Abstract: Embodiments of the present disclosure provide a multistage procedure for treatment of biological samples (e.g., living cells with membranes, and the like) with a substance (e.g., a drug, DNA, RNA, plasmids, and other biomolecules or materials) to achieve more efficacious intracellular delivery and transfection.

Abstract: Embodiments of the present disclosure provide for a self-pumping structure, methods of self-pumping, and the like.

Abstract: Embodiments of the present disclosure provide for methods and systems for making structures using an electrospray system while under vacuum. In particular, embodiments of the present disclosure provide for methods and systems for ultra-fast growth of high aspect ratio nano/meso/micro-structures with three dimensional topological complexity and control of phase and composition of the structure formed.

Abstract: Embodiments of the present disclosure provide for a self-pumping structure, methods of self-pumping, and the like.

Abstract: Thermal ground planes, thermal ground plane structures, and methods of thermal energy management, are disclosed. Embodiments of the disclosure provide for thermal ground planes and/or thermal ground plane structures for both fully passive and active two-phase heat spreaders, as well as the cooling devices and thermal management methods enabled by these planes and/or structures that enable heat dissipation from one or more high heat flux domains followed by spreading the heat laterally over a large area achieving essentially the spatially isothermal plane, structure, system, or device.

Abstract: Capillary trap-vapor pumps, systems, methods of heat management, and the like, are disclosed.

Abstract: Embodiments of the present disclosure provide a multistage procedure for treatment of biological samples (e.g., living cells with membranes, and the like) with a substance (e.g., a drug, DNA, RNA, plasmids, and other biomolecules or materials) to achieve more efficacious intracellular delivery and transfection.

Abstract: Embodiments of the present disclosure provide a multistage procedure for treatment of biological samples (e.g., living cells with membranes, and the like) with a substance (e.g., a drug, DNA, RNA, plasmids, and other biomolecules or materials) to achieve more efficacious intracellular delivery and transfection.

Abstract: The present disclosure provides compositions including thermo-electro-chemical converter, methods of converting thermal energy into electrical energy, and the like. In general, embodiments of the present disclosure can be used to convert thermal energy into electrical energy by way of a chemical process.

Abstract: Reactors and methods that generate hydrogen from fuel, such as naturally-occurring or synthesized hydrocarbon fuel. One embodiment of the reactor comprises a CO2/H2 active membrane piston disposed inside a cylinder that provides for highly efficient and scalable hydrogen generation from hydrocarbon fuels. This embodiment may function in a two or four stroke modes. Another embodiment of the reactor comprises a dual piston configuration having CO2 and H2 active membrane pistons inside a single cylinder. Other embodiments of the reactor comprise flexible membranes or diaphragms that operate in a manner similar to pistons with or without regeneration of residual reaction products.

Abstract: SMS probe imaging systems, methods of use thereof, and the like are disclosed. Embodiments of the present disclosure can use direct interrogation of objects (e.g., cells or tissue) within a small pool/droplet of liquid, optional thermal, mechanical, electrical, optical and chemical manipulation, followed immediately by liquid sampling, optional sample conditioning, and soft ionization of biomolecules.

Abstract: The present disclosure provides compositions including method of producing H2, variable volume reactors, methods of using variable volume reactors, and the like.

Abstract: SMS probe imaging systems, methods of use thereof, and the like are disclosed. Embodiments of the present disclosure can use direct interrogation of objects (e.g., cells or tissue) within a small pool/droplet of liquid, optional thermal, mechanical, electrical, optical and chemical manipulation, followed immediately by liquid sampling, optional sample conditioning, and soft ionization of biomolecules.

Abstract: A fully-passive, dynamically configurable directed cooling system for a microelectronic device is disclosed. In general, movable pins are suspended within a cooling plenum between an active layer and a second layer of the microelectronic device. In one embodiment, the second layer is another active layer of the microelectronic device. The movable pins are formed of a material that has a surface tension that decreases as temperature increases such that, in response to a temperature gradient on the surface of the active layer, the movable pins move by capillary flow in the directions of decreasing temperature. By moving in the direction of decreasing temperature, the movable pins move away from hot spots on the surface of the active layer, thereby opening a pathway for preferential flow of a coolant through the cooling plenum at a higher flow rate towards the hot spots.

Abstract: Devices or systems that include a composite thermal capacitor disposed in thermal communication with a hot spot of the device, methods of dissipating thermal energy in a device or system, and the like, are provided herein. In particular, the device includes a composite thermal capacitor including a phase change material and a high thermal conductivity material in thermal communication with the phase change material. The high thermal conductivity material is also in thermal communication with an active regeneration cooling device. The heat from the composite thermal capacitor is dissipated by the active regeneration cooling device.

Abstract: Embodiments of the present disclosure provide a multistage procedure for treatment of biological samples (e.g., living cells with membranes, and the like) with a substance (e.g., a drug, DNA, RNA, plasmids, and other biomolecules or materials) to achieve more efficacious intracellular delivery and transfection.

Abstract: Briefly described, embodiments of this disclosure include heat management devices, heat management systems, methods of heat management, and the like.

Abstract: Embodiments of the present disclosure include devices or systems that include a composite thermal capacitor disposed in thermal communication with a hot spot of the device, methods of dissipating thermal energy in a device or system, and the like.

Abstract: A system for controlling temperatures during medical procedures is disclosed. The system can include a high-thermal conductivity matrix with embedded thermal capacitors. The matrix can be a cream or gel, for example, and can enable the system to be easily applied to the skin, or other area to be treated. The thermal capacitors can include phase change materials, polymers, fats, or other materials that undergo an endothermic physico-chemical transformation above a first predetermined temperature (e.g., room temperature), but below a second predetermined temperature (e.g., the patient's pain threshold). The system can further include one or more thickeners to provide the desired rheological properties for application. The system can also include one or more lubricants to ease some operations during the medical procedure.

Abstract: Fuel processors, methods of using fuel processors, and the like, are disclosed.