Abstract: Exemplary embodiments provide for fabricating a nanosheet stack structure having one or more sub-stacks.

Abstract: A finFET device can include a source/drain contact recess having an optimal depth beyond which an incremental decrease in a spreading resistance value for a horizontal portion of a source/drain contact in the recess provided by increased depth may be less than an incremental increase in total resistance due to the increase in the vertical portion of the source/drain contact at the increased depth.

Abstract: A field effect transistor includes a fin having a stack of nanowire-like channel regions including at least first and a second nanowire-like channel regions, source and drain electrodes on opposite sides of the fin, a dielectric separation region including a dielectric material between the first and second nanowire-like channel regions, and a gate stack extending along a pair of sidewalls of the stack of nanowire-like channel regions. The dielectric separation region extending completely from a surface of the second nanowire-like channel region facing the first nanowire-like channel region to a surface of the first nanowire-like channel region facing the second nanowire-like channel region. The gate stack includes a gate dielectric layer and a metal layer on the gate dielectric layer. The metal layer of the gate stack does not extend between the first and second nanowire-like channel regions.

Abstract: A semiconductor integrated circuit including a substrate, a series of metal layers, and a series of insulating layers. The metal layers and the insulating layers are alternately arranged in a stack on the substrate. The semiconductor integrated circuit also includes at least two standard cells in the substrate and at least one power rail crossing over boundaries of the at least two standard cells. The power rail includes a vertical section of conductive material extending continuously through at least two vertical levels of the stack. The two vertical levels of the stack include one metal layer and one insulating layer. The insulating layer is above the metal layer.

Abstract: A semiconductor device includes a series of metal routing layers and a complementary pair of planar field-effect transistors (FETs) on an upper metal routing layer of the metal routing layers. The upper metal routing layer is M3 or higher. Each of the FETs includes a channel region of a crystalline material. The crystalline material may include one or more transition metal dichalcogenide materials such as MoS2, WS2, WSe2, and/or combinations thereof.

Abstract: Multi-Vt horizontal nanosheet devices and a method of making the same. In one embodiment, an integrated circuit includes a plurality of horizontal nanosheet devices (hNS devices) on a top surface of a substrate, the plurality of hNS devices including a first hNS device and a second hNS device spaced apart from each other horizontally. Each of the hNS devices includes a first and a second horizontal nanosheets spaced apart vertically; and a gate stack between the first and second horizontal nanosheets, the gate stack including a work function metal (WFM) layer. A thickness of the first and second horizontal nanosheets of the first hNS device is different from a thickness of the first and second horizontal nanosheets of the second hNS device, and a thickness of the WFM layer of the first hNS device is different from a thickness of the WFM layer of the second hNS device.

Abstract: According to an embodiment of the present invention, a method of manufacturing a FET device having a set BTBT leakage and a maximum VDD includes: determining an x value in InxGa1-xAs according to the BTBT leakage and the maximum VDD, and forming a channel utilizing InxGa1-xA, wherein x is not 0.53.

Abstract: A method of manufacturing a gate-all-around (GAA) nanosheet (NS) field effect transistor (FET) includes forming a stack on a substrate. The stack includes an alternating arrangement of conducting channel layers and non-uniform sacrificial regions. Each of the non-uniform sacrificial regions includes upper, middle, and lower sacrificial layers. The upper and lower sacrificial layers are configured to etch at a first etch rate and the middle sacrificial layer is configured to etch at a second etch rate greater than the first etch rate.

Abstract: A neuromorphic device for the analog computation of a linear combination of input signals, for use, for example, in an artificial neuron. The neuromorphic device provides non-volatile programming of the weights, and fast evaluation and programming, and is suitable for fabrication at high density as part of a plurality of neuromorphic devices. The neuromorphic device is implemented as a vertical stack of flash-like cells with a common control gate contact and individually contacted source-drain (SD) regions. The vertical stacking of the cells enables efficient use of layout resources.

Abstract: A field effect transistor (FET) for an nFET and/or a pFET device including a substrate and a fin including at least one channel region decoupled from the substrate. The FET also includes a source electrode and a drain electrode on opposite sides of the fin, and a gate stack extending along a pair of sidewalls of the channel region of the fin. The gate stack includes a gate dielectric layer and a metal layer on the gate dielectric layer. The FET also includes an oxide separation region separating the channel region of the fin from the substrate. The oxide separation region includes a dielectric material that includes a portion of the gate dielectric layer of the gate stack. The oxide separation region extends completely from a surface of the channel region facing the substrate to a surface of the substrate facing the channel region.

Abstract: A semiconductor device and a method to form the semiconductor device are disclosed. An n-channel component of the semiconductor device includes a first horizontal nanosheet (hNS) stack and a p-channel component includes a second hNS stack. The first hNS stack includes a first gate structure having a plurality of first gate layers and at least one first channel layer. A first internal spacer is disposed between at least one first gate layer and a first source/drain structure in which the first internal spacer has a first length. The second hNS stack includes a second gate structure having a plurality of second gate layers and at least one second channel layer. A second internal spacer is disposed between at least one second gate layer and a second source/drain structure in which the second internal spacer has a second length that is greater than the first length.

Abstract: A semiconductor device includes a series of metal routing layers and a complementary pair of planar field-effect transistors (FETs) on an upper metal routing layer of the metal routing layers. The upper metal routing layer is M3 or higher. Each of the FETs includes a channel region of a crystalline material. The crystalline material may include polycrystalline silicon. The upper metal routing layer M3 or higher may include cobalt.

Abstract: A CMOS circuit includes a partial GAA nFET and a partial GAA pFET. The nFET and the pFET each include a fin including a stack of nanowire-like channel regions and a dielectric separation region extending completely between first and second nanowire-like channel regions of the stack. The nFET and the pFET each also include a source electrode and a drain electrode on opposite sides of the fin, and a gate stack extending along a pair of sidewalls of the stack of nanowire-like channel regions. The gate stack includes a gate dielectric layer and a metal layer on the gate dielectric layer. The metal layer does not extend between the first and second nanowire-like channel regions. The channel heights of the nanowire-like channel regions of the partial GAA nFET and the partial GAA pFET are different.

Abstract: A method of manufacturing a nanosheet or nanowire device from a stack including an alternating arrangement of sacrificial layers and channel layers on a substrate. The method includes deep etching portions of the stack to form electrode recesses for a source electrode and a drain electrode, forming conductive passivation layers in the electrode recesses, and epitaxially growing the source and drain electrodes in the electrode recesses. Each conductive passivation layer extends at least partially along a side of one of the electrode recesses. Portions of the substrate at lower ends of the electrode recesses are uncovered by the conductive passivation layers. The source and drain electrodes are grown from the substrate and the conductive passivation layers substantially inhibit the source and drain electrodes from being grown from the channel layers.

Abstract: A semiconductor device can include a channel region with a first semiconductor material for a majority carrier in the channel region during operation (on state) of the device and a metal contact. A source/drain region can include a semiconductor material alloy including a second semiconductor material and at least one heterojunction located between the metal contact and the channel region, wherein the heterojunction forms a band-edge offset for the majority carrier that is less than or equal to about 0.2 eV.

Abstract: A method to form a nanosheet stack for a semiconductor device includes forming a stack of a plurality of sacrificial layers and at least one channel layer on an underlayer in which a sacrificial layer is in contact with the underlayer, each channel layer being in contact with at least one sacrificial layer, the sacrificial layers are formed from SiGe and the at least one channel layer is formed from Si; forming at least one source/drain trench region in the stack to expose surfaces of the SiGe sacrificial layers and a surface of the at least one Si channel layer; and oxidizing the exposed surfaces of the SiGe sacrificial layers and the exposed surface of the at least one Si layer in an environment of wet oxygen, or ozone and UV.

Abstract: Multi-Vt horizontal nanosheet devices and a method of making the same. In one embodiment, an integrated circuit includes a plurality of horizontal nanosheet devices (hNS devices) on a top surface of a substrate, the plurality of hNS devices including a first hNS device and a second hNS device spaced apart from each other horizontally. Each of the hNS devices includes a first and a second horizontal nanosheets spaced apart vertically; and a gate stack between the first and second horizontal nanosheets, the gate stack including a work function metal (WFM) layer. A thickness of the first and second horizontal nanosheets of the first hNS device is different from a thickness of the first and second horizontal nanosheets of the second hNS device, and a thickness of the WFM layer of the first hNS device is different from a thickness of the WFM layer of the second hNS device.

Abstract: A metal oxide semiconductor field effect transistor (MOSFET) includes a substrate having a source region, a drain region, and a channel region between the source region and the drain region, the substrate having an epitaxial III-V material that includes three elements thereon, a source electrode over the source region, a drain electrode over the drain region, and a crystalline oxide layer including an oxide formed on the epitaxial III-V material in the channel region, the epitaxial III-V material including three elements.

Abstract: A method for fabricating a fin field effect transistor (finFET) device with a strained channel. During fabrication, after the fin is formed, a dummy gate is deposited on the fin, and processed, e.g., by plasma doping and annealing, to cause stress in the dummy gate. Deep source drain (SD) recesses are formed, resulting in strain in the channel, and SD structures are formed to anchor the ends of the fin. The dummy gate is then removed.

Abstract: A method for fabricating a fin field effect transistor (finFET) device with a strained channel. During fabrication, after the fin is formed, a sacrificial epitaxial gate stressor is deposited on the fin, causing strain in the fin. SD structures are then formed to anchor the ends of the fin, and the sacrificial epitaxial gate stressor is removed.