Abstract: Methods and apparatus for increasing reflectivity of an aluminum layer on a substrate. In some embodiments, a method of depositing an aluminum layer on a substrate comprises depositing a layer of cobalt or cobalt alloy or a layer of titanium or titanium alloy on the substrate with a chemical vapor deposition (CVD) process, pre-treating the layer of cobalt or cobalt alloy with a thermal hydrogen anneal at a temperature of approximately 400 degrees Celsius if a top surface of the layer of cobalt or cobalt alloy is compromised, and depositing a layer of aluminum on the layer of cobalt or cobalt alloy or the layer of titanium or titanium alloy with a CVD process at a temperature of approximately 120 degrees Celsius. Pre-treatment of the layer of cobalt or cobalt alloy may be accomplished for a duration of approximately 60 seconds to approximately 120 seconds.

Abstract: A fingerprint enrollment method, an electronic apparatus, a computer-readable storage medium are provided. The method includes following steps. An indication icon is displayed, wherein the indication icon is divided into N regions, N is a positive integer larger than 1, a region of the N regions is initially painted with a first color, and other regions of the N regions are initially painted with a second color. Whether a sensor apparatus is being touched is determined. When determined that the sensor apparatus is being touched, whether to capture a fingerprint image is determined. Each time when the fingerprint image is captured, the region with the first color is painted to a third color, and one of the N regions with the second color is painted to the first color. When number of the captured fingerprint image is up to N, a fingerprint sample is obtained from the captured fingerprint images.

Abstract: Methods and apparatus for increasing reflectivity of an aluminum layer on a substrate. In some embodiments, a method of depositing an aluminum layer on a substrate comprises depositing a layer of cobalt or cobalt alloy or a layer of titanium or titanium alloy on the substrate with a chemical vapor deposition (CVD) process, pre-treating the layer of cobalt or cobalt alloy with a thermal hydrogen anneal at a temperature of approximately 400 degrees Celsius if a top surface of the layer of cobalt or cobalt alloy is compromised, and depositing a layer of aluminum on the layer of cobalt or cobalt alloy or the layer of titanium or titanium alloy with a CVD process at a temperature of approximately 120 degrees Celsius. Pre-treatment of the layer of cobalt or cobalt alloy may be accomplished for a duration of approximately 60 seconds to approximately 120 seconds.

Abstract: An energy-resolved X-ray image detector includes a scintillation crystal layer, a photon detector layer and an optical layer. The scintillation crystal layer includes a plurality of scintillation crystals. The photon detector layer includes a plurality of photon detector elements. The optical layer is disposed between the scintillation crystal layer and the photon detector layer. The optical layer includes a plurality of optical elements having different light transmittances. The scintillation crystal is used for converting the X-ray beams into scintillation lights, and, when each scintillation light injects the corresponding optical elements, the light transmittances of the optical elements determine whether the scintillation lights can pass through the respective optical elements. The photon detection element then detects the scintillation lights passing through the corresponding optical elements to discriminate the energy of the X-ray beams.

Abstract: Methods for depositing an EUV hardmask film on a substrate by physical vapor deposition which allow for reduced EUV dose. Certain embodiments relate to metal oxide hardmasks which require smaller amounts of EUV energy for processing and allow for higher throughput. A silicon or metal target can be sputtered onto a substrate in the presence of an oxygen and or doping gas containing plasma.

Abstract: An energy-resolved X-ray image detector includes a scintillation crystal layer, a photon detector layer and an optical layer. The scintillation crystal layer includes a plurality of scintillation crystals. The photon detector layer includes a plurality of photon detector elements. The optical layer is disposed between the scintillation crystal layer and the photon detector layer. The optical layer includes a plurality of optical elements having different light transmittances. The scintillation crystal is used for converting the X-ray beams into scintillation lights, and, when each scintillation light injects the corresponding optical elements, the light transmittances of the optical elements determine whether the scintillation lights can pass through the respective optical elements. The photon detection element then detects the scintillation lights passing through the corresponding optical elements to discriminate the energy of the X-ray beams.

Abstract: A method for determining three dimensional locations and energy of gamma incidence events includes the steps of: providing a multi edge-read imaging probe, the multi edge-read imaging probe detecting scintillating photons generated by a gamma incidence event and obtaining a plurality of reaction locations corresponding to the scintillating photons; performing a location-judging process; performing a process for screening valid events; performing an energy-correction process upon the valid events; and, performing a process of energy calculation so as to obtain a total energy value for the gamma incidence event.

Abstract: A fingerprint enrollment method, an electronic apparatus, a computer-readable storage medium are provided. The method includes following steps. An indication icon is displayed, wherein the indication icon is divided into N regions, N is a positive integer larger than 1, a region of the N regions is initially painted with a first color, and other regions of the N regions are initially painted with a second color. Whether a sensor apparatus is being touched is determined. When determined that the sensor apparatus is being touched, whether to capture a fingerprint image is determined. Each time when the fingerprint image is captured, the region with the first color is painted to a third color, and one of the N regions with the second color is painted to the first color. When number of the captured fingerprint image is up to N, a fingerprint sample is obtained from the captured fingerprint images.

Abstract: Photovoltaic cells (e.g., p-CdTe thin film photovoltaic cells) comprising a back contact buffer layer that makes low-resistance electrical contact to the p-type semiconductor material of the cell (e.g., CdTe). The back contact buffer material comprises Cu and Te.

Abstract: A photovoltaic cell comprising a metal oxide back buffer layer. Improved n-CdS/p-CdTe heterojunction photovoltaic cells comprising a metal oxide buffer layer for making low-resistance electrical contact to the p-type CdTe layer. The back buffer layer comprises metal oxides having a high work function.