2015
DOI: 10.1088/0741-3335/57/9/095006
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Kinetic modelling of runaway electron avalanches in tokamak plasmas

Abstract: Runaway electrons can be generated in tokamak plasmas if the accelerating force from the toroidal electric field exceeds the collisional drag force owing to Coulomb collisions with the background plasma. In ITER, disruptions are expected to generate runaway electrons mainly through knock-on collisions [1], where enough momentum can be transferred from existing runaways to slow electrons to transport the latter beyond a critical momentum, setting off an avalanche of runaway electrons. Since knock-on runaways ar… Show more

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Cited by 44 publications
(58 citation statements)
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“…For the Rosenbluth-Putvinski operator, this behavior was also observed by Nilsson et al (2015). When the test-particle operator is added, but the Coulomb logarithm ln Λ is left unmodified, the growth rate is decreased.…”
Section: Sensitivity To the Cut-off Parameter P Msupporting
confidence: 53%
See 1 more Smart Citation
“…For the Rosenbluth-Putvinski operator, this behavior was also observed by Nilsson et al (2015). When the test-particle operator is added, but the Coulomb logarithm ln Λ is left unmodified, the growth rate is decreased.…”
Section: Sensitivity To the Cut-off Parameter P Msupporting
confidence: 53%
“…In the non-relativistic limit, p m e c, secondaries are born at perpendicular angles, p ∼ 0, and are prone to trapping in an inhomogeneous magnetic field. Away from the magnetic axis of a tokamak, this can lead to a strong reduction in the avalanche growth rate, as recently shown by Nilsson et al (2015). A more general model was later described by Chiu et al (1998) (from now on referred to as the Chiu-Harvey operator), which has also been used in runaway studies (Chiu et al 1998;Harvey et al 2000;Stahl et al 2016).…”
Section: Introductionmentioning
confidence: 90%
“…A more recent work [102] reports a much stronger reduction with a numerical factor 1.2 rather than 0.5, but it does not offer any comments on such disagreement with the previous results. Incidentally, Ref.…”
Section: A Dreicer Sourcementioning
confidence: 62%
“…For the remainder of this work, we therefore neglect the effect of radiation reaction on the Dreicer generation rate. We also disregard the effect of toroidicity, which may have an appreciable effect on Dreicer generation off the magnetic axis: if the bounce time is much shorter than the detrapping time, the generation rate is reduced due to magnetic trapping (Nilsson et al 2015). Conversely, at high densities and electric fields E E c , which can be present during tokamak disruptions, the Dreicer generation is approximately local (as in this work), but will be spatially non-uniform since the induced electric field decreases in magnitude with major radius (McDevitt & Tang 2019).…”
Section: Kinetic Modelmentioning
confidence: 99%