Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. A photovoltaic (PV) unit, according to embodiments of the invention, may have a very thin absorber layer produced by epitaxial lift-off (ELO), all electrical contacts positioned on the back side of the PV device to avoid shadowing, and/or front side and back side light trapping employing a diffuser and a reflector to increase absorption of the photons impinging on the front side of the PV unit. Several PV units may be combined into PV banks, and an array of PV banks may be connected to form a PV module with thin strips of metal or conductive polymer applied at low temperature. Such innovations may allow for greater efficiency and flexibility in PV devices when compared to conventional solar cells.

Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. A photovoltaic (PV) unit, according to embodiments of the invention, may have a very thin absorber layer produced by epitaxial lift-off (ELO), all electrical contacts positioned on the back side of the PV device to avoid shadowing, and/or front side and back side light trapping employing a diffuser and a reflector to increase absorption of the photons impinging on the front side of the PV unit. Several PV units may be combined into PV banks, and an array of PV banks may be connected to form a PV module with thin strips of metal or conductive polymer applied at low temperature. Such innovations may allow for greater efficiency and flexibility in PV devices when compared to conventional solar cells.

Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. A photovoltaic (PV) device may incorporate front side and/or back side light trapping techniques in an effort to absorb as many of the photons incident on the front side of the PV device as possible in the absorber layer. The light trapping techniques may include a front side antireflective coating, multiple window layers, roughening or texturing on the front and/or the back sides, a back side diffuser for scattering the light, and/or a back side reflector for redirecting the light into the interior of the PV device. With such light trapping techniques, more light may be absorbed by the absorber layer for a given amount of incident light, thereby increasing the efficiency of the PV device.

Abstract: Embodiments of the invention generally relate to methods for chemical vapor deposition (CVD) processes. In one embodiment, a method for heating a substrate or a substrate susceptor within a vapor deposition reactor system includes exposing a lower surface of a substrate susceptor, such as a wafer carrier, to energy emitted from a heating lamp assembly, and heating the substrate susceptor to a predetermined temperature. The heating lamp assembly generally contains a lamp housing disposed on an upper surface of a support base and contains at least one lamp holder, a plurality of lamps extending from the lamp holder, and a reflector disposed on the upper surface of the support base, next to the lamp holder, and below the lamps. The plurality of lamps may have split filament lamps and/or non-split filament lamps for heating inner and outer portions of the substrate susceptor.

Abstract: Chemical vapor deposition (CVD) processes include, in one embodiment, a method for processing a wafer within a vapor deposition reactor comprising heating at least one wafer disposed on a wafer carrier by exposing a lower surface of the wafer carrier to radiation emitted from a lamp assembly and flowing a liquid through a passageway extending throughout the reactor to maintain the reactor lid assembly at a predetermined temperature, such as within a range from about 275° C. to about 325° C. The method further includes traversing the wafer carrier along a wafer carrier track through at least a chamber containing a showerhead assembly and an isolator assembly and another chamber containing a showerhead assembly and an exhaust assembly, and removing gases from the reactor through the exhaust assembly.

Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. A photovoltaic (PV) device may incorporate front side and/or back side light trapping techniques in an effort to absorb as many of the photons incident on the front side of the PV device as possible in the absorber layer. The light trapping techniques may include a front side antireflective coating, multiple window layers, roughening or texturing on the front and/or the back sides, a back side diffuser for scattering the light, and/or a back side reflector for redirecting the light into the interior of the PV device. With such light trapping techniques, more light may be absorbed by the absorber layer for a given amount of incident light, thereby increasing the efficiency of the PV device.

Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. In one embodiment of a photovoltaic (PV) device, the PV device generally includes an n-doped layer and a p+-doped layer adjacent to the n-doped layer to form a p-n layer such that electric energy is created when electromagnetic radiation is absorbed by the p-n layer. The n-doped layer and the p+-doped layer may compose an absorber layer having a thickness less than 500 nm. Such a thin absorber layer may allow for greater efficiency and flexibility in PV devices when compared to conventional solar cells.

Abstract: Methods and apparatus are provided for converting electromagnetic radiation, such as solar energy, into electric energy with increased efficiency when compared to conventional solar cells. In one embodiment of a photovoltaic (PV) device, the PV device generally includes an n-doped layer and a p+-doped layer adjacent to the n-doped layer to form a p-n layer such that electric energy is created when electromagnetic radiation is absorbed by the p-n layer. The n-doped layer and the p+-doped layer may compose an absorber layer having a thickness less than 500 nm. Such a thin absorber layer may allow for greater efficiency and flexibility in PV devices when compared to conventional solar cells.

Abstract: Embodiments of the invention generally relate to a levitating substrate carrier or support. In one embodiment, a substrate carrier for supporting and carrying at least one substrate or wafer is provided which includes a substrate carrier body containing an upper surface and a lower surface, and at least one indentation pocket disposed within the lower surface. In another embodiment, the substrate carrier includes at least open indentation area within the upper surface, and at least two indentation pockets disposed within the lower surface. Each indentation pocket may be rectangular and have four side walls extending substantially perpendicular to the lower surface.

Abstract: An optoelectronic device is disclosed. The optoelectronic device comprises a semiconductor structure; a plurality of contacts on the front side of the semiconductor structure; and a plurality of non-continuous metal contacts on a back side of the semiconductor structure. In an embodiment, a plurality of non-continuous back contacts on an optoelectronic device improve the reflectivity and reduce the losses associated with the back surface of the device.

Abstract: Embodiments of the invention generally relate to a chemical vapor deposition system and related method of use. In one embodiment, the system includes a reactor lid assembly having a body, a track assembly having a body and a guide path located along the body, and a heating assembly operable to heat the substrate as the substrate moves along the guide path. The body of the lid assembly and the body of the track assembly are coupled together to form a gap that is configured to receive a substrate. In another embodiment, a method of forming layers on a substrate using the chemical vapor deposition system includes introducing the substrate into a guide path, depositing a first layer on the substrate and depositing a second layer on the substrate, while the substrate moves along the guide path; and preventing mixing of gases between the first deposition step and the second deposition step.

Abstract: A chemical vapor deposition reactor has one or more deposition zones bounded by gas flow virtual walls, within a housing having closed walls. Each deposition zone supports chemical vapor deposition onto a substrate. Virtual walls formed of gas flows laterally surround the deposition zone, including a first gas flow of reactant gas from within the deposition zone and a second gas flow of non-reactant gas from a region laterally external to the deposition zone. The first and second gas flows are mutually pressure balanced to form the virtual walls. The virtual walls are formed by merging of gas flows at the boundary of each deposition zone. The housing has an exhaust valve to prevent pressure differences or pressure build up that would destabilize the virtual walls. Cross-contamination is reduced, between the deposition zones and the closed walls of the housing or an interior region of the housing outside the gas flow virtual walls.

Abstract: A thermal bridge connecting first and second processing zones and a method for transferring a work piece from a first to a second processing zone by way of the thermal bridge are disclosed. A work piece, transportable from the first to the second processing zone on or above the thermal bridge, is maintained at a temperature between the temperatures of the processing zones. The thermal bridge member features a thermally conductive transport member for the work piece supported over an infrared transmissive member that is insulative to heat conduction and convection. The bridge insulative member extends between the first and second processing zones or between reactors. An infrared radiation beam source emits infrared radiation which passes through the bridge insulative member to the transport member, heating the member. In an alternate embodiment, the transport member may be heated directly. A liner member may be mounted above the bridge member to retain heat.

Abstract: A chemical vapor deposition (CVD) reactor comprises a deposition zone, a substrate carrier and a liner assembly. The deposition zone is constructed so as to have a positive pressure reactant gases fixed showerhead introducing reactant gas supporting thin film CVD deposition. The substrate carrier movably supports a substrate and the liner assembly within the deposition zone and is heated so as to be subjected to a CVD process. The liner assembly partly encloses selected portions of the deposition zone, particularly portions of the substrate carrier and thereby enclose a hot zone surrounding a substrate to be processed so as to retain heat in that zone but allows gas flow radially outwardly toward walls of a surrounding cold-wall reactor with exhaust ports surrounding the deposition zone that exhaust spent reactant gases. The liner assembly is a sink for solid reaction byproducts while gaseous reaction byproducts are pumped out at the exhaust ports.

Abstract: An optoelectronic semiconductor device includes an absorber layer made of a direct bandgap semiconductor and having only one type of doping. An emitter layer is located closer than the absorber layer to a back side of the device, the emitter layer made of a different material than the absorber layer and having a higher bandgap than the absorber layer. A heterojunction is formed between the emitter layer and the absorber layer, and a p-n junction is formed between the emitter layer and the absorber layer at a location offset from the heterojunction. The p-n junction causes a voltage to be generated in the device in response to the device being exposed to light at a front side of the device. The device also includes an n-metal contact disposed on a front side of the device and a p-metal contact disposed on the back side of the device.

Abstract: Embodiments of the invention generally relate to epitaxial lift off (ELO) thin films and devices and methods used to form such films and devices. In one embodiment, a method for forming an ELO thin film is provided which includes depositing an epitaxial material over a sacrificial layer on a substrate, adhering a universally shrinkable support handle onto the epitaxial material, wherein the universally shrinkable support handle contains a shrinkable material, and shrinking the support handle to form tension in the support handle and compression in the epitaxial material during a shrinking process. The method further includes removing the sacrificial layer during an etching process, peeling the epitaxial material from the substrate while forming an etch crevice therebetween, and bending the support handle to have substantial curvature.

Abstract: Embodiments of the invention generally relate to apparatuses and methods for chemical vapor deposition (CVD). In one embodiment, a heating lamp assembly for a CVD reactor system is provided which includes a lamp housing disposed on an upper surface of a support base and containing a plurality of lamps extending from a first lamp holder to a second lamp holder. The lamps may have split filament lamps and/or non-split filament lamps, and in some examples, split and non-split filament may be alternately disposed between the first and second lamp holders. A reflector may be disposed on the upper surface of the support base between the first and second lamp holders. In another embodiment, the method includes exposing a lower surface of a wafer carrier to energy emitted from the heating lamp assembly and heating the wafer carrier to a predetermined temperature.

Abstract: Embodiments of the invention generally relate to apparatuses for chemical vapor deposition (CVD) processes. In one embodiment, a wafer carrier track for levitating and traversing a wafer carrier within a vapor deposition reactor system is provided which includes upper and lower sections of a track assembly having a gas cavity formed therebetween. A guide path extends along an upper surface of the upper section and between two side surfaces which extend along and above the guide path and parallel to each other. A plurality of gas holes along the guide path extends from the upper surface of the upper section, through the upper section, and into the gas cavity. In some examples, the upper and lower sections of the track assembly may independently contain quartz, and in some examples, may be fused together.

Abstract: Embodiments of the invention generally relate to apparatuses and methods for chemical vapor deposition (CVD) processes. In one embodiment, a CVD reactor has a reactor lid assembly disposed on a reactor body and containing a first showerhead assembly, an isolator assembly, a second showerhead assembly, and an exhaust assembly consecutively and linearly disposed next to each other on a lid support. The CVD reactor further contains first and second faceplates disposed on opposite ends of the reactor body, wherein the first showerhead assembly is disposed between the first faceplate and the isolator assembly and the exhaust assembly is disposed between the second showerhead assembly and the second faceplate. The reactor body has a wafer carrier disposed on a wafer carrier track and a lamp assembly disposed below the wafer carrier track and containing a plurality of lamps which may be utilized to heat wafers disposed on the wafer carrier.

Abstract: Embodiments of the invention generally relate to apparatuses for chemical vapor deposition (CVD) processes. In one embodiment, a reactor lid assembly for vapor deposition is provided which includes a first showerhead assembly and an isolator assembly disposed next to each other on a lid support, and a second showerhead assembly and an exhaust assembly disposed next to each other on the lid support, wherein the isolator assembly is disposed between the first and second showerhead assemblies and the second showerhead assembly is disposed between the isolator assembly and the exhaust assembly.