There is provided a drying apparatus for covering an upper surface of the substrate with an uneven pattern formed thereon with a liquid film and subsequently drying the substrate, including: a first heat transfer part whose temperature is adjusted to a first temperature, wherein a first heat is transferred between the first heat transfer part and the substrate by a first temperature difference; a second heat transfer part whose temperature is adjusted to a second temperature different from the first temperature, wherein a second heat is transferred between the second heat transfer part and the substrate by a second temperature difference; and a controller configured to control the first temperature and the second temperature and to control a surface tension distribution of the liquid film so as to control an agglomeration of the liquid film.

An insulating layer structure for a semiconductor product. The insulating layer structure includes a device substrate, a supporting substrate and a thin film layer. The device substrate and the supporting substrate are silicon wafers. The thin film layer(s) is/are arranged on the device substrate or/and the supporting substrate. The device substrate and the supporting substrate are bonded together through the thin film layer arranged on at least one of the device substrate and the supporting substrate to form an integral multilayer SOI structure. The insulating layer structure formed by the present invention solves problems of serious spontaneous heating of an existing SOI device, severe warpage of an existing SOI structure caused by high-temperature annealing, a poor radio frequency characteristic and the like, and has a predictable relatively higher economic and social value.

A substrate processing apparatus includes a substrate holding device, a rotation mechanism, a drying liquid supply nozzle, a movement mechanism, a flow rate control mechanism, and a control device including circuitry which controls one or more of the rotation mechanism, movement mechanism and flow rate control mechanism such that the drying liquid forms a drying liquid flow line having distance (L) equal to or less than preset upper limit distance (M), where when a liquid contact point is position at which the drying liquid discharged from the nozzle reaches the substrate, the flow line is formed when the liquid contact point is moved from a center portion of the substrate toward a peripheral edge portion of the substrate, and the distance (L) of the flow line is measured from center of the liquid contact point to an edge of the flow line on a rotation center side of the substrate.

A substrate is provided with a monocrystalline silicon-germanium layer with a first surface covered by a protective oxide obtained by wet process and having a degradation temperature. The protective oxide is transformed into fluorinated salt which is then eliminated. The substrate is placed in a processing chamber at a lower temperature than the degradation temperature and is subjected to a temperature ramp up to a higher temperature than the degradation temperature. The first surface is annealed in a hydrogen atmosphere devoid of silicon, germanium and precursors of the materials forming the target layer. When the temperature ramp is applied, a silicon precursor is inserted in the processing chamber between a loading temperature and the degradation temperature to deposit a monocrystalline buffer layer. A mono-crystalline target layer is deposited by chemical vapour deposition.

Disclosed is a substrate processing apparatus. The substrate processing apparatus includes a container body, and a holding member that conveys the substrate from an outside of the container body into the container body and holds the substrate inside the container body during the processing. A substrate support pin supporting a wafer and a cooling plate cooling the holding member are provided outside the container body.

A method for fabricating semiconductor device includes the steps of: forming fin-shaped structures on a substrate; using isopropyl alcohol (IPA) to perform a rinse process; performing a baking process; and forming a gate oxide layer on the fin-shaped structures. Preferably, a duration of the rinse process is between 15 seconds to 60 seconds, a temperature of the baking process is between 50 C. to 100 C., and a duration of the baking process is between 5 seconds to 120 seconds.

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.

Various embodiments comprise apparatuses for cleaning and drying a substrate and methods of operating the apparatuses. In one embodiment, an exemplary apparatus includes a vertical substrate holder to hold and rotate the substrate at various speeds. An inner shield and an outer shield, when in a closed position, surround the vertical substrate holder during operation of the apparatus. Each of the inner shield and the outer shield can operate independently in at least one of rotational speed and direction from the other shield. A front-side spray jet and a back-side spray jet are arranged to spray at least one fluid onto both sides of the substrate and edges of the substrate substantially concurrently. A gas flow, combined with a high rotational-speed of the shields and substrate, assist in drying the substrate. Additional apparatuses and methods of forming the apparatuses are disclosed.

A method for in-situ dry cleaning of a SiGe semiconductor surface, ex-situ degreases the Ge containing semiconductor surface and removes organic contaminants. The surface is then dosed with HF (aq) or NH.sub.4F (g) generated via NH.sub.3+NH or NF.sub.3 with H.sub.2 or H.sub.2O to remove oxygen containing contaminants. In-situ dosing of the SiGe surface with atomic H removes carbon containing contaminants.

The present invention relates to a novel process for producing a surface-treated gallium arsenide substrate as well as novel provided gallium arsenide substrates as such as well as the use thereof. The improvement of the process according to the invention is based on a particular final surface treatment with an oxidation treatment of at least one surface of the gallium arsenide substrate in dry condition by means of UV radiation and/or ozone gas, a contacting of the at least one surface of the gallium arsenide substrate with at least one liquid medium and a Marangoni drying of the gallium arsenide substrate. 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, specifically by means of ellipsometric lateral substrate mapping for the optical contact-free quantitative characterization.