A 3D semiconductor device, the device comprising: a first level comprising a first single crystal layer, said first level comprising first transistors, wherein each of said first transistors comprises a single crystal channel; first metal layers interconnecting at least said first transistors; a second metal layer overlaying said first metal layers; and a second level comprising a second single crystal layer, said second level comprising second transistors, wherein said second level overlays said first level, wherein at least one of said second transistors comprises a gate all around structure, wherein said second level is directly bonded to said first level, and wherein said bonded comprises direct oxide to oxide bonds.

Provided is a capacitor device, a unit synapse using the capacitor device, a synapse array using the unit synapses. The capacitor device comprises a semiconductor layer which include first and second doping regions formed to be spaced apart from each other and a body region formed between the first and second doping regions; a gate electrode provided above the body region; and a gate insulator stack to have a memory function and disposed between the gate electrode and the semiconductor layer. The capacitance between the gate electrode and the first doping region is determined according to information stored in the gate insulator stack, and the state of the capacitor device is determined according to the capacitance to be one of two preset states. The unit synapse comprises a pair of capacitor devices to perform an XNOR operation.

Apparatuses and methods to provide a patterned substrate are described. A plurality of patterned and spaced first lines and carbon material lines and formed on the substrate surface by selectively depositing and etching films extending in a first direction and films extending in a second direction that crosses the first direction to pattern the underlying structures.

Disclosed are semiconductor packages and semiconductor devices. In one embodiment, a semiconductor package includes a package, a first integrated passive device, and a second integrated passive device. The first integrated passive device is disposed below the package. The second integrated passive device is disposed between the package and the first integrated passive device. The first integrated passive device is electrically connected to the package through the second integrated passive device.

A method for forming a shallow trench isolation (STI) structure using two individual STI trench etching processes is provided. A first STI etching process forms first trenches with one or more sizes in rows along a first dimension in a silicon substrate. A first dielectric is filled in the first trenches following a first thermal oxidation forming a first liner oxide surrounding the first trenches. A second STI trench etching process forms second trenches with one or more sizes in a second dimension to define active regions separated from each other by the first trenches filled with the first dielectric material and second trenches. A second dielectric is filled in the second trenches following a second thermal oxidation forming a second liner oxide surrounding the second trenches. Active region encroachment caused by the first and second thermal oxidation is reduced by doing the two individual STI trench etching processes.

A method for forming a shallow trench isolation (STI) structure using two individual STI trench etching processes is provided. A first STI etching process forms first trenches with one or more sizes in rows along a first dimension in a silicon substrate. A first dielectric is filled in the first trenches following a first thermal oxidation forming a first liner oxide surrounding the first trenches. A second STI trench etching process forms second trenches with one or more sizes in a second dimension to define active regions separated from each other by the first trenches filled with the first dielectric material and second trenches. A second dielectric is filled in the second trenches following a second thermal oxidation forming a second liner oxide surrounding the second trenches. Active region encroachment caused by the first and second thermal oxidation is reduced by doing the two individual STI trench etching processes.

A semiconductor memory device, includes: a first region including a first memory cell array; a second region arranged with the first region; and a third region arranged with the second region and including a second memory cell array. Each memory cell array includes: a field effect transistor above a semiconductor substrate, including a gate, a source, and a drain, the gate being connected to a first wiring, and one of the source and the drain being connected to a second wiring; and a capacitor below the transistor, including a first electrode connected to the other of the source and the drain, a second electrode facing the first electrode, and a third electrode connected to the second electrode and extending to the second region. The second region includes a conductor, the conductor connecting the third electrodes of the memory cell arrays.

A method for forming a semiconductor memory structure includes forming a hard mask layer over a semiconductor substrate, etching the hard mask layer to form first mask patterns and second mask patterns, transferring the first and second mask patterns to the substrate to form semiconductor blocks, and thinning down the second mask element. After thinning down the second mask element, the thickness of the second mask elements is less than the thickness of the first mask elements. The method also includes forming a first capping layer to laterally extend over the first mask patterns and the second mask patterns, and etching the first capping layer and the second mask pattern to form contact openings.

A semiconductor memory device is provided in the present invention, including a substrate, word lines in the substrate, bit lines over the word lines, partition structures between the bit lines and right above the word lines, storage node contacts in spaces defined by the bit lines and the partition structures and electrically connecting with the substrate, wherein a portion of the storage node contact protruding from top surfaces of the bit lines and the partition structures is contact pad, and contact pad isolation structures on the partition structures and between the contact pads, wherein the contact pad isolation structure includes outer silicon nitride layers and inner silicon oxide layers.

A sense amplifier circuit architecture includes a first NMOS layout, a second NMOS layout, a first PMOS layout, a second PMOS layout, a first processing structure layout and a second processing structure layout. The first NMOS layout includes first N-type active layers and first gate layers discretely arranged on the first N-type active layers. The second NMOS layout includes second N-type active layers and second gate layers discretely arranged on the second N-type active layers. The first PMOS layout includes first P-type active layers and third gate layers discretely arranged on the first P-type active layers. The second PMOS layout includes second P-type active layers and fourth gate layers discretely arranged on the second P-type active layers. The first processing structure layout includes first active layers and a first isolation gate. The second processing structure layout includes second active layers and a second isolation gate.