An integrated circuit includes a substrate and at least one component unfavorably sensitive to compressive stress which is arranged at least partially within an active region of the substrate limited by an insulating region. To address compressive stress in the active region, the circuit further includes at least one electrically inactive trench located at least in the insulating region and containing an internal area configured to reduce compressive stress in the active region. The internal area is filled with polysilicon. The polysilicon filled trench may further extend through the insulating region and into the substrate.

Provided is a memory device including an array of memory cells. A first bit-line coupled to memory cells of a first column of the array of memory cells. The first bit-line is disposed on a first metal layer. A second bit-line is coupled to the first bit-line. The second bit-line is disposed on a second metal layer and coupled to the first bit-line by at least one via. A word line is coupled to a row of the array of memory cells.

A field effect transistor having a higher breakdown voltage can be provided by forming a contiguous dielectric material layer over gate stacks, forming via cavities laterally spaced from the gate stacks, selectively depositing a single crystalline semiconductor material, and converting upper portions of the deposited single crystalline semiconductor material into elevated source/drain regions. Lower portions of the selectively deposited single crystalline semiconductor material in the via cavities can have a doping of a lesser concentration, thereby effectively increasing the distance between two steep junctions at edges of a source region and a drain region. Optionally, embedded active regions for additional devices can be formed prior to formation of the contiguous dielectric material layer. Raised active regions contacting a top surface of a substrate can be formed simultaneously with formation of the elevated active regions that are vertically spaced from the top surface.

Integrated circuits described herein implement an x-input logic gate. The integrated circuit includes a plurality of Schottky diodes that includes x Schottky diodes and a plurality of source-follower transistors that includes x source-follower transistors. Each respective source-follower transistor of the plurality of source-follower transistors includes a respective gate node that is coupled to a respective Schottky diode. A first source-follower transistor of the plurality of source-follower transistors is connected serially to a second source-follower transistor of the plurality of source-follower transistors.

This application is directed to a low cost IC solution that provides Super CMOS microelectronics macros. Hereinafter, SCMOS refers to Super CMOS and Schottky CMOS. SCMOS device solutions includes a niche circuit element, such as complementary low threshold Schottky barrier diode pairs (SBD) made by selected metal barrier contacts (Co, Ti, Ni or other metal atoms or compounds) to P- and N- Si beds of the CMOS transistors. A DTL like new circuit topology and designed wide contents of broad product libraries, which used the integrated SBD and transistors (BJT, CMOS, and Flash versions) as basic components. The macros are composed of diodes that are selectively attached to the diffusion bed of the transistors, configuring them to form (i) generic logic gates, (ii) functional blocks of microprocessors and microcontrollers such as but not limited to data paths, multipliers, muliplier-accumaltors, (ii) memory cells and control circuits of various types (SRAM's with single or multiple read/write port(s), binary and ternary CAM's), (iii) multiplexers, crossbar switches, switch matrices in network processors, graphics processors and other processors to implement a variety of communication protocols and algorithms of data processing engines for (iv) Analytics, (v) block-chain and encryption-based security engines (vi) Artificial Neural Networks with specific circuits to emulate or to implement a self-learning data processor similar to or derived from the neurons and synapses of human or animal brains, (vii) analog circuits and functional blocks from simple to the complicated including but not limited to power conversion, control and management either based on charge pumps or inductors, sensor signal amplifiers and conditioners, interface drivers, wireline data transceivers, oscillators and clock synthesizers with phase and/or delay locked loops, temperature monitors and controllers; all the above are built from discrete components to all grades of VLSI chips. Solar photovoltaic electricity conversion, bio-lab-on-a-chip, hyperspectral imaging (capture/sensing and processing), wireless communication with various transceiver and/or transponder circuits for ranges of frequency that extend beyond a few 100 MHz, up to multi-THz, ambient energy harvesting either mechanical vibrations or antenna-based electromagnetic are newly extended or nacent fields of the SCMOS IC applications.

This application is directed to a low cost IC solution that provides Super CMOS microelectronics macros. Hereinafter, SCMOS refers to Super CMOS and Schottky CMOS. SCMOS device solutions includes a niche circuit element, such as complementary low threshold Schottky barrier diode pairs (SBD) made by selected metal barrier contacts (Co, Ti, Ni or other metal atoms or compounds) to P- and N-Si beds of the CMOS transistors. A DTL like new circuit topology and designed wide contents of broad product libraries, which used the integrated SBD and transistors (BJT, CMOS, and Flash versions) as basic components. The macros are composed of diodes that are selectively attached to the diffusion bed of the transistors, configuring them to form (i) generic logic gates, (ii) functional blocks of microprocessors and microcontrollers such as but not limited to data paths, multipliers, muliplier-accumaltors, (ii) memory cells and control circuits of various types (SRAM's with single or multiple read/write port(s), binary and ternary CAM's), (iii) multiplexers, crossbar switches, switch matrices in network processors, graphics processors and other processors to implement a variety of communication protocols and algorithms of data processing engines for (iv) Analytics, (v) block-chain and encryption-based security engines (vi) Artificial Neural Networks with specific circuits to emulate or to implement a self-learning data processor similar to or derived from the neurons and synapses of human or animal brains, (vii) analog circuits and functional blocks from simple to the complicated including but not limited to power conversion, control and management either based on charge pumps or inductors, sensor signal amplifiers and conditioners, interface drivers, wireline data transceivers, oscillators and clock synthesizers with phase and/or delay locked loops, temperature monitors and controllers; all the above are built from discrete components to all grades of VLSI chips. Solar photovoltaic electricity conversion, bio-lab-on-a-chip, hyperspectral imaging (capture/sensing and processing), wireless communication with various transceiver and/or transponder circuits for ranges of frequency that extend beyond a few 100 MHz, up to multi-THz, ambient energy harvesting either mechanical vibrations or antenna-based electromagnetic are newly extended or nacent fields of the SCMOS IC applications.

A wide trench having a width W1 and narrow trenches having a width W2 that is less than W1 are formed in a dielectric layer, the wide trench extending deeper in outer regions than in a central region. A trench modification step changes the width of the wide trench and reduces a depth difference between the outer regions and the central region of the wide trench.

A wide trench having a width W1 and narrow trenches having a width W2 that is less than W1 are formed in a dielectric layer, the wide trench extending deeper in outer regions than in a central region. A trench modification step changes the width of the wide trench and reduces a depth difference between the outer regions and the central region of the wide trench.

A pillar-shaped semiconductor memory device includes a silicon pillar, and a tunnel insulating layer, a data charge storage insulating layer, a first interlayer insulating layer, and a first conductor layer, which surround an outer periphery of the silicon pillar in that order, and a second interlayer insulating layer that is in contact with an upper surface or a lower surface of the first conductor layer. A side surface of the second interlayer insulating layer facing a side surface of the first interlayer insulating layer is separated from the side surface of the first interlayer insulating layer with a distance therebetween, the distance being larger than a distance from the side surface of the first interlayer insulating layer to a side surface of the first conductor layer facing the side surface of the first interlayer insulating layer.

An anti-fuse memory cell is provided. The anti-fuse memory cell includes a programmable transistor and a selection transistor. The programmable transistor includes a gate structure, a first doped region and a lightly doped region. The first doped region is divided into a first portion doped region, a second portion doped region and a third portion doped region. The first and second portion doped regions are respectively a source and a drain of the programmable transistor, and the third portion doped region is disposed between the first and second portion doped regions. The lightly doped region is distributed around a channel region of the programmable transistor, and adjacent to the first, second and third portion doped regions. The selection transistor includes a gate structure and a second doped region, and connected in series to the programmable transistor through the first portion doped region.