Provided are electronic devices and methods of manufacturing the same. An electronic device may include a substrate, a gate electrode on the substrate, a ferroelectric layer between the substrate and the gate electrode, and a carbon layer between the substrate and the ferroelectric layer. The carbon layer may have an sp.sup.2 bonding structure.

A new class of logic gates are presented that use non-linear polar material. The logic gates include multi-input majority gates and threshold gates. Input signals in the form of analog, digital, or combination of them are driven to first terminals of non-ferroelectric capacitors. The second terminals of the non-ferroelectric capacitors are coupled to form a majority node. Majority function of the input signals occurs on this node. The majority node is then coupled to a first terminal of a capacitor comprising non-linear polar material. The second terminal of the capacitor provides the output of the logic gate, which can be driven by any suitable logic gate such as a buffer, inverter, NAND gate, NOR gate, etc. Any suitable logic or analog circuit can drive the output and inputs of the majority logic gate. As such, the majority gate of various embodiments can be combined with existing transistor technologies.

Various embodiments of the present disclosure are directed towards a memory device including a first bottom electrode layer over a substrate. A ferroelectric switching layer is disposed over the first bottom electrode layer. A first top electrode layer is disposed over the ferroelectric switching layer. A second bottom electrode layer is disposed between the first bottom electrode layer and the ferroelectric switching layer. The second bottom electrode layer is less susceptible to oxidation than the first bottom electrode layer.

Some embodiments of a method for manufacturing integrated circuits include the operations of forming a back gate structure on a substrate, forming a memory layer over the back gate structure, forming a buffer layer over the memory layer, forming a conductive channel over the buffer layer, and forming source/drain regions over the conductive channel. In some embodiments, a second buffer layer is formed between the back gate structure and the memory layer.

A semiconductor memory device according to an embodiment includes: a semiconductor layer extending in a first direction; a first gate electrode layer; a first insulating layer between the semiconductor layer and the first gate electrode layer; a second insulating layer between the first insulating layer and the first gate electrode layer, the second insulating layer having a first portion containing a ferroelectric material; and a first layer between the first insulating layer and the second insulating layer, the first layer containing silicon, nitrogen, and fluorine, the first layer having a first region and a second region between the first region and the second insulating layer, the first layer having a second atomic ratio of nitrogen to silicon in the second region higher than a first atomic ratio of nitrogen to silicon in the first region, and the first layer having fluorine concentration higher than the second region.

Aspects of the present inventive concept provide a semiconductor device capable of enhancing performance and reliability through source/drain engineering in a transistor including an oxide semiconductor layer. The semiconductor device includes a substrate, a metal oxide layer disposed on the substrate, a source/drain pattern being in contact with the metal oxide layer and including a portion protruding from a top surface of the metal oxide layer, a plurality of gate structures disposed on the metal oxide layer with the source/drain pattern interposed therebetween and each including gate spacers and an insulating material layer, the insulating material layer being in contact with the metal oxide layer, and not extending along a top surface of the source/drain pattern, and a contact disposed on the source/drain pattern, the contact being connected to the source/drain pattern.

A thin film structure including a dielectric material layer and an electronic device to which the thin film structure is applied are provided. The dielectric material layer includes a compound expressed by ABO.sub.3, wherein at least one of A and B in ABO.sub.3 is substituted and doped with another atom having a larger atom radius, and ABO.sub.3 becomes A.sub.1-xA′.sub.xB.sub.1-yB′.sub.yO.sub.3 (where x>=0, y>=0, at least one of x and y≠0, a dopant A′ has an atom radius greater than A and/or a dopant B′ has an atom radius greater than B) through substitution and doping. A dielectric material property of the dielectric material layer varies according to a type of a substituted and doped dopant and a substitution doping concentration.

A ferroelectric field-effect transistor (FeFET) configured as a multi-bit storage device, the FeFET including: a semiconductor substrate that has a source region in the semiconductor substrate, and a drain region in the semiconductor substrate; a gate stack over the semiconductor substrate, with the source region and the drain region extending to opposite sides of the gate stack, the gate stack including a ferroelectric layer over the semiconductor substrate, and a gate region over the ferroelectric layer. The transistor also includes first and second ends of the ferroelectric layer which are proximal correspondingly to the source and drain regions. The ferroelectric layer includes dipoles. A first set of dipoles at the first end of the ferroelectric layer has a first polarization. A second set of dipoles at the second end of the ferroelectric layer has a second polarization, the second polarization being substantially opposite of the first polarization.

An approach for utilizing an IC (integrated circuit) that is capable of storing multi-bit in storage is disclosed. The approach leverages the use of multiple nanowires structures as channels in a gate of a transistor. The use of multiple nanowires as channels allows for different V.sub.t (i.e., voltage of device) to be dependent on the thickness of the fe (ferroelectric layer) that surrounds each of the nanowire channels. Memory window is about 2d (thickness of a fe layer). Setting voltage is also proportional to the fe layer thickness. The V.sub.t of the device is the superposition of the various fe layers. For example, if there are three channels with three different Fe layer (of varying thickness), then four memory states can be achieved. More states can be achieved based on the number of channels in the device.

A semiconductor integrated circuit device including a substrate with a first element region of a P type and a second element region of an N type, a channel active region that extends in the first element region or the second element region, the channel active region including a plurality of channels, a plurality of gate lines that extend in a second direction intersecting and include a gate metal layer, and a gate insulating film in contact with the gate metal layer, a plurality of first spacers on opposite side portions of respective ones of the gate lines, and a plurality of source/drain regions that are between ones of the plurality of gate lines. The channel active region includes a first channel directly on the substrate, and a second channel spaced apart from the first channel and extends into the gate metal layer.