Systems, methods and apparatus are provided for an array of vertically stacked memory cells having horizontally oriented access devices having a first source/drain region and a second source drain region separated by a channel region, and gates opposing the channel region, vertically oriented access lines coupled to the gates and separated from a channel region by a gate dielectric. The memory cells have horizontally oriented storage nodes coupled to the second source/drain region and horizontally oriented digit lines coupled to the first source/drain regions. A vertical body contact is formed in direct electrical contact with a body region of one or more of the horizontally oriented access devices and separate from the first source/drain region and the horizontally oriented digit lines by a dielectric.

A method for fabricating a semiconductor structure includes following steps. First, a first layer, a second layer and a third layer are sequentially formed on the substrate. The second layer is conformally disposed on the top surface of the first layer. The second layer and the first layer have different compositions, and the third layer and the second layer also have different compositions. Then, a planarizing process is performed on the third layer until portions of the second layer are exposed. Afterwards, hydrofluoric acid and aqueous oxidant are concurrently or sequentially provided to the remaining second and third layers. Finally, an etch back process is carried out to remove all the second layer and portions of the first layer.

The flash memory includes a stacked gate disposed on a substrate. The stacked gate includes an erase gate and two floating gates. Each floating gate has an acute angle pointing toward the erase gate. There is a high electric field formed around the acute angle so that the flash memory can perform an erase mode even at a lower operational voltage. Furthermore, the flash memory does not use any control gate to perform a write mode.

Provided is a method and apparatus for depositing an amorphous silicon film. The method includes supplying a source gas and an atmospheric gas onto a substrate in a state where the substrate is loaded in a chamber to deposit the amorphous silicon film on the substrate. The atmospheric gas includes at least one of hydrogen and helium. The source gas includes at least one of silane (SiH.sub.2), disilane (Si.sub.2H.sub.6), and dichlorosilane (SiCl.sub.2H.sub.2).

A method includes forming a gate spacer along sidewalls of a gate structure, forming a source region and a drain region on opposite sides of the gate structure, wherein a sidewall of the source region is vertically aligned with a first sidewall of the gate spacer, depositing a dielectric layer over the substrate, depositing a conductive layer over the dielectric layer, patterning the dielectric layer and the conductive layer to form a field plate, wherein the dielectric layer comprises a horizontal portion extending from the second drain/source region to a second sidewall of the gate spacer and a vertical portion formed along the second sidewall of the gate spacer, forming a plurality of metal silicide layers by applying a salicide process to the conductive layer, the gate structure, the first drain/source region and the second drain/source region and forming contact plugs over the plurality of metal silicide layers.

Methods of forming semiconductor structures that include bodies of a semiconductor material disposed between rails of a dielectric material are disclosed. Such methods may include filling a plurality of trenches in a substrate with a dielectric material and removing portions of the substrate between the dielectric material to form a plurality of openings. In some embodiments, portions of the substrate may be undercut to form a continuous void underlying the bodies and the continuous void may be filled with a conductive material. In other embodiments, portions of the substrate exposed within the openings may be converted to a silicide material to form a conductive material under the bodies. For example, the conductive material may be used as a conductive line to electrically interconnect memory device components. Semiconductor structures and devices formed by such methods are also disclosed.

A method of manufacturing a nanosheet or nanowire device from a stack including an alternating arrangement of sacrificial layers and channel layers on a substrate. The method includes deep etching portions of the stack to form electrode recesses for a source electrode and a drain electrode, forming conductive passivation layers in the electrode recesses, and epitaxially growing the source and drain electrodes in the electrode recesses. Each conductive passivation layer extends at least partially along a side of one of the electrode recesses. Portions of the substrate at lower ends of the electrode recesses are uncovered by the conductive passivation layers. The source and drain electrodes are grown from the substrate and the conductive passivation layers substantially inhibit the source and drain electrodes from being grown from the channel layers.

An electrode is included in a base substrate. A trench is produced in the base substrate. The trench is filled with an annealed amorphous material to form the electrode. The electrode is made of a crystallized material which includes particles that are implanted into a portion of the electrode that is located adjacent the front-face side of the base substrate.

Apparatus and associated methods relate to an edge-termination structure surrounding a high-voltage MOSFET for reducing a peak lateral electric field. The edge-termination structure includes a sequence of annular trenches and semiconductor pillars circumscribing the high-voltage MOSFET. Each of the annular trenches is laterally separated from the other annular trenches by one of the semiconductor pillars. Each of the annular trenches has dielectric sidewalls and a dielectric bottom electrically isolating a conductive core within each of the annular trenches from a drain-biased region of the semiconductor pillar outside of and adjacent to the annular trench. The conductive core of the innermost trench is biased, while the conductive cores of one or more outer trenches are floating. In some embodiments, a surface of an inner semiconductor pillar is biased as well. The peak lateral electric field can advantageously be reduced by physical arrangement of trenches and electrical biasing sequence.

The present disclosure provides a silicon film forming method for forming a silicon film on a workpiece having a processed surface, including: forming a seed layer by supplying a high-order aminosilane-based gas containing two or more silicon atoms in a molecular formula onto the processed surface and by having silicon adsorbed onto the processed surface; and forming a silicon film by supplying a silane-based gas not containing an amino group onto the seed layer and by depositing silicon onto the seed layer, wherein, when forming a seed layer, a process temperature is set within a range of 350 degrees C. or lower and a room temperature or higher.