin is formed on a dielectric layer present on the surface of a semiconductor substrate. An isolation layer may be formed over the exposed portions of the dielectric layer and the at least one semiconductor fin. At least two contact vias may be formed through the isolation layer to expose the top surface of the semiconductor fin. A continuous silicide may be formed on and substantially below the exposed surfaces of the semiconductor fin extending laterally at least between the at least two contact vias to form an electronic fuse (eFuse). In another embodiment, the at least one semiconductor fin may be subjected to ion implantation to facilitate the formation of silicide. | 12-04-2014 |
20140370681 | FIELD-EFFECT TRANSISTOR (FET) WITH SOURCE-DRAIN CONTACT OVER GATE SPACER - A field-effect transistor (FET) and methods for fabricating such. The FET includes a substrate having a crystalline orientation, a source region in the substrate, and a drain region in the substrate. Gate spacers are positioned over the source region and the drain region. The gate spacers include a gate spacer height. A source contact physically and electrically contacts the source region and extends beyond the gate spacer height. A drain contact physically and electrically contacts the drain region and extends beyond the gate spacer height. The source and drain contacts have the same crystalline orientation as the substrate. | 12-18-2014 |
20140374800 | OVERLAPPED III-V FINFET WITH DOPED SEMICONDUCTOR EXTENSIONS - A semiconductor structure that includes a semiconductor fin comprising an III-V compound semiconductor material. A functional gate structure straddles a portion of the semiconductor fin. A semiconductor channel material having an electron mobility greater than silicon and comprising a different semiconductor material than the semiconductor fin and is located beneath the functional gate structure. The semiconductor channel material is present on at least each vertical sidewall of the semiconductor fin. A dielectric spacer is located on each vertical sidewall surface of the functional gate structure. A doped semiconductor is located on each side of the functional gate structure and underneath each dielectric spacer. A portion of the doped semiconductor material located beneath each dielectric spacer directly contacts a sidewall surface of semiconductor channel material located on each vertical sidewall of the semiconductor fin. | 12-25-2014 |
20140374878 | MEMORY CELL WITH INTEGRATED III-V DEVICE - A method including forming an oxide layer on a top of a substrate; forming a deep trench capacitor in the substrate; bonding a III-V compound semiconductor to a top surface of the oxide layer; and forming a III-V device in the III-V compound semiconductor. | 12-25-2014 |
20140377918 | OVERLAPPED III-V FINFET WITH DOPED SEMICONDUCTOR EXTENSIONS - A semiconductor structure that includes a semiconductor fin comprising an III-V compound semiconductor material. A functional gate structure straddles a portion of the semiconductor fin. A semiconductor channel material having an electron mobility greater than silicon and comprising a different semiconductor material than the semiconductor fin and is located beneath the functional gate structure. The semiconductor channel material is present on at least each vertical sidewall of the semiconductor fin. A dielectric spacer is located on each vertical sidewall surface of the functional gate structure. A doped semiconductor is located on each side of the functional gate structure and underneath each dielectric spacer. A portion of the doped semiconductor material located beneath each dielectric spacer directly contacts a sidewall surface of semiconductor channel material located on each vertical sidewall of the semiconductor fin. | 12-25-2014 |
20150048476 | SEMICONDUCTOR DEVICES AND METHODS OF MANUFACTURE - Semiconductor devices with reduced substrate defects and methods of manufacture are disclosed. The method includes forming a dielectric material on a substrate. The method further includes forming a shallow trench structure and deep trench structure within the dielectric material. The method further includes forming a material within the shallow trench structure and deep trench structure. The method further includes forming active areas of the material separated by shallow trench isolation structures. The shallow trench isolation structures are formed by: removing the material from within the deep trench structure and portions of the shallow trench structure to form trenches; and depositing an insulator material within the trenches. | 02-19-2015 |
20150061017 | SEMICONDUCTOR DEVICES AND METHODS OF MANUFACTURE - Semiconductor devices with reduced substrate defects and methods of manufacture are disclosed. The method includes forming at least one gate structure over a plurality of fin structures. The method further includes removing dielectric material adjacent to the at least one gate structure using a maskless process, thereby exposing an underlying epitaxial layer formed adjacent to the at least one gate structure. The method further includes depositing metal material on the exposed underlying epitaxial layer to form contact metal in electrical contact with source and drain regions, adjacent to the at least one gate structure. The method further includes forming active areas and device isolation after the formation of the contact metal, including the at least one gate structure. The active areas and the contact metal are self-aligned with each other in a direction parallel to the at least one gate structure. | 03-05-2015 |
20150061018 | SPACERLESS FIN DEVICE WITH REDUCED PARASITIC RESISTANCE AND CAPACITANCE AND METHOD TO FABRICATE SAME - A structure includes a substrate having an insulator layer and a plurality of elongated semiconductor fin structures disposed on a surface of the insulator layer. The fin structures are disposed substantially parallel to one another. The structure further includes a plurality of elongated sacrificial gate structures each comprised of silicon nitride. The sacrificial gate structures are disposed substantially parallel to one another and orthogonal to the plurality of fin structures, where a portion of each of a plurality of adjacent fin structures is embedded within one of the sacrificial gate structures leaving other portions exposed between the sacrificial gate structures. The structure further includes a plurality of semiconductor source/drain (S/D) structures disposed over the exposed portions of the fin structures between the sacrificial gate structures. The embodiments eliminate a need to form a conventional spacer on the fin structures. | 03-05-2015 |
20150064854 | SPACERLESS FIN DEVICE WITH REDUCED PARASITIC RESISTANCE AND CAPACITANCE AND METHOD TO FABRICATE SAME - A structure includes a substrate having an insulator layer and a plurality of elongated semiconductor fin structures disposed on a surface of the insulator layer. The fin structures are disposed substantially parallel to one another. The structure further includes a plurality of elongated sacrificial gate structures each comprised of silicon nitride. The sacrificial gate structures are disposed substantially parallel to one another and orthogonal to the plurality of fin structures, where a portion of each of a plurality of adjacent fin structures is embedded within one of the sacrificial gate structures leaving other portions exposed between the sacrificial gate structures. The structure further includes a plurality of semiconductor source/drain (S/D) structures disposed over the exposed portions of the fin structures between the sacrificial gate structures. The embodiments eliminate a need to form a conventional spacer on the fin structures. A method to fabricate the structure is also disclosed. | 03-05-2015 |
20150064892 | SEMICONDUCTOR DEVICES AND METHODS OF MANUFACTURE - Semiconductor devices with reduced substrate defects and methods of manufacture are disclosed. The method includes forming at least one gate structure over a plurality of fin structures. The method further includes removing dielectric material adjacent to the at least one gate structure using a maskless process, thereby exposing an underlying epitaxial layer formed adjacent to the at least one gate structure. The method further includes depositing metal material on the exposed underlying epitaxial layer to form contact metal in electrical contact with source and drain regions, adjacent to the at least one gate structure. The method further includes forming active areas and device isolation after the formation of the contact metal, including the at least one gate structure. The active areas and the contact metal are self-aligned with each other in a direction parallel to the at least one gate structure. | 03-05-2015 |
20150064897 | PROCESS VARIABILITY TOLERANT HARD MASK FOR REPLACEMENT METAL GATE FINFET DEVICES - Embodiments include a method comprising depositing a hard mask layer over a first layer, the hard mask layer including; lower hard mask layer, hard mask stop layer, and upper hard mask. The hard mask layer and the first layer are patterned and a spacer deposited on the patterned sidewall. The upper hard mask layer and top portion of the spacer are removed by selective etching with respect to the hard mask stop layer, the remaining spacer material extending to a first predetermined position on the sidewall. The hard mask stop layer is removed by selective etching with respect to the lower hard mask layer and spacer. The first hard mask layer and top portion of the spacer are removed by selectively etching the lower hard mask layer and the spacer with respect to the first layer, the remaining spacer material extending to a second predetermined position on the sidewall. | 03-05-2015 |
20150069328 | STACKED NANOWIRE DEVICE WITH VARIABLE NUMBER OF NANOWIRE CHANNELS - A method of forming a semiconductor structure including forming a stack of layers on a top surface of a substrate, the stack of layers including alternating layers of a semiconductor material and a sacrificial material, where a bottommost layer of the stack of layers is a top semiconductor layer of the substrate, patterning a plurality of material stacks from the stack of layers, each material stack including an alternating stack of a plurality of nanowire channels and a plurality of sacrificial spacers, the plurality of nanowire channels including the semiconductor material, and the plurality of sacrificial spacers including the sacrificial material, and removing at least one of the plurality of nanowire channels from at least one of the plurality of material stacks without removing one or more of the plurality of nanowire channels from an adjacent material stack. | 03-12-2015 |