Abstract: Techniques are disclosed for forming a non-planar germanium quantum well structure. In particular, the quantum well structure can be implemented with group IV or III-V semiconductor materials and includes a germanium fin structure. In one example case, a non-planar quantum well device is provided, which includes a quantum well structure having a substrate (e.g. SiGe or GaAs buffer on silicon), a IV or III-V material barrier layer (e.g., SiGe or GaAs or AlGaAs), a doping layer (e.g., delta/modulation doped), and an undoped germanium quantum well layer. An undoped germanium fin structure is formed in the quantum well structure, and a top barrier layer deposited over the fin structure. A gate metal can be deposited across the fin structure. Drain/source regions can be formed at respective ends of the fin structure.

Abstract: A method of centering a contact on a layer of a magnetic memory device. In one embodiment, a spacers is formed in an opening surrounding the upper layer and the contact is formed within the spacer. The spacer is formed from an anisotropically etched conformal layer deposited on an upper surface and into the opening.

Abstract: A method of patterning a semiconductor film is described. According to an embodiment of the present invention, a hard mask material is formed on a silicon film having a global crystal orientation wherein the semiconductor film has a first crystal plane and second crystal plane, wherein the first crystal plane is denser than the second crystal plane and wherein the hard mask is formed on the second crystal plane. Next, the hard mask and semiconductor film are patterned into a hard mask covered semiconductor structure. The hard mask covered semiconductor structured is then exposed to a wet etch process which has sufficient chemical strength to etch the second crystal plane but insufficient chemical strength to etch the first crystal plane.

Abstract: III-N transistors with recessed gates. An epitaxial stack includes a doped III-N source/drain layer and a III-N etch stop layer disposed between a the source/drain layer and a III-N channel layer. An etch process, e.g., utilizing photochemical oxidation, selectively etches the source/drain layer over the etch stop layer. A gate electrode is disposed over the etch stop layer to form a recessed-gate III-N HEMT. At least a portion of the etch stop layer may be oxidized with a gate electrode over the oxidized etch stop layer for a recessed gate III-N MOS-HEMT including a III-N oxide. A high-k dielectric may be formed over the oxidized etch stop layer with a gate electrode over the high-k dielectric to form a recessed gate III-N MOS-HEMT having a composite gate dielectric stack.

Abstract: The present disclosure provides a system and method for forming a resistive random access memory (RRAM) device. A RRAM device consistent with the present disclosure includes a substrate and a first electrode disposed thereon. The RRAM device includes a second electrode disposed over the first electrode and a RRAM dielectric layer disposed between the first electrode and the second electrode. The RRAM dielectric layer has a recess at a top center portion at the interface between the second electrode and the RRAM dielectric layer. The present disclosure further provides a computing device. The computing device includes a motherboard, a processor mounted on the motherboard, and a communication chip fabricated on the same chip as the processor or mounted on the motherboard. The processor comprises a substrate, a first electrode, second electrode, and a RRAM layer which has a recess at the interface between the second electrode and RRAM oxide layer.

Abstract: A nonplanar semiconductor device having a semiconductor body formed on an insulating layer of a substrate. The semiconductor body has a top surface opposite a bottom surface formed on the insulating layer and a pair of laterally opposite sidewalls wherein the distance between the laterally opposite sidewalls at the top surface is greater than at the bottom surface. A gate dielectric layer is formed on the top surface of the semiconductor body and on the sidewalls of the semiconductor body. A gate electrode is formed on the gate dielectric layer on the top surface and sidewalls of the semiconductor body. A pair of source/drain regions are formed in the semiconductor body on opposite sides of the gate electrode.

Abstract: The present disclosure provides a system and method for forming a resistive random access memory (RRAM) device. A RRAM device consistent with the present disclosure includes a substrate and a first electrode disposed thereon. The RRAM device includes a second electrode disposed over the first electrode and a RRAM dielectric layer disposed between the first electrode and the second electrode. The RRAM dielectric layer has a recess at a top center portion at the interface between the second electrode and the RRAM dielectric layer.

Abstract: III-N transistors with recessed gates. An epitaxial stack includes a doped III-N source/drain layer and a III-N etch stop layer disposed between a the source/drain layer and a III-N channel layer. An etch process, e.g., utilizing photochemical oxidation, selectively etches the source/drain layer over the etch stop layer. A gate electrode is disposed over the etch stop layer to form a recessed-gate III-N HEMT. At least a portion of the etch stop layer may be oxidized with a gate electrode over the oxidized etch stop layer for a recessed gate III-N MOS-HEMT including a III-N oxide. A high-k dielectric may be formed over the oxidized etch stop layer with a gate electrode over the high-k dielectric to form a recessed gate III-N MOS-HEMT having a composite gate dielectric stack.

Abstract: Heat-trapping bulk layers or thermal-boundary film stacks are formed between a heat-assisted active layer and an associated electrode to confine such transient heat to the active layer in a heat-assisted device (e.g., certain types of resistance-switching and selector elements used in non-volatile memory. Preferably, the heat-trapping layers or thermal-boundary stacks are electrically conductive while being thermally insulating or reflective. Heat-trapping layers use bulk absorption and re-radiation to trap heat. Materials may include, without limitation, chalcogenides with Group 6 elements. Thermal-boundary stacks use reflection from interfaces to trap heat and may include film layers as thin as 1-5 monolayers. Effectiveness of a thermal-boundary stack depends on the thermal impedance mismatch between layers of the stack, rendering thermally insulating bulk materials optional for thermal-boundary stack components.

Abstract: Perpendicular spin transfer torque memory (STTM) devices with enhanced stability and methods of fabricating perpendicular STTM devices with enhanced stability are described. For example, a material layer stack for a magnetic tunneling junction includes a fixed magnetic layer. A dielectric layer is disposed above the fixed magnetic layer. A free magnetic layer is disposed above the dielectric layer. A conductive oxide material layer is disposed on the free magnetic layer.

Abstract: Conductive oxide random access memory (CORAM) cells and methods of fabricating CORAM cells are described. For example, a material layer stack for a memory element includes a first conductive electrode. An insulating layer is disposed on the first conductive oxide and has an opening with sidewalls therein that exposes a portion of the first conductive electrode. A conductive oxide layer is disposed in the opening, on the first conductive electrode and along the sidewalls of the opening. A second electrode is disposed in the opening, on the conductive oxide layer.

Abstract: Magnetic tunnel junctions (MTJ) suitable for spin transfer torque memory (STTM) devices, include perpendicular magnetic layers and one or more anisotropy enhancing layer(s) separated from a free magnetic layer by a crystallization barrier layer. In embodiments, an anisotropy enhancing layer improves perpendicular orientation of the free magnetic layer while the crystallization barrier improves tunnel magnetoresistance (TMR) ratio with better alignment of crystalline texture of the free magnetic layer with that of a tunneling layer.

Abstract: The present disclosure provides a system and method for forming a resistive random access memory (RRAM) device. A RRAM device consistent with the present disclosure includes a substrate and a first electrode disposed thereon. The RRAM device includes a second electrode disposed over the first electrode and a RRAM dielectric layer disposed between the first electrode and the second electrode. The RRAM dielectric layer has a recess at a top center portion at the interface between the second electrode and the RRAM dielectric layer.

Abstract: Heat-trapping bulk layers or thermal-boundary film stacks are formed between a heat-assisted active layer and an associated electrode to confine such transient heat to the active layer in a heat-assisted device (e.g., certain types of resistance-switching and selector elements used in non-volatile memory. Preferably, the heat-trapping layers or thermal-boundary stacks are electrically conductive while being thermally insulating or reflective. Heat-trapping layers use bulk absorption and re-radiation to trap heat. Materials may include, without limitation, chalcogenides with Group 6 elements. Thermal-boundary stacks use reflection from interfaces to trap heat and may include film layers as thin as 1-5 monolayers. Effectiveness of a thermal-boundary stack depends on the thermal impedance mismatch between layers of the stack, rendering thermally insulating bulk materials optional for thermal-boundary stack components.

Abstract: III-N transistors with recessed gates. An epitaxial stack includes a doped III-N source/drain layer and a III-N etch stop layer disposed between a the source/drain layer and a III-N channel layer. An etch process, e.g., utilizing photochemical oxidation, selectively etches the source/drain layer over the etch stop layer. A gate electrode is disposed over the etch stop layer to form a recessed-gate III-N HEMT. At least a portion of the etch stop layer may be oxidized with a gate electrode over the oxidized etch stop layer for a recessed gate III-N MOS-HEMT including a III-N oxide. A high-k dielectric may be formed over the oxidized etch stop layer with a gate electrode over the high-k dielectric to form a recessed gate III-N MOS-HEMT having a composite gate dielectric stack.

Abstract: An insulating layer is deposited over a transistor structure. The transistor structure comprises a gate electrode over a device layer on a substrate. The transistor structure comprises a first contact region and a second contact region on the device layer at opposite sides of the gate electrode. A trench is formed in the first insulating layer over the first contact region. A metal-insulator phase transition material layer with a S-shaped IV characteristic is deposited in the trench or in the via of the metallization layer above on the source side.

Abstract: Perpendicular spin transfer torque memory (STTM) devices having offset cells and methods of fabricating perpendicular STTM devices having offset cells are described. For example, a spin torque transfer memory (STTM) array includes a first load line disposed above a substrate and having only a first STTM device. The STTM array also includes a second load line disposed above the substrate, adjacent the first load line, and having only a second STTM device, the second STTM device non-co-planar with the first STTM device.

Abstract: Perpendicular spin transfer torque memory (STTM) devices with enhanced stability and methods of fabricating perpendicular STTM devices with enhanced stability are described. For example, a material layer stack for a magnetic tunneling junction includes a fixed magnetic layer. A dielectric layer is disposed above the fixed magnetic layer. A free magnetic layer is disposed above the dielectric layer. A conductive oxide material layer is disposed on the free magnetic layer.

Abstract: A method of patterning a semiconductor film is described. According to an embodiment of the present invention, a hard mask material is formed on a silicon film having a global crystal orientation wherein the semiconductor film has a first crystal plane and second crystal plane, wherein the first crystal plane is denser than the second crystal plane and wherein the hard mask is formed on the second crystal plane. Next, the hard mask and semiconductor film are patterned into a hard mask covered semiconductor structure. The hard mask covered semiconductor structured is then exposed to a wet etch process which has sufficient chemical strength to etch the second crystal plane but insufficient chemical strength to etch the first crystal plane.

Abstract: An insulating layer is deposited over a transistor structure. The transistor structure comprises a gate electrode over a device layer on a substrate. The transistor structure comprises a first contact region and a second contact region on the device layer at opposite sides of the gate electrode. A trench is formed in the first insulating layer over the first contact region. A metal-insulator phase transition material layer with a S-shaped IV characteristic is deposited in the trench or in the via of the metallization layer above on the source side.