A semiconductor storage device includes a substrate, a first wiring, a second wiring, a third wiring, a fourth wiring, a charge storage unit. The first wiring extends in a first direction along a surface of the substrate. The second wiring is aligned with the first wiring in a second direction intersecting with the first direction and extends in the first direction. The third wiring is in contact with the first wiring and the second wiring and includes a semiconductor. The fourth wiring is located between the first wiring and the second wiring, extends in a third direction intersecting with the first direction and the second direction, and is aligned with the third wiring in at least the first direction. The charge storage unit is located between the third wiring and the fourth wiring.

A method for manufacturing a three-dimensional storage includes: providing a substrate; forming a first connecting layer and a first sacrificial layer; etching part of the first sacrificial layer to form first grooves and second grooves; forming first connecting structures in the first grooves and second connecting structures in the second grooves; forming a second connecting layer on the first sacrificial layer, the second connecting layer filling up the first and second grooves; forming a stacked structure on a surface of the second connecting layer; forming a channel structure and a gate line slit penetrating the stacked structure and extending to the first sacrificial layer; removing the first sacrificial layer and a part of the channel structure corresponding to the first sacrificial layer by the gate line slit to form an opening region; and forming an epitaxial structure layer in the opening region through the gate line slit.

A semiconductor memory device includes a substrate having a first active area and a second active area in proximity to the first active area. A trench isolation region is between the first active area and the second active area. A source line region is disposed in the first active area and adjacent to the trench isolation region. An erase gate is disposed on the source line region. A floating gate is disposed on a first side of the erase gate. A first control gate is disposed on the floating gate. A first word line is disposed adjacent to the floating gate and the first control gate and insulated therefrom. A second control gate is disposed on a second side of the erase gate and directly on the trench isolation region. A second word line is disposed adjacent to the second control gate and insulated therefrom.

Some embodiments include a memory array having a vertical stack of alternating insulative levels and control gate levels. Channel material extends vertically along the stack. The control gate levels comprising conductive regions. The conductive regions include at least three different materials. Charge-storage regions are adjacent the control gate levels. Charge-blocking regions are between the charge-storage regions and the conductive regions.

Some embodiments include a memory array having a vertical stack of alternating insulative levels and control gate levels. Channel material extends vertically along the stack. The control gate levels comprising conductive regions. The conductive regions include at least three different materials. Charge-storage regions are adjacent the control gate levels. Charge-blocking regions are between the charge-storage regions and the conductive regions.

A method used in forming a memory array comprising strings of memory cells comprises forming a conductor tier comprising conductor material on a substrate. Laterally-spaced memory-block regions individually comprise a vertical stack comprising alternating first tiers and second tiers are formed directly above the conductor tier. Channel-material strings of memory cells extend through the first tiers and the second tiers. A lower of the first tiers comprises sacrificial material. A horizontally-elongated slot is formed through the first and second tiers to the sacrificial material in individual of the memory-block regions to form laterally-spaced sub-block regions in the individual memory-block regions. The sacrificial material is isotropically etched from the lower first tier through the horizontally-elongated slots. After the isotropic etching, conducting material is formed in the horizontally-elongated slots and in the lower first tier that directly electrically couples together the channel material of individual of the channel-material strings and the conductor material of the conductor tier. After forming the conducting material, horizontally-elongated trenches are formed through the first tiers and the second tiers and that are individually laterally between immediately-adjacent of the memory-block regions. Other embodiments, including structure independent of method, are disclosed.

A semiconductor device includes a substrate and a gate structure disposed over the substrate. The gate structure includes gate electrode layers and interlayer insulation structures that are alternately stacked with each other. The semiconductor device includes a dielectric structure disposed over the substrate to contact a sidewall surface of the gate structure, and a channel layer disposed on a sidewall surface of the dielectric structure over the substrate. Each of the interlayer insulation structure includes an insulation layer and a metal-organic framework layer that are disposed on the same plane.

A variety of applications can include apparatus or methods that provide a well ring for resistive ground power domain segregation. The well ring can be implemented as a n-well in a p-type substrate. Resistive separation between ground domains can be generated by biasing a n-well ring to an external supply voltage. This approach can provide a procedure, from a process standpoint, that provides relatively high flexibility to design for chip floor planning and simulation, while providing sufficient noise rejection between independent ground power domains when correctly sized. Significant noise rejection between ground power domains can be attained.

A three-dimensional memory device includes a vertical repetition of multiple instances of a unit layer stack. The unit layer stack includes, in order, an airgap-containing insulating layer, a first interfacial dielectric capping layer, a metal layer, and a second interfacial dielectric capping layer. Memory stack structures extend through the vertical repetition. Each of the memory stack structures includes a vertical semiconductor channel and a vertical stack of memory elements located at levels of the metal layers.

A 3D memory device, the device including: a plurality of memory cells, where each memory cell of the plurality of memory cells includes at least one memory transistor, where each of the at least one memory transistor includes a source, a drain, and a channel; and a plurality of bit-line pillars, where each bit-line pillar of the plurality of bit-line pillars is directly connected to a plurality of the source or the drain, where the bit-line pillars are vertically oriented, where the channel is horizontally oriented, and where the device includes a temperature sensor.