Abstract: Disclosed are various embodiments of memristive devices comprising a number of nodes. Memristive fibers are used to form conductive and memristive paths in the devices. Each memristive fiber may couple one or more nodes to one or more other nodes. In one case, a memristive device includes a first node, a second node, and a memristive fiber. The memristive fiber includes a conductive core and a memristive shell surrounding at least a portion of the conductive core along at least a portion of the memristive fiber.

Abstract: Disclosed are various embodiments of memristive devices comprising a number of nodes. Memristive fibers are used to form conductive and memristive paths in the devices. Each memristive fiber may couple one or more nodes to one or more other nodes. In one case, a memristive device includes a first node, a second node, and a memristive fiber. The memristive fiber includes a conductive core and a memristive shell surrounding at least a portion of the conductive core along at least a portion of the memristive fiber. The memristive fiber couples the first node to the second node through a portion of the memristive shell and at least a portion of the conductive core.

Abstract: Methods and systems of the present disclosure can function to capture flue gas and convert the flue gas to a synthesis gas, which can be further processed to other components such as liquid fuels. Aspects of the present disclosure provide for a process designed to capture flue gas from large scale (i.e. ˜GW), fossil based power plants in a 24/7 continuous operation. In addition, the method and system can convert the flue gas to a synthesis gas (mainly carbon monoxide and hydrogen), which will be processed into high quality liquid fuels, like diesel.

Abstract: Disclosed are various embodiments of memristive devices comprising a number of nodes. Memristive fibers are used to form conductive and memristive paths in the devices. Each memristive fiber may couple one or more nodes to one or more other nodes. In one case, a memristive device includes a first node, a second node, and a memristive fiber. The memristive fiber includes a conductive core and a memristive shell surrounding at least a portion of the conductive core along at least a portion of the memristive fiber.

Abstract: Disclosed are various embodiments of memristive devices comprising a number of nodes. Memristive fibers are used to form conductive and memristive paths in the devices. Each memristive fiber may couple one or more nodes to one or more other nodes. In one case, a memristive device includes a first node, a second node, and a memristive fiber. The memristive fiber includes a conductive core and a memristive shell surrounding at least a portion of the conductive core along at least a portion of the memristive fiber. The memristive fiber couples the first node to the second node through a portion of the memristive shell and at least a portion of the conductive core.

Abstract: Various embodiments of biocompatible textile mesh and tissue constructs from Manicaria saccifera, methods of growing cells and tissues using the Manicaria saccifera-based textile mesh/tissue scaffolds, and methods of treating subjects with the biocompatible textile mesh and tissue constructs are described. The mesh, constructs and methods can include a biocompatible textile mesh made from a naturally woven fiber mat from a Manicaria saccifera palm bract that has been treated to remove oils and lignin from the surface of palm fibers in the mat and seeded with a population of cells. An engineered, biocompatible tissue construct, a method of growing mammalian tissue in vivo, and a method of treating a subject are also described.

Abstract: Disclosed are various embodiments of memristive devices comprising a number of nodes. Memristive fibers are used to form conductive and memristive paths in the devices. Each memristive fiber may couple one or more nodes to one or more other nodes. In one case, a memristive device includes a first node, a second node, and a memristive fiber. The memristive fiber includes a conductive core and a memristive shell surrounding at least a portion of the conductive core along at least a portion of the memristive fiber.

Abstract: Embodiments of the present disclosure relate to compositions including a doped material, batteries including the composition, photovoltaic devices including the battery, and the like.

Abstract: Disclosed are various embodiments of memristive networks comprising a number of nodes. Memristive nanofibers are used to form conductive and memristive paths in the networks. Each memristive nanofiber may couple one or more nodes to one or more other nodes. In one case, a memristive network includes a first node, a second node, and a memristive fiber that couples the first node to the neural node. The memristive fiber comprises a conductive core and a memristive shell, where the conductive core forms a conductive path between the first node and the second node and the memristive shell forms a memristive path between the first node and the second node.

Abstract: Disclosed are various embodiments of memristive networks comprising a number of nodes. Memristive nanofibers are used to form conductive and memristive paths in the networks. Each memristive nanofiber may couple one or more nodes to one or more other nodes. In one case, a memristive network includes a first node, a second node, and a memristive fiber that couples the first node to the neural node. The memristive fiber comprises a conductive core and a memristive shell, where the conductive core forms a conductive path between the first node and the second node and the memristive shell forms a memristive path between the first node and the second node.

Abstract: Disclosed are various embodiments of memristive neural networks comprising neural nodes. Memristive nanofibers are used to form artificial synapses in the neural networks. Each memristive nanofiber may couple one or more neural nodes to one or more other neural nodes. In one case, a memristive neural network includes a first neural node, a second neural node, and a memristive fiber that couples the first neural node to the second neural node. The memristive fiber comprises a conductive core and a memristive shell, where the conductive core forms a communications path between the first neural node and the second neural node and the memristive shell forms a memristor synapse between the first neural node and the second neural node.

Abstract: Disclosed herein is a tissue harvester comprising a substrate having an airfoil shape; and a textured surface disposed upon the substrate, where the textured surface comprises a spatial array of nanometer or micrometer sized pillars of varying cross-sections. Disclosed herein too is method comprising disposing upon a substrate a textured surface; where the substrate has an airfoil shape and where the textured surface where the textured surface comprises nanometer or micrometer sized pillars; contacting the tissue harvester with biological cells whose proliferation under different conditions is desired; and disposing the tissue harvester in a flow field such that cells disposed on the tissue harvester at different locations may experience different flow fields.

Abstract: Embodiments of the present disclosure relate to compositions including a doped material, batteries including the composition, photovoltaic devices including the battery, and the like.

Abstract: Disclosed are various embodiments of memristive neural networks comprising neural nodes. Memristive nanofibers are used to form artificial synapses in the neural networks. Each memristive nanofiber may couple one or more neural nodes to one or more other neural nodes. In one case, a memristive neural network includes a first neural node, a second neural node, and a memristive fiber that couples the first neural node to the second neural node. The memristive fiber comprises a conductive core and a memristive shell, where the conductive core forms a communications path between the first neural node and the second neural node and the memristive shell forms a memristor synapse between the first neural node and the second neural node.

Abstract: Embodiments of the present disclosure relate to compositions including a doped material, batteries including the composition, photovoltaic devices including the battery, and the like.

Abstract: Disclosed herein is a tissue harvester comprising a substrate having an airfoil shape; and a textured surface disposed upon the substrate, where the textured surface comprises a spatial array of nanometer or micrometer sized pillars of varying cross-sections. Disclosed herein too is method comprising disposing upon a substrate a textured surface; where the substrate has an airfoil shape and where the textured surface where the textured surface comprises nanometer or micrometer sized pillars; contacting the tissue harvester with biological cells whose proliferation under different conditions is desired; and disposing the tissue harvester in a flow field such that cells disposed on the tissue harvester at different locations may experience different flow fields.

Abstract: The subject invention pertains to a piezoelectric device structure for improved acoustic wave sensing and/or generation, and process for making same. The piezoelectric thin film field effect transducer can be a thin film transistor (TFT) with either a piezoelectric film gate or a composite gate having a dielectric film and a piezoelectric film. The TFT structure can be either a top gate device or a bottom gate device. In an embodiment, the piezoelectric device structure can be used to form an array of piezoelectric thin film field effect transducers. A TFT switch can drive each piezoelectric transducer in the array. The piezoelectric transducers can both generate and sense acoustic waves. In a sensing mode, a signal from an acoustic wave can be collected at a readout terminal of the piezoelectric transducer. In a generating mode, an excitation signal can be applied across the piezoelectric transducer while the switch is ‘on’.

Abstract: The subject invention pertains to a piezoelectric device structure for improved acoustic wave sensing and/or generation, and process for making same. The piezoelectric thin film field effect transducer can be a thin film transistor (TFT) with either a piezoelectric film gate or a composite gate having a dielectric film and a piezoelectric film. The TFT structure can be either a top gate device or a bottom gate device. In an embodiment, the piezoelectric device structure can be used to form an array of piezoelectric thin film field effect transducers. A TFT switch can drive each piezoelectric transducer in the array. The piezoelectric transducers can both generate and sense acoustic waves. In a sensing mode, a signal from an acoustic wave can be collected at a readout terminal of the piezoelectric transducer. In a generating mode, an excitation signal can be applied across the piezoelectric transducer while the switch is ‘on’.