Experimental observation of the effect of aftercavity interaction in a depressed collector gyrotron oscillator

Choi, Eun‐Mi; Shapiro, Michael A.; Sirigiri, J.R.; Temkin, Richard J.

doi:10.1063/1.2776911

Cited by 32 publications

(12 citation statements)

References 10 publications

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“…The detailed experimental setup for the results reported in this section is provided in [3]. Figure 2 shows the relationship between the beam current required to excite the TE 22,6 mode and the collector depression voltage, with the cathode-anode voltage and the beam compression ratio fixed at 96 kV and 23.6, respectively.…”

Section: Effects Of Collector Depression On Cavity Interactionmentioning

confidence: 99%

“…Generally, without either altering the accelerating voltage or the magnetic field during the pulse, the efficiency of a MW-class gyrotron is usually below 50%, which is much lower than the theoretically predicted value. Our recent experimental study found a possible cause for this underperformance, namely, the after cavity interaction (ACI) [2,3]. In this paper, we describe this phenomenon and its effects on the performance of a gyrotron using MAGY simulations [4].…”

Section: Introductionmentioning

confidence: 99%

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Effects of after cavity interaction in a 1.5 MW, 110 GHz gyrotron with a depressed collector

Hidaka

Choi²,

Mastovsky³

et al. 2008

2008 33rd International Conference on Infrared, Millimeter and Terahertz Waves

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We report experimental results on a 1.5 MW, 110 GHz gyrotron operating in 3 microsecond pulses with a singlestage depressed collector. Our research is focused on the observation of the after cavity interaction (ACI), and its effect on re-absorption of microwave power by the electron beam and, more importantly, broadening of the spent beam energy distribution in the launcher, i.e., the region after the cavity. The second effect limits the efficiency of a depressed collector considerably. Simulations indicate that this reduced depressed collector capability deteriorates with higher initial velocity spread of the electron beam. Efforts to design a cavity or magnetic field profile that minimizes the ACI effects are under way. While ACI affects the depressed collector operation as mentioned above, we recently found experimental evidence of collector depression affecting the cavity interaction itself. The minimum amount of current required to sustain the design mode, TE 22,6 in the hard self excitation regime decreased by as much as 6 A as the collector was depressed by up to 30 kV. This has implications in being able to reach further into the high efficiency hard self excitation regime. The microwave frequency also increased by as much as 15 MHz.

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Section: Effects Of Collector Depression On Cavity Interactionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of after cavity interaction in a 1.5 MW, 110 GHz gyrotron with a depressed collector

Hidaka

Choi²,

Mastovsky³

et al. 2008

2008 33rd International Conference on Infrared, Millimeter and Terahertz Waves

Self Cite

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show abstract

“…In practice, however, the transverse-to-axial velocity ratio does not reach a value of about 2 at present. In order to recover the kinetic energy related to the parallel momentum of the electrons, a depressed collector should be used [14]. The gyrotron oscillator should employ a cavity with a highquality factor.…”

Section: Introductionmentioning

confidence: 99%

A Study on 94 GHz Low-Voltage, Low-Current Gyrotron

Niu¹,

Chaojun²,

Liu

et al. 2013

IEEE Trans. Electron Devices

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A theoretical and experimental study on a 94 GHz low-voltage, low-current gyrotron is presented in this paper. In order to obtain stable radiation and make great use of the equipment in the lab, the TE 6,2 mode is selected as the operating mode of the desired gyrotron. The efficiency of the electron beam interaction with RF fields under different conditions has been calculated by a code, which is based on the self-consistent nonlinear theory for gyrotrons. The gyrotron is equipped with a single-stage depressed collector and a quasi-optical mode converter. Then, a gyrotron with optimized parameters has been designed, constructed, and tested. An output power of 23 kW is obtained at an accelerating beam voltage of 31.5 kV, a beam current of 1.8 A, and a collector depression voltage of 7.4 kV, corresponding to an overall efficiency of 53%.

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“…FTER cavity interaction (ACI) in gyrotron oscillators, namely in the uptaper section, has been discussed recently as a major factor influencing the overall efficiency, both with and without depressed collector 1,2,3 . The crucial point is that in the uptaper section, at increased waveguide radius, regions exist where the decreasing magnetic field allows for undesired gyrotron interaction.…”

Section: Introductionmentioning

confidence: 99%

After cavity interaction in gyrotrons: On the influence of different models for non-uniform magnetic fields

Kern

Borie

2008

2008 33rd International Conference on Infrared, Millimeter and Terahertz Waves

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Experimental observation of the effect of aftercavity interaction in a depressed collector gyrotron oscillator

Cited by 32 publications

References 10 publications

Effects of after cavity interaction in a 1.5 MW, 110 GHz gyrotron with a depressed collector

Effects of after cavity interaction in a 1.5 MW, 110 GHz gyrotron with a depressed collector

A Study on 94 GHz Low-Voltage, Low-Current Gyrotron

After cavity interaction in gyrotrons: On the influence of different models for non-uniform magnetic fields

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