Literature DB >> 24476286

Photonic-band-gap traveling-wave gyrotron amplifier.

E A Nanni1, S M Lewis1, M A Shapiro1, R G Griffin2, R J Temkin1.   

Abstract

We report the experimental demonstration of a gyrotron traveling-wave-tube amplifier at 250 GHz that uses a photonic band gap (PBG) interaction circuit. The gyrotron amplifier achieved a peak small signal gain of 38 dB and 45 W output power at 247.7 GHz with an instantaneous -3  dB bandwidth of 0.4 GHz. The amplifier can be tuned for operation from 245-256 GHz. The widest instantaneous -3  dB bandwidth of 4.5 GHz centered at 253.25 GHz was observed with a gain of 24 dB. The PBG circuit provides stability from oscillations by supporting the propagation of transverse electric (TE) modes in a narrow range of frequencies, allowing for the confinement of the operating TE03-like mode while rejecting the excitation of oscillations at nearby frequencies. This experiment achieved the highest frequency of operation for a gyrotron amplifier; at present, there are no other amplifiers in this frequency range that are capable of producing either high gain or high output power. This result represents the highest gain observed above 94 GHz and the highest output power achieved above 140 GHz by any conventional-voltage vacuum electron device based amplifier.

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Year:  2013        PMID: 24476286      PMCID: PMC4066963          DOI: 10.1103/PhysRevLett.111.235101

Source DB:  PubMed          Journal:  Phys Rev Lett        ISSN: 0031-9007            Impact factor:   9.161


  16 in total

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Journal:  Phys Rev Lett       Date:  2000-03-20       Impact factor: 9.161

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Authors:  N S Ginzburg; I V Zotova; A S Sergeev; V Yu Zaslavsky; I V Zheleznov
Journal:  Phys Rev Lett       Date:  2012-03-06       Impact factor: 9.161

3.  Large-orbit gyrotron operation in the terahertz frequency range.

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Journal:  Phys Rev Lett       Date:  2009-06-18       Impact factor: 9.161

4.  Self-induced transparency and electromagnetic pulse compression in a plasma or an electron beam under cyclotron resonance conditions.

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Journal:  Phys Rev Lett       Date:  2010-12-22       Impact factor: 9.161

5.  Photonic-band-gap resonator gyrotron.

Authors:  J R Sirigiri; K E Kreischer; J Machuzak; I Mastovsky; M A Shapiro; R J Temkin
Journal:  Phys Rev Lett       Date:  2001-06-11       Impact factor: 9.161

6.  Amplification of picosecond pulses in a 140-GHz gyrotron-traveling wave tube.

Authors:  H J Kim; E A Nanni; M A Shapiro; J R Sirigiri; P P Woskov; R J Temkin
Journal:  Phys Rev Lett       Date:  2010-09-20       Impact factor: 9.161

7.  Low-Loss Transmission Lines for High-Power Terahertz Radiation.

Authors:  Emilio A Nanni; Sudheer K Jawla; Michael A Shapiro; Paul P Woskov; Richard J Temkin
Journal:  J Infrared Millim Terahertz Waves       Date:  2012-02-01       Impact factor: 1.768

8.  Demonstration of a 140-GHz 1-kW Confocal Gyro-Traveling-Wave Amplifier.

Authors:  Colin D Joye; Michael A Shapiro; Jagadishwar R Sirigiri; Richard J Temkin
Journal:  IEEE Trans Electron Devices       Date:  2009-05-01       Impact factor: 2.917

9.  Hollow multilayer photonic bandgap fibers for NIR applications.

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Journal:  Opt Express       Date:  2004-04-19       Impact factor: 3.894

10.  Corrugated Waveguide and Directional Coupler for CW 250-GHz Gyrotron DNP Experiments.

Authors:  Paul P Woskov; Vikram S Bajaj; Melissa K Hornstein; Richard J Temkin; Robert G Griffin
Journal:  IEEE Trans Microw Theory Tech       Date:  2005-06       Impact factor: 3.599
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  14 in total

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Authors:  Samantha M Lewis; Emilio A Nanni; Richard J Temkin
Journal:  IEEE Microw Wirel Compon Lett       Date:  2014-12-01       Impact factor: 2.862

2.  Adiabatic Solid Effect.

Authors:  Kong Ooi Tan; Ralph T Weber; Thach V Can; Robert G Griffin
Journal:  J Phys Chem Lett       Date:  2020-04-20       Impact factor: 6.475

3.  Photonic-band-gap gyrotron amplifier with picosecond pulses.

Authors:  Emilio A Nanni; Sudheer Jawla; Samantha M Lewis; Michael A Shapiro; Richard J Temkin
Journal:  Appl Phys Lett       Date:  2017-12-05       Impact factor: 3.791

4.  Frequency-Swept Integrated Solid Effect.

Authors:  Thach V Can; Ralph T Weber; Joseph J Walish; Timothy M Swager; Robert G Griffin
Journal:  Angew Chem Int Ed Engl       Date:  2017-05-12       Impact factor: 15.336

5.  Operation of a 140 GHz Gyro-amplifier using a Dielectric-loaded, Sever-less Confocal Waveguide.

Authors:  Alexander V Soane; Michael A Shapiro; Sudheer Jawla; Richard J Temkin
Journal:  IEEE Trans Plasma Sci IEEE Nucl Plasma Sci Soc       Date:  2017-10-05       Impact factor: 1.222

6.  Off-resonance NOVEL.

Authors:  Sheetal K Jain; Guinevere Mathies; Robert G Griffin
Journal:  J Chem Phys       Date:  2017-10-28       Impact factor: 3.488

7.  Ramped-amplitude NOVEL.

Authors:  T V Can; R T Weber; J J Walish; T M Swager; R G Griffin
Journal:  J Chem Phys       Date:  2017-04-21       Impact factor: 3.488

8.  Pulsed Dynamic Nuclear Polarization with Trityl Radicals.

Authors:  Guinevere Mathies; Sheetal Jain; Marcel Reese; Robert G Griffin
Journal:  J Phys Chem Lett       Date:  2015-12-21       Impact factor: 6.475

9.  Time domain DNP with the NOVEL sequence.

Authors:  T V Can; J J Walish; T M Swager; R G Griffin
Journal:  J Chem Phys       Date:  2015-08-07       Impact factor: 3.488

10.  Theory of Linear and Nonlinear Gain in a Gyroamplifier using a Confocal Waveguide.

Authors:  Alexander V Soane; Michael A Shapiro; Jacob C Stephens; Richard J Temkin
Journal:  IEEE Trans Plasma Sci IEEE Nucl Plasma Sci Soc       Date:  2017-08-22       Impact factor: 1.222
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