Artificial synaptic devices with an HfO.sub.2-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 HfO.sub.2-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.

Artificial synaptic devices with an HfO.sub.2-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 HfO.sub.2-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.

One illustrative method disclosed herein includes forming a gate structure above a portion of a fin and performing a first epitaxial growth process to form a silicon-carbide (SiC) semiconductor material above the fin in the source and drain regions of a FinFET device. In this example, the method also includes performing a heating process so as to form a source/drain graphene contact from the silicon-carbide (SiC) semiconductor material in both the source and drain regions of the FinFET device and forming first and second source/drain contact structures that are conductively coupled to the source/drain graphene contact in the source region and the drain region, respectively, of the FinFET device.

One illustrative method disclosed herein includes forming a gate structure above a portion of a fin and performing a first epitaxial growth process to form a silicon-carbide (SiC) semiconductor material above the fin in the source and drain regions of a FinFET device. In this example, the method also includes performing a heating process so as to form a source/drain graphene contact from the silicon-carbide (SiC) semiconductor material in both the source and drain regions of the FinFET device and forming first and second source/drain contact structures that are conductively coupled to the source/drain graphene contact in the source region and the drain region, respectively, of the FinFET device.

An integrated circuit containing an SRAM may be formed using one or more periodic photolithographic patterns for elements of the integrated circuit such as gates and contacts, which have alternating line and space configurations in SRAM cells. Strap rows of the SRAM containing well ties and/or substrate taps which have SRAM cells on two opposite sides are configured so that the alternating line and space configurations are continuous across the regions containing the well ties and substrate taps.

An integrated circuit containing an SRAM may be formed using one or more periodic photolithographic patterns for elements of the integrated circuit such as gates and contacts, which have alternating line and space configurations in SRAM cells. Strap rows of the SRAM containing well ties and/or substrate taps which have SRAM cells on two opposite sides are configured so that the alternating line and space configurations are continuous across the regions containing the well ties and substrate taps.

Devices and structures that include a gate spacer having a gap or void are described along with methods of forming such devices and structures. In accordance with some embodiments, a structure includes a substrate, a gate stack over the substrate, a contact over the substrate, and a spacer disposed laterally between the gate stack and the contact. The spacer includes a first dielectric sidewall portion and a second dielectric sidewall portion. A void is disposed between the first dielectric sidewall portion and the second dielectric sidewall portion.

Devices and structures that include a gate spacer having a gap or void are described along with methods of forming such devices and structures. In accordance with some embodiments, a structure includes a substrate, a gate stack over the substrate, a contact over the substrate, and a spacer disposed laterally between the gate stack and the contact. The spacer includes a first dielectric sidewall portion and a second dielectric sidewall portion. A void is disposed between the first dielectric sidewall portion and the second dielectric sidewall portion.

A technique to additively print onto a dissimilar material, especially ceramics and glasses (e.g., semiconductors, graphite, diamond, other metals) is disclosed herein. The technique enables manufacture of heat removal devices and other deposited structures, especially on heat sensitive substrates. It also enables novel composites through additive manufacturing. The process enables rapid bonding, orders-of-magnitude faster than conventional techniques.

A technique to additively print onto a dissimilar material, especially ceramics and glasses (e.g., semiconductors, graphite, diamond, other metals) is disclosed herein. The technique enables manufacture of heat removal devices and other deposited structures, especially on heat sensitive substrates. It also enables novel composites through additive manufacturing. The process enables rapid bonding, orders-of-magnitude faster than conventional techniques.