Abstract: The disclosure includes a system and method for detecting fine grain copresence between users. The system includes a processor and a memory storing instructions that when executed cause the system to receive user input regarding copresence detection settings for a first user device, the copresence detection settings comprising a location and/or a user access control list, and determine a current location of the first user device. The system may determine whether copresence detection of the first user device is enabled at the current location based on the copresence detection settings and the current location. Based on determining that copresence detection is enabled, the system may refine copresence and perform an action based on fine grain copresence of the first and second user device.

Abstract: A solution deposition method includes: applying a liquid precursor solution to a substrate, the precursor solution including an oxide of a first metal, a hydroxide of the first metal, or a combination thereof, dissolved in an aqueous ammonia solution; evaporating the precursor solution to directly form a solid seed layer on the substrate, the seed layer including an oxide of the first metal, a hydroxide of the first metal, or a combination thereof, the seed layer being substantially free of organic compounds; and growing a bulk layer on the substrate, using the seed layer as a growth site or a nucleation site.

Abstract: A solution deposition method including: applying a liquid precursor solution to a substrate, the precursor solution including an oxide of a first metal, a hydroxide of the first metal, or a combination thereof, dissolved in an aqueous ammonia solution; evaporating the precursor solution to directly form a solid seed layer on the substrate, the seed layer including an oxide of the first metal, a hydroxide of the first metal, or a combination thereof, the seed layer being substantially free of organic compounds; and growing a bulk layer on the substrate, using the seed layer as a growth site or a nucleation site.

Abstract: A light-emitting diode includes, a semiconductor stack including a first semiconductor layer, a second semiconductor layer, and an active layer. The light-emitting diode also includes a transparent conductive layer including a first transparent conductive layer disposed on the second semiconductor layer and a second transparent conductive layer disposed on the first transparent conductive layer. The second transparent conductive layer has a conductivity different than the first transparent conductive layer.

Abstract: The disclosure includes a system and method for detecting fine grain copresence between users. The system includes a processor and a memory storing instructions that when executed cause the system to: process one or more signals to determine coarse grain location information of a first device and a second device; determine whether the first device and the second device are copresent based on the coarse grain location information; in response to determining that the first device and the second device are copresent based on the coarse grain location information, transmit a signal to the second device to alert the second device to listen for a fine grain copresence token from the first device; and refine copresence based on receiving an indication that the second device has received the fine grain copresence token.

Abstract: A solution deposition method including: applying a liquid precursor solution to a substrate, the precursor solution including an oxide of a first metal, a hydroxide of the first metal, or a combination thereof, dissolved in an aqueous ammonia solution; evaporating the precursor solution to directly form a solid seed layer on the substrate, the seed layer including an oxide of the first metal, a hydroxide of the first metal, or a combination thereof, the seed layer being substantially free of organic compounds; and growing a bulk layer on the substrate, using the seed layer as a growth site or a nucleation site.

Abstract: The disclosure includes a system and method for detecting fine grain copresence between users. The system includes a processor and a memory storing instructions that when executed cause the system to: process one or more signals to determine coarse grain location information of a first device and a second device; determine whether the first device and the second device are copresent based on the coarse grain location information; in response to determining that the first device and the second device are copresent based on the coarse grain location information, transmit a signal to the second device to alert the second device to listen for a fine grain copresence token from the first device; and refine copresence based on receiving an indication that the second device has received the fine grain copresence token.

Abstract: A method of forming a ZnO layer on a substrate and an LED including a ZnO layer formed by the method are provided. The ZnO layer is formed by using a Successive Ionic Layer Adsorption and Reaction (SILAR) process. The SILAR process includes: applying a first solution to a substrate comprising GaN, to form an inner ionic layer on the substrate and an outer ionic layer on the inner ionic layer; performing a first washing operation on the substrate to remove the outer ionic layer; and applying a second solution to the washed substrate to convert the inner ionic layer into a ZnO oxide layer.

Abstract: A device location is determined, and the location of an area of interest that is a geographic area referred to as a geo-fence is identified. Multiple geo-fences can be identified by the device, and different geo-fences can be associated with different programs on the device. An operating system of the device implements multiple different periods of operation for the device, including a conservation period during which certain programs are not typically scheduled to run, and an execution period during which such programs are typically scheduled to run. A system identifies geo-fence events, which occur when the device enters or exits the geo-fence. The system maintains a record of the geo-fence events for each of multiple geo-fences, and provides to a program selected ones of those geo-fence events at a time when the program is scheduled to run on the device during an execution period of the operating system.

Abstract: A method of forming a ZnO layer on a substrate and an LED including a ZnO layer formed by the method are provided. The ZnO layer is formed by using a Successive Ionic Layer Adsorption and Reaction (SILAR) process. The SILAR process includes: applying a first solution to a substrate comprising GaN, to form an inner ionic layer on the substrate and an outer ionic layer on the inner ionic layer; performing a first washing operation on the substrate to remove the outer ionic layer; and applying a second solution to the washed substrate to convert the inner ionic layer into a ZnO oxide layer.

Abstract: A method of forming a ZnO layer on a substrate and an LED including a ZnO layer formed by the method are provided. The ZnO layer is formed by using a Successive Ionic Layer Adsorption and Reaction (SILAR) process. The SILAR process includes: applying a first solution to a substrate comprising GaN, to form an inner ionic layer on the substrate and an outer ionic layer on the inner ionic layer; performing a first washing operation on the substrate to remove the outer ionic layer; and applying a second solution to the washed substrate to convert the inner ionic layer into a ZnO oxide layer.

Abstract: A method of forming a ZnO layer on a substrate and an LED including a ZnO layer formed by the method are provided. The ZnO layer is formed by using a Successive Ionic Layer Adsorption and Reaction (SILAR) process. The SILAR process includes: applying a first solution to a substrate comprising GaN, to form an inner ionic layer on the substrate and an outer ionic layer on the inner ionic layer; performing a first washing operation on the substrate to remove the outer ionic layer; and applying a second solution to the washed substrate to convert the inner ionic layer into a ZnO oxide layer.