Abstract: A semiconductor device including pairs of multiple threshold voltage (Vt) devices includes at least a first region corresponding to a first pair of Vt devices, a second region corresponding to a second pair of Vt devices including a first dipole layer, and a third region corresponding to a third pair of Vt devices including a second dipole layer different from the first dipole layer.

Abstract: A process for preparing D-glucaro-6,3-lactone from a salt of D-glucaric acid is provided. The process includes: adding a mineral acid to a pre-cooled solution including a salt of D-glucaric acid, water, and acetone to obtain a crude mixture; allowing the crude mixture to rise to a temperature in a range of ?15° C. to ?35° C. and stirring the crude mixture; filtrating the crude mixture and washing with an acetone and water solvent mixture to obtain a filtrate; concentrating the filtrate under vacuum pressure to obtain a concentrated filtrate having a water content in a range of ?20.0 wt. % to ?40.0 wt. %, relative to an overall weight of the concentrated filtrate; storing the concentrated filtrate at a temperature in a range of ?0° C. to ?5° C., and optionally repeating the concentrating and storing steps to obtain a precipitate comprising D-glucaro-6,3-lactone.

Abstract: A conformal disposable absorber is disclosed which is capable of providing efficient heat transfer to an embedded memory device during a localized absorber anneal, without adversary impacting the back-end-of-the-line (BEOL) structure. The disposable absorber is composed of an amorphous carbonitride material that can be designed to have a low reflection coefficient for laser/flash illumination, and a high extinction coefficient for efficient laser/flash illumination absorption. The disposable absorber is formed at a temperature of 400° C. or less.

Abstract: A method for fabricating a semiconductor device including multiple pairs of threshold voltage (Vt) devices includes forming a stack on a base structure having a first region corresponding to a first pair of Vt devices, a second region corresponding to a second pair of Vt devices and a third region corresponding to a third pair of Vt devices. The stack includes a first dipole layer, a first sacrificial layer formed on the first dipole layer, a second sacrificial layer formed on the first sacrificial layer, and a third sacrificial layer formed on the second sacrificial layer. The method further includes forming a second dipole layer different from the first dipole layer.

Abstract: Methods are provided to form pure silicon oxide layers on silicon-germanium (SiGe) layers, as well as an FET device having a pure silicon oxide interfacial layer of a metal gate structure formed on a SiGe channel layer of the FET device. For example, a method comprises growing a first silicon oxide layer on a surface of a SiGe layer using a first oxynitridation process, wherein the first silicon oxide layer comprises nitrogen. The first silicon oxide layer is removed, and a second silicon oxide layer is grown on the surface of the SiGe layer using a second oxynitridation process, which is substantially the same as the first oxynitridation process, wherein the second silicon oxide layer is substantially devoid of germanium oxide and nitrogen. For example, the first silicon oxide layer comprises a SiON layer and the second silicon oxide layer comprises a pure silicon dioxide layer.

Abstract: A private key of a public-private key pair with a corresponding identity is written to an integrated circuit including a processor, a non-volatile memory, and a cryptographic engine coupled to the processor and the non-volatile memory. The private key is written to the non-volatile memory. The integrated circuit is implemented in complementary metal-oxide semiconductor 14 nm or smaller technology. The integrated circuit is permanently modified, subsequent to the writing, such that further writing to the non-volatile memory is disabled and such that the private key can be read only by the cryptographic engine and not off-chip. Corresponding integrated circuits and wafers are also disclosed.

Abstract: A method for converting a dielectric material including a type IV transition metal into a crystalline material that includes forming a predominantly non-crystalline dielectric material including the type IV transition metal on a supporting substrate as a component of an electrical device having a scale of microscale or less; and converting the predominantly non-crystalline dielectric material including the type IV transition metal to a crystalline crystal structure by exposure to energy for durations of less than 100 milliseconds and, in some instances, less than 10 microseconds. The resultant material is fully or partially crystallized and contains a metastable ferroelectric phase such as the polar orthorhombic phase of space group Pca21 or Pmn21. During the conversion to the crystalline crystal structure, adjacently positioned components of the electrical devices are not damaged.

Abstract: A semiconductor device including pairs of multiple threshold voltage (Vt) devices includes at least a first region corresponding to a first pair of Vt devices, a second region corresponding to a second pair of Vt devices including a first dipole layer, and a third region corresponding to a third pair of Vt devices including a second dipole layer different from the first dipole layer.

Abstract: A conformal disposable absorber is disclosed which is capable of providing efficient heat transfer to an embedded memory device during a localized absorber anneal, without adversary impacting the back-end-of-the-line (BEOL) structure. The disposable absorber is composed of an amorphous carbonitride material that can be designed to have a low reflection coefficient for laser/flash illumination, and a high extinction coefficient for efficient laser/flash illumination absorption. The disposable absorber is formed at a temperature of 400° C. or less.

Abstract: A private key of a public-private key pair with a corresponding identity is written to an integrated circuit including a processor, a non-volatile memory, and a cryptographic engine coupled to the processor and the non-volatile memory. The private key is written to the non-volatile memory. The integrated circuit is implemented in complementary metal-oxide semiconductor 14 nm or smaller technology. The integrated circuit is permanently modified, subsequent to the writing, such that further writing to the non-volatile memory is disabled and such that the private key can be read only by the cryptographic engine and not off-chip. Corresponding integrated circuits and wafers are also disclosed.

Abstract: A gate structure for effective work function adjustments of semiconductor devices that includes a gate dielectric on a channel region of a semiconductor device; a first metal nitride in direct contact with the gate dielectric; a conformal carbide of Aluminum material layer having an aluminum content greater than 30 atomic wt. %; and a second metal nitride layer in direct contact with the conformal aluminum (Al) and carbon (C) containing material layer. The conformal carbide of aluminum (Al) layer includes aluminum carbide, or Al4C3, yielding an aluminum (Al) content up to 57 atomic % (at. %) and work function setting from 3.9 eV to 5.0 eV at thicknesses below 25 ?. Such structures can present metal gate length scaling and resistance benefit below 25 nm compared to state of the art work function electrodes.

Abstract: Methods are provided to form pure silicon oxide layers on silicon-germanium (SiGe) layers, as well as an FET device having a pure silicon oxide interfacial layer of a metal gate structure formed on a SiGe channel layer of the FET device. For example, a method comprises growing a first silicon oxide layer on a surface of a SiGe layer using a first oxynitridation process, wherein the first silicon oxide layer comprises nitrogen. The first silicon oxide layer is removed, and a second silicon oxide layer is grown on the surface of the SiGe layer using a second oxynitridation process, which is substantially the same as the first oxynitridation process, wherein the second silicon oxide layer is substantially devoid of germanium oxide and nitrogen. For example, the first silicon oxide layer comprises a SiON layer and the second silicon oxide layer comprises a pure silicon dioxide layer.

Abstract: Semiconductor devices and methods of forming the same include forming a first channel region on a first semiconductor region. A second channel region is formed on a second semiconductor region. The second semiconductor region is formed from a semiconductor material that is different from a semiconductor material of the first semiconductor region. A semiconductor cap is formed on one or more of the first and second channel regions. A gate dielectric layer is formed over the nitrogen-containing layer. A gate is formed on the gate dielectric.

Abstract: A semiconductor device including pairs of multiple threshold voltage (Vt) devices includes at least a first region corresponding to a first pair of Vt devices, a second region corresponding to a second pair of Vt devices including a first dipole layer, and a third region corresponding to a third pair of Vt devices including a second dipole layer different from the first dipole layer.

Abstract: Methods are provided to form pure silicon oxide layers on silicon-germanium (SiGe) layers, as well as an FET device having a pure silicon oxide interfacial layer of a metal gate structure formed on a SiGe channel layer of the FET device. For example, a method comprises growing a first silicon oxide layer on a surface of a SiGe layer using a first oxynitridation process, wherein the first silicon oxide layer comprises nitrogen. The first silicon oxide layer is removed, and a second silicon oxide layer is grown on the surface of the SiGe layer using a second oxynitridation process, which is substantially the same as the first oxynitridation process, wherein the second silicon oxide layer is substantially devoid of germanium oxide and nitrogen. For example, the first silicon oxide layer comprises a SiON layer and the second silicon oxide layer comprises a pure silicon dioxide layer.

Abstract: Artificial synaptic devices with an HfO2-based ferroelectric layer that can be implemented in the CMOS back-end are provided. In one aspect, an artificial synapse element is provided. The artificial synapse element includes: a bottom electrode; a ferroelectric layer disposed on the bottom electrode, wherein the ferroelectric layer includes an HfO2-based material that crystallizes in a ferroelectric phase at a temperature of less than or equal to about 400° C.; and a top electrode disposed on the bottom electrode. An artificial synaptic device including the present artificial synapse element and methods for formation thereof are also provided.

Abstract: A private key of a public-private key pair with a corresponding identity is written to an integrated circuit including a processor, a non-volatile memory, and a cryptographic engine coupled to the processor and the non-volatile memory. The private key is written to the non-volatile memory. The integrated circuit is implemented in complementary metal-oxide semiconductor 14 nm or smaller technology. The integrated circuit is permanently modified, subsequent to the writing, such that further writing to the non-volatile memory is disabled and such that the private key can be read only by the cryptographic engine and not off-chip. Corresponding integrated circuits and wafers are also disclosed.

Abstract: A method of fabricating a semiconductor structure having multiple defined threshold voltages includes: forming multiple field-effect transistor (FET) devices in the semiconductor structure, each of the FET devices including a channel and a gate stack formed of one of at least two different work function metals, the gate stack being formed proximate the channel; and varying a band-gap of the channel in each of at least a subset of the FET devices by controlling a percentage of one or more compositions of a material forming the channel; wherein a threshold voltage of each of the FET devices is configured as a function of a type of work function metal forming the gate stack and the percentage of one or more compositions of the material forming the channel.

Abstract: A method of fabricating a semiconductor structure having multiple defined threshold voltages includes: forming multiple field-effect transistor (FET) devices in the semiconductor structure, each of the FET devices including a channel and a gate stack formed of one of at least two different work function metals, the gate stack being formed proximate the channel; and varying a band-gap of the channel in each of at least a subset of the FET devices by controlling a percentage of one or more compositions of a material forming the channel; wherein a threshold voltage of each of the FET devices is configured as a function of a type of work function metal forming the gate stack and the percentage of one or more compositions of the material forming the channel.

Abstract: Semiconductor devices and methods of making the same include forming a first channel region on a first semiconductor region. A second channel region is formed on a second semiconductor region, the second semiconductor region being formed from a semiconductor material that is different from a semiconductor material of the first semiconductor region. A nitrogen-containing layer is formed on one or more of the first and second channel regions. A gate dielectric layer is formed over the nitrogen-containing layer. A gate is formed on the gate dielectric.