A semiconductor manufacturing apparatus according to an embodiment includes: a stage to have a plurality of pins to hold a semiconductor substrate having a first surface on which a film to be etched is formed and a second surface positioned on an opposite side to the first surface; a nozzle to eject a liquid chemical toward the first surface of the semiconductor substrate from above the stage; and an optical measurer to radiate light toward the second surface of the semiconductor substrate from a side of the stage during ejection of the liquid chemical, and to measure a displacement amount of the semiconductor substrate based on a state of reception of light reflected on the second surface.

In a variety of processes for forming electronic devices that use spin-on dielectric materials, properties of the spin-on dielectric materials can be enhanced by curing these materials using plasma doping. For example, hardness and Young's modulus can be increased for the cured material. Other properties may be enhanced. The plasma doping to cure the spin-on dielectric materials uses a mechanism that is a combination of plasma ion implant and high energy radiation associated with the species ionized. In addition, physical properties of the spin-on dielectric materials can be modified along a length of the spin-on dielectric materials by selection of an implant energy and dopant dose for the particular dopant used, corresponding to a selection variation with respect to length.

A planarization apparatus, including a chuck having a first surface and a second surface at two opposing sides thereof. The chuck includes a first zone extending along a periphery of the chuck, a second zone at an inner portion of the chuck, the second zone being surrounded by the first zone; and a flexure connecting the first zone with the second zone. The first zone includes a first member extending along the first surface from the flexure and a first ring land protruding from the first member adjacent to the flexure.

A coating liquid for forming a metal oxide film, the coating liquid including: a metal source, which is at least one selected from the group consisting of inorganic salts, oxides, hydroxides, metal complexes, and organic acid salts; at least one alkali selected from the group consisting of organic alkalis and inorganic alkalis; and a solvent.

Provided is a method for manufacturing a semiconductor device suitable for achieving low wiring resistance between semiconductor elements that is bonded via an adhesive layer and multi-layered. The method according to the present invention is as follows. First, a wafer laminate (W) is prepared, the wafer laminate (W) including a wafer (10) having a circuit forming surface (10a), a wafer (20) having a main surface (20a) and a back surface (20b), and an adhesive layer (30) containing an SiOC-based polymer. Then, a hole (H) is formed in the wafer laminate (W) by etching the wafer laminate (W) from the wafer (20) side via a mask pattern masking a portion of the main surface (20a) side of the wafer (20), the hole (H) extending through the wafer (20) and the adhesive layer (30) and reaching a wiring pattern (12b) in the wafer (10). Then, an insulating film (41) is formed on an inner surface of the hole (H). Then, the insulating film (41) on a bottom surface of the hole (H) is removed. Then, the wafer laminate (W) is subjected to a cleaning treatment (an oxygen plasma treatment and/or an Ar sputtering treatment). Then, a conductive portion is formed in the hole (H).

An object of the present invention is to provide: a compound containing an imide group which is not only cured under film formation conditions of inert gas as well as air and has excellent heat resistance and properties of filling and planarizing a pattern formed on a substrate, but can also form an organic underlayer film with favorable adhesion to a substrate, and a material for forming an organic film containing the compound. A material for forming an organic film, including: (A) a compound for forming an organic film shown by the following general formula (1A); and (B) an organic solvent, ##STR00001## noting that in the general formula (1B), when W.sub.1 represents ##STR00002##  R.sub.1 does not represent any of ##STR00003##

A semiconductor device and method of manufacture which utilize isolation structures between semiconductor regions is provided. In embodiments different isolation structures are formed between different fins in different regions with different spacings. Some of the isolation structures are formed using flowable processes. The use of such isolation structures helps to prevent damage while also allowing for a reduction in spacing between different fins of the devices.

In a variety of processes for forming electronic devices that use spin-on dielectric materials, properties of the spin-on dielectric materials can be enhanced by curing these materials using plasma doping. For example, hardness and Young's modulus can be increased for the cured material. Other properties may be enhanced. The plasma doping to cure the spin-on dielectric materials uses a mechanism that is a combination of plasma ion implant and high energy radiation associated with the species ionized. In addition, physical properties of the spin-on dielectric materials can be modified along a length of the spin-on dielectric materials by selection of an implant energy and dopant dose for the particular dopant used, corresponding to a selection variation with respect to length.

Methods and improved process flows are provided herein for forming self-aligned contacts using spin-on silicon carbide (SiC). More specifically, the disclosed methods and process flows form self-aligned contacts by using spin-on SiC as a cap layer for at least one other structure, instead of depositing a SiC layer via plasma vapor deposition (PVD), chemical vapor deposition (CVD), atomic layer deposition (ALD), etc. The other structure may be a source and drain contact made through the use of a trench conductor. By utilizing spin-on SiC as a cap layer material, the disclosed methods and process flows avoid problems that typically occur when SiC is deposited, for example by CVD, and subsequently planarized. As such, the disclosed methods and process flows improve upon conventional methods and process flows for forming self-aligned contacts by reducing defectivity and improving yield.

Materials and methods for modifying semiconducting substrate surfaces in order to dramatically change surface energy are provided. Preferred materials include perfluorocarbon molecules or polymers with various functional groups. The functional groups (carboxylic acids, hydroxyls, epoxies, aldehydes, and/or thiols) attach materials to the substrate surface by physical adsorption or chemical bonding, while the perfluorocarbon components contribute to low surface energy. Utilization of the disclosed materials and methods allows rapid transformation of surface properties from hydrophilic to hydrophobic (water contact angle 120° and PGMEA contact angle) 70°. Selective liquiphobic modifications of copper over Si/SiOx, TiOx over Si/SiOx, and SiN over SiOx are also demonstrated.