摘要:
A transistor is provided that comprises a source region overlying a base structure, a drain region overlying the base structure, and a block of semiconducting material overlying the base structure and being disposed between the source region and the drain region. The block of semiconducting material comprises a gate controlled region adjacent the source region, and a drain access region disposed between the gate controlled region and the drain region. The drain access region is formed of a plurality of semiconducting material ridges spaced apart from one another by non-channel trench openings, wherein at least a portion of the non-channel trench openings being filled with a doped material to provide a depletion region to improve breakdown voltage of the transistor.
摘要:
One example includes a semiconductor device. The semiconductor device include a carbon nanotube substrate, a self-assembled monolayer, and a gate oxide. The self-assembled monolayer overlies the carbon nanotube substrate and is comprised of molecules each including a tail group, a carbon backbone, and a head group. The gate oxide overlies the self-assembled monolayer, wherein the self-assembled monolayer forms an interface between the carbon nanotube substrate and the gate oxide.
摘要:
A transistor is provided that comprises a source region overlying a base structure, a drain region overlying the base structure, and a block of semiconducting material overlying the base structure and being disposed between the source region and the drain region. The block of semiconducting material comprises a gate controlled region adjacent the source region, and a drain access region disposed between the gate controlled region and the drain region. The drain access region is formed of a plurality of semiconducting material ridges spaced apart from one another by non-channel trench openings, wherein at least a portion of the non-channel trench openings being filled with a doped material to provide a depletion region to improve breakdown voltage of the transistor.
摘要:
One example includes a semiconductor device. The semiconductor device include a carbon nanotube substrate, a self-assembled monolayer, and a gate oxide. The self-assembled monolayer overlies the carbon nanotube substrate and is comprised of molecules each including a tail group, a carbon backbone, and a head group. The gate oxide overlies the self-assembled monolayer, wherein the self-assembled monolayer forms an interface between the carbon nanotube substrate and the gate oxide.
摘要:
A method of forming a superconductor device is provided. The method includes depositing a non-oxide based dielectric layer over a substrate, depositing a photoresist material layer over the non-oxide based dielectric layer, irradiating and developing the photoresist material layer to form a via pattern in the photoresist material layer, and etching the non-oxide based dielectric layer to form openings in the non-oxide based dielectric layer based on the via pattern. The method further comprises stripping the photoresist material layer, and filling the openings in the non-oxide based dielectric with a superconducting material to form a set of superconducting contacts.
摘要:
A silicon nitride spacer material for use in forming a PFET device and a method for making the spacer includes the use of a dual-frequency plasma enhanced CVD process wherein the temperature is in the range depositing a silicon nitride layer by means of a low-temperature dual-frequency plasma enhanced CVD process, at a temperature in the range 400° C. to 550° C. The process pressure is in the range 2 Torr to 5 Torr. The low frequency power is in the range 0 W to 50 W, and the high frequency power is in the range 90 W to 110 W. The precursor gases of silane, ammonia and nitrogen flow at flow rates in the ratio 240:3200:4000 sccm. The use of the silicon nitride spacer of the invention to form a PFET device having a dual spacer results in a 10%–15% performance improvement compared to a similar PFET device having a silicon nitride spacer formed by a RTCVD process.
摘要:
A method is provided of forming a superconductor device interconnect structure. The method comprises forming a first dielectric layer overlying a substrate and forming a superconducting interconnect element in the first dielectric layer. The superconducting interconnect element includes a top surface aligned with a top surface of the first dielectric layer to form a first interconnect layer. The superconductor device interconnect structure is moved into a dielectric deposition chamber. The method further comprises performing a cleaning process on a top surface of the first interconnect layer in the dielectric deposition chamber to remove oxidization from a top surface of the first interconnect layer, and depositing a second dielectric layer over the first interconnect layer in the dielectric deposition chamber.
摘要:
One example includes a semiconductor device. The semiconductor device include a carbon nanotube substrate, a self-assembled monolayer, and a gate oxide. The self-assembled monolayer overlies the carbon nanotube substrate and is comprised of molecules each including a tail group, a carbon backbone, and a head group. The gate oxide overlies the self-assembled monolayer, wherein the self-assembled monolayer forms an interface between the carbon nanotube substrate and the gate oxide.
摘要:
A method of forming a superconductor device is provided. The method includes depositing a non-oxide based dielectric layer over a substrate, depositing a photoresist material layer over the non-oxide based dielectric layer, irradiating and developing the photoresist material layer to form a via pattern in the photoresist material layer, and etching the non-oxide based dielectric layer to form openings in the non-oxide based dielectric layer based on the via pattern. The method further comprises stripping the photoresist material layer, and filling the openings in the non-oxide based dielectric with a superconducting material to form a set of superconducting contacts.
摘要:
A back-end-of-line (BEOL) interconnect structure and a method of forming an interconnect structure. The interconnect structure comprises a conductor, such as copper, embedded in a dielectric layer, and a low-k dielectric capping layer, which acts as a diffusion barrier, on the conductor. A method of forming the BEOL interconnect structure is disclosed, where the capping layer is deposited using plasma-enhanced chemical vapor deposition (PECVD) and is comprised of Si, C, H, and N. The interconnect structure provides improved oxygen diffusion resistance and improved barrier qualities allowing for a reduction in film thickness.