A hafnium oxide-based ferroelectric field effect transistor includes a substrate, an isolation region arranged around the substrate; a gate structure including a buffer layer, a floating gate electrode, a hafnium oxide-based ferroelectric film layer, a control gate electrode and a film electrode layer which are sequentially stacked from bottom to top at a middle part of an upper surface of the substrate, a side wall arranged outside the gate structure, a source region and a drain region arranged oppositely at two sides of the gate structure and are formed by extending from an inner side of the isolation region to the middle part of the substrate, a first metal silicide layer formed by extending from the inner side of the isolation region to the side wall, and a second metal silicide layer arranged on an upper surface of the gate structure.

A field effect transistor construction includes a semiconductive channel core. A source/drain region is at opposite ends of the channel core. A gate is proximate a periphery of the channel core. A gate insulator is between the gate and the channel core. The gate insulator has local regions radially there-through that have different capacitance at different circumferential locations relative to the channel core periphery. Additional constructions, and methods, are disclosed.

Provided is a semiconductor device including a substrate, a tunneling insulating film disposed on the substrate, a control gate electrode disposed on the tunneling insulating film, a first floating gate electrode disposed between the control gate electrode and the tunneling insulating film, a second floating gate electrode disposed between the first floating gate electrode and the tunneling insulating film, a first control gate insulating film disposed between the first floating gate electrode and the control gate electrode, a second control gate insulating film disposed between the second floating gate electrode and the first floating gate electrode, and a source electrode and a drain electrode disposed on the substrate to be spaced apart from each other with respect to the control gate electrode, wherein the control gate electrode includes a first metal material, wherein the first floating gate electrode includes a second metal material, wherein the second floating gate electrode includes a third metal material, wherein the first to third metal materials are different from each other, wherein an oxidizing power of the second metal material is smaller than an oxidizing power of the first metal material.

In some implementations, one or more semiconductor processing tools may deposit a first dielectric layer on a substrate of a semiconductor device. The one or more semiconductor processing tools may deposit a floating gate on the first dielectric layer. The one or more semiconductor processing tools may deposit a second dielectric layer on the floating gate and on the substrate of the semiconductor device. The one or more semiconductor processing tools may deposit a first control gate on a first portion of the second dielectric layer. The one or more semiconductor processing tools may deposit a second control gate on a second portion of the second dielectric layer, wherein a third portion of the second dielectric layer is between the first control gate and the floating gate and between the second control gate and the floating gate.

Disclosed are a neuromorphic synapse device having an excellent linearity characteristic, and an operating method thereof. According to an embodiment, a neuromorphic synapse device includes a channel region formed on a substrate, a gate insulating film region formed on the channel region, a floating gate region formed on the gate insulating film region, a charge transfer layer region formed on the floating gate region, and a control gate region, which is formed on the charge transfer layer region and which generates a potential difference with the floating gate region in response to a fact that a potential that is not less than a reference potential is applied, and performs a weight update operation by releasing at least one charge stored in the floating gate region or storing the at least one charge into the floating gate region by using the potential difference.

A field effect transistor construction includes a semiconductive channel core. A source/drain region is at opposite ends of the channel core. A gate is proximate a periphery of the channel core. A gate insulator is between the gate and the channel core. The gate insulator has local regions radially there-through that have different capacitance at different circumferential locations relative to the channel core periphery. Additional constructions, and methods, are disclosed.

A multi-gate transistor includes; a doped drain region; a doped source region; a gate group including a first gate and a second gate; a channel, the doped drain region and the doped source region being on respective two sides of the channel; and an interlayer, formed between the channel and the gate group, wherein a first gate voltage and a second gate voltage are applied to the first gate and the second gate of the gate group, respectively, the channel is induced as at least a P sub-channel and at least an N sub-channel and the multi-gate transistor equivalently behaves as a PNPN structure.

A multi-gate transistor includes: a doped drain region; a doped source region; a gate group including a first gate and a second gate; a channel, the doped drain region and the doped source region being on respective two sides of the channel; and an interlayer, formed between the channel and the gate group, wherein a first gate voltage and a second gate voltage are applied to the first gate and the second gate of the gate group, respectively, the channel is induced as at least a P sub-channel and at least an N sub-channel and the multi-gate transistor equivalently behaves as a PNPN structure.

A field effect transistor construction includes a semiconductive channel core. A source/drain region is at opposite ends of the channel core. A gate is proximate a periphery of the channel core. A gate insulator is between the gate and the channel core. The gate insulator has local regions radially there-through that have different capacitance at different circumferential locations relative to the channel core periphery. Additional constructions, and methods, are disclosed.

Provided are nonvolatile memory devices including 2-dimensional (2D) material and apparatuses including the nonvolatile memory devices. A nonvolatile memory device may include a storage stack including a plurality of charge storage layers between a channel element and a gate electrode facing the channel element. The plurality of charge storage layers may include a 2D material. An interlayer barrier layer may be further provided between the plurality of charge storage layers. The nonvolatile memory device may have a multi-bit or multi-level memory characteristic due to the plurality of charge storage layers.