Abstract: Methods and apparatuses for manipulating the temperature of a surface are provided. Devices of the present disclosure may include a thermal adjustment apparatus, such as a controller in electrical communication with one or more thermoelectric materials, placed adjacent to the surface of skin. The device may generate a series of thermal pulses at the surface, for providing an enhanced thermal sensation for a user. The thermal pulses may be characterized by temperature reversibility, where each pulse includes an initial temperature adjustment, followed by a return temperature adjustment, over a short period of time (e.g., less than 120 seconds). The average rate of temperature change upon initiation and upon return may be between about 0.1° C./sec and about 10.0° C./sec. In some cases, the average rate of the initial temperature adjustment is greater in magnitude than the average rate of the return temperature adjustment.

Abstract: In one embodiment, a method is provided. The method includes receiving a registration message from a network device. The registration request indicates that a first computing device has connected to the computing devices. The method also includes determining a category for the first computing device based on the registration message. The method further includes determining a set of rules for the computing device based on the category. The method further includes transmitting the set of rules to the network device. The set of rules indicates permissions for the first computing device. Each network of the set of networks is initially isolated from other networks of the set of networks when the network is created. Each network of the set of networks comprises a respective computing device of the set of computing devices.

Abstract: In one embodiment, a method is provided. The method includes receive, by a networking device, a request from a first computing device, to connect to the networking device. The method also includes creating a first network. The first network is one of a set of networks of the networking device. The first computing device is one of a set of computing devices that are connected to the network device. Each network of the set of networks is initially isolated from other networks of the set of networks when the network is created. Each network of the set of networks comprises a respective computing device of the set of computing devices. The method further includes assigning the first computing device to the first network.

Abstract: In one embodiment, a method is provided. The method includes receiving a registration message from a network device. The registration request indicates that a first computing device has connected to the computing devices. The method also includes determining a category for the first computing device based on the registration message. The method further includes determining a set of rules for the computing device based on the category. The method further includes transmitting the set of rules to the network device. The set of rules indicates permissions for the first computing device. Each network of the set of networks is initially isolated from other networks of the set of networks when the network is created. Each network of the set of networks comprises a respective computing device of the set of computing devices.

Abstract: In one embodiment, a method is provided. The method includes receive, by a networking device, a request from a first computing device, to connect to the networking device. The method also includes creating a first network. The first network is one of a set of networks of the networking device. The first computing device is one of a set of computing devices that are connected to the network device. Each network of the set of networks is initially isolated from other networks of the set of networks when the network is created. Each network of the set of networks comprises a respective computing device of the set of computing devices. The method further includes assigning the first computing device to the first network.

Abstract: According to some embodiments, a system for widening and densifying a scrape-off layer (SOL) in a field reversed configuration (FRC) fusion reactor is disclosed. The system includes a gas box at one end of the reactor including a gas inlet system and walls of suitable heat bearing materials. The system further includes an exit orifice adjoining the gas box, wherein the exit orifice has a controllable radius and length to allow plasma to flow out from the gas box to populate the SOL with the plasma. The system may also include fusion products, which decrease in speed in the plasma in the SOL, allowing energy to be extracted and converted into thrust or electrical power and further allowing ash to be extracted to reduce neutron emissions and maintain high, steady-state fusion power.

Abstract: According to various embodiments, an FRC fusion reactor is disclosed. The FRC fusion reactor includes a main chamber containing an FRC core and an energy and ash removal shell (EARS). The FRC fusion reactor further includes at least one divertor chamber connected to the main chamber via a divertor throat. The divertor chamber includes a plasma extruder positioned on a major axis of the FRC fusion reactor and a controllable distance along the major axis from the divertor throat. The plasma extruder has a diameter approximately ½ a diameter of the divertor throat and is configured to block plasma flow towards the FRC core to create a gap region between the FRC core and the EARS.

Abstract: According to some embodiments, a system for widening and densifying a scrape-off layer (SOL) in a field reversed configuration (FRC) fusion reactor is disclosed. The system includes a gas box at one end of the reactor including a gas inlet system and walls of suitable heat bearing materials. The system further includes an exit orifice adjoining the gas box, wherein the exit orifice has a controllable radius and length to allow plasma to flow out from the gas box to populate the SOL with the plasma. The system may also include fusion products, which decrease in speed in the plasma in the SOL, allowing energy to be extracted and converted into thrust or electrical power and further allowing ash to be extracted to reduce neutron emissions and maintain high, steady-state fusion power.

Abstract: A thiazolidinedione or rhodanine compound or a pharmaceutically acceptable salt, tautomer, solvate, hydrate, prodrug, derivative, stereoisomer, analog or isotopically labelled derivative thereof, for use in the treatment and/or prevention of an ophthalmological condition, wherein said compound is not Pioglitazone, Rosiglitazone, Rivoglitazone, Balaglitazone or Mitoglitazone.

Abstract: A thiazolidinedione or rhodanine compound or a pharmaceutically acceptable salt, tautomer, solvate, hydrate, prodrug, derivative, stereoisomer, analog or isotopically labelled derivative thereof, for use in the treatment and/or prevention of a protein misfolding disease, wherein said compound is not Pioglitazone, Rosiglitazone, Rivoglitazone, Balaglitazone or Mitoglitazone.

Abstract: According to some embodiments, a system for widening and densifying a scrape-off layer (SOL) in a field reversed configuration (FRC) fusion reactor is disclosed. The system includes a gas box at one end of the reactor including a gas inlet system and walls of suitable heat bearing materials. The system further includes an exit orifice adjoining the gas box, wherein the exit orifice has a controllable radius and length to allow plasma to flow out from the gas box to populate the SOL with the plasma. The system may also include fusion products, which decrease in speed in the plasma in the SOL, allowing energy to be extracted and converted into thrust or electrical power and further allowing ash to be extracted to reduce neutron emissions and maintain high, steady-state fusion power.

Abstract: According to some embodiments, a system for widening and densifying a scrape-off layer (SOL) in a field reversed configuration (FRC) fusion reactor is disclosed. The system includes a gas box at one end of the reactor including a gas inlet system and walls of suitable heat bearing materials. The system further includes an exit orifice adjoining the gas box, wherein the exit orifice has a controllable radius and length to allow plasma to flow out from the gas box to populate the SOL with the plasma. The system may also include fusion products, which decrease in speed in the plasma in the SOL, allowing energy to be extracted and converted into thrust or electrical power and further allowing ash to be extracted to reduce neutron emissions and maintain high, steady-state fusion power.

Abstract: According to various embodiments, an FRC fusion reactor is disclosed. The FRC fusion reactor includes a main chamber containing an FRC core and an energy and ash removal shell (EARS). The FRC fusion reactor further includes at least one divertor chamber connected to the main chamber via a divertor throat. The divertor chamber includes a plasma extruder positioned on a major axis of the FRC fusion reactor and a controllable distance along the major axis from the divertor throat. The plasma extruder has a diameter approximately ½ a diameter of the divertor throat and is configured to block plasma flow towards the FRC core to create a gap region between the FRC core and the EARS.

Abstract: A system and method for fueling a fusion reactor. The system includes a reactor chamber containing a stable plasma including a fusion fuel; a heating system configured to heat the plasma and increase an ion energy of the plasma to a level sufficient for producing net power from fusion reactions in the stable plasma; a plurality of magnets coaxial to the reactor chamber, the plurality of magnets producing a magnetic field sufficient to confine the stable plasma and promote rapid loss of fusion products into a scrape off layer; and a neutral beam injection system configured to inject additional quantities of the fusion fuel to sustain the power output of the fusion reaction.

Abstract: The invention is for a startup system for nuclear fusion engines in space. The combustion of hydrogen and oxygen produces heat that is used by a heat engine to produce electricity. This can be supplemented by electricity from other operating engines. The exhaust from the combustion is condensed and electrolyzed to produce hydrogen and oxygen once the engine is in operation. This provides a constant source of energy for future startups. The engine is started up at partial power in electricity generation mode and this power replaces the power from the combustion as it grows. The combustor uses the same heat engine as the nuclear engine uses for power generation.

Abstract: Methods for determining the lateral diffusion of one or more components are provided.

Abstract: The invention is for a startup system for nuclear fusion engines in space. The combustion of hydrogen and oxygen produces heat that is used by a heat engine to produce electricity. This can be supplemented by electricity from other operating engines. The exhaust from the combustion is condensed and electrolyzed to produce hydrogen and oxygen once the engine is in operation. This provides a constant source of energy for future startups. The engine is started up at partial power in electricity generation mode and this power replaces the power from the combustion as it grows. The combustor uses the same heat engine as the nuclear engine uses for power generation.

Abstract: A system and method for fueling a fusion reactor. The system includes a reactor chamber containing a stable plasma including a fusion fuel; a heating system configured to heat the plasma and increase an ion energy of the plasma to a level sufficient for producing net power from fusion reactions in the stable plasma; a plurality of magnets coaxial to the reactor chamber, the plurality of magnets producing a magnetic field sufficient to confine the stable plasma and promote rapid loss of fusion products into a scrape off layer; and a neutral beam injection system configured to inject additional quantities of the fusion fuel to sustain the power output of the fusion reaction.

Abstract: A garment hanger having a central region defining a boundary of an opening through the thickness of the hanger. A web of material extends across the opening, between contact points with the boundary to depict an image formed of the web of material across the opening. Flocking can be applied to the hanger.