Abstract: A thin film transistor may be manufactured by forming a gate electrode in an insulating layer over a substrate, forming a gate dielectric over the gate electrode and the insulating layer, forming an active layer over the gate electrode, and forming a source electrode and a drain electrode contacting a respective portion of a top surface of the active layer. A surface oxygen concentration may be increased in at least one of the gate dielectric and the active layer by introducing oxygen atoms into a surface region of a respective one of the gate dielectric and the active layer.

Abstract: A method for forming a memory device includes: forming a first layer stack and a second layer stack successively over a substrate, wherein each of the first and the second layer stacks comprises a dielectric layer, a channel layer, and a source/drain layer formed successively over the substrate; forming openings that extends through the first layer stack and the second layer stack, where the openings includes first openings within boundaries of the first and the second layer stacks, and a second opening extending from a sidewall of the second layer stack toward the first openings; forming inner spacers by replacing portions of the source/drain layer exposed by the openings with a dielectric material; lining sidewalls of the openings with a ferroelectric material; and forming first gate electrodes in the first openings and a dummy gate electrode in the second opening by filling the openings with an electrically conductive material.

Abstract: In a method for forming an integrated semiconductor device, a first inter-layer dielectric (ILD) layer is formed over a semiconductor device that includes a first transistor structure, a two-dimensional (2D) material layer is formed over and in contact with the first ILD layer, the 2D material layer is patterned to form a channel layer of a second transistor structure, a source electrode and a drain electrode of the second transistor structure are formed over the patterned 2D material layer and laterally spaced apart from each other, a gate dielectric layer of the second transistor structure is formed over the patterned 2D material layer, the source electrode and the drain electrode, and a gate electrode of the second transistor structure is formed over the gate dielectric layer and laterally between the source electrode and the drain electrode.

Abstract: A device includes a semiconductor substrate, a low-k dielectric layer over the semiconductor substrate, an isolation layer over the low-k dielectric layer, and a work function layer over the etch stop layer. The work function layer is an n-type work function layer. The device further includes a low-dimensional semiconductor layer on a top surface and a sidewall of the work function layer, source/drain contacts contacting opposing end portions of the low-dimensional semiconductor layer, and a dielectric doping layer over and contacting a channel portion of the low-dimensional semiconductor layer. The dielectric doping layer includes a metal selected from aluminum and hafnium, and the channel portion of the low-dimensional semiconductor layer further comprises the metal.

Abstract: A method includes: providing a bottom layer; forming a first transistor over a substrate; forming a bottom electrode over the transistor; depositing a first seed layer over the bottom electrode; performing a surface treatment on the first seed layer, wherein after the surface treatment the first seed layer includes at least one of a tetragonal crystal phase and an orthorhombic crystal phase; depositing a dielectric layer over the bottom layer adjacent to the first seed layer, the dielectric layer including an amorphous crystal phase; depositing an upper layer over the dielectric layer; performing a thermal operation on the dielectric layer to thereby convert the dielectric layer into a ferroelectric layer.

Abstract: An attaching apparatus, an intermediary mechanism thereof, and an attaching method are provided. The intermediary mechanism is provided for being selectively arranged between a pressing mechanism and a carrying mechanism. The intermediary mechanism includes a frame, a deformable sheet fixed on the frame, and an adhesive layer disposed on the deformable sheet. The frame is provided for being fastened to one of the pressing mechanism and the carrying mechanism. The adhesive layer is provided for adhering at least one attaching object onto one side of the deformable sheet facing the carrying mechanism. The deformable sheet is configured to be gradually deformed toward the carrying mechanism by being pressed with the pressing mechanism, so that the at least one attaching object is abutted against an attached object on the carrying mechanism.

Abstract: A transistor device having fin structures, source and drain terminals, channel layers and a gate structure is provided. The fin structures are disposed on a material layer. The fin structures are arranged in parallel and extending in a first direction. The source and drain terminals are disposed on the fin structures and the material layer and cover opposite ends of the fin structures. The channel layers are disposed respectively on the fin structures, and each channel layer extends between the source and drain terminals on the same fin structure. The gate structure is disposed on the channel layers and across the fin structures. The gate structure extends in a second direction perpendicular to the first direction. The materials of the channel layers include a transition metal and a chalcogenide, the source and drain terminals include a metallic material, and the channel layers are covalently bonded with the source and drain terminals.

Abstract: A semiconductor device includes a semiconductor fin, a gate structure, a capacitor structure, a conductive contact, and a hard mask layer. The gate structure is disposed across the semiconductor fin. The capacitor structure is disposed on the gate structure. The capacitor structure includes a ferroelectric layer. The conductive contact is disposed on the capacitor structure. The hard mask layer laterally surrounds the conductive contact. The conductive contact protrudes from a top surface of the hard mask layer.

Abstract: A negative capacitance device includes a semiconductor layer. An interfacial layer is disposed over the semiconductor layer. An amorphous dielectric layer is disposed over the interfacial layer. A ferroelectric layer is disposed over the amorphous dielectric layer. A metal gate electrode is disposed over the ferroelectric layer. At least one of the following is true: the interfacial layer is doped; the amorphous dielectric layer has a nitridized outer surface; a diffusion-barrier layer is disposed between the amorphous dielectric layer and the ferroelectric layer; or a seed layer is disposed between the amorphous dielectric layer and the ferroelectric layer.

Abstract: A semiconductor device includes a substrate, a first poly-material pattern, a first conductive element, a first semiconductor layer, and a first gate structure. The first poly-material pattern is over and protrudes outward from the substrate, wherein the first poly-material pattern includes a first active portion and a first poly-material portion joined to the first active portion. The first conductive element is over the substrate, wherein the first conductive element includes the first poly-material portion and a first metallic conductive portion covering at least one of a top surface and a sidewall of the first poly-material portion. The first semiconductor layer is over the substrate and covers the first active portion of the first poly-material pattern and the first conductive element. The first gate structure is over the first semiconductor layer located within the first active portion.

Abstract: In an embodiment, a method includes forming a multi-layer stack including alternating layers of an isolation material and a semiconductor material, patterning the multi-layer stack to form a first channel structure in a first region of the multi-layer stack, where the first channel structure includes the semiconductor material, depositing a memory film layer over the first channel structure, etching a first trench extending through a second region of the multi-layer stack to form a first dummy bit line and a first dummy source line in the second region, where the first dummy bit line and first dummy source line each include the semiconductor material, and replacing the semiconductor material of the first dummy bit line and the first dummy source line with a conductive material to form a first bit line and a first source line.

Abstract: A method includes: providing a bottom layer; depositing a first seed layer over the bottom layer, the first seed layer having at least one of a tetragonal crystal phase and an orthorhombic crystal phase; depositing a dielectric layer over the bottom layer adjacent to the first seed layer, the dielectric layer including an amorphous crystal phase; depositing an upper layer over the dielectric layer; performing a thermal operation on the dielectric layer; and cooling the dielectric layer, wherein after the cooling the dielectric layer becomes a ferroelectric layer.

Abstract: In a method for forming an integrated semiconductor device, a first transistor over is formed on a substrate; an inter-layer dielectric (ILD) layer is deposited over the first transistor; a gate conductive layer is deposited over the ILD layer; a gate dielectric layer is deposited over the gate conductive layer; the gate dielectric layer and the gate conductive layer are etched to form a gate stack; and a 2D material layer that has a first portion extending along a top surface and sidewalls of the gate stack and a second portion extending along a top surface of the ILD layer.

Abstract: A device includes a first transistor over a substrate, a second transistor disposed over the first transistor, and a memory element disposed over the second transistor. The second transistor includes a channel layer, a gate dielectric layer surrounding a sidewall of the channel layer, and a gate electrode surrounding a sidewall of the gate dielectric layer.

Abstract: A transistor device having fin structures, source and drain terminals, channel layers and a gate structure is provided. The fin structures are disposed on a material layer. The fin structures are arranged in parallel and extending in a first direction. The source and drain terminals are disposed on the fin structures and the material layer and cover opposite ends of the fin structures. The channel layers are disposed respectively on the fin structures, and each channel layer extends between the source and drain terminals on the same fin structure. The gate structure is disposed on the channel layers and across the fin structures. The gate structure extends in a second direction perpendicular to the first direction. The materials of the channel layers include a transition metal and a chalcogenide, the source and drain terminals include a metallic material, and the channel layers are covalently bonded with the source and drain terminals.

Abstract: A semiconductor device includes a semiconductor substrate, a gate structure, a capacitor structure, and a conductive contact. The semiconductor substrate has at least one semiconductor fin thereon. The gate structure is disposed across the semiconductor fin. The capacitor structure is disposed on the gate structure. The capacitor structure includes a ferroelectric layer and a first metal layer disposed on the ferroelectric layer. The capacitor structure is sandwiched between the conductive contact and the gate structure.

Abstract: A semiconductor device includes a substrate, a first poly-material pattern, a first conductive element, a first semiconductor layer, and a first gate structure. The first poly-material pattern is over and protrudes outward from the substrate, wherein the first poly-material pattern includes a first active portion and a first poly-material portion joined to the first active portion. The first conductive element is over the substrate, wherein the first conductive element includes the first poly-material portion and a first metallic conductive portion covering at least one of a top surface and a sidewall of the first poly-material portion. The first semiconductor layer is over the substrate and covers the first active portion of the first poly-material pattern and the first conductive element. The first gate structure is over the first semiconductor layer located within the first active portion.

Abstract: A method includes: providing a bottom layer; depositing a first seed layer over the bottom layer, the first seed layer having at least one of a tetragonal crystal phase and an orthorhombic crystal phase; depositing a dielectric layer over the bottom layer adjacent to the first seed layer, the dielectric layer including an amorphous crystal phase; depositing an upper layer over the dielectric layer; performing a thermal operation on the dielectric layer; and cooling the dielectric layer, wherein after the cooling the dielectric layer becomes a ferroelectric layer.

Abstract: A semiconductor device and a manufacturing method thereof are provided. The semiconductor device includes a gate layer, a low-doping semiconductor layer, a crystalline ferroelectric layer and source and drain terminals. The crystalline ferroelectric layer is disposed between the gate layer and the low-doping semiconductor layer. The source terminal and the drain terminal are disposed on the low-doping semiconductor layer.

Abstract: A ferroelectric tunnel junction (FTJ) memory device includes a bottom electrode located over a substrate, a top electrode overlying the bottom electrode, and a ferroelectric tunnel junction memory element located between the bottom electrode and the top electrode. The ferroelectric tunnel junction memory element includes at least one ferroelectric material layer and at least one tunneling dielectric layer.