This disclosure provides an array substrate and a preparation method thereof as well as a touch display device. The array substrate includes: a substrate; a plurality of gate lines and a plurality of data lines located on the substrate, wherein the plurality of gate lines extend along a first direction and are arranged in a second direction different from the first direction, the plurality of data lines extend in the second direction and are arranged in the first direction, the plurality of gate lines intersect with the plurality of data lines to define a plurality of pixel areas; and a plurality of touch signal lines located on the substrate, wherein the plurality of touch signal lines extend in the second direction, each of the plurality of touch signal lines comprises a lower touch signal line and an upper touch signal line, and an edge of the upper touch signal line is spaced apart from an edge of the lower touch signal line in the first direction.

Integrated circuit structures having backside source or drain contact differentiated access are described. In an example, an integrated circuit structure includes first, second and third pluralities of horizontally stacked nanowires or fins, and first, second and third gate stacks. A first epitaxial source or drain structure is between the first plurality of horizontally stacked nanowires or fin and the second plurality of horizontally stacked nanowires or fin, the first epitaxial source or drain structure over a first conductive material having a first depth below the first epitaxial source or drain structure. A second epitaxial source or drain structure is between the second plurality of horizontally stacked nanowires or fin and the third plurality of horizontally stacked nanowires or fin, the second epitaxial source or drain structure over a second conductive material having a second depth below the second epitaxial source or drain structure, the second depth greater than the first depth.

A semiconductor device that has two transistors and a source/drain contact. The first transistor has a layer of semiconductor material that acts as a channel, a structure that serves as a gate and wraps around the semiconductor channel layer, and two epitaxy structures on either end of the semiconductor channel layer that function as the source and drain. The second transistor is situated above the first transistor and has similar components, including a semiconductor channel layer, gate structure, and source/drain epitaxy structures. The connection between the first and second source/drain epitaxy structures is made by a source/drain contact that passes through one of the second source/drain epitaxy structures. This contact is made up of a metal plug and a metal liner that lines the plug.

A structure includes a substrate, a first transistor on the substrate and a second transistor on the substrate. The second transistor is spaced apart from the first transistor by an isolation region. At least one stress-inducing liner is over the first transistor and the second transistor. An opening extends through at least one stress-inducing liner over at least the isolation region, and a dielectric layer is in at least a portion of the opening. The structure allows for local enhanced high-pressure deuterium (HPD) passivation, which increases threshold voltage of the transistors and improves hot carrier injection with no additional masking. A method of forming the structure is also provided.

An integrated circuit device includes a first semiconductor layer, a second semiconductor layer, a first source/drain epitaxial structure, a second source/drain epitaxial structure, and a first contact plug. The second semiconductor layer is above the first semiconductor layer. The first and second semiconductor layers are vertically spaced apart from each other. The first source/drain epitaxial structure is on a side of the first semiconductor layer. The second source/drain epitaxial structure is on a side of the second semiconductor layer and above the first source/drain epitaxial structure. The first source/drain epitaxial structure has a portion extending beyond a sidewall of the second source/drain epitaxial structure from a top view. The first contact plug is over a frontside of the first source/drain epitaxial structure. The first contact plug overlaps the portion of the first source/drain epitaxial structure from the top view.

A 3D semiconductor device, the device including: a first level including a first single crystal layer and including first transistors which each includes a single crystal channel; a first metal layer; a second metal layer overlaying the first metal layer; a second level including second transistors, first memory cells including at least one second transistor, and overlaying the second metal layer; a third level including third transistors and overlaying the second level; a fourth level including fourth transistors, second memory cells including at least one fourth transistor, and overlaying the third level, where at least one of the second transistors includes a metal gate, where the first level includes memory control circuits which control writing to the second memory cells, and at least one Phase-Lock-Loop (PLL) circuit or at least one Digital-Lock-Loop (DLL) circuit.

Various embodiments of the present disclosure are directed towards an integrated chip. The integrated chip comprises a semiconductor substrate. A semiconductor layer is disposed over the semiconductor substrate. An insulating structure is buried between the semiconductor substrate and the semiconductor layer. The insulating structure has a first region and a second region. The insulating structure has a first thickness in the first region of the insulating structure, and the insulating structure has a second thickness different than the first thickness in the second region of the insulating structure.

A high-voltage switching device that can be fabricated in a standard low-voltage process, such as CMOS, and more specifically SOI CMOS. Embodiments include integrated circuits that combine, in a unitary structure, a FET device and an integrated, co-fabricated modulated resistance region (MRR) controlled by one or more Voltage-Drop Modulation Gates (VDMGs). The VDMGs are generally biased independently of the gate of the FET device, and in such a way as to protect each VDMG from excessive and potentially destructive voltages. In a first embodiment, an integrated circuit high voltage switching device includes a transistor structure including a source, a gate, and an internal drain; an MRR connected to the internal drain of the transistor structure; at least one VDMG that controls the resistance of the MRR; and a drain electrically connected to the MRR. Each VDMG at least partially depletes the MRR upon application of a bias voltage.

A microelectronic structure including a logic device and a passive device. The passive device includes a doped substrate, a silicide layer located on a backside surface of the doped substrate, and a metal plane located on a backside surface of the silicide layer.

A dielectric layer is on top of a first semiconductor stack. The first semiconductor stack is compressively strained. A second semiconductor stack is on top of the dielectric layer. The second semiconductor stack is tensely strained.