A method for forming a semiconductor structure includes forming a gate structure over a substrate. The method also includes forming a spacer on a sidewall of the gate structure. The method also includes forming a source/drain recess beside the spacer. The method also includes treating the source/drain recess and partially removing the spacers in a first cleaning process. The method also includes treating the source/drain recess with a plasma process after performing the first cleaning process. The method also includes treating the source/drain recess in a second cleaning process after treating the source/drain recess with the plasma process. The method also includes forming a source/drain structure in the source/drain recess after performing the second cleaning process.

A low surface tension liquid supply unit supplies a low surface tension liquid onto the upper surface of a substrate to form a liquid film of the low surface tension liquid on the substrate. An opening is formed in a central region of the liquid film of an organic solvent. The liquid film is removed from the upper surface of the substrate by expanding the opening. While a low surface tension liquid is supplied from the low surface tension liquid supply unit, to the liquid film, toward a liquid landing point set outside the opening, the liquid landing point is moved so as to follow the expansion of the opening. While an facing surface of a drying head faces a dry region set inside the opening to form a low-humidity space between the facing surface and the dry region, with the low-humidity space having a humidity lower than that outside the space, the dry region and the facing surface are moved so as to follow the expansion of the opening.

A plasma treatment apparatus includes a discharge device generating plasma under atmospheric pressure, and a nonmetallic tube capable of advancing the plasma generated in the discharge device. The discharge device includes a discharge body with an internal space, and the plasma being generated in the internal space. The nonmetallic tube is connected to the discharge body, and includes a material different from a material of the discharge body. The plasma is released from the nonmetallic tube to an environment under atmospheric pressure.

The present invention includes a liquid film formation step of supplying a processing liquid in which a sublimation drying processing agent obtained by mixing a first sublimable substance and a second sublimable substance which are different from each other in a eutectic composition or a near-eutectic composition is liquefied, onto a front surface of a substrate on which a pattern is formed, to thereby form a liquid film of the processing liquid on the front surface of the substrate, a solidified film formation step of solidifying the liquid film of the processing liquid, to thereby form a solidified film of the sublimation drying processing agent, and a sublimation step of sublimating the solidified film, to thereby remove the solidified film from the front surface of the substrate.

A method of manufacturing a hybrid substrate is disclosed, which comprises: bonding a first semiconductor substrate to a first combined substrate via at least one layer of dielectric material to form a second combined substrate, the first combined substrate includes a layer of III-V compound semiconductor and a second semiconductor substrate, the layer of III-V compound semiconductor arranged intermediate the layer of dielectric material and second semiconductor substrate; removing the second semiconductor substrate from the second combined substrate to expose at least a portion of the layer of III-V compound semiconductor to obtain a third combined substrate; and annealing the third combined substrate at a temperature about 250 C. to 1000 C. to reduce threading dislocation density of the layer of III-V compound semiconductor to obtain the hybrid substrate.

Provided is a substrate processing apparatus in which a drying process of drying a substrate using a processing fluid in a supercritical state is performed. The substrate processing apparatus includes: a processing container in which the drying process is performed; a discharge valve provided in a discharge flow path that discharges the processing fluid from the processing container; and a controller configured to control the discharge valve. When the inside of the processing container is decompressed from a first pressure at which the processing fluid is in the supercritical state to an atmospheric pressure, through a second pressure than the first pressure and a third pressure lower than the second pressure, the controller controls a valve opening degree of the discharge valve so that the decompression rate is equal from the second pressure to the third pressure.

A method of cleaning and polishing a backside surface of a semiconductor wafer is provided. The method includes placing an abrasive brush, comprising an abrasive tape wound around an outer surface of a brush member of the abrasive brush, on the backside surface of the semiconductor wafer. The method also includes rotating the brush member to polish the backside surface of the semiconductor wafer by abrasive grains formed on the abrasive tape and to clean the backside surface of the semiconductor wafer by the brush member which is not covered by the abrasive tape.

A substrate drying apparatus includes a drying gas nozzle configured so that, assuming that a surface WA of the substrate W is a projection plane, regarding the drying gas flow Gf in the nozzle moving direction Dr, a collision position Gfw with the substrate W is located downstream of a projected discharge position Gfv, the projected discharge position Gfv being a discharge position from the drying gas nozzle projected on the projection plane. In a three-dimensional space, the drying gas flow Gf is inclined, such that an angle formed by an axis Ga of the drying gas flow Gf and a vertical line Wp of the substrate W is in a range from a half contact angle /2 to an angle determined by deducting the half contact angle /2 from 90, the half contact angle /2 being a half of the contact angle .

The present invention relates to a novel provided gallium arsenide substrates as well as the use thereof. The gallium arsenide substrates provided according to the invention exhibit a so far not obtained surface quality, in particular a homogeneity of surface properties, which is detectable by means of optical surface analyzers, by way of example by means of ellipsometric lateral substrate mapping for optical contact-free quantitative characterization.

In some embodiments, a system is provided that includes (1) a loading position; (2) a drying position; (3) a movable tank configured to (a) hold at least one substrate; (b) hold a cleaning chemistry so as to expose a substrate within the movable tank to the cleaning chemistry; and (c) translate between the loading position and the drying position; and (4) a drying station located at the drying position and configured to rinse and dry a substrate as the substrate is unloaded from the movable tank when the movable tank is at the drying position. Numerous other aspects are provided.