Novosibirsk terahertz free electron laser: instrumentation development and experimental achievements

Knyazev, B. A.; Кулипанов, Г.Н.; Винокуров, Н.А.

doi:10.1088/0957-0233/21/5/054017

Cited by 124 publications

(51 citation statements)

References 59 publications

(67 reference statements)

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“…We measured transparency of a few AO materials in the THz region of spectrum in a preliminary experiment carried out by means of the Novosibirsk free-electron laser (FEL) [4]. It was found that the majority of known AO-materials were opaque.…”

Section: Resultsmentioning

confidence: 99%

Regular Trends of Acousto-Optic Interaction in Terahertz Region of Electromagnetic Radiation

et al. 2015

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Basic problems of acousto-optic interaction in terahertz region of electromagnetic spectrum are considered. We obtained experimental results that are tted by generalized theoretical model developed with the goals to describe the interaction in detail. Our analysis showed that crystalline germanium is one of the best materials to observe the acousto-optic interaction in the terahertz range. The carried out study proved that a germanium based acousto-optic device could be used for fast and reliable deection of monochromatic radiation in the terahertz spectral region.

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Section: Resultsmentioning

confidence: 99%

Regular Trends of Acousto-Optic Interaction in Terahertz Region of Electromagnetic Radiation

et al. 2015

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“…A free electron laser 3 reported by the Institute of Nuclear Physics (Novosibirsk, Russia) generates an average power of 0.5 kW; however, it is as large as a building, housed in a large high bay facility. In addition to that, a gyrotron with pulsed magnetic field operating in a single 50 µs pulse with output power 1.5 kW 4 has been reported by the Institute of Applied Physics (Nizhny Novgorod, Russia).…”

Section: Introductionmentioning

confidence: 99%

“…In addition to that, a gyrotron with pulsed magnetic field operating in a single 50 µs pulse with output power 1.5 kW 4 has been reported by the Institute of Applied Physics (Nizhny Novgorod, Russia). This gyrotron requires a cryomagnet and a diamond window, and including its power supply is about 2m 3 in volume and not portable.…”

Section: Introductionmentioning

confidence: 99%

Efficient power combiner for THz radiation

et al. 2016

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Most dangerous explosive materials, both toxic and radioactive, contain nitrogen salts with resonant absorption lines in the frequency range 0.3-10 THz. Therefore, there has been growing interest in remotely detecting such materials by observing the spectrum of reflected signals when the suspicious material is interrogated by THz radiation. Practical portable THz sources available today generate only 20–40 mW output power. This power level is too low to interrogate suspicious material from a safe distance, especially if the material is concealed. Hence, there is a need for sources that can provide greater power in the THz spectrum. Generating and extracting high output power from THz sources is complicated and inefficient. The efficiency of vacuum electronic microwave sources is very low when scaled to the THz range and THz sources based on scaling down semiconductor laser sources have low efficiency as well, resulting in the well known “THz gap.” The reason for such low efficiencies for both source types is material losses in the THz band. In this article an efficient power combiner is described that is based on scaling to higher frequencies a microwave combiner that increases the output power in the THz range of interest in simulation studies. The proposed power combiner not only combines the THz power output from several sources, but can also form a Gaussian wavebeam output. A minimum conversion efficiency of 89% with cophased inputs in a lossy copper power combiner and maximum efficiency of 100% in a Perfect Electric Conductor (PEC)-made power combiner were achieved in simulations. Also, it is shown that the TE01 output mode is a reasonable option for THz applications due to the fact that conductive loss decreases for this mode as frequency increases.

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“…Linac driven FELs use each electron pulse once, leading to low duty cycles. (Energy recovery linacs reach high duty cycles by recovering the electron energy [36,37,38].) Storage rings, by contrast, naturally operate at MHz repetition rates (determined by the revolution time of the electrons), and fully filled rings can provide CW radiation.…”

Section: Introductionmentioning

confidence: 99%

Much Ado about Microbunching: Coherent Bunching in High Brightness Electron Beams

Ratner

2011

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Novosibirsk terahertz free electron laser: instrumentation development and experimental achievements

Cited by 124 publications

References 59 publications

Regular Trends of Acousto-Optic Interaction in Terahertz Region of Electromagnetic Radiation

Regular Trends of Acousto-Optic Interaction in Terahertz Region of Electromagnetic Radiation

Efficient power combiner for THz radiation

Much Ado about Microbunching: Coherent Bunching in High Brightness Electron Beams

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