An apparatus can have first and second memory cells. The first memory cell can have a first storage device selectively coupled to a first digit line at a first level by a first vertical transistor at a second level. The second memory cell can have a second storage device selectively coupled to a second digit line at the first level by a second vertical transistor at the second level. A third digit line can be at a third level and can be coupled to a main sense amplifier. A local sense amplifier can be coupled to the first digit line, the second digit line, and the third digit line. The second level can be between the first and third levels.

A half-bridge circuit includes a low-side transistor and a high-side transistor each having a load path and a control terminal, and a high-side drive circuit having a level shifter with a level shifter transistor. The low-side transistor and the level shifter transistor are integrated in a common semiconductor body.

Disclosed is a vertically stacked 3D memory device, and the memory device may include a bit line extended vertically from a substrate, and including a first vertical portion and a second vertical portion, a vertical active layer configured to surround the first and second vertical portions of the bit line, a word line configured to surround the vertical active layer and the first vertical portion of the bit line, and a capacitor spaced apart vertically from the word line, and configured to surround the vertical active layer and the second vertical portion of the bit line.

A capacitive element includes a trench extending vertically into a well from a first side. The trench is filled with a conductive central section clad with an insulating cladding. The capacitive element further includes a first conductive layer covering a first insulating layer that is located on the first side and a second conductive layer covering a second insulating layer that is located on the first conductive layer. The conductive central section and the first conductive layer are electrically connected to form a first electrode of the capacitive element. The second conductive layer and the well are electrically connected to form a second electrode of the capacitive element. The insulating cladding, the first insulating layer and the second insulating layer form a dielectric region of the capacitive element.

A capacitive element includes a trench extending vertically into a well from a first side. The trench is filled with a conductive central section clad with an insulating cladding. The capacitive element further includes a first conductive layer covering a first insulating layer that is located on the first side and a second conductive layer covering a second insulating layer that is located on the first conductive layer. The conductive central section and the first conductive layer are electrically connected to form a first electrode of the capacitive element. The second conductive layer and the well are electrically connected to form a second electrode of the capacitive element. The insulating cladding, the first insulating layer and the second insulating layer form a dielectric region of the capacitive element.

An integrated circuit includes one or more layers of insulating material defining a vertical bore with a first portion and a second portion. A capacitor structure is in the first portion of the vertical bore and includes a first electrode, a second electrode, and a dielectric between the first electrode and the second electrode. A transistor structure is in the second portion of the vertical bore and includes a third electrode extending into the second portion of the vertical bore, a layer of semiconductor material in contact with the first electrode and in contact with the second electrode, and a dielectric between the semiconductor material and the insulating material. A fourth electrode wraps around the transistor structure such that the dielectric is between the semiconductor material and the fourth electrode. The capacitor structure can be above or below the transistor structure in a self-aligned vertical arrangement.

Some embodiments include a memory cell having a first transistor supported by a semiconductor base, and having second and third transistors above the first transistor and vertically stacked one atop the other. Some embodiments include a memory cell having first, second and third transistors. The third transistor is above the second transistor, and the second and third transistors are above the first transistor. The first transistor has first and second source/drain regions, the second transistor has third and fourth source/drain regions, and the third transistor has fifth and sixth source/drain regions. A read bitline is coupled with the sixth source/drain region. A write bitline is coupled with the first source/drain region. A write wordline includes a gate of the first transistor. A read wordline includes a gate of the third transistor. A capacitor is coupled with the second source/drain region and with a gate of the second transistor.

Some embodiments include a memory cell having first, second and third transistors, with the second and third transistors being vertically displaced relative to one another. The memory cell has a semiconductor pillar extending along the second and third transistors, with the semiconductor pillar containing channel regions and source/drain regions of the second and third transistors. A capacitor may be electrically coupled between a source/drain region of the first transistor and a gate of the second transistor.

A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate, forming a first bottom source/drain region at sides of a first fin of the plurality of fins in a first transistor region, and forming a second bottom source/drain region at sides of a second fin of the plurality of fins in a second transistor region. The first and second bottom source/drain regions are oppositely doped. In the method, a bottom spacer layer is formed on the first and second bottom source/drain regions, and the bottom spacer layer is removed from the second bottom source/drain region. A high-k dielectric layer is formed on the bottom spacer layer in the first transistor region, and directly formed on the second bottom source/drain region in the second transistor region. The method also includes forming a gate conductor on the high-k dielectric layer.

A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate, forming a first bottom source/drain region at sides of a first fin of the plurality of fins in a first transistor region, and forming a second bottom source/drain region at sides of a second fin of the plurality of fins in a second transistor region. The first and second bottom source/drain regions are oppositely doped. In the method, a bottom spacer layer is formed on the first and second bottom source/drain regions, and the bottom spacer layer is removed from the second bottom source/drain region. A high-k dielectric layer is formed on the bottom spacer layer in the first transistor region, and directly formed on the second bottom source/drain region in the second transistor region. The method also includes forming a gate conductor on the high-k dielectric layer.