Effect of emission velocity spread of secondary electrons in two-sided multipactor

Sazontov, A. G.; Buyanova, M.; Semenov, V. E.; Rakova, E.; Vdovicheva, N. K.; Anderson, D.; Lisak, M.; Puech, J.; Lapierre, L.

doi:10.1063/1.1881532

Cited by 37 publications

(21 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is more difficult to compare our results with Sazontov et al 17 , for they do not state explicitly at what fraction v ω /v 1 the limiting values for the SEY were found. It is also difficult to compare with the values of Kossyi et al 28 and Sakamoto et al 33 , for in the first case there is the presence of a DC field to account for, and in the second case, the model for secondary emission is rather different.…”

Section: B Solutionscontrasting

confidence: 42%

“…In this example, the emission velocity is assumed to follow a normal (Gaussian) distribution, with a standard deviation ∆v 2 e = 0.025v d . According to (17), this value of emission velocity spread implies that the non-resonant regime should be reached when dω/(2πv d ) > 40, but it is clear from the figure that the mixing of the consecutive electron bunches becomes significant far before this.…”

Section: B Long Range Impactsmentioning

confidence: 99%

“…For complicated structures this process becomes extremely complex. For this reason, the statistical approach has so far only been applied to double-sided multipactor between parallel plates [15][16][17][18] , in a rectangular waveguide 19 , and single-sided multipactor on a dielectric surface 20 . The theory has also recently been generalized to multicarrier signals, again in the parallel plates geometry 21 .…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Non-resonant multipactor—A statistical model

Rasch

Johansson

2012

Physics of Plasmas

View full text Add to dashboard Cite

High power microwave systems operating in vacuum or near vacuum run the risk of multipactor breakdown. In order to avoid multipactor, it is necessary to make theoretical predictions of critical parameter combinations. These treatments are generally based on the assumption of electrons moving in resonance with the electric field while traversing the gap between critical surfaces.Through comparison with experiments, it has been found that only for small system dimensions will the resonant approach give correct predictions. Apparently, the resonance is destroyed due to the statistical spread in electron emission velocity, and for a more valid description it is necessary to resort to rather complicated statistical treatments of the electron population, and extensive simulations. However, in the limit where resonance is completely destroyed it is possible to use a much simpler treatment, here called non-resonant theory. In this paper we develop the formalism for this theory, use it to calculate universal curves for the existence of multipactor, and compare with previous results. Two important effects that leads to an increase in the multipactor threshold in comparison with the resonant prediction are identified. These are the statistical spread of impact speed, which leads to a lower average electron impact speed, and the impact of electrons in phase regions where the secondary electrons are immediately reabsorbed, leading to an effective removal of electrons from the discharge.

show abstract

Section: B Solutionscontrasting

confidence: 42%

Section: B Long Range Impactsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Non-resonant multipactor—A statistical model

Rasch

Johansson

2012

Physics of Plasmas

View full text Add to dashboard Cite

show abstract

“…On the other hand, the spread of the emission energy of the secondary emitted electrons is taken into account in both the analytical and the numerical analyses, since it results also in a spread in the electron impacting energy and, therefore, an increase in the range of valid phases at the end of the OFF interval. 13 This presumably enhances the probability of the electron to participate in the multipactor process of the consecutive ON interval.…”

Section: Introductionmentioning

confidence: 99%

Long-term multipactor discharge in multicarrier systems

et al. 2007

View full text Add to dashboard Cite

A new mechanism of long-term multipactor in multicarrier systems is studied employing both analytical and numerical methods. In particular, the investigation is focused on the impact that a realistic secondary emission yield at low energies produces on the development of long term multipactor. A novel analytical model for this interperiod charge accumulation is presented using the traditional multipactor theory for parallel plates, and approximating the multicarrier signal as a single-carrier signal modulated by a pulsed signal envelope. The analytical predictions are verified by numerical simulations for a typical rectangular waveguide. The analytical and numerical results demonstrate that the susceptibility of the system to develop a long-term multipactor discharge increases with higher values of low-energy secondary emission yield.

show abstract

“…This type of discharge is an undesirable phenomenon in many practical microwave applications and the intense study of this phenomenon during the last decades has mainly been stimulated by the necessity to be able to accurately predict the multipactor threshold in different microwave subsystems. [1][2][3][4][5] These studies have resulted in development of various numerical tools capable of simulating multipactor in different geometries including parallel plates, 6,7 coaxial cables, [8][9][10] dielectric windows, [11][12][13] rectangular and wedge-shaped waveguides, [14][15][16] microstrip lines, 17 waveguide irises, [18][19][20] and rf filters and transformers. [21][22][23] A notable exception is multipactor breakdown in circular waveguides, which has been given scant interest, in spite of its technical importance.…”

Section: Introductionmentioning

confidence: 99%

Simulations of multipactor in circular waveguides

et al. 2010

Self Cite

View full text Add to dashboard Cite

Detailed numerical simulations have been done to investigate the properties of multipactor breakdown in circular waveguides operating in the propagating fundamental TE11 mode. Main attention has been given to a comparison between the two fundamental cases corresponding to linear and circular polarizations, respectively, of the propagating electromagnetic wave. It is found that circular polarization is considerably more susceptible to multipactor than linear polarization. The reason for this difference is clarified by a comprehensive study of the electron motion in the waveguide.

show abstract

Effect of emission velocity spread of secondary electrons in two-sided multipactor

Cited by 37 publications

References 11 publications

Non-resonant multipactor—A statistical model

Non-resonant multipactor—A statistical model

Long-term multipactor discharge in multicarrier systems

Simulations of multipactor in circular waveguides

Contact Info

Product

Resources

About