Abstract: A resistive random access memory is provided. The resistive random access memory includes a conductive line structure and a memory unit. The conductive line structure is disposed in an array area and a periphery circuit area. The memory unit is disposed on the conductive line structure in the array area. The memory unit includes a lower electrode, a resistive switching layer, and an upper electrode. The lower electrode is disposed on the conductive line structure. The resistive switching layer is disposed on the lower electrode. The upper electrode is disposed on the resistive switching layer. The upper surface of the conductive line structure is in direct contact with the lower electrode.

Abstract: A method for wireless capture of real-time audio and video at a live event using a mobile computing device includes receiving a data representation of a live audio signal corresponding to the live event via a wireless network. The method also includes processing the data representation of the live audio signal into a live audio stream. The method also includes initiating a video capture corresponding to the live event. The method also includes producing, concurrent with the video capture, a shareable video corresponding to the live event based on the captured video and the live audio stream.

Abstract: A method for wireless capture of real-time audio and video at a live event using a mobile computing device includes receiving a data representation of a live audio signal corresponding to the live event via a wireless network. The method also includes processing the data representation of the live audio signal into a live audio stream. The method also includes initiating a video capture corresponding to the live event. The method also includes producing, concurrent with the video capture, a shareable video corresponding to the live event based on the captured video and the live audio stream.

Abstract: A resistive random access memory, including a first electrode layer and a second electrode layer disposed opposite to each other, a variable resistance layer located between the first electrode layer and the second electrode layer, an oxygen exchange layer located between the variable resistance layer and the second electrode layer, a vacancy-supplying layer surrounding a middle sidewall of the oxygen exchange layer; and a vacancy-driving electrode layer located on the vacancy-supply layer and surrounding an upper sidewall of the oxygen exchange layer, is provided. A method of fabricating the resistive random access memory is also provided.

Abstract: Provided is a resistive random access memory (RRAM) including a first electrode layer and a second electrode layer disposed opposite to each other, a variable resistance layer located between the first electrode layer and the second electrode layer, an oxygen exchange layer located between the variable resistance layer and the second electrode layer, a conductive layer laterally surrounding a sidewall of the oxygen exchange layer, a first barrier layer located between the conductive layer and the oxygen exchange layer and between the oxygen exchange layer and the variable resistance layer, and a second barrier layer located between the conductive layer and the second electrode layer and between the second electrode layer and the oxygen exchange layer.

Abstract: A resistive random access memory is provided. The resistive random access memory includes a conductive line structure and a memory unit. The conductive line structure is disposed in an array area and a periphery circuit area. The memory unit is disposed on the conductive line structure in the array area. The memory unit includes a lower electrode, a resistive switching layer, and an upper electrode. The lower electrode is disposed on the conductive line structure. The resistive switching layer is disposed on the lower electrode. The upper electrode is disposed on the resistive switching layer. The upper surface of the conductive line structure is in direct contact with the lower electrode.

Abstract: Provided are a resistive random access memory and a method of manufacturing the same. The resistive random access memory includes a stacked structure and a bit line structure. The stacked structure is disposed on a substrate. The stacked structure includes a bottom electrode, a top electrode and a resistance-switching layer. The bottom electrode is disposed on the substrate. The top electrode is disposed on the bottom electrode. The resistance-switching layer is disposed between the bottom electrode and the top electrode. The bit line structure covers a top surface of the stacked structure and covers a portion of a sidewall of the stacked structure. The bit line structure is electrically connected to the stacked structure.

Abstract: A resistive random access memory, including a first electrode layer and a second electrode layer disposed opposite to each other, a variable resistance layer located between the first electrode layer and the second electrode layer, an oxygen exchange layer located between the variable resistance layer and the second electrode layer, a vacancy-supplying layer surrounding a middle sidewall of the oxygen exchange layer; and a vacancy-driving electrode layer located on the vacancy-supply layer and surrounding an upper sidewall of the oxygen exchange layer, is provided. A method of fabricating the resistive random access memory is also provided.

Abstract: Provided is a resistive random access memory (RRAM) including a first electrode layer and a second electrode layer disposed opposite to each other, a variable resistance layer located between the first electrode layer and the second electrode layer, an oxygen exchange layer located between the variable resistance layer and the second electrode layer, a conductive layer laterally surrounding a sidewall of the oxygen exchange layer, a first barrier layer located between the conductive layer and the oxygen exchange layer and between the oxygen exchange layer and the variable resistance layer, and a second barrier layer located between the conductive layer and the second electrode layer and between the second electrode layer and the oxygen exchange layer.

Abstract: Provided are a resistive random access memory and a method of manufacturing the same. The resistive random access memory includes a stacked structure and a bit line structure. The stacked structure is disposed on a substrate. The stacked structure includes a bottom electrode, a top electrode and a resistance-switching layer. The bottom electrode is disposed on the substrate. The top electrode is disposed on the bottom electrode. The resistance-switching layer is disposed between the bottom electrode and the top electrode. The bit line structure covers a top surface of the stacked structure and covers a portion of a sidewall of the stacked structure. The bit line structure is electrically connected to the stacked structure.

Abstract: A resistive random access memory is provided. The resistive random access memory includes a substrate, a first electrode formed on the substrate, a second electrode formed on the substrate and located on one side of the first electrode, a first metal oxide layer formed on sidewalls of the second electrode, a first control layer formed between the first electrode and the first metal oxide layer, and a second control layer formed on the first control layer and located between the first electrode and the first metal oxide layer.

Abstract: A memory device includes a first electrode, a resistive switching layer, a cap layer, a protective layer, and a second electrode. The resistive switching layer is disposed over the first electrode. The cap layer is disposed over the resistive switching layer, wherein the bottom surface of the cap layer is smaller than the top surface of the resistive switching layer. The protective layer is disposed over the resistive switching layer and surrounds the cap layer. At least a portion of the second electrode is disposed over the cap layer and covers the protective layer.

Abstract: A resistive random access memory is provided. The resistive random access memory includes a substrate, a first electrode formed on the substrate, a second electrode formed on the substrate and located on one side of the first electrode, a first metal oxide layer formed on sidewalls of the second electrode, a first control layer formed between the first electrode and the first metal oxide layer, and a second control layer formed on the first control layer and located between the first electrode and the first metal oxide layer.

Abstract: A memory device includes a first electrode, a resistive switching layer, a cap layer, a protective layer, and a second electrode. The resistive switching layer is disposed over the first electrode. The cap layer is disposed over the resistive switching layer, wherein the bottom surface of the cap layer is smaller than the top surface of the resistive switching layer. The protective layer is disposed over the resistive switching layer and surrounds the cap layer. At least a portion of the second electrode is disposed over the cap layer and covers the protective layer.

Abstract: A traceable patch cable (3) used to transmit signals from one receptacle (10) to another comprises a cable (32) and two connectors (31, 33) attached to opposite ends of the cable. The cable comprises at least one electrical wire (35) for transmitting signals and an optical fiber (36). The connectors each terminate an end of the electrical wire so that the electrical wire can be electrically connected to terminals in receptacles. Each connector forms an illuminating member (334) thereon with a passage (335) being defined in the illuminating member. Ends of the optical fiber are respectively terminated in the connectors under the illuminating members. Using a light beam shining through the passage at a first end of the cable, the light beam travels through the optical fiber to illuminates the illuminating member at a second end of the cable, thus making it easy to identify from among many cables.