Abstract: A phase change memory (PCM) cell includes a transistor, a PCM structure, and a heater. The transistor has a first current electrode and a second current electrode in a structure, and a channel region having a first portion along a first sidewall of the structure and having a second portion along a second sidewall of the structure. The second sidewall is opposite the first sidewall. The transistor has a control electrode that has a first portion adjacent to the first sidewall and a second portion adjacent to the second sidewall. The PCM structure exhibits first and second resistive values when in first and second phase states, respectively. The heater is on the structure and produces heat when current flows through the heater for changing the phase state of the phase change structure.

Abstract: An electrostatic discharge (ESD) protected circuit is coupled to a power supply voltage rail and includes a multiple independent gate field effect transistor (MIGFET), a pre-driver, and a hot gate bias circuit. The MIGFET has a source/drain path coupled between an output pad and the power supply voltage rail and has a first gate terminal and a second gate terminal. The pre-driver circuit has an output. The hot gate bias circuit is coupled to the first gate terminal of the MIGFET, and the output of the pre-driver circuit is coupled to the second gate terminal of the MIGFET. The hot gate bias circuit is configured to apply a bias voltage to the first gate terminal of the MIGFET during an ESD event that increases the breakdown voltage of the MIGFET so as to better withstand the ESD event.

Abstract: A semiconductor optical device includes an insulating layer, a photoelectric region formed on the insulating layer, a first electrode having a first conductivity type formed on the insulating layer and contacting a first side of the photoelectric region, and a second electrode having a second conductivity type formed on the insulating layer and contacting a second side of the photoelectric region. The photoelectric region may include nanoclusters or porous silicon such that the device operates as a light emitting device. Alternatively, the photoelectric region may include an intrinsic semiconductor material such that the device operates as a light sensing device. The semiconductor optical device may be further characterized as a vertical optical device. In one embodiment, different types of optical devices, including light emitting and light sensing devices, may be integrated together.

Abstract: A semiconductor fabrication process includes forming a gate electrode (112) overlying a gate dielectric (114) overlying a semiconductor substrate (104) of a wafer (101) and a liner dielectric layer (116) including vertical portions (118) adjacent sidewalls of the gate electrode and horizontal portions (117) overlying an upper surface of the semiconductor substrate (104). A spacer (108) is formed adjacent a vertical portion (118) and overlying a horizontal portion (117) of the liner dielectric layer (116). After forming the spacer (108), exposed portions of the liner dielectric layer (116) are removed to form a liner dielectric structure (126) covered by the extension spacer (108). The extension spacer (108) is then etched back to expose or uncover extremities of the liner dielectric structure (126). Prior to etching back the spacer (108), a metal (130) may be sputtered deposited over the wafer (101) preparatory to forming a silicide (134).

Abstract: A non-volatile memory cell can include a substrate, an active region overlying the substrate, and a capacitor structure overlying the substrate. From a plan view, the capacitor structure surrounds the active region. In one embodiment, the non-volatile memory cell includes a floating gate electrode and a control gate electrode. The capacitor structure comprises a first capacitor portion, and the first capacitor portion comprises a first capacitor electrode and a second capacitor electrode. The first capacitor electrode is electrically connected to the floating gate electrode, and the second capacitor electrode is electrically connected to the control gate electrode. A process for forming the non-volatile memory cell can include forming an active region over a substrate, and forming a capacitor structure over the substrate, wherein from a plan view, the capacitor structure surrounds the active region.

Abstract: A semiconductor optical device includes an insulating layer, a photoelectric region formed on the insulating layer, a first electrode having a first conductivity type formed on the insulating layer and contacting a first side of the photoelectric region, and a second electrode having a second conductivity type formed on the insulating layer and contacting a second side of the photoelectric region. The photoelectric region may include nanoclusters or porous silicon such that the device operates as a light emitting device. Alternatively, the photoelectric region may include an intrinsic semiconductor material such that the device operates as a light sensing device. The semiconductor optical device may be further characterized as a vertical optical device. In one embodiment, different types of optical devices, including light emitting and light sensing devices, may be integrated together.

Abstract: A fin field effect transistor (FinFET) memory cell and method of formation has a substrate for providing mechanical support. A first dielectric layer overlies the substrate. A fin structure overlies the dielectric layer and has a first current electrode and a second current electrode separated by a channel. A floating gate has a vertical portion that is adjacent to and electrically insulated from a side of the channel and has a horizontal portion overlying the first dielectric layer and extending laterally away from the channel. The floating gate stores electrical charge. A second dielectric layer is adjacent the floating gate. A control gate adjacent the second dielectric layer and physically separated from the floating gate by the second dielectric layer. The “L-shape” of the floating gate enhances capacitive coupling ratio between the control gate and the floating gate.

Abstract: A method for making a semiconductor device is provided. The method includes forming a first transistor with a vertical active region and a horizontal active region extending on both sides of the vertical active region. The method further includes forming a second transistor with a vertical active region. The method further includes forming a third transistor with a vertical active region and a horizontal active region extending on only one side of the vertical active region.

Abstract: A multi-bit split-gate memory device is formed over a substrate. A storage layer is formed over the substrate. A first conductive layer is formed over the storage layer. A thickness of a portion of the conductive layer is removed to leave a pillar of the conductive layer and an area of reduced thickness of the conductive layer. A first sidewall spacer is formed adjacent to the pillar to cover a first portion and a second portion of the area of reduced thickness of the conductive layer. The pillar is replaced with a select gate. The area of reduced thickness is selectively removed to leave the first and second portions as control gates.

Abstract: A semiconductor device (51) is provided herein. The semiconductor device comprises (a) a substrate (57), a semiconductor layer (53) disposed on said substrate and comprising a horizontal region (54) and a fin which extends above, and is disposed adjacent to, said horizontal region, and (c) at least one channel region (63) defined in said fin and in said horizontal region.

Abstract: An electronic device can include a gated diode, wherein the gated diode includes a junction diode structure including a junction. A first conductive member spaced apart from and adjacent to the junction can be connected to a first signal line. A second conductive member, spaced apart from and adjacent to the junction, can be both electrically connected to a second signal line and electrically insulated from the first conductive member. The junction diode structure can include a p-n or a p-i-n junction. A process for forming the electronic device is also described.

Abstract: A method for making a semiconductor device is provided. The method includes forming a first transistor with a vertical active region and a horizontal active region extending on both sides of the vertical active region. The method further includes forming a second transistor with a vertical active region. The method further includes forming a third transistor with a vertical active region and a horizontal active region extending on only one side of the vertical active region.

Abstract: A method for depositing metals on surfaces is provided which comprises (a) providing a substrate (103) having a horizontal surface (107) and a vertical surface (105); (b) depositing a first metal layer (109) over the horizontal and vertical surfaces; (c) depositing a layer of polysilicon (111) over the horizontal and vertical surfaces; (d) treating the layer of polysilicon with a plasma such that a residue (113) remaining from the treatment is preferentially formed over the horizontal surfaces rather than the vertical surfaces, and wherein the residue is resistant to a first metal etch; and (e) exposing the substrate to the first metal etch.

Abstract: A method for making a transistor is provided which comprises (a) providing a semiconductor structure having a gate (211) overlying a semiconductor layer (203), and having at least one spacer structure (213) disposed adjacent to said gate; (b) removing a portion of the semiconductor structure adjacent to the spacer structure, thereby exposing a portion (215) of the semiconductor structure which underlies the spacer structure; and (c) subjecting the exposed portion of the semiconductor structure to an angled implant (253, 254).

Abstract: A semiconductor fabrication process includes forming a gate electrode (112) overlying a gate dielectric (114) overlying a semiconductor substrate (104) of a wafer (101) and a liner dielectric layer (116) including vertical portions (118) adjacent sidewalls of the gate electrode and horizontal portions (117) overlying an upper surface of the semiconductor substrate (104). A spacer (108) is formed adjacent a vertical portion (118) and overlying a horizontal portion (117) of the liner dielectric layer (116). After forming the spacer (108), exposed portions of the liner dielectric layer (116) are removed to form a liner dielectric structure (126) covered by the extension spacer (108). The extension spacer (108) is then etched back to expose or uncover extremities of the liner dielectric structure (126). Prior to etching back the spacer (108), a metal (130) may be sputtered deposited over the wafer (101) preparatory to forming a silicide (134).

Abstract: A method for making a semiconductor device includes patterning a semiconductor layer, overlying an insulator layer, to create a first active region and a second active region, wherein the first active region is of a different height from the second active region, and wherein at least a portion of the first active region has a first conductivity type and at least a portion of the second active region has a second conductivity type different from the first conductivity type in at least a channel region of the semiconductor device. The method further includes forming a gate structure over at least a portion of the first active region and the second active region. The method further includes removing a portion of the second active region on one side of the semiconductor device.

Abstract: A device and method for temperature compensation of an electronic device are disclosed. The device includes a temperature bias controller with a temperature sensor. A bias signal based upon a signal from the temperature sensor is provided to a first gate of a multiple fin gate field effect transistor (multigate FinFET) transistor of a functional block. A second gate of the multigate FinFET transistor receives a control signal to control its operation within the functional block. In this configuration the first gate of the multigate FinFET transistor can be used for temperature compensation while the second gate is used for functional operation of the transistor. Specific embodiments of the present disclosure will be better understood with respect to the figures.

Abstract: An electronic device can include a gated diode, wherein the gated diode includes a junction diode structure including a junction. A first conductive member spaced apart from and adjacent to the junction can be connected to a first signal line. A second conductive member, spaced apart from and adjacent to the junction, can be both electrically connected to a second signal line and electrically insulated from the first conductive member. The junction diode structure can include a p-n or a p-i-n junction. A process for forming the electronic device is also described.

Abstract: Removing a portion of a structure in a semiconductor device to separate the structure. The structure has two portions of different heights. In one example, the structure is removed by forming a spacer over the lower portion adjacent to the sidewall of the higher portion. A second material is then formed on the structure outside of the spacer. The spacer is removed and the portion under the spacer is then removed to separate the structure at that location. In one embodiment, separate channel regions are implemented in the separated structures. In other embodiments, separate gate structures are implemented in the separated structures.

Abstract: A semiconductor device is formed using a semiconductor substrate. A gate dielectric is formed over the semiconductor substrate. A gate electrode layer is formed over the gate dielectric. A patterned masking layer is formed over the gate electrode layer. A first region of the gate electrode layer lies within an opening in the patterned masking layer. The first region of the gate electrode layer is partially etched to leave an elevated portion of the gate electrode layer and a lower portion adjacent to the elevated portion. A sidewall spacer is formed adjacent to the elevated portion and over the lower portion. An implant is performed into the semiconductor substrate using the elevated portion and the sidewall spacer as a mask. The sidewall spacer and the lower portion are removed.