Methods for inducing reversible or permanent conductivity in wide band gap metal oxides such as Ga.sub.2O.sub.3, using light without doping, as well as related compositions and devices, are described.

An object of the present invention is to provide a technique suitable for achieving low wiring resistance and reducing a variation in the resistance value between semiconductor elements to be multilayered in a method of manufacturing a semiconductor device in which the semiconductor elements are multilayered through laminating semiconductor wafers via an adhesive layer. The method of the present invention includes first to third processes. In the first process, a wafer laminate Y is prepared, the wafer laminate Y having a laminated structure including a wafer 3, wafers 1T with a thickness from 1 to 20 um, and an adhesive layer 4 with a thickness from 0.5 to 4.5 m interposed between a main surface 3a of the wafer 3 and a back surface 1b of the wafer 1T. In the second process, holes extending from the main surface 1a of the wafer 1T and reaching a wiring pattern of the wafer 3 are formed by a predetermined etching treatment. In the third process, the holes are filled with a conductive material to form through electrodes. The adhesive layer 4 has an etching rate of 1 to 2 m/min in dry etching performed using an etching gas containing CF.sub.4, O.sub.2, and Ar at a volume ratio of 100:400:200 under predetermined conditions.

A semiconductor device in which variation in characteristics is small is provided. A first insulator is formed; a first insulator is formed; a conductor is formed over the first insulator; a second insulator is formed over the conductor; a third insulator is formed over the second insulator; an oxide is formed over the third insulator; first heat treatment is performed; and second heat treatment following the first heat treatment is performed. The temperature of the first heat treatment is lower than the temperature of the second heat treatment.

A method for manufacturing a display module includes preparing a display module comprising a plurality of layers and forming a through-hole in the display module. The forming the through-hole includes performing a first irradiation process of irradiating a first laser beam along a first boundary defining the through-hole, performing a second irradiation process of irradiating a second laser beam along a second boundary after the first irradiation process, and performing a third irradiation process of irradiating a third laser beam along a third boundary after the second irradiation process. A time interval between the first irradiation process and the second irradiation process may be different from a time interval between the second irradiation process and the third irradiation process.

A fabrication method of a semiconductor device comprises the steps of: providing a substrate, which is divided into several chip areas; forming a protective layer on the substrate, the protective layer covers the scribe lines and the chip areas; exposing and developing the protective layer to form a plurality of grooves in the protective layer over the chip areas, and the depth of the grooves is smaller than the initial thickness of the protective layer.

A multilayer structure comprises: a substrate; and, a plurality of polymerizable layers successively deposited on the substrate, with each successive layer having a greater dielectric polarizability than the preceding layer(s), so that each successive layer will absorb microwave energy preferentially to the preceding layer(s). In this way, successive layers can be cured without over-curing the preceding layers. The individual layers are preferably materials from a single chemical family (e.g., epoxies, polyimides, PBO, etc.) and have similar properties after curing. The dielectric polarizabilities may be adjusted by modifying such factors as chain endcap dipole strength, cross-linker dipole strength, promoter, solvent, and backbone type. The invention is particularly suitable for producing various polymer layers on silicon for electronic applications. An associated method is also disclosed.

A curable composition for optical imprinting which is excellent in ink jet adequacy and releasability, a pattern forming method, a fine pattern, and a method for manufacturing a semiconductor device are provided. The curable composition for optical imprinting contains a polymerizable compound (A), a photopolymerization initiator (B), and a compound (C) expressed by General Formula (I); in General Formula (I), A represents a dihydric to hexahydric polyhydric alcohol residue. p represents 0 to 2, l q represents 1 to 6, p+q represents an integer of 2 to 6, each of m and n independently represents 0 to 20. r expressed by Formula (1) is 6 to 20. Each R independently represents an alkyl group having 1 to 10 carbon atoms, an aryl group, or an acyl group. ##STR00001##

Techniques are disclosed for realizing a two-dimensional target lithography feature/pattern by decomposing (splitting) it into multiple unidirectional target features that, when aggregated, substantially (e.g., fully) represent the original target feature without leaving an unrepresented remainder (e.g., a whole-number quantity of unidirectional target features). The unidirectional target features may be arbitrarily grouped such that, within a grouping, all unidirectional target features share a common target width value. Where multiple such groupings are provided, individual groupings may or may not have the same common target width value. In some cases, a series of reticles is provided, each reticle having a mask pattern correlating to a grouping of unidirectional target features. Exposure of a photoresist material via the aggregated series of reticles substantially (e.g., fully) produces the original target feature/pattern. The pattern decomposition techniques may be integrated into any number of patterning processes, such as litho-freeze-litho-etch and litho-etch-litho-etch patterning processes.

A semiconductor device having favorable electrical characteristics is provided. A first oxide is formed over a substrate; a first insulator is formed over the first oxide; an opening reaching the first oxide is formed in the first insulator; a first oxide film is deposited in contact with the first oxide and the first insulator in the opening; a first insulating film is deposited over the first oxide film; microwave treatment is performed from above the first insulating film; heat treatment is performed on one or both of the first insulating film and the first oxide; a first conductive film is deposited over the first insulating film; and part of the first oxide film, part of the first insulating film, and part of the first conductive film are removed until a top surface of the first insulator is exposed, so that a second oxide, a second insulator, and a first conductor are formed. The microwave treatment is performed using a gas containing oxygen under reduced pressure, and the heat treatment is performed under reduced pressure.

A method of forming a semiconductor device, includes: forming a design pattern on a substrate, wherein the design pattern protrudes from the substrate; forming a filling layer on the substrate, wherein the filling layer at least partially covers the design pattern; forming a polishing resistance pattern adjacent to the design pattern in the filling layer using a laser irradiation process and/or an ion implantation process; and removing the filling layer using a chemical mechanical polishing (CMP) process to expose the design pattern.