A method of fabricating semiconductor device, the semiconductor device includes a substrate, a first transistor and a second transistor. The substrate includes a high-voltage region and a low-voltage region. The first transistor is disposed on the HV region, and includes a first gate dielectric layer disposed on a first base, and a first gate electrode on the first gate dielectric layer. The first gate dielectric layer includes a composite structure having a first dielectric layer and a second dielectric layer stacked sequentially. The second transistor is disposed on the LV region, and includes a fin shaped structure protruded from a second base on the substrate, and a second gate electrode disposed on the fin shaped structure. The first dielectric layer covers sidewalls of the second gate electrode and a top surface of the first dielectric layer is even with a top surface of the second gate electrode.

A vertical tunneling field-effect transistor and a method for its manufacture are provided. According to methods herein disclosed, oppositely doped source and drain regions are formed, and an APAM delta layer is formed in the surface of the transistor substrate, beneath a metal gate, in electrical contact with, e.g., the source region. A dielectric layer intervenes between the substrate surface and the metal gate. An epitaxial cap layer directly over the APAM layer forms a dielectric layer interface with a dielectric layer, which is located between the epitaxial cap layer and the metal gate. A vertical channel is defined for tunneling between the APAM delta layer and an induced conduction channel adjacent to the dielectric layer interface that is formed in operation, and that is in electrical contact with, e.g., the drain region.

Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a plurality of nanostructures over a substrate, and a gate electrode surrounding the nanostructures. The semiconductor device structure includes a source/drain portion adjacent to the gate electrode, and a semiconductor layer between the gate electrode and the source/drain portion.

The present disclosure relates to semiconductor structures and, more particularly, to a device with a vertical nanowire channel region and methods of manufacture. The structure includes: a bottom source/drain region; a top source/drain region; a gate structure extending between the bottom source/drain region and the top source/drain region; and a vertical nanowire in a channel region of the gate structure.

A method of microfabrication includes epitaxially growing a first vertical channel structure of silicon-containing material on a first sacrificial layer of silicon containing material, the first sacrificial layer having etch selectivity with respect to the vertical channel structure. A core opening is directionally etched through the vertical channel structure to expose the first sacrificial layer, and the first sacrificial layer is isotropically etched through the core opening to form a first isolation opening for isolating the first vertical channel structure.

Some embodiments include an assembly having pillars of semiconductor material arranged in rows extending along a first direction. The rows include spacing regions between the pillars. The rows are spaced from one another by gap regions. Two conductive structures are within each of the gap regions and are spaced apart from one another by a separating region. The separating region has a floor section with an undulating surface that extends across semiconductor segments and insulative segments. The semiconductor segments have upper surfaces which are above upper surfaces of the insulative segments; Transistors include channel regions within the pillars of semiconductor material, and include gates within the conductive structures. Some embodiments include methods for forming integrated circuitry.

A semiconductor device includes substrate, a first gate structure, a second gate structure, and an epitaxy layer. The first gate structure and the second gate structure are over the substrate, in which the first gate structure and the second gate structure each comprises a shielding electrode, a gate electrode over the shielding electrode, and a first gate dielectric layer vertically separating the shielding electrode from the gate electrode. The epitaxy layer is over the substrate and cups an underside of the first gate structure and the second gate structure, in which the epitaxy layer comprises a doped region laterally between the first gate dielectric layer of the first gate structure and the first gate dielectric layer of the second gate structure, a dopant concentration of the doped region being non-uniform along a lateral direction.

A memory device includes pages arranged in columns and each constituted by a plurality of memory cells on a substrate, voltages applied to a first gate conductor layer, a second gate conductor layer, a first impurity layer, and a second impurity layer in each memory cell included in each of the pages are controlled to perform a page write operation of retaining, inside a channel semiconductor layer, a group of positive holes generated by an impact ionization phenomenon or by a gate-induced drain leakage current, and the voltages applied to the first gate conductor layer, the second gate conductor layer, the first impurity layer, and the second impurity layer are controlled to perform a page erase operation of discharging the group of positive holes from inside the channel semiconductor layer. The first impurity layer of the memory cell is connected to a source line, the second impurity layer thereof is connected to a bit line, one of the first gate conductor layer or the second gate conductor layer thereof is connected to a word line, the other of the first gate conductor layer or the second gate conductor layer thereof is connected to a first driving control line, and the bit lines are connected to sense amplifier circuits with a switch circuit therebetween. In a page read operation, page data in a group of memory cells selected by the word line is read to the sense amplifier circuits, and in a page addition read operation, at least two sets of page data selected by at least two word lines in multiple selection are added up for each of the bit lines and read to a corresponding one of the sense amplifier circuits.

A semiconductor device is provided. The semiconductor device includes a substrate and a gate structure. The gate structure is disposed in the substrate and includes a shielded gate, a control gate, and a plurality of insulating layers. The shielded gate includes a bottom gate and a top gate. The bottom gate includes a step structure consisting of a plurality of electrodes. A width of the electrode is smaller as the electrode is farther away from the top gate, and a width of the top gate is smaller than a width of the electrode closest to the top gate. The control gate is disposed on the shielded gate. A first insulating layer is disposed between the shielded gate and the substrate. A second insulating layer is disposed on the shielded gate. A third insulating layer is disposed between the control gate and the substrate.

A memory device includes pages each constituted by memory cells on a substrate. Voltages applied to first and second gate conductor layers and impurity layers in each memory cell are controlled to retain positive holes inside a channel semiconductor layer. In a page write operation, the voltage of the channel semiconductor layer is set to a first data retention voltage. In a page erase operation, the applied voltages are controlled to discharge the positive holes, and the voltage of the channel semiconductor layer is set to a second data retention voltage. At a second time after a first time, a memory re-erase operation is performed for the channel semiconductor layers at the second data retention voltage at the first time. At a third time after the second time, a memory re-write operation is performed for the channel semiconductor layers at the first data retention voltage at the first time.