A substrate processing device is provided. The substrate processing device includes a processing container including a mounting table, a refrigeration device disposed to have a gap between the mounting table and the refrigeration device, a first elevating device configured to raise or lower the refrigeration device, a refrigerant flow path to supply a refrigerant to the gap, a compression device configured to compress the refrigerant supplied to the refrigerant flow path, and refrigerant transfer pipes connected to both a first connection-fixing unit which is a flow path port of the refrigerant flow path and a second connection-fixing unit fluid-communicating with the compression device. Further, each of the refrigeration transfer pipes extends such that at least a portion of the refrigerant transfer pipe is curved between the first and second connection-fixing units, and each of the refrigerant transfer pipes is placed on a support member at the second connection-fixing unit.

In a plasma enhanced physical vapor deposition of a material onto workpiece, a metal target faces the workpiece across a target-to-workpiece gap less than a diameter of the workpiece. A carrier gas is introduced into the chamber and gas pressure in the chamber is maintained above a threshold pressure at which mean free path is less than 5% of the gap. RF plasma source power from a VHF generator is applied to the target to generate a capacitively coupled plasma at the target, the VHF generator having a frequency exceeding 30 MHz. The plasma is extended across the gap to the workpiece by providing through the workpiece a first VHF ground return path at the frequency of the VHF generator.

In a plasma enhanced physical vapor deposition of a material onto workpiece, a metal target faces the workpiece across a target-to-workpiece gap less than a diameter of the workpiece. A carrier gas is introduced into the chamber and gas pressure in the chamber is maintained above a threshold pressure at which mean free path is less than 5% of the gap. RF plasma source power from a VHF generator is applied to the target to generate a capacitively coupled plasma at the target, the VHF generator having a frequency exceeding 30 MHz. The plasma is extended across the gap to the workpiece by providing through the workpiece a first VHF ground return path at the frequency of the VHF generator.

In one embodiment, a semiconductor manufacturing apparatus includes a carrier having first and second ends extending in a first direction, and third and fourth ends extending in a second direction and being not shorter than the first and second ends. The apparatus further includes a member holder having a magnet placement face on which first and second magnetic-pole portions are placed, the magnet placement face having fifth and sixth ends extending in the first direction and being shorter than the first and second ends, and seventh and eighth ends extending in the second direction, being longer than the fifth and sixth ends, and being longer than the third and fourth ends. The apparatus further includes a carrier transporter transporting the carrier along the first direction. The carrier transporter can transport the carrier such that the third and fourth ends pass under a center line of the magnet placement face.

In one embodiment, a semiconductor manufacturing apparatus includes a carrier having first and second ends extending in a first direction, and third and fourth ends extending in a second direction and being not shorter than the first and second ends. The apparatus further includes a member holder having a magnet placement face on which first and second magnetic-pole portions are placed, the magnet placement face having fifth and sixth ends extending in the first direction and being shorter than the first and second ends, and seventh and eighth ends extending in the second direction, being longer than the fifth and sixth ends, and being longer than the third and fourth ends. The apparatus further includes a carrier transporter transporting the carrier along the first direction. The carrier transporter can transport the carrier such that the third and fourth ends pass under a center line of the magnet placement face.

Methods and apparatus for forming substrates having magnetically patterned surfaces is provided. A magnetic layer comprising one or more materials having magnetic properties is formed on a substrate. The magnetic layer is subjected to a patterning process in which selected portions of the surface of the magnetic layer are altered such that the altered portions have different magnetic properties from the non-altered portions without changing the topography of the substrate. A protective layer and a lubricant layer are deposited over the patterned magnetic layer. The patterning is accomplished through a number of processes that expose substrates to energy of varying forms. Apparatus and methods disclosed herein enable processing of two major surfaces of a substrate simultaneously, or sequentially by flipping. In some embodiments, magnetic properties of the substrate surface may be uniformly altered by plasma exposure and then selectively restored by exposure to patterned energy.

According to one embodiment, an apparatus of manufacturing a radiation detection panel, includes an evaporation source configured to evaporate a scintillator material and emit the scintillator material vertically upward, a holding mechanism located vertically above the evaporation source, and holding a photoelectric conversion substrate, and a heat conductor arranged opposite to the holding mechanism with a gap.

A masking fixture for coating dishware includes a support base having a first ferromagnetic member and a contoured support surface configured for engagement with a lower contour of the dishware. A mask base includes a second ferromagnetic member. The second ferromagnetic member is magnetically attracted to the first ferromagnetic member. The mask base includes a mask guide. A mask includes a masking surface configured for engagement with the upper contour. The mask is moveably coupled to the mask guide for movement between an engaged position in which the masking surface is engageable with the upper contour and a disengaged position. The mask can be moved to the disengaged position to facilitate removal of the mask base from the dishware after a coating operation.

One embodiment of the present invention can provide a system for fabrication of a photovoltaic structure. The system can include a physical vapor deposition tool configured to sequentially deposit a transparent conductive oxide layer and a metallic layer on an emitter layer formed in a first surface of a Si substrate, without requiring the Si substrate to be removed from the physical vapor deposition tool after depositing the transparent conductive oxide layer. The system can further include an electroplating tool configured to plate a metallic grid on the metallic layer and a thermal annealing tool configured to anneal the transparent conductive oxide layer.

One embodiment of the present invention can provide a system for fabrication of a photovoltaic structure. The system can include a physical vapor deposition tool configured to sequentially deposit a transparent conductive oxide layer and a metallic layer on an emitter layer formed in a first surface of a Si substrate, without requiring the Si substrate to be removed from the physical vapor deposition tool after depositing the transparent conductive oxide layer. The system can further include an electroplating tool configured to plate a metallic grid on the metallic layer and a thermal annealing tool configured to anneal the transparent conductive oxide layer.