High Power Microwave Amplifiers to generate smart waveforms for magnetic resonance spectroscopy

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Title
High Power Microwave Amplifiers to generate smart waveforms for magnetic resonance spectroscopy

CoPED ID
6894e8cf-40a8-414b-ad6c-1791e265c697

Status
Active

Funders

Value
No funds listed.

Start Date
Sept. 30, 2020

End Date
March 31, 2024

Description

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Fast wave amplifiers offer potential to generate extremely high power microwave pulses. A recent innovation impacting high power microwave amplifiers is the introduction of a weak helical corrugation on the inner wall of nominally cylindrical waveguide. Such a corrugation results in new solutions (eigenmodes) to Maxwell's equations, which may be thought of as a coupling of space harmonics of the modes of an uncorrugated waveguide. Depending on the exact geometry chosen for the corrugation, these new modes can exhibit a nearly constant group velocity in a region where the phase velocity tends to infinity. This arrangement is ideal for tuneable fast wave amplifiers, since the linear dispersion can overlap with the dispersion of a cyclotron mode of an electron beam over a wide frequency range giving wide bandwidth, whilst enhancing efficiency and mitigating against the risk of spurious oscillation. Such amplifiers have demonstrated megawatt capability in the X-band (around 10GHz) with 20% instantaneous bandwidth and efficiency approaching 30%. It is also an ideal wave dispersion for tuneable oscillators where the frequency of the source can be adjusted by changing the magnetic field which supports the electron cyclotron motion of a large orbit beam at the 2nd electron cyclotron harmonic.
Here we propose to study tuneable backward wave oscillators and amplifiers in WR-2.2 waveguide band (320GHz to 500GHz) for magnetic resonance spectroscopy applications. We will initially design and construct a tuneable backward wave oscillator in the 360GHz to 395GHz frequency range applying ideas such as the use of a large diametre 5-fold helically corrugated waveguide interaction region. We will also develop new theory and computational models of gyrotron travelling wave amplifiers based on a 5-fold helically corrugated interaction region operating in the 365GHz to 395GHz frequency range.

Adrian Cross SUPER_PER
Jack Easton STUDENT_PER

Subjects by relevance
  1. Electromagnetism
  2. Amplifiers
  3. Oscillators
  4. Microwaves
  5. Wave motion
  6. Electronics
  7. Waves
  8. Electromagnetic radiation
  9. Spectroscopy

Extracted key phrases
  1. High Power Microwave Amplifiers
  2. Tuneable fast wave amplifier
  3. Magnetic resonance spectroscopy application
  4. Tuneable backward wave oscillator
  5. High power microwave pulse
  6. Ideal wave dispersion
  7. Smart waveform
  8. Magnetic field
  9. Waveguide interaction region
  10. 2nd electron cyclotron harmonic
  11. Tuneable oscillator
  12. WR-2.2 waveguide band
  13. Wide frequency range
  14. Electron cyclotron motion
  15. New mode

Related Pages

UKRI project entry

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