Asymmetric linear efficiency and bunching mechanisms of TM modes for electron cyclotron maser

Chang, Tsun-Hsu; Huang, Wei-Chen; Yao, Hsin-Yu; Hung, C. L.; Chen, W. C.; Su, Bo-Yuan

doi:10.1063/1.4976639

Cited by 14 publications

(5 citation statements)

References 16 publications

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“…In our cases, the interaction is always occurring in the backward wave regime, but the assumption of considering only TE modes was found to be valid. Evaluating the TE and TM mode coupling coefficients 32 for a typical case treated in this work, the TM mode coupling coefficient was found to be three orders of magnitude lower than the TE mode coupling coefficient.…”

Section: B Validity Of the Modelmentioning

confidence: 84%

“…When the resonance condition takes place with an important Doppler shift (k z >> 0), the beam-wave coupling with a TM mode could be important. It has been shown 32 that the beam coupling to a TM mode is much stronger for the backward wave interaction, due to the fact that the azimuthal and axial bunching processes cooperate with each other, while for a forward wave interaction, the two bunching processes compete against each other. In our cases, the interaction is always occurring in the backward wave regime, but the assumption of considering only TE modes was found to be valid.…”

Section: B Validity Of the Modelmentioning

confidence: 99%

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Linear studies of spurious backward-wave instabilities in a dielectric-loaded smooth-wall gyrotron beam ducts

Genoud

Alberti

Hogge

2020

2020 45th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz)

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The self-consistent simulation of the electron beam interaction was performed in the presence of a lossy dielectric layer in the smooth-wall beam duct of a gyrotron oscillator. For this purpose, the linear and spectral code TWANGlinspec was extended. In this code, the local transverse structure of the TE mode is adapted to the solution of the complex cold dispersion relation of an infinite, homogeneous, dielectric coated cylindrical waveguide. Before considering the realistic situation, the validity of the TE pure mode (E z = 0) assumed in TWANGlinspec had to be assessed for SiC or BeOSiC materials. The effect of the dielectric layer on the parasitic starting current is large for parasitic oscillations localized at the end of the beam duct and in the so called spacer region. For the realistic case, the geometry of the dual frequency gyrotron for the Tokamak à Configuration Variable (TCV) was considered, and the effect of a dielectric layer was numerically investigated. The electron beam velocity spread was also included in the simulations. The result is that in such conditions the parasitic oscillations starting currents are increased above the operating beam current. The observation of these spurious modes would therefore not be expected.

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Section: B Validity Of the Modelmentioning

confidence: 84%

Section: B Validity Of the Modelmentioning

confidence: 99%

Linear studies of spurious backward-wave instabilities in a dielectric-loaded smooth-wall gyrotron beam ducts

Genoud

Alberti

Hogge

2020

2020 45th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz)

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“…Previous research has investigated the bunching mechanism of TM-mode gyrotrons under the assumption of weakly relativistic electron beam. 46 An important finding has been obtained for gyro-BWO, indicating that the azimuthal bunching (through Dc) and the axial bunching (through Dv z ) induced by E z always cooperate. The cooperation becomes prominent during the far from cutoff operation.…”

Section: Tm-mode Bunching Mechanisms Under Near-cutoff Operationmentioning

confidence: 93%

“…Without loss of generality, the behaviors of electron bunching in the phase space can be examined by applying the temporal variation on the effective electron cyclotron frequency 1,46 We then obtain…”

Section: Tm-mode Bunching Mechanisms Under Near-cutoff Operationmentioning

confidence: 99%

“…Based on the analyses presented in the previous work 46 The beam-wave energy transfer can be further examined by the change in Lorentz factors Dc of all electron ensembles. Figure 6(a) demonstrates Dc of 21 representative electrons calculated in particletracing simulation at near-cutoff operation (B 0 ¼ 36 kG), while the similar plot at a relative far from cutoff region (B 0 ¼ 38 kG) is shown in Fig.…”

Section: Tm-mode Bunching Mechanisms Under Near-cutoff Operationmentioning

confidence: 99%

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Intrinsic resonance in gyrotron using non-resonant RF structure

Yang,

Yao,

Chen

et al. 2024

Physics of Plasmas

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Gyromonotrons are typically believed to rely on the convective interaction between the co-propagating beam and wave, with the extended energy-exchanging process stemming from the external feedback. However, numerous studies focusing on both transverse electric (TE) mode and transverse magnetic (TM) mode gyrotrons have consistently shown that beam–wave interactions in weak-feedback systems or even in uniform tubes without any structural feedback can yield a theoretical beam efficiency of more than 30% with major forward-wave output during near-cutoff operation, which is the typical operating condition for gyromonotrons. These intriguing findings raise questions about the actual feedback mechanism of gyromonotrons. In this article, comparative studies on the linear and nonlinear behaviors of uniform-tube gyrotron are investigated. The forward and backward waves are observed to co-generate and exhibit similar characteristics of ultra-slow group velocity under near-cutoff operation. This situation allows the as-generated forward wave to modulate the fresh beam, establishing a new backward-wave-like internal feedback loop. Additionally, the quasi-degenerate nature of the bi-directional propagating waves ensures their intrinsic in-phase relationship. The consequent constructive interference enables the uniform tube to function as a high-Q resonator. These findings are found to be independent of the choices of TE or TM modes, providing valuable insights into the underlying interaction mechanism of gyrotron devices.

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Nonlinear oscillations of TM-mode gyrotrons

Chang

Yao

et al. 2017

Physics of Plasmas

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This study investigates the interaction between the relativistic electrons and the waves in cavities with fixed field profiles. Both the transverse electric (TE) and the transverse magnetic (TM) cavity modes are examined, including three first-axial modes, TE011, TM011, and TM111, and two zero-axial modes, TM010 and TM110. The first-axial modes have the same resonant frequency, so a direct comparison can be made. By sweeping the electron pitch factor (α) and the electron transit angle (Θ), the optimal converting efficiency of TM modes occurs at α = 1.5 and Θ = 1.5π, unlike the TE mode of α = 2.0 and Θ = 1.0π. The converting efficiencies of both the first-axial TM modes are much lower than that of TE011 mode. The starting currents of TM011 and TM111 modes are four times higher than that of TE011 mode, indicating that these two TM modes are very difficult to oscillate. This evidences that under the traditional operating conditions, the TM-mode gyrotrons are insignificant. However, the two unique, zero-axial TM modes have relatively high converting efficiency. The highest converting efficiency of TM110 is 27.4%, the same value as that of TE011 mode. The starting currents of TM110 mode and TE011 mode are at the same level. The results suggest that some TM-mode gyrotron oscillators are feasible and deserve further theoretical and experimental studies.

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Asymmetric linear efficiency and bunching mechanisms of TM modes for electron cyclotron maser

Cited by 14 publications

References 16 publications

Linear studies of spurious backward-wave instabilities in a dielectric-loaded smooth-wall gyrotron beam ducts

Linear studies of spurious backward-wave instabilities in a dielectric-loaded smooth-wall gyrotron beam ducts

Intrinsic resonance in gyrotron using non-resonant RF structure

Nonlinear oscillations of TM-mode gyrotrons

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