The present disclosure relates to semiconductor structures and, more particularly, to a symmetric tunnel field effect transistor and methods of manufacture. The structure includes a gate structure including a source region and a drain region both of which comprise a doped VO.sub.2 region.

The present disclosure provides an embodiment of a fin-like field-effect transistor (FinFET) device. The device includes a substrate having a first gate region, a first fin structure over the substrate in the first gate region. The first fin structure includes an upper semiconductor material member, a lower semiconductor material member, surrounded by an oxide feature and a liner wrapping around the oxide feature of the lower semiconductor material member, and extending upwards to wrap around a lower portion of the upper semiconductor material member. The device also includes a dielectric layer laterally proximate to an upper portion of the upper semiconductor material member. Therefore the upper semiconductor material member includes a middle portion that is neither laterally proximate to the dielectric layer nor wrapped by the liner.

A method of forming a TSV isolation layer and a transistor-to-BEOL isolation layer during a single deposition process and the resulting device are disclosed. Embodiments include providing a gate stack, with source/drain regions at opposite sides thereof, and an STI layer on a silicon substrate; forming a TSV trench, laterally separated from the gate stack, through the STI layer and the silicon substrate; forming an isolation layer on sidewalls and a bottom surface of the TSV trench and over the gate stack, the STI layer, and the silicon substrate; forming a TSV in the TSV trench; forming a dielectric cap over the isolation layer and the TSV; and forming a source/drain contact through the dielectric cap and the isolation layer down to the source/drain contract regions.

An apparatus comprising: a first layer (512) configured to enable a flow of charge carriers from a source electrode (505) to a drain electrode (506); a second layer (513) configured to generate a voltage in response to a physical stimulus, the second layer (513) positioned so that the generated voltage can affect the conductance of the first layer (512); and a third layer (514) positioned between the first (512) and second (513) layers to prevent a flow of charge carriers therebetween. The third layer (514) comprises a material configured to form electric double-layers (516, 517) at the interfaces with the first (512) and second (513) layers in response to the generated voltage. The formation of the electric double-layers (516, 517) enhances the effect of the generated voltage on the conductance of the first layer (512) such that determination of the conductance of the first layer (512) can be used to allow the magnitude of the physical stimulus to be derived.

In one general aspect, an apparatus can include a semiconductor substrate, and a trench defined within the semiconductor substrate and having a depth aligned along a vertical axis, a length aligned along a longitudinal axis, and a width aligned along a horizontal axis. The apparatus includes a dielectric disposed within the trench, and an electrode disposed within the dielectric and insulated from the semiconductor substrate by the dielectric. The semiconductor substrate can have a portion aligned vertically and adjacent the trench, and the portion of the semiconductor substrate can have a conductivity type that is continuous along an entirety of the depth of the trench. The apparatus is biased to a normally-on state.

A semiconductor device has gate-all-around devices formed in respective regions on a substrate. The gate-all-around devices have nanowires at different levels. The threshold voltage of a gate-all-around device in first region is based on a thickness of an active layer in an adjacent second region. The active layer in the second region may be at substantially a same level as the nanowire in the first region. Thus, the nanowire in the first region may have a thickness based on the thickness of the active layer in the second region, or the thicknesses may be different. When more than one active layer is included, nanowires in different ones of the regions may be disposed at different heights and/or may have different thicknesses.

An integrated circuit including a link or string of semiconductor memory cells, wherein each memory cell includes a floating body region for storing data. The link or siring includes at least one contact configured to electrically connect the memory cells to at least one control line, and the number of contacts in the string or link is the same as or less than the number of memory cells in the string or link.

A direct current to direct current (DC-DC) converter can include a chip embedded integrated circuit (IC), one or more switches, and an inductor. The IC can be embedded in a PCB. The IC can include driver, switches, and PWM controller. The IC and/or switches can include eGaN. The inductor can be stacked above the IC and/or switches, reducing an overall footprint. One or more capacitors can also be stacked above the IC and/or switches. Vias can couple the inductor and/or capacitors to the IC (e.g., to the switches). The DC-DC converter can offer better transient performance, have lower ripples, or use fewer capacitors. Parasitic effects that prevent efficient, higher switching speeds are reduced. The inductor size and overall footprint can be reduced. Multiple inductor arrangements can improve performance. Various feedback systems can be used, such as a ripple generator in a constant on or off time modulation circuit.

An integrated circuit is formed on a semiconductor substrate and includes a trench conductor and a first transistor formed on the surface of the substrate. The transistor includes: a transistor gate structure, a first doped region extending in the substrate between a first edge of the gate structure and an upper edge of the trench conductor, and a first spacer formed on the first edge of the gate structure and above the first doped region. The first spacer completely covers the first doped region and a silicide is present on the trench conductor but is not present on the surface of the first doped region.

A method of forming a TSV isolation layer and a transistor-to-BEOL isolation layer during a single deposition process and the resulting device are disclosed. Embodiments include providing a gate stack, with source/drain regions at opposite sides thereof, and an STI layer on a silicon substrate; forming a TSV trench, laterally separated from the gate stack, through the STI layer and the silicon substrate; forming an isolation layer on sidewalls and a bottom surface of the TSV trench and over the gate stack, the STI layer, and the silicon substrate; forming a TSV in the TSV trench; forming a dielectric cap over the isolation layer and the TSV; and forming a source/drain contact through the dielectric cap and the isolation layer down to the source/drain contract regions.