Patent application number | Description | Published |
20080217705 | TRENCH FORMATION IN A SEMICONDUCTOR MATERIAL - A semiconductor device is formed on a semiconductor layer. A gate dielectric layer is formed over the semiconductor layer. A layer of gate material is formed over the gate dielectric layer. The layer of gate material is patterned to form a gate structure. Using the gate structure as a mask, an implant into the semiconductor layer is performed. To form a first patterned gate structure and a trench in the semiconductor layer surrounding a first portion and a second portion of the semiconductor layer and the gate, an etch through the gate structure and the semiconductor layer is performed. The trench is filled with insulating material. | 09-11-2008 |
20080261361 | Shallow trench isolation for SOI structures combining sidewall spacer and bottom liner - A method for making a semiconductor device is provided which comprises (a) providing a layer stack comprising a semiconductor layer ( | 10-23-2008 |
20090108296 | SEMICONDUCTOR DEVICES WITH DIFFERENT DIELECTRIC THICKNESSES - An integrated circuit with devices having dielectric layers with different thicknesses. The dielectric layers include a high-k dielectric and some of the dielectric layers include an oxide layer that is formed from an oxidation process. Each device includes a layer including germanium or carbon located underneath the electrode stack of the device. A silicon cap layers is located over the layer including germanium or carbon. | 04-30-2009 |
20100025805 | SEMICONDUCTOR DEVICES WITH EXTENDED ACTIVE REGIONS - A method of making a semiconductor device is achieved in and over a semiconductor layer. A trench is formed adjacent to a first active area. The trench is filled with insulating material. A masking feature is formed over a center portion of the trench to expose a first side of the trench between a first side of the masking feature and the first active area. A step of etching into the first side of the trench leaves a first recess in the trench. A first epitaxial region is grown in the first recess to extend the first active area to include the first recess and thereby form an extended first active region. | 02-04-2010 |
20110291180 | ANGLED ION IMPLANTATION IN A SEMICONDUCTOR DEVICE - Angled ion implants are utilized to form doped regions in a semiconductor pillar formed in an opening of a mask. The pillar is formed to a height less than the height of the mask. Angled ion implantation can be used to form regions of a semiconductor device such as a body tie region, a halo region, or current terminal extension region of a semiconductor device implemented with the semiconductor pillar. | 12-01-2011 |
20110294292 | METHOD OF FORMING A SHARED CONTACT IN A SEMICONDUCTOR DEVICE - A method for forming a shared contact in a semiconductor device having a gate electrode corresponding to a first transistor and a source/drain region corresponding to a second transistor is provided. The method includes forming a first opening in a dielectric layer overlying the gate electrode and the source/drain region, wherein the first opening extends substantially to the gate electrode corresponding to the first transistor. The method further includes after forming the first opening, forming a second opening, contiguous with the first opening, in the overlying dielectric layer, wherein the second opening extends substantially to the source/drain region corresponding to the second transistor. The method further includes forming the shared contact between the gate electrode corresponding to the first transistor and the source/drain region corresponding to the second transistor by filling the first opening and the second opening with a conductive material. | 12-01-2011 |
20120007155 | SEMICONDUCTOR DEVICES WITH EXTENDED ACTIVE REGIONS - A method of making a semiconductor device is achieved in and over a semiconductor layer. A trench is formed adjacent to a first active area. The trench is filled with insulating material. A masking feature is formed over a center portion of the trench to expose a first side of the trench between a first side of the masking feature and the first active area. A step of etching into the first side of the trench leaves a first recess in the trench. A first epitaxial region is grown in the first recess to extend the first active area to include the first recess and thereby form an extended first active region. | 01-12-2012 |
20120068305 | LATERAL CAPACITOR AND METHOD OF MAKING - An active device region is formed in and on a semiconductor substrate. An interconnect layer is formed over the active device region, wherein the interconnect layer comprises a first dielectric material having a first dielectric constant, a first metal interconnect in the first dielectric material, and a second metal interconnect in the first dielectric material and laterally spaced apart from the first metal interconnect. A portion of the first dielectric material is removed such that a remaining portion of the first dielectric material remains within the interconnect layer, wherein the removed portion is removed from a location between the first and second metal interconnects. The location between the first and second metal interconnects from which the portion of the first dielectric material was removed is filled with a second dielectric material having a second dielectric constant, the second dielectric constant being higher than the first dielectric constant. | 03-22-2012 |
20120104483 | NON-VOLATILE MEMORY AND LOGIC CIRCUIT PROCESS INTEGRATION - A method of making a logic transistor in a logic region of a substrate and a non-volatile memory cell in an NVM region of the substrate includes forming a gate dielectric layer on the substrate. A first polysilicon layer is formed on the gate dielectric. The first polysilicon layer is formed over the NVM region and removing the first polysilicon layer over the logic region. A dielectric layer is formed over the NVM region including the first polysilicon layer and over the logic region. A protective layer is formed over the dielectric layer. The dielectric layer and the protective layer are removed from the logic region to leave a remaining portion of the dielectric layer and a remaining portion of the protective layer over the NVM region. A high-k dielectric layer is formed over the logic region and the remaining portion of the protective layer. A first metal layer is formed over the high K dielectric layer. The first metal layer, the high K dielectric, and the remaining portion of the protective layer are removed over the NVM region to leave a remaining portion of the first metal layer and a remaining portion of the high K dielectric layer over the logic region. A conductive layer is deposited over the remaining portion of the dielectric layer and over the first metal layer. The NVM cell and the logic transistor are formed and this includes patterning the conductive layer. | 05-03-2012 |
20120175697 | MULTI-STATE NON-VOLATILE MEMORY CELL INTEGRATION AND METHOD OF OPERATION - A semiconductor device includes a region in a semiconductor substrate having a top surface with a first charge storage layer on the top surface. A first conductive line is on the first charge storage layer. A second charge storage layer is on the top surface. A second conductive line is on the second charge storage layer. A third charge storage layer is on the top surface. A third conductive line is on the third charge storage layer. A fourth charge storage layer has a first side adjoining a first sidewall of the first conductive line and a second side adjoining a first sidewall of the second conductive line. A fifth charge storage layer has a first side adjoining a second sidewall of the second conductive line and a second side adjoining a first sidewall of the third conductive line. Source and drain regions are formed in the substrate on either side of the semiconductor device. | 07-12-2012 |
20120248523 | NON-VOLATILE MEMORY AND LOGIC CIRCUIT PROCESS INTEGRATION - An integrated circuit is disclosed that includes a split gate memory device comprising a select gate is located over a substrate. A charge storage layer includes a layer of discrete storage elements and a layer of high-k dielectric material covering at least one side of the layer of discrete storage elements. At least a portion of a control gate is located over the charge storage layer. The control gate includes a layer of barrier work function material and a layer of gate material located over the layer of barrier work function material. | 10-04-2012 |
20120252171 | NON-VOLATILE MEMORY AND LOGIC CIRCUIT PROCESS INTEGRATION - A method for forming an integrated circuit for a non-volatile memory cell transistor is disclosed that includes: forming a layer of discrete storage elements over a substrate in a first region of the substrate and in a second region of the substrate; forming a first layer of dielectric material over the layer of discrete storage elements in the first region and the second region; forming a first layer of barrier work function material over the first layer of dielectric material in the first region and the second region; and removing the first layer of barrier work function material from the second region, the first layer of dielectric material from the second region, and the layer of discrete storage elements from the second region. After the removing, a second layer of barrier work function material is formed over the substrate in the first region and the second region. The second layer of barrier work function material is removed from the first region. A first gate of a memory device is formed in the first region. The first gate includes a portion of the first layer of barrier work function material. The memory device includes a charge storage structure including a portion of the layer of discrete storage elements. A second gate of a transistor is formed in the second region, the second gate including a portion of the second layer of barrier work function material. | 10-04-2012 |
20120267758 | Isolated Capacitors Within Shallow Trench Isolation - A semiconductor process and apparatus provide a shallow trench isolation capacitor structure that is integrated in an integrated circuit and includes a bottom capacitor plate that is formed in a substrate layer ( | 10-25-2012 |
20120267759 | DECOUPLING CAPACITORS RECESSED IN SHALLOW TRENCH ISOLATION - A semiconductor process and apparatus provide a shallow trench isolation capacitor structure that is integrated in an integrated circuit and includes a bottom capacitor plate that is formed in a substrate layer below a trench opening, a capacitor dielectric layer and a recessed top capacitor plate that is covered by an STI region and isolated from cross talk by a sidewall dielectric layer. | 10-25-2012 |
20120273857 | SEMICONDUCTOR DEVICE STRUCTURE AS A CAPACITOR - A capacitor structure includes a conductive region; a first dielectric layer over the conductive region; a conductive material within the first dielectric layer, wherein the conductive material is on the conductive region and forms a first plate electrode of the capacitor structure; an insulating layer within the first dielectric layer and surrounding the conductive material; a first conductive layer within the first dielectric layer and surrounding the insulating layer, wherein the first conductive layer forms a second plate electrode of the capacitor structure; a second conductive layer laterally extending from the first conductive layer at a top surface of the first dielectric layer; a second dielectric layer over the first dielectric layer; and a third conductive layer within the second dielectric layer and on the conductive material. | 11-01-2012 |
20120273889 | SHALLOW TRENCH ISOLATION FOR SOI STRUCTURES COMBINING SIDEWALL SPACER AND BOTTOM LINER - A method for making a semiconductor device is provided which includes (a) providing a layer stack comprising a semiconductor layer ( | 11-01-2012 |
20120276705 | METHOD OF MAKING A SEMICONDUCTOR DEVICE AS A CAPACITOR - Forming a capacitor structure includes forming a first dielectric layer over a conductive region, wherein the first dielectric layer has a first conductive layer at a top surface of the first dielectric layer; forming a first opening in the first dielectric layer over the conductive region, wherein the first opening exposes a first sidewall of the first conductive layer; forming a second conductive layer within the first opening, wherein the second conductive layer contacts the first sidewall of the first conductive layer; removing a portion of the second conductive layer from the bottom of the first opening; forming an insulating layer within the first opening; removing a portion of the insulating layer from the bottom of the first opening; extending the first opening through the first dielectric layer to expose the conductive region; and filling the first opening with a conductive material, wherein the conductive material contacts the conductive region. | 11-01-2012 |
20130062529 | INCIDENT CAPACITIVE SENSOR - A capacitive sensor device for measuring radiation. The device includes two sensor regions and top plate structure. The sensor regions are of a material that generates electron-hole pairs when radiation strikes the material. A separation region is located between the two sensor regions. The capacitance between a sensor region and top plate is dependent upon radiation striking the sensor region. A blocking structure selectively and differentially blocks radiation having a parameter value in a range from the sensor region so as to differentially impact electron-hole pair generation of one sensor region with respect to electron-hole pair generation of the other sensor region at selected angles of incidence of the radiation. | 03-14-2013 |
20130063164 | CAPACITIVE SENSOR RADIATION MEASUREMENT - A system that includes at least one capacitive sensor for least one angle of incidence component of radiation being measured striking the sensor. The measured capacitance of the sensor is affected by radiation striking the sensor. In some embodiments, the system includes multiple sensors where differences in the capacitive measurements of the sensors can be used to determine information about the radiation such as e.g. horizontal angle, directional angle, and dose. | 03-14-2013 |
20130137227 | LOGIC AND NON-VOLATILE MEMORY (NVM) INTEGRATION - A method includes forming a gate dielectric over a substrate in an NVM region and a logic region; forming a first conductive layer over the gate dielectric in the NVM region and the logic region; patterning the first conductive layer in the NVM region to form a select gate; forming a charge storage layer over the select gate in the NVM region and the first conductive layer in the logic region; forming a second conductive layer over the charge storage layer in the NVM region and the logic region; removing the second conductive layer and the charge storage layer from the logic region; patterning the first conductive layer in the logic region to form a first logic gate; and after forming the first logic gate, patterning the second conductive layer in the NVM region to form a control gate which overlaps a sidewall of the select gate. | 05-30-2013 |
20130171785 | NON-VOLATILE MEMORY (NVM) AND LOGIC INTEGRATION - A method of forming an NVM cell and a logic transistor uses a semiconductor substrate. A metal select gate of the NVM cell is formed over a high-k dielectric as is metal logic gate of a logic transistor. The logic transistor is formed, including forming source/drains, while the metal select gate of the NVM cell is formed. The logic transistor is protected while the NVM cell is then formed including forming a charge storage region using metal nanocrystals and a metal control gate over a portion of the metal select gate and a portion of the charge storage region over the substrate. The charge storage region is etched to be aligned to the metal control gate. | 07-04-2013 |
20130171786 | NON-VOLATILE MEMORY (NVM) AND LOGIC INTEGRATION - A method of forming an NVM cell and a logic transistor uses a semiconductor substrate. A metal select gate of the NVM cell is formed over an NVM work function setting metal, the NVM work function setting metal is on a high-k dielectric, and a metal logic gate of a logic transistor is similarly formed over work function setting and high-k dielectric materials. The logic transistor is formed while portions of the metal select gate of the NVM cell are formed. The logic transistor is protected while the NVM cell is then formed including forming a charge storage region using nanocrystals and a metal control gate over a portion of the metal select gate and a portion of the charge storage region over the substrate. The charge storage region is etched to be aligned to the metal control gate. | 07-04-2013 |
20130178027 | NON-VOLATILE MEMORY (NVM) AND LOGIC INTEGRATION - A method of forming an NVM cell and a logic transistor uses a semiconductor substrate. A polysilicon select gate of the NVM cell is formed over a first thermally-grown oxygen-containing layer in an NVM region and a polysilicon dummy gate is formed over a second thermally-grown oxygen-containing layer in a logic region. Source/drains, a sidewall spacer, and silicided regions of the logic transistor are formed after the first and second thermally-grown oxygen-containing layers are formed. The second thermally-grown oxygen-containing layer and the dummy gate are replaced by a metal gate and a high-k dielectric. The logic transistor is protected while the NVM cell is then formed including forming a charge storage layer. | 07-11-2013 |
20130178054 | METHODS OF MAKING LOGIC TRANSISTORS AND NON-VOLATILE MEMORY CELLS - Methods of making a logic transistor in a logic region and an NVM cell in an NVM region of a substrate include forming a conductive layer on a gate dielectric, patterning the conductive layer over the NVM region, removing the conductive layer over the logic region, forming a dielectric layer over the NVM region, forming a protective layer over the dielectric layer, removing the dielectric layer and the protective layer from the logic region, forming a high-k dielectric layer over the logic region and a remaining portion of the protective layer, and forming a first metal layer over the high-k dielectric layer. The first metal layer, the high-k dielectric, and the remaining portion of the protective layer are removed over the NVM region. A conductive layer is deposited over the remaining portions of the dielectric layer and over the first metal layer, and the conductive layer is patterned. | 07-11-2013 |
20130214346 | NON-VOLATILE MEMORY CELL AND LOGIC TRANSISTOR INTEGRATION - A first conductive layer and an underlying charge storage layer are patterned to form a control gate in an NVM region. A first dielectric layer is formed over the control gate. A sacrificial layer is formed over the first dielectric layer and planarized. A patterned masking layer is formed over the sacrificial layer which includes a first portion which defines a select gate location laterally adjacent the control gate in the NVM region and a second portion which defines a logic gate in a logic region. Exposed portions of the sacrificial layer are removed such that a first portion remains at the select gate location. A second dielectric layer is formed over the first portion and planarized to expose the first portion. The first portion is removed to result in an opening at the select gate location. A gate dielectric layer and a select gate are formed in the opening. | 08-22-2013 |
20130217197 | INTEGRATION TECHNIQUE USING THERMAL OXIDE SELECT GATE DIELECTRIC FOR SELECT GATE AND REPLACEMENT GATE FOR LOGIC - A control gate overlying a charge storage layer is formed. A thermally-grown oxygen-containing layer is formed over the control gate. A polysilicon layer is formed over the oxygen-containing layer and planarized. A first masking layer is formed defining a select gate location laterally adjacent the control gate and a second masking layer is formed defining a logic gate location. Exposed portions of the polysilicon layer are removed such that a select gate remains at the select gate location and a polysilicon portion remains at the logic gate location. A dielectric layer is formed around the select and control gates and polysilicon portion. The polysilicon portion is removed to result in an opening in the dielectric. A high-k gate dielectric and logic gate are formed in the opening. | 08-22-2013 |
20130249015 | SEMICONDUCTOR DEVICES WITH DIFFERENT DIELECTRIC THICKNESSES - An integrated circuit with devices having dielectric layers with different thicknesses. The dielectric layers include a high-k dielectric and some of the dielectric layers include an oxide layer that is formed from an oxidation process. Each device includes a layer including germanium or carbon located underneath the electrode stack of the device. A silicon cap layers is located over the layer including germanium or carbon. | 09-26-2013 |
20130264633 | LOGIC TRANSISTOR AND NON-VOLATILE MEMORY CELL INTEGRATION - A first conductive layer and an underlying charge storage layer are patterned to form a control gate in an NVM region. A first dielectric layer and barrier layer are formed over the control gate. A sacrificial layer is formed over the barrier layer and planarized. A first patterned masking layer is formed over the sacrificial layer and control gate in the NVM region which defines a select gate location laterally adjacent the control gate in the NVM region. A second masking layer is formed in the logic region which defines a logic gate location. Exposed portions of the sacrificial layer are removed such that a first portion remains at the select gate location. A second dielectric layer is formed over the first portion and planarized to expose the first portion. The first portion is removed to result in an opening at the select gate location which exposes the barrier layer. | 10-10-2013 |
20130264634 | LOGIC TRANSISTOR AND NON-VOLATILE MEMORY CELL INTEGRATION - A first conductive layer and an underlying charge storage layer are patterned to form a control gate in an NVM region. A first dielectric layer and barrier layer are formed over the control gate. A sacrificial layer is formed over the barrier layer and planarized. A first patterned masking layer is formed over the sacrificial layer and control gate in the NVM region which defines a select gate location laterally adjacent the control gate in the NVM region. A second masking layer is formed in the logic region which defines a logic gate location. Exposed portions of the sacrificial layer are removed such that a first portion remains at the select gate location. A second dielectric layer is formed over the first portion and planarized to expose the first portion. The first portion is removed to result in an opening at the select gate location which exposes the barrier layer. | 10-10-2013 |
20130267072 | NON-VOLATILE MEMORY (NVM) AND LOGIC INTEGRATION - A method of forming an NVM cell and a logic transistor uses a semiconductor substrate. In an NVM region, a polysilicon select gate of the NVM cell is formed over a first thermally-grown oxygen-containing layer, and in a logic region, a work-function-setting material is formed over a high-k dielectric and a polysilicon dummy gate is formed over the work-function-setting material. Source/drains, a sidewall spacer, and silicided regions of the logic transistor are formed after the first thermally-grown oxygen-containing layer is formed. The polysilicon dummy gate is replaced by a metal gate. The logic transistor is protected while the NVM cell is then formed including forming a charge storage region. | 10-10-2013 |
20130267074 | INTEGRATION TECHNIQUE USING THERMAL OXIDE SELECT GATE DIELECTRIC FOR SELECT GATE AND APARTIAL REPLACEMENT GATE FOR LOGIC - A thermally-grown oxygen-containing layer is formed over a control gate in an NVM region, and a high-k dielectric layer and barrier layer are formed in a logic region. A polysilicon layer is formed over the oxygen-containing layer and barrier layer and is planarized. A first masking layer is formed over the polysilicon layer and control gate defining a select gate location laterally adjacent the control gate. A second masking layer is formed defining a logic gate location. Exposed portions of the polysilicon layer are removed such that a select gate remains at the select gate location and a polysilicon portion remains at the logic gate location. A dielectric layer is formed around the select and control gates and polysilicon portion. The polysilicon portion is removed to result in an opening at the logic gate location which exposes the barrier layer. | 10-10-2013 |
20130330893 | INTEGRATING FORMATION OF A REPLACEMENT GATE TRANSISTOR AND A NON-VOLATILE MEMORY CELL USING A HIGH-K DIELECTRIC - A first dielectric layer is formed in an NVM region and a logic region. A charge storage layer is formed over the first dielectric layer and is patterned to form a dummy gate in the logic region and a charge storage structure in the NVM region. A second dielectric layer is formed in the NVM and logic regions which surrounds the charge storage structure and dummy gate. The second dielectric layer is removed from the NVM region while protecting the second dielectric layer in the logic region. The dummy gate is removed, resulting in an opening. A third dielectric layer is formed over the charge storage structure and within the opening, and a gate layer is formed over the third dielectric layer and within the opening, wherein the gate layer forms a control gate layer in the NVM region and the gate layer within the opening forms a logic gate. | 12-12-2013 |
20140001432 | APPLICATIONS FOR NANOPILLAR STRUCTURES | 01-02-2014 |
20140120713 | METHOD OF MAKING A LOGIC TRANSISTOR AND A NON-VOLATILE MEMORY (NVM) CELL - An oxide-containing layer is formed directly on a semiconductor layer in an NVM region, and a first partial layer of a first material is formed over the oxide-containing layer in the NVM region. A first high-k dielectric layer is formed directly on the semiconductor layer in a logic region. A first conductive layer is formed over the first dielectric layer in the logic region. A second partial layer of the first material is formed directly on the first partial layer in the NVM region and over the first conductive layer in the logic region. A logic device is formed in the logic region. An NVM cell is formed in the NVM region, wherein the first and second partial layer together are used to form one of a charge storage layer if the cell is a floating gate cell or a select gate if the cell is a split gate cell. | 05-01-2014 |
20140131788 | SEMICONDUCTOR DEVICES WITH NON-VOLATILE MEMORY CELLS - A semiconductor device includes a region in a semiconductor substrate having a top surface with a first charge storage layer on the top surface. A first conductive line is on the first charge storage layer. A second charge storage layer is on the top surface. A second conductive line is on the second charge storage layer. A third charge storage layer is on the top surface. A third conductive line is on the third charge storage layer. A fourth charge storage layer has a first side adjoining a first sidewall of the first conductive line and a second side adjoining a first sidewall of the second conductive line. A fifth charge storage layer has a first side adjoining a second sidewall of the second conductive line and a second side adjoining a first sidewall of the third conductive line. Source and drain regions are formed in the substrate on either side of the semiconductor device. | 05-15-2014 |
20140299935 | SHALLOW TRENCH ISOLATION FOR SOI STRUCTURES COMBINING SIDEWALL SPACER AND BOTTOM LINER - A method for making a semiconductor device is provided which includes (a) providing a layer stack comprising a semiconductor layer ( | 10-09-2014 |
20150015306 | SYSTEMS AND METHODS FOR REDUCING POWER CONSUMPTION IN SEMICONDUCTOR DEVICES - A method of making a first timing path includes developing a first design of the first timing path with a first logic circuit and a first functional cell, wherein the first functional cell comprises a first transistor that is spaced from a first well boundary. The timing path is analyzed to determine if the first timing path has positive timing slack. If the analyzed speed of operation shows positive timing slack, the design is changed to a modified design to reduce power consumption of the first timing path by moving the first transistor closer to the first well boundary. Also the first timing path is then built using the modified design to reduce power consumption of the first timing path by reducing leakage power consumption of the first transistor. | 01-15-2015 |
20150037958 | METHODS OF MAKING MULTI-STATE NON-VOLATILE MEMORY CELLS - A semiconductor device includes a region in a semiconductor substrate having a top surface with a first charge storage layer on the top surface. A first conductive line is on the first charge storage layer. A second charge storage layer is on the top surface. A second conductive line is on the second charge storage layer. A third charge storage layer is on the top surface. A third conductive line is on the third charge storage layer. A fourth charge storage layer has a first side adjoining a first sidewall of the first conductive line and a second side adjoining a first sidewall of the second conductive line. A fifth charge storage layer has a first side adjoining a second sidewall of the second conductive line and a second side adjoining a first sidewall of the third conductive line. Source and drain regions are formed in the substrate on either side of the semiconductor device. | 02-05-2015 |