Abstract: In a particular embodiment, a method includes forming a second hardmask layer adjacent to a first sidewall structure and adjacent to a mandrel of a semiconductor device. A top portion of the mandrel is exposed prior to formation of the second hardmask layer. The method further includes removing the first sidewall structure to expose a first portion of a first hardmask layer. The method also includes etching the first portion of the first hardmask layer to expose a second portion of a dielectric material. The method also includes etching the second portion of the dielectric material to form a first trench. The method also includes forming a first metal structure within the first trench.

Abstract: An apparatus includes a first read port, a second read port, a write port, and at least one storage latch. A width of a bit cell that includes the first read port, the second read port, and the write port is greater than twice a contacted poly pitch (CPP) associated with the bit cell. For example, a bit cell may be a 3-port static random access memory (SRAM) bit cell that is compatible with self-aligned double patterning (SADP) processes and that can be manufactured using semiconductor manufacturing processes of less than 14 nanometers (nm).

Abstract: An apparatus includes a first metal layer coupled to a bit cell. The apparatus also includes a third metal layer including a write word line that is coupled to the bit cell. The apparatus further includes a second metal layer between the first metal layer and the third metal layer. The second metal layer includes two read word lines coupled to the bit cell.

Abstract: An apparatus includes a multiple time programmable (MTP) memory device. The MTP memory device includes a metal gate, a substrate material, and an oxide structure between the metal gate and the substrate material. The oxide structure includes a hafnium oxide layer and a silicon dioxide layer. The hafnium oxide layer is in contact with the metal gate and in contact with the silicon dioxide layer. The silicon dioxide layer is in contact with the substrate material. The MTP device includes a transistor, and a non-volatile state of the MTP memory device is based on a threshold voltage of the transistor.

Abstract: Methods of fabricating middle of line (MOL) layers and devices including MOL layers. A method in accordance with an aspect of the present disclosure includes depositing a hard mask across active contacts to terminals of semiconductor devices of a semiconductor substrate. Such a method also includes patterning the hard mask to selectively expose some of the active contacts and selectively insulate some of the active contacts. The method also includes depositing a conductive material on the patterned hard mask and the exposed active contacts to couple the exposed active contacts to each other over an active area of the semiconductor devices.

Abstract: One feature pertains to an integrated circuit, comprising an access transistor and an antifuse. The access transistor includes at least one source/drain region, and the antifuse has a conductor-insulator-conductor structure. The antifuse includes a first conductor that acts as a first electrode, and also includes an antifuse dielectric, and a second conductor. A first surface of the first electrode is coupled to a first surface of the antifuse dielectric, a second surface of the antifuse dielectric is coupled to a first surface of the second conductor. The second conductor is electrically coupled to the access transistor's source/drain region. The antifuse is adapted to transition from an open circuit state to a closed circuit state if a programming voltage Vpp greater than or equal to an antifuse dielectric breakdown voltage is applied between the first electrode and the second conductor.

Abstract: Provided are methods and apparatus for enabling selective push processing during design and fabrication of an integrated circuit to improve performance of selected circuits of the integrated circuit. An exemplary method includes identifying a critical portion of an integrated circuit layout that defines a functional element having a critical operating frequency requirement and designing a subcircuit in the critical portion to enable performing a speed push process to increase performance of the subcircuit. The method can also include identifying at least one of a power supply node, a clock supply node, and an interface node at a boundary between the critical portion and a portion of the integrated circuit that is outside of the critical portion. The critical portion can be designed with a power domain that is independent of the portion of the integrated circuit that is outside of the critical portion.

Abstract: An OTP memory array includes a plurality of differential P-channel metal oxide semiconductor (PMOS) OTP memory cells programmable and readable in predetermined states of program and read operations, and is capable of providing sufficient margins against global process variations and temperature variations while being compatible with standard logic fin-shaped field effect transistor (FinFET) processes to obviate the need for additional masks and costs associated with additional masks.

Abstract: A method of forming fins of different materials includes providing a substrate with a layer of a first material having a top surface, masking a first portion of the substrate leaving a second portion of the substrate exposed, etching a first opening at the second portion, forming a body of a second material in the opening to a level of the top surface of the layer of the first material, removing the mask, and forming fins of the first material at the first portion and forming fins of the second material at the second portion. A finFET device having fins formed of at least two different materials is also disclosed.

Abstract: A device capacitor structure within middle of line (MOL) layers includes a first MOL interconnect layer. The first MOL interconnect layer may include active contacts between a set of dummy gate contacts on an active surface of a semiconductor substrate. The device capacitor structure also includes a second MOL interconnect layer. The second MOL interconnect layer may include a set of stacked contacts directly on exposed ones of the active contacts. The second MOL interconnect layer may also include a set of fly-over contacts on portions of an etch-stop layer on some of the active contacts. The fly-over contacts and the stacked contacts may provide terminals of a set of device capacitors.

Abstract: A device includes a static random access memory (SRAM) cell and a read buffer coupled to an output of the SRAM cell. The read buffer includes an inverter and a switch. An input of the inverter is responsive to the output of the SRAM cell. A control terminal of the switch is responsive to an output of the inverter.

Abstract: An advanced metal-nitride-oxide-silicon (MNOS) multiple time programmable (MTP) memory is provided. In an example, an apparatus includes a two field effect transistor (2T field FET) metal-nitride-oxide-silicon (MNOS) MTP memory. The 2T field FET MNOS MTP memory can include an interlayer dielectric (ILD) oxide region that is formed on a well and separates respective gates of first and second transistors from the well. A control gate is located between the respective gates of the first and second transistors, and a silicon-nitride-oxide (SiN) region is located between a metal portion of the control gate and a portion of the ILD oxide region.

Abstract: An apparatus includes an array of bit cells that include a first row of bit cells and a second row of bit cells. The apparatus also includes a first global read word line configured to be selectively coupled to the first row of bit cells and to the second row of bit cells. The apparatus further includes a second global read word line configured to be selectively coupled to the first row of bit cells and to the second row of bit cells. The apparatus also includes a global write word line configured to be selectively coupled to the first row of bit cells and to the second row of bit cells. The first global read word line, the second global read word line, and the global write word line are located in a common metal layer.

Abstract: A volatile and one-time program (OTP) compatible asymmetric memory cell may include a first pull-up transistor having a first threshold voltage. The asymmetric memory cell may also include a second pull-up transistor having a second threshold voltage that differs from the first threshold voltage. The asymmetric memory cell may further include a switch coupled to a well of the first pull-up transistor and the second pull-up transistor to alternate between a program voltage (Vpg) and a power supply voltage. The asymmetric memory cell may also include a peripheral switching circuit to control programming of the asymmetric memory cell.

Abstract: An OTP memory array includes a plurality of differential P-channel metal oxide semiconductor (PMOS) OTP memory cells programmable and readable in predetermined states of program and read operations, and is capable of providing sufficient margins against global process variations and temperature variations while being compatible with standard logic fin-shaped field effect transistor (FinFET) processes to obviate the need for additional masks and costs associated with additional masks.

Abstract: A semiconductor device for a one-time programmable (OTP) memory according to some examples of the disclosure includes a gate, a dielectric region below the gate, a source terminal below the dielectric region and offset to one side, a drain terminal below the dielectric region and offset to an opposite side from the source terminal, a drain side charge trap in the dielectric region capable of programming the semiconductor device, and a source side charge trap in the dielectric region opposite the drain side charge trap and capable of programming the semiconductor device.

Abstract: A method of operation of a static random access memory (SRAM) storage element includes programming a value to the SRAM storage element prior to a power-down event. The method further includes, in response to a power-on event at the SRAM storage element after the power-down event, increasing a supply voltage of the SRAM storage element and sensing a state of the SRAM storage element to determine the value programmed to the SRAM storage element prior to the power-down event. In a particular example, an apparatus includes the SRAM storage element and control circuitry coupled to the SRAM storage element. The control circuitry may be configured to program the value to the SRAM storage element, to increase the supply voltage, and to sense the state of the SRAM storage element to determine the value programmed to the SRAM storage element prior to the power-down event.

Abstract: An apparatus includes a static random-access memory and circuitry configured to initiate a corrective action associated with the static random-access memory. The corrective action may be initiated based on a number of static random-access memory cells that have a particular state responsive to a power-up of the static random-access memory.

Abstract: Aspects disclosed include static random access memory (SRAM) arrays having substantially constant operational yields across multiple modes of operation. In one aspect, a method of designing SRAM arrays with multiple modes operation is provided. The method includes determining performance characteristics associated with each mode of operation. SRAM bit cells configured to operate in each mode of operation are provided to the SRAM array. SRAM bit cells are biased to operate in a mode of operation using dynamic adaptive assist techniques, wherein the SRAM bit cells achieve a substantially constant operational yield across the modes. The SRAM bit cells have a corresponding type, wherein the number of SRAM bit cell types in the method is less than the number of modes of operation. Thus, each SRAM array may achieve a particular mode of operation without requiring a separate SRAM bit cell type for each mode, thereby reducing costs.

Abstract: Systems and methods are directed to an integrated circuit comprising a reduced height M1 metal line formed of an exemplary material with lower mean free path than Copper, for local routing of on-chip circuit elements of the integrated circuit, wherein the height of the reduced height M1 metal line is lower than a minimum allowed or allowable height of a conventional M1 metal line formed of Copper. The exemplary materials for forming the reduced height M1 metal line include Tungsten (W), Molybdenum (Mo), and Ruthenium (Ru), wherein these exemplary materials also exhibit lower capacitance and lower RC delays than Copper, while providing high electromigration reliability.