Abstract: Described are systems and methods for compressing a plasma through electric and magnetic interactions between groups of positively charged particles and negatively charged particles of the plasma.

Abstract: Described are systems and methods for compressing a plasma through electric and magnetic interactions between groups of positively charged particles and negatively charged particles of the plasma.

Abstract: Systems, apparatuses, and methods are provided for producing a directional electric field from an end of the solenoid in an efficient manner. For example, voltage pulses can be used to charge the turns of the coil so that the coil acts as a capacitor. The voltage pulses can be of a specified time width (e.g., 1 ?s or less) so as to reduce the amount of current flowing in the coil, and thus reduce the input power used in the coil. The electric field can be used for a variety of purposes, e.g., for charging or communication. An output conductor can be positioned such that electrons can be moved in the output conductor. The motion of electrons can correspond to the communication of data or be used to operate a load (e.g., in charging a device or otherwise providing power).

Abstract: Apparatuses and methods are provided for driving a conductor with a signal comprising a series of pulses for inducing a voltage in an output circuit wirelessly. The pulses can be sufficiently short so as to reduce an amount of current produced along the conductor, thereby reducing the Lenz effect, which is proportional to a change in current along the conductor. Further, the pulses can have a sufficiently fast rise time (e.g., less than 30 ns) to induce a sufficiently high voltage in the output circuit (e.g., greater than 5 or 10 V). A surprisingly high voltage can be induced in an output circuit when using fast rise times of less than 30 ns.

Abstract: Apparatuses and methods are provided for driving an input conductor with a signal comprising a series of voltage pulses. The pulses can beneficially invoke the skin effect to generate a time-varying magnetic vector potential that projects radially from a surface of the input conductor. The time-varying magnetic vector potential can provide an electric field for inducing output voltage pulses in an output circuit. The input conductor and output circuit can have various configurations. For example, the input conductor can extend along a plane, and the output circuit can at least partially reside in the plane and extend away from the input conductor in the plane. Such a geometry can reduce any back coupling between the two circuits, e.g., between electromagnetic fields caused by any current in the two circuits. Such a geometry would not normally allow for induction between the two circuits, which can reduce any Lenz effects.

Abstract: Apparatuses and methods are provided for driving an input conductor with a signal comprising a series of voltage pulses. The pulses can beneficially invoke the skin effect to generate a time-varying magnetic vector potential that projects radially from a surface of the input conductor. The time-varying magnetic vector potential can provide an electric field for inducing output voltage pulses in an output circuit. The input conductor and output circuit can have various configurations. For example, the input conductor can extend along a plane, and the output circuit can at least partially reside in the plane and extend away from the input conductor in the plane. Such a geometry can reduce any back coupling between the two circuits, e.g., between electromagnetic fields caused by any current in the two circuits. Such a geometry would not normally allow for induction between the two circuits, which can reduce any Lenz effects.

Abstract: Apparatuses and methods are provided for driving a conductor with a signal comprising a series of pulses for inducing a voltage in an output circuit wirelessly. The pulses can be sufficiently short so as to reduce an amount of current produced along the conductor, thereby reducing the Lenz effect, which is proportional to a change in current along the conductor. Further, the pulses can have a sufficiently fast rise time (e.g., less than 30 ns) to induce a sufficiently high voltage in the output circuit (e.g., greater than 5 or 10 V). A surprisingly high voltage can be induced in an output circuit when using fast rise times of less than 30 ns.

Abstract: Systems, apparatuses, and methods are provided for producing a directional electric field from an end of the solenoid in an efficient manner. For example, voltage pulses can be used to charge the turns of the coil so that the coil acts as a capacitor. The voltage pulses can be of a specified time width (e.g., 1 ?s or less) so as to reduce the amount of current flowing in the coil, and thus reduce the input power used in the coil. The electric field can be used for a variety of purposes, e.g., for charging or communication. An output conductor can be positioned such that electrons can be moved in the output conductor. The motion of electrons can correspond to the communication of data or be used to operate a load (e.g., in charging a device or otherwise providing power).