An optical image capturing system comprising, in order from an object side to an image side, a first lens element, a second lens element, a third lens element, a fourth lens element, a fifth lens element, a sixth lens element and a seventh lens element. The first lens element with negative refractive power has a concave image-side surface. The second lens element, the third lens element and the fourth lens element have refractive power. The fifth lens element has refractive power. The sixth lens element with refractive power has an image-side surface being concave in a paraxial region and includes at least one convex shape in an off-axial region, wherein the surfaces thereof are aspheric. The seventh lens element with refractive power has an image-side surface being concave in a paraxial region and includes at least one convex shape in an off-axial region, wherein the surfaces thereof are aspheric.

Disclosed is a processing apparatus for performing a processing on a workpiece using gas clusters. The processing apparatus includes: a processing container in which the workpiece is disposed, and an inside of which is maintained in a vacuum state; an exhaust mechanism that exhausts an atmosphere in the processing container; a gas supply unit that supplies a gas containing a cluster generating gas; a cluster nozzle provided in the processing container and configured to generate gas clusters by adiabatically expanding the cluster generating gas and inject a gas component containing the generated gas clusters into the processing container; and a plasma generating mechanism that generates plasma in the cluster nozzle portion. The gas clusters are ionized by the plasma generated in the cluster nozzle portion, and the ionized gas clusters are injected from the cluster nozzle and irradiated onto the workpiece, so that a predetermined processing is performed.

An apparatus for wafer bonding includes a transfer module and a plasma module. The transfer module is configured to transfer a semiconductor wafer. The plasma module is configured to apply a first type of plasma to perform a reduction operation upon a surface of the semiconductor wafer at a temperature within a predetermined temperature range to convert metal oxides on the surface of the semiconductor wafer to metal, and apply a second type of plasma to perform a plasma operation upon the surface of the semiconductor wafer at a room temperature outside the predetermined temperature range to activate a surface of the semiconductor wafer.

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.

An apparatus and methods for selectively etching a particular layer are disclosed. The apparatus and methods are directed towards maintaining the etch rate of the particular layer, while keeping intact a non-etched layer. The etching process may be accomplished by co-flowing a hydrogen precursor gas and a fluorine precursor gas into a remote plasma unit. A resulting gas mixture may then be flowed onto the substrate having a silicon oxide layer as an etch layer and a silicon nitride layer as a non-etched layer, for example. A reaction between the resulting gas mixture and the particular layer takes place, resulting in etching of the silicon oxide layer while maintaining the silicon nitride layer in the above example.

In some embodiments, a method for semiconductor processing preclean includes removing an oxide layer from a substrate using anhydrous hydrogen fluoride in combination with water vapor. A system for the preclean may be configured to separate the anhydrous hydrogen fluoride and the water vapor until they are delivered to a common volume near the substrate. Corrosion within components of the system may be limited by purification of anhydrous hydrogen fluoride, passivation of components, changing component materials, and heating components. Passivation may be achieved by filling a gas delivery component with anhydrous hydrogen fluoride and allowing the anhydrous hydrogen fluoride to remain in the gas delivery component to form a passivation layer. Consistent water vapor delivery may be achieved in part by heating components using heaters.

A method for removing a native oxide film from a semiconductor substrate includes repetitively depositing layers of germanium on the native oxide and heating the substrate causing the layer of germanium to form germanium oxide, desorbing a portion of the native oxide film. The process is repeated until the oxide film is removed. A subsequent layer of strontium titanate can be deposited on the semiconductor substrate, over either residual germanium or a deposited germanium layer. The germanium can be converted to silicon germanium oxide by exposing the strontium titanate to oxygen.

A plasma purge method that is performed after dry cleaning in a process container and before applying a deposition process to a substrate includes: (a) activating and supplying a first process gas containing Cl.sub.2 in the process container; and (b) activating and supplying a second process gas containing H.sub.2 and O.sub.2 in the process container.

There is provided a gas cluster processing device for performing a predetermined process on a workpiece by irradiating the workpiece with a gas cluster, including: a processing container in which the workpiece is disposed; a gas supply part configured to supply a gas for generating the gas cluster; a flow rate controller configured to control a flow rate of the gas supplied from the gas supply part; a cluster nozzle configured to receive the gas for generating the gas cluster at a predetermined supply pressure, spray the gas into the processing container maintained in a vacuum state, and convert the gas into the gas cluster through an adiabatic expansion; and a pressure control part provided in a pipe between the flow rate controller and the cluster nozzle and including a back pressure controller configured to control a supply pressure of the gas for generating the gas cluster.

The production method of a substrate with a patterned film according to the present disclosure includes: a cleaning step of performing UV/ozone cleaning or oxygen plasma cleaning on a substrate with a patterned film to obtain a first substrate with a patterned film, the substrate with a patterned film including a substrate and a patterned film on the substrate, the patterned film containing a fluorine-containing copolymer having a specific repeating unit; and a heating step of heating the first substrate with a patterned film to obtain a second substrate with a patterned film.