Solid-state repetitive generators of short GW-range pulses: a review

Rukin, S. N.

doi:10.1088/1748-0221/13/08/p08001

Cited by 8 publications

(1 citation statement)

References 37 publications

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“…In the past, several methods have been proposed and demonstrated to generate microwaves (such as X/Ka-bands). Using electron-beam and backward oscillators (BWO) can provide high intensity of microwaves (usually in the range of several hundred megawatts to even giga-watts), and they are widely applied in the field of radar, remote sensing, communications, and plasma sciences [3][4][5]. However, this technology is difficult to tune the emission frequency because it is predetermined by the fixed wave-guiding structure, and the size of this structure is usually in millimeter or centimeter.…”

Section: Introductionmentioning

confidence: 99%

Widely Tunable Single/Dual RF Signal Generation by a Monolithic Three-Section DFB Laser

et al. 2020

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A three-section distributed feedback laser with a 2.5 InP/air pair of distributed Bragg reflectors (DBRs) was fabricated and analyzed in terms of its microwave generation capability. A widely tunable single radio frequency (RF) signal can be detected using optical heterodyning, and the tuning range is from 2 to 45 GHz. The incorporation of the third section provides an opportunity to present the dual RF operation when three emission peaks are near to each other in the wavelength domain. The proposed design provides a 21.3% enhancement in the RF tuning range compared with the range of a two-section laser (35.29 GHz versus 42.81 GHz). The compactness of the proposed device can be useful for future radio-over-fiber applications.

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Section: Introductionmentioning

confidence: 99%

Widely Tunable Single/Dual RF Signal Generation by a Monolithic Three-Section DFB Laser

et al. 2020

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A phase-stabilized superradiant Ka-band oscillator driven by nanosecond voltage pulses with amplitude variations and reduced rise rates

Sharypov

Rostov

Sadykova

et al. 2018

Applied Physics Letters

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This paper presents the results of experiments and a numerical simulation of the conditions for phase stabilization (standard deviation < 0.5 rad) of a subgigawatt relativistic superradiant Ka-band backward wave oscillator with the accelerating voltage amplitude varying within 15%. It is shown that phase stabilization can be achieved for the voltage rise rate (dU/dt)max ∼ 2 MV/ns by using our recently developed approach. Particular emphasis is given to the cases of substantially lower voltage rise rates at which stabilization of the microwave oscillation phase is also possible. The mode with (dU/dt)max ≪ 1 MV/ns is considered for specific voltage waveforms that ensure efficient kinematic peaking of the beam current. In this case, stabilization of the microwave oscillation phase can be achieved by initiating a voltage prepulse, provided that the accelerating pulse leading edge has a segment of stable rise rate and stable shape.

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Pulsed power technology based on semiconductor opening switches: A review

Rukin

2020

Review of Scientific Instruments

101

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This paper presents a systematized review of the research on the production of nanosecond high-power pulses using solid-state generators based on an inductive energy store and a semiconductor opening switch that have been performed in the past 25 years. This research has been underway since 1992–1993 when the nanosecond cutoff of ultrahigh-density currents in semiconductor diodes was discovered and named the SOS (Semiconductor Opening Switch) effect. The discovery of the SOS effect provided a breakthrough in the development of semiconductor generators, as their most important characteristics, such as pulse power and output voltage, were increased tens and hundreds of times compared with previously known semiconductor generators. In particular, in the nanosecond semiconductor technology, megavolt voltages combined with gigawatt peak powers have been achieved. This review considers the main physical processes that determine the mechanism of operation of a SOS based on the SOS effect. The principle of operation, design, and characteristics of SOS diodes and SOS generators is described, and prospects for their further development are discussed. Examples are given of using SOS generators in various pulsed power applications such as electron accelerators, X-ray pulse devices, high-power microwave electronics, pumping of gas lasers, and ignition of electrical discharges.

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Solid-state repetitive generators of short GW-range pulses: a review

Cited by 8 publications

References 37 publications

Widely Tunable Single/Dual RF Signal Generation by a Monolithic Three-Section DFB Laser

Widely Tunable Single/Dual RF Signal Generation by a Monolithic Three-Section DFB Laser

A phase-stabilized superradiant Ka-band oscillator driven by nanosecond voltage pulses with amplitude variations and reduced rise rates

Pulsed power technology based on semiconductor opening switches: A review

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