A method for forming a semiconductor structure is provided. The method includes forming a first material and a second material on a semiconductor substrate. The first material is different from the second material. The method also includes heating the first material to a first temperature and the second material to a second temperature with a laser beam. The first temperature is different from the second temperature. The method also includes depositing a third material on the first material.

A field effect transistor includes: a semiconductor region including a first inactive region, an active region, and a second inactive region arranged side by side in a first direction; a gate electrode, a source electrode, and a drain electrode on the active region; a gate pad on the first inactive region; a gate guard on and in contact with the semiconductor region, the gate guard being apart from the gate pad and located between an edge on the first inactive region side of the semiconductor region and the gate pad; a drain pad on the second inactive region; a drain guard on and in contact with the semiconductor region, the drain guard being apart from the drain pad and located between an edge on the second inactive region side of the semiconductor region and the drain pad; and a metal film electrically connected to the gate guard.

In a thin film electrode separation method using thermal expansion coefficient, a first solution is coated on a substrate. The first solution coated on the substrate is hardened. The substrate is left in a predetermined time, to form a first thin film having a first thermal expansion coefficient on the substrate. A photoresist is coated on the substrate having the thin film formed thereon. The photoresist coated on the substrate is hardened, to form a photoresist film having a second thermal expansion coefficient. A metal and a passivation layer are formed on the photoresist film. The photoresist film is detached from the first thin film, using difference of a thermal expansion coefficient between the photoresist film and the first thin film.

A tunable amorphous silicon layer for use with multilayer patterning stacks can be used to maximize transparency and minimize reflections so as to improve overlay metrology contrast. By increasing the hydrogen content in the amorphous silicon layer, the extinction coefficient (k) value and the refractive index (n) value can be decreased to desired values. Methods for improving overlay metrology contrast with the tunable amorphous silicon layer are disclosed.

A method for forming openings in an underlayer includes: forming a photoresist layer on an underlayer formed on a substrate; exposing the photoresist layer; forming photoresist patterns by developing the exposed photoresist layer, the photoresist patterns covering regions of the underlayer in which the openings are to be formed; forming a liquid layer over the photoresist patterns; after forming the liquid layer, performing a baking process so as to convert the liquid layer to an organic layer in a solid form; performing an etching back process to remove a portion of the organic layer on a level above the photoresist patterns; removing the photoresist patterns, so as to expose portions of the underlayer by the remaining portion of the organic layer; forming the openings in the underlayer by using the remaining portion of the organic layer as an etching mask; and removing the remaining portion of the organic layer.

A line structure for fan-out circuit having a dense-line area and a fan-out area is provided. The line structure includes a plurality of dense lines arranged in the dense-line area parallel to a first direction, a plurality of pads disposed in the fan-out area, and a plurality of connecting lines arranged in the fan-out area parallel to a second direction. The connecting lines respectively connect one of the dense lines with one of the pads, wherein at least one of the connecting lines is a wavy line.

Ultra-compact inductor devices for use in integrated circuits (e.g., RF ICs) that use 3-dimensional Dirac materials for providing the inductor. Whereas inductors currently require significant real estate on an integrated circuit, because they require use of an electrically conductive winding around an insulative core, or such metal deposited in a spiral geometry, the present devices can be far more compact, occupying significantly less space on an integrated circuit. For example, an ultra-compact inductor that could be included in an integrated circuit may include a 3-dimensional Dirac material formed into a geometric shape capable of inductance (e.g., as simple as a stripe or series of stripes of such material), deposited on a substantially non-conductive (i.e., insulative) substrate, on which the Dirac material in the selected geometric shape is positioned. Low temperature manufacturing methods compatible with CMOS manufacturing are also provided.

A method of manufacturing a semiconductor device according to the present invention includes a step of forming an opening portion in a resist coated on a substrate, a step of coating a thermally-shrinking shrink agent on the resist to fill the opening portion with the shrink agent, a shrinking step of heating and thermally shrinking the shrink agent to reduce a width of the opening portion, a removing step of removing the shrink agent after the shrinking step, a step of forming a metal layer on the resist and in the opening portion after the removing step and a step of removing a portion of the metal layer above the resist and the resist, wherein in the shrinking step, a side surface of the resist forming the opening portion forms a curved surface protruding toward a center portion of the opening portion.

A semiconductor device and a process of forming the semiconductor device are disclosed. The semiconductor device type of a high electron mobility transistor (HEMT) has double SiN films on a semiconductor layer, where the first SiN film is formed by the lower pressure chemical vapor deposition (LPCVD) technique, while, the second SiN film is deposited by the plasma assisted CVD (p-CVD) technique. Moreover, the gate electrode has an arrangement of double metals, one of which contains nickel (Ni) as a Schottky metal, while the other is free from Ni and covers the former metal. A feature of the invention is that the first metal is in contact with the semiconductor layer but apart from the second SiN film.

A semiconductor device manufacturing method includes: forming an electrode including an Ni layer and an Au layer successively stacked on a semiconductor layer; forming a Ni oxide film by performing heat treatment to the electrode at a temperature of 350° C. or more to deposit Ni at least at a part of a surface of the Au layer and to oxidize the deposited Ni; and forming an insulating film in contact with the Ni oxide film and containing Si.