A semiconductor structure and a method for forming a semiconductor structure are provided. The method includes receiving a semiconductor substrate having a first region and a second region; forming a dielectric layer over the semiconductor substrate; removing portions of the dielectric layer to form a dielectric structure in the first region, wherein the dielectric structure includes a base structure and a plurality of first isolation structures over the base structure; forming a semiconductor layer covering the first region and the second region; removing a portion of the semiconductor layer to expose a top surface of the plurality of first isolation structures; and forming a plurality of second isolation structures in the second region.

A transistor includes a first gate electrode, a composite channel layer, a first gate dielectric layer, and source/drain contacts. The composite channel layer is over the first gate electrode and includes a first capping layer, a crystalline semiconductor oxide layer, and a second capping layer stacked in sequential order. The first gate dielectric layer is located between the first gate electrode and the composite channel layer. The source/drain contacts are disposed on the composite channel layer.

A method for forming an integrated circuit device is provided. The method includes forming a transistor over a frontside of a substrate; forming an interconnect structure over the transistor; depositing a first transition metal layer over the interconnect structure; performing a plasma treatment to turn the first transition metal layer into a first transition metal dichalcogenide layer; forming a dielectric layer over the first transition metal dichalcogenide layer; forming a first gate electrode over the dielectric layer and a first portion of the first transition metal dichalcogenide layer; and forming a first source contact and a first drain contact respectively connected with a second portion and a third portion of the first transition metal dichalcogenide layer, the first portion of the first transition metal dichalcogenide layer being between the second and third portions of the first transition metal dichalcogenide layers.

A semiconductor device includes first to tenth transistors and first to fourth capacitors. Gates of the first and the fourth transistors are electrically connected to each other. First terminals of the first, second, fifth, and eighth transistors are electrically connected to a first terminal of the fourth capacitor. A second terminal of the fifth transistor is electrically connected to a gate of the sixth transistor and a first terminal of the second capacitor. A second terminal of the eighth transistor is electrically connected to a gate of the ninth transistor and a first terminal of the third capacitor. Gates of the second, seventh, and tenth transistors are electrically connected to first terminals of the third and fourth transistors and a first terminal of the first capacitor. First terminals of the sixth and seventh transistors are electrically connected to a second terminal of the second capacitor.

A semiconductor device structure includes a first MOSFET device disposed at a first region of a semiconductor substrate, the first MOSFET device comprises a bulk semiconductor layer contacting the semiconductor substrate, and the bulk semiconductor layer has a first height, a first gate structure disposed over the bulk semiconductor layer, and first S/D regions disposed in the bulk semiconductor layer on opposite sides of the first gate structure; a second MOSFET device disposed at a second region of the semiconductor substrate, the second MOSFET device comprises a semiconductor layer disposed over the semiconductor substrate, and the semiconductor layer has a second height different than the first height, a second gate structure disposed over the semiconductor layer, and second S/D regions disposed in the semiconductor layer on opposite sides of the second gate structure; an insulator between and in contact with the semiconductor substrate and semiconductor layer; and a spacer layer isolating the first and second MOSFET devices, and a portion of the spacer layer is disposed between and in contact with the insulator layer and bulk semiconductor layer.

A wafer having a semiconductor substrate including a peripheral region and a central region, an insulating layer and a semiconductor layer is prepared first. Next, a plurality of trenches penetrating through the semiconductor layer and the insulating layer and reaching an inside of the semiconductor substrate are formed. Next, an inside of each of the plurality of trenches is filled with an insulating film, so that a plurality of element isolating portions is formed. Next, in the central region, the semiconductor layer exposed from a resist pattern is removed. The end portion closest to the outer edge of the semiconductor substrate among ends of the resist pattern used for removing the semiconductor layer in the central region is formed so as to be positioned closer to the outer edge of the semiconductor substrate than a position of the end portion closest to the outer edge of the semiconductor substrate among ends of the resist pattern used for forming the trenches.

An integrated circuit (IC) structure, a switch and related method, are disclosed. The IC structure includes an active device, e.g., a switch, over a bulk semiconductor substrate, and an isolation structure under the active device in the bulk semiconductor substrate. The isolation structure may include a trench isolation adjacent the active device in the bulk semiconductor substrate, a dielectric layer laterally adjacent the trench isolation and over the active device, and a porous semiconductor layer in the bulk semiconductor substrate under the dielectric layer laterally adjacent the trench isolation. The IC structure employs a lower cost, low resistivity bulk semiconductor substrate rather than a semiconductor-on-insulator (SOI) substrate, yet it has better performance characteristics for RF switches than an SOI substrate.

On a semiconductor substrate having an SOI region and a bulk silicon region formed on its upper surface, epitaxial layers are formed in source and drain regions of a MOSFET formed in the SOI region, and no epitaxial layer is formed in source and drain regions of a MOSFET formed in the bulk silicon region. By covering the end portions of the epitaxial layers with silicon nitride films, even when diffusion layers are formed by implanting ions from above the epitaxial layers, it is possible to prevent the impurity ions from being implanted down to a lower surface of a silicon layer.

A first transistor, a second transistor, a capacitor, and first to third conductors are included. The first transistor includes a first gate, a source, and a drain. The second transistor includes a second gate, a third gate over the second gate, first and second low-resistance regions, and an oxide sandwiched between the second gate and the third gate. The capacitor includes a first electrode, a second electrode, and an insulator sandwiched therebetween. The first low-resistance region overlaps with the first gate. The first conductor is electrically connected to the first gate and is connected to a bottom surface of the first low-resistance region. The capacitor overlaps with the first low-resistance region. The second conductor is electrically connected to the drain. The third conductor overlaps with the second conductor and is connected to the second conductor and a side surface of the second low-resistance region.

A display device capable of performing image processing is provided. A memory node is provided in each pixel included in the display device. An intended correction data is held in the memory node. The correction data is calculated by an external device and written into each pixel. The correction data is added to image data by capacitive coupling, and the resulting data is supplied to a display element. Thus, the display element can display a corrected image. The correction enables image upconversion, for example.