Disclosed are methods and systems for subnanosecond rise time high voltage (HV) electric pulse delivery to biological loads. The system includes an imaging device and monitoring apparatus used for bio-photonic studies of pulse induced intracellular effects. The system further features a custom fabricated microscope slide having micro-machined electrodes. A printed circuit board to interface the pulse generator to the micro-machined glass slide having the cell solution is disclosed. An low-parasitic electronic setup to interface with avalanche transistor-switched pulse generation system is also disclosed. The pc-board and the slide are configured to match the output impedance of the pulse generator which minimizes reflection back into the pulse generator, and minimizes distortion of the pulse shape and pulse parameters. The pc-board further includes a high bandwidth voltage divider for real-time monitoring of pulses delivered to the cell solutions.

Disclosed are methods and systems for subnanosecond rise time high voltage (HV) electric pulse delivery to biological loads. The system includes an imaging device and monitoring apparatus used for bio-photonic studies of pulse induced intracellular effects. The system further features a custom fabricated microscope slide having micro-machined electrodes. A printed circuit board to interface the pulse generator to the micro-machined glass slide having the cell solution is disclosed. An low-parasitic electronic setup to interface with avalanche transistor-switched pulse generation system is also disclosed. The pc-board and the slide are configured to match the output impedance of the pulse generator which minimizes reflection back into the pulse generator, and minimizes distortion of the pulse shape and pulse parameters. The pc-board further includes a high bandwidth voltage divider for real-time monitoring of pulses delivered to the cell solutions.

The present invention relates to a power amplification device capable of being powered by a single input voltage and comprising a switching module comprising a first discharge electrode and a second discharge electrode. The power amplification device comprises a triggering module configured to convert the input voltage into a first supply voltage and a second supply voltage, detect an activation event, generate an activation signal from the first supply voltage when an activation event has been detected, generate a pulse command from the second supply voltage when an activation signal has been generated, and transmit the generated pulse control to the triggering means of the switching module so that it triggers the formation of an electric arc between the first discharge electrode and the second discharge electrode.

The present invention relates to a power amplification device capable of being powered by a single input voltage and comprising a switching module comprising a first discharge electrode and a second discharge electrode. The power amplification device comprises a triggering module configured to convert the input voltage into a first supply voltage and a second supply voltage, detect an activation event, generate an activation signal from the first supply voltage when an activation event has been detected, generate a pulse command from the second supply voltage when an activation signal has been generated, and transmit the generated pulse control to the triggering means of the switching module so that it triggers the formation of an electric arc between the first discharge electrode and the second discharge electrode.

An apparatus and a method for a circuit can include a voltage divider having a first and a second impedance in series, and having a voltage divider output. A switchable element is arranged in parallel with the first impedance and connected with the voltage divider output. The switchable element has an open state and a closed state. A spark gap device is configured to not generate a spark when the switchable element is in the open state and generate a spark when the switchable element is in the closed state.

A pulse generator for generating an HPEM pulse includes a Marx generator having a plurality of capacitors that are connected in series between two output poles, providing a Marx voltage between the output poles during operation of the Marx generator. A DS resonator has two input poles and each of the input poles is connected to a respective one of the output poles by a respective supply line. The capacitors are physically disposed along a profile line having two ends at each of which a respective one of the output poles is located. A distance between the output poles is smaller than a longitudinal extent of the Marx generator along the profile line.

A wastewater plant and method for treatment of wastewater sludge or other wastewater fluids are described. The wastewater plant utilizes an electrical discharge system configured for receiving a wastewater fluid, and generating a transient voltage and arcing electric current pulse through the received wastewater fluid to create an electro-hydraulic shock wave within the wastewater fluid accompanied by a high electric field, intensive heat and light radiation.

A parallel Marx generator topology capable of producing high power, high current output pulses is provided. The parallel Marx generator topology can include a plurality of Marx generators that operate in parallel to one another to jointly generate an output pulse. The topology can further include a pulse transformer configured to step up the voltage of the pulse created by the plurality of generators and also ensure that each Marx generator of the plurality of Marx generators is outputting substantially the same amount of current. The system can include a common interface that allows for fault detection and control of all the Marx generators using one common control panel. The parallel Marx generator topology can allow for a high voltage, high current pulse to be generated using import/export compliant switches.

A parallel Marx generator topology capable of producing high power, high current output pulses is provided. The parallel Marx generator topology can include a plurality of Marx generators that operate in parallel to one another to jointly generate an output pulse. The topology can further include a pulse transformer configured to step up the voltage of the pulse created by the plurality of generators and also ensure that each Marx generator of the plurality of Marx generators is outputting substantially the same amount of current. The system can include a common interface that allows for fault detection and control of all the Marx generators using one common control panel. The parallel Marx generator topology can allow for a high voltage, high current pulse to be generated using import/export compliant switches.

A Marx generator has at least two branches for providing a Marx voltage at an output pole. Each of the branches has a plurality of capacitor stages with voltage poles, cross branches with spark gaps, a last capacitor stage at its output end, and a first capacitor stage connected to an operating voltage. The branches have a common triggering section with a common first capacitor stage, a first adjacent cross branch, and an input pole. Each of the branches has the triggering section and also an individual portion with at least one capacitor stage that is only associated with the branch. A resonator arrangement contains the Marx generator and resonators at the respective output poles of the branches. A radiation arrangement has the resonator arrangement and a multi-feed waveguide with at least two of the resonators for respectively feeding an electromagnetic wave.