A device includes a substrate. A first nanostructure is over the substrate, and includes a semiconductor having a first resistance. A second nanostructure is over the substrate, is offset laterally from the first nanostructure, is at about the same height above the substrate as the first nanostructure, and includes a conductor having a second resistance lower than the first resistance. A first gate structure is over and wrapped around the first nanostructure, and a second gate structure is over and wrapped around the second nanostructure.

A method of forming an array of capacitors comprises forming a vertical stack above a substrate. The stack comprises a horizontally-elongated conductive structure and an insulator material directly above the conductive structure. Horizontally-spaced openings are formed in the insulator material to the conductive structure. An upwardly-open container-shaped bottom capacitor electrode is formed in individual of the openings. The bottom capacitor electrode is directly against conductive material of the conductive structure. The conductive structure directly electrically couples the bottom capacitor electrodes together. A capacitor insulator is formed in the openings laterally-inward of the bottom capacitor electrodes. A top capacitor electrode is formed in individual of the openings laterally-inward of the capacitor insulator. The top capacitor electrodes are not directly electrically coupled together. Structure independent of method is disclosed.

Embodiments provide a semiconductor structure and a method for fabricating a semiconductor structure, relating to the field of semiconductor technology. The semiconductor structure includes a substrate, a capacitor structure, a transistor structure, a bit line and a word line; and the substrate includes a semiconductor layer and a spacer. The capacitor structure is arranged on the substrate, and the spacer is positioned between the capacitor structure and at least a part of the semiconductor layer. The transistor structure and the word line are arranged on a side of the capacitor structure distant from the substrate, one of a source and a drain of the transistor structure is electrically connected to the capacitor structure, a gate of the transistor structure is electrically connected to the word line, and other one of the source and the drain of the transistor structure is electrically connected to the bit line.

A semiconductor storage device according to the present embodiment includes a plurality of first wires provided above a surface of a semiconductor substrate to extend in a first direction, and a plurality of second wires provided above the first wires to extend in a second direction crossing the first direction. A plurality of capacitor elements are arranged every other intersection region among intersection regions between the first wires and the second wires as viewed from above the surface of the semiconductor substrate. A plurality of transistors are provided above the capacitor elements to correspond thereto, respectively. A first distance between two of the capacitor elements, which are adjacent to each other in the first direction, is narrower than a second distance between two of the capacitor elements, which are adjacent to each other in the second direction.

Embodiments of three-dimensional memory devices are disclosed. A disclosed memory structure can comprises a memory cell, a bit line contact coupled to the memory cell, a bit line coupled to the bit line contact, a source line contact coupled to the memory cell, and a source line coupled to the source line contact. The memory cell comprises a cylindrical body having a cylindrical shape, an insulating layer surrounding the cylindrical body, a word line contact surrounding a first portion of the insulating layer, the word line contact coupled to a word line, and a plurality of plate line contact segments surrounding a second portion of the insulating layer, the plurality of plate line contact segments coupled to a common plate line.

On a substrate, dynamic flash memory cell transistors and, on their outside, driving-signal processing circuit transistors are disposed. A source line wiring layer, a bit line wiring layer, a plate line wiring layer, and a word line wiring layer extend in the horizontal direction relative to the substrate and connect, from the outside of a dynamic flash memory region, in the perpendicular direction, to lead-out wiring layers on an insulating layer. The transistors in driving-signal processing circuit regions connect, via multilayered wiring layers, to upper wiring layers on the insulating layer. A high-thermal-conductivity layer is disposed over the entirety of the dynamic flash memory region and in a portion above the bit line wiring layer.

A method of forming a semiconductor structure includes forming a capacitor on a substrate. A recess is formed in the capacitor. A drain region is formed in the recess. A word line is formed on the drain region. A gate structure is formed on the drain region, and the gate structure is electrically connected to the word line. A first bit line is formed on the gate structure, such that the first bit line servers as a source region.

In certain aspects, a memory device includes a vertical transistor including a semiconductor body extending in a first direction, a stack structure including interleaved dielectric layers and conductive layers each extending perpendicularly to the first direction, an electrode layer including a conductive material and coupled to a first end of the semiconductor body, and a storage layer over the electrode layer. The electrode layer and the storage layer extend in the first direction through the stack structure.

In certain aspects, a memory device includes a vertical transistor, a storage unit, a bit line, and a body line. The vertical transistor includes a semiconductor body extending in a first direction. The semiconductor body includes a doped source, a doped drain, and a channel portion. The storage unit is coupled to a first terminal. The first terminal is one of the source and the drain. The bit line extends in a second direction perpendicular to the first direction and coupled to a second terminal. The second terminal is another one of the source and the drain. The body line is coupled to the channel portion of the semiconductor body.

A device includes a substrate. A first nanostructure is over the substrate, and includes a semiconductor having a first resistance. A second nanostructure is over the substrate, is offset laterally from the first nanostructure, is at about the same height above the substrate as the first nanostructure, and includes a conductor having a second resistance lower than the first resistance. A first gate structure is over and wrapped around the first nanostructure, and a second gate structure is over and wrapped around the second nanostructure.