Abstract: A method of forming a semiconductor device is provided. A gate electrode is formed within an insulating layer that overlies a substrate. A gate dielectric layer is formed over the gate electrode. A first oxide semiconductor layer is formed over the gate dielectric layer. A dielectric layer is formed over the first oxide semiconductor layer. The dielectric layer and the first oxide semiconductor layer are patterned, so as to form first and second openings that expose portions of the gate dielectric layer. An interfacial layer is conformally formed on sidewalls and bottoms of the first and second openings. A second oxide semiconductor layer is formed over the interfacial layer in the first and second openings. A metal layer is formed over the second oxide semiconductor layer in the first and second openings.

Abstract: A memory device includes a bit line, a word line, a memory cell, select bit lines, and a controller. The memory cell includes a first transistor, data storage elements, and second transistors corresponding to the data storage elements. The first transistor includes a gate electrically coupled to the word line, a first source/drain, and a second source/drain. Each of the select bit lines is electrically coupled to a gate of a corresponding second transistor. Each data storage element and the corresponding second transistor are electrically coupled in series between the first source/drain of the first transistor and the bit line. The controller turns ON the first transistor and a selected second transistor, and, while the first transistor and the selected second transistor are turned ON, applies different voltages to the bit line to perform corresponding different operations on the data storage element coupled to the selected second transistor.

Abstract: A memory cell includes a write bit line, a read word line, a write transistor, and a read transistor. The write transistor is coupled between the write bit line and a first node. The read transistor is coupled to the write transistor by the first node. The read transistor includes a ferroelectric layer, a drain terminal of the read transistor is coupled to the read word line, and a source terminal of the read transistor is coupled to a second node. The write transistor is configured to set a stored data value of the memory cell by a write bit line signal that adjusts a polarization state of the read transistor. The polarization state corresponds to the stored data value.

Abstract: Doping techniques for fin-like field effect transistors (FinFETs) are disclosed herein. An exemplary method includes forming a fin structure, forming a doped amorphous layer over a portion of the fin structure, and performing a knock-on implantation process to drive a dopant from the doped amorphous layer into the portion of the fin structure, thereby forming a doped feature. The doped amorphous layer includes a non-crystalline form of a material. In some implementations, the knock-on implantation process crystallizes at least a portion of the doped amorphous layer, such that the portion of the doped amorphous layer becomes a part of the fin structure. In some implementations, the doped amorphous layer includes amorphous silicon, and the knock-on implantation process crystallizes a portion of the doped amorphous silicon layer.

Abstract: A magnetic tunnel junction memory device includes a vertical stack of magnetic tunnel junction NOR strings located over a substrate. Each magnetic tunnel junction NOR string includes a respective semiconductor material layer that contains a semiconductor source region, a plurality of semiconductor channels, and a plurality of semiconductor drain regions, a plurality of magnetic tunnel junction memory cells having a respective first electrode that is located on a respective one of the plurality of semiconductor drain regions, and a metallic bit line contacting each second electrode of the plurality of magnetic tunnel junction memory cells. The vertical stack of magnetic tunnel junction NOR strings may be repeated along a channel direction to provide a three-dimensional magnetic tunnel junction memory device.

Abstract: Various embodiments of the present disclosure provide a memory device and methods of forming the same. In one embodiment, a memory device is provided. The memory device includes a gate electrode disposed in an insulating material layer, a ferroelectric dielectric layer disposed over the gate electrode, a metal oxide semiconductor layer disposed over the ferroelectric dielectric layer, a source feature disposed over the metal oxide semiconductor layer, wherein the source feature has a first dimension, and a source extension. The source extension includes a first portion disposed over the source feature, wherein the first portion has a second dimension that is greater than the first dimension. The source extension also includes a second portion extending downwardly from the first portion to an elevation that is lower than a top surface of the source feature.

Abstract: A semiconductor device includes a word line (WL) structure. The semiconductor device includes a ferroelectric layer over the WL structure. The semiconductor device includes a channel layer over the ferroelectric layer. The semiconductor device includes a source line (SL) structure over the channel layer. The semiconductor device includes a bit line (BL) structure over the channel layer. The BL structure includes a portion that laterally extends toward the SL structure. The semiconductor device further includes a dielectric layer laterally interposed between the SL structure and the BL structure.

Abstract: An integrated circuit is provided. The integrated circuit includes a three-dimensional memory device, a first word line driving circuit and a second word line driving circuit. The three-dimensional memory device includes stacking structures separately extending along a column direction. Each stacking structure includes a stack of word lines. The stacking structures have first staircase structures at a first side and second staircase structures at a second side. The word lines extend to steps of the first and second staircase structures. The first and second word line driving circuits lie below the three-dimensional memory device, and extend along the first and second sides, respectively. Some of the word lines in each stacking structure are routed to the first word line driving circuit from a first staircase structure, and others of the word lines in each stacking structure are routed to the second word line driving circuit from a second staircase structure.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a substrate having a fin structure that includes a first negative capacitance material, and an isolation structure formed over the substrate. The semiconductor device structure includes a gate structure formed over the fin structure, and a source feature and a drain feature formed over the fin structure. An interface between the fin structure and the source feature is lower than a top surface of the isolation structure.

Abstract: Various embodiments of the present disclosure are directed towards a method for forming an integrated chip, the method includes depositing a grid layer over a substrate. The grid layer is patterned to form a grid structure. The grid structure comprises a plurality of sidewalls defining a plurality of openings. A ferroelectric layer is deposited over the substrate. The ferroelectric layer fills the plurality of openings and is disposed along the plurality of sidewalls of the grid structure. An upper conductive structure is formed over the grid structure.

Abstract: Methods for forming contacts to source/drain regions and gate electrodes in low- and high-voltage devices and devices formed by the same are disclosed. In an embodiment a device includes a first channel region in a substrate adjacent a first source/drain region; a first gate over the first channel region; a second channel region in the substrate adjacent a second source/drain region, a top surface of the second channel region being below a top surface of the first channel region; a second gate over the second channel region; an ILD over the first gate and the second gate; a first contact extending through the ILD and coupled to the first source/drain region; and a second contact extending through the ILD, coupled to the second source/drain region, and having a width greater a width of the first contact and a height greater than a height of the first contact.

Abstract: A method of forming a device includes providing a transistor having a gate structure and a source/drain structure adjacent to the gate structure. A cavity is formed along a sidewall surface of a contact opening over the source/drain structure. After forming the cavity, a sacrificial layer is deposited over a bottom surface and along the sidewall surface of the contact opening including within the cavity. A first portion of the sacrificial layer along the bottom surface of the contact opening is removed to expose a portion of the source/drain structure. A metal plug is then formed over the portion of the exposed source/drain structure. A remaining portion of the sacrificial layer is removed to form an air gap disposed between the metal plug and the gate structure. Thereafter, a seal layer is deposited over the air gap to form an air gap spacer.

Abstract: A thin film transistor, a semiconductor device having a thin film transistor and a method of fabricating a thin film transistor are provided. The thin film transistor includes a gate metal; a gate dielectric layer disposed on the gate metal; a semiconductor layer disposed on the gate dielectric layer; an interlayer dielectric disposed on the semiconductor layer and having a contact hole over the semiconductor layer; a source/drain metal disposed in the contact hole; a first liner disposed between the interlayer dielectric and the source/drain metal; and a second liner disposed between the first liner and the source/drain metal and being in contact with the semiconductor layer in the contact hole.

Abstract: A device includes a semiconductor substrate; a first word line over the semiconductor substrate, the first word line providing a first gate electrode for a first transistor; and a second word line over the first word line. The second word line is insulated from the first word line by a first dielectric material, and the second word line providing a second gate electrode for a second transistor over the first transistor. The device further including a source line intersecting the first word line and the second word line; a bit line intersecting the first word line and the second word line; a memory film between the first word line and the source line; and a first semiconductor material between the memory film and the source line.

Abstract: Small sized and closely pitched features can be formed by patterning a layer to have holes therein and then expanding the layer so that the holes shrink. If the expansion is sufficient to pinch off the respective holes, multiple holes can be formed from one larger hole. Holes smaller and of closer pitch than practical or possible may be obtained in this way. One process for expanding the layer includes implanting a dopant species having a larger average atomic spacing than does the material of the layer.

Abstract: A semiconductor device according to the present disclosure includes an anti-punch-through (APT) region over a substrate, a plurality of channel members over the APT region, a gate structure wrapping around each of the plurality of channel members, a source/drain feature adjacent to the gate structure, and a diffusion retardation layer. The source/drain feature is spaced apart from the APT region by the diffusion retardation layer. The source/drain feature is spaced apart from each of the plurality of channel members by the diffusion retardation layer. The diffusion retardation layer is a semiconductor material.

Abstract: Semiconductor devices and methods of manufacture are provided wherein a ferroelectric random access memory array is formed with bit line drivers and source line drivers formed below the ferroelectric random access memory array. A through via is formed using the same processes as the processes used to form individual memory cells within the ferroelectric random access memory array.

Abstract: A method includes etching a first semiconductor fin and a second semiconductor fin to form first recesses. The first and the second semiconductor fins have a first distance. A third semiconductor fin and a fourth semiconductor fin are etched to form second recesses. The third and the fourth semiconductor fins have a second distance equal to or smaller than the first distance. An epitaxy is performed to simultaneously grow first epitaxy semiconductor regions from the first recesses and second epitaxy semiconductor regions from the second recesses. The first epitaxy semiconductor regions are merged with each other, and the second epitaxy semiconductor regions are separated from each other.

Abstract: Embodiments of the present disclosure relate to a FinFET device having gate spacers with reduced capacitance and methods for forming the FinFET device. Particularly, the FinFET device according to the present disclosure includes gate spacers formed by two or more depositions. The gate spacers are formed by depositing first and second materials at different times of processing to reduce parasitic capacitance between gate structures and contacts introduced after epitaxy growth of source/drain regions.

Abstract: A MIM structure and manufacturing method thereof are provided. The MIM structure includes a substrate and a metallization structure over the substrate. The metallization structure includes a bottom electrode layer, a dielectric layer on the bottom electrode layer, a ferroelectric layer on the dielectric layer, a top electrode layer on the ferroelectric layer, a first contact electrically coupled to the top electrode layer, and a second contact penetrating the dielectric layer and the ferroelectric layer, electrically coupled to a base portion of the bottom electrode layer. The bottom electrode layer includes the base portion and a plurality of protrusions, each of the protrusions is protruding from the base portion and leveled with a lower surface of the dielectric layer, each portion of the dielectric layer over the bottom electrode layer substantially have identical thicknesses.