What is the fate of runaway positrons in tokamaks?

Liu, Jian; Qin, Hong; Fisch, Nathaniel J.; Teng, Qian; Wang, Xiaogang

doi:10.1063/1.4882435

Cited by 16 publications

(20 citation statements)

References 39 publications

(39 reference statements)

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“…For extremely energetic runaway electrons, their synchrotron radiation loss could be strong enough to balance out the acceleration by the loop electric field. The radiation dissipation then provides runaway electrons an upper bound of energy, i.e., the synchrotron energy limit [22][23][24][25]. The typical duration for a runaway electron with low energy (1keV-1MeV) to reach the energy limit has the order of magnitude of one second while the smallest timescale of Lorentz force is 10 −11 s [24,26], which means the dynamical behavior of runaway electrons spans about 11 orders of magnitude in timescale.…”

Section: Introductionmentioning

confidence: 99%

“…Fruitful results of this theory have been accomplished. Considering the gyro-center approximation regardless of the toroidal geometry, one can transfer the full-orbit dynamical equations of runaway electrons to a set of relaxation equations which are much easier to solve theoretically and numerically [24]. By use of relaxation equations, the momentum evolution structure as well as energy limit has been studied in detail under several kinds of dissipations, such as collision, synchrotron radiation, and bremsstrahlung radiation [22,23,27].…”

Section: Introductionmentioning

confidence: 99%

“…Both of these phenomena reflect the conservation of the toroidal canonical angular momentum. Recently, gyro-center simulations have been equipped with structure-preserving discrete methods and shown better long-term numerical accuracy than traditional methods [24,25,31].…”

Section: Introductionmentioning

confidence: 99%

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Multi-scale full-orbit analysis on phase-space behavior of runaway electrons in tokamak fields with synchrotron radiation

2016

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In this paper, the secular full-orbit simulations of runaway electrons with synchrotron radiation in tokamak fields are carried out using a relativistic volume-preserving algorithm. Detailed phasespace behaviors of runaway electrons are investigated in different dynamical timescales spanning 11 orders. In the small timescale, i.e., the characteristic timescale imposed by Lorentz force, the severely deformed helical trajectory of energetic runaway electron is witnessed. A qualitative analysis of the neoclassical scattering, a kind of collisionless pitch-angle scattering phenomena, is provided when considering the coupling between the rotation of momentum vector and the background magnetic field. In large timescale up to one second, it is found that the initial condition of runaway electrons in phase space globally influences the pitch-angle scattering, the momentum evolution, and the loss-gain ratio of runaway energy evidently. However, the initial value has little impact on the synchrotron energy limit. It is also discovered that the parameters of tokamak device, such as the toroidal magnetic field, the loop voltage, the safety factor profile, and the major radius, can modify the synchrotron energy limit as well as the strength of neoclassical scattering.The maximum runaway energy is also proved to be lower than the synchrotron limit when the magnetic field ripple is considered.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Multi-scale full-orbit analysis on phase-space behavior of runaway electrons in tokamak fields with synchrotron radiation

2016

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“…[11,12] is given only for a simple toroidal geometry and if one calculates the corresponding equations of motion using the Euler-Lagrange equation, the result does not give the "effective electric field" that they start with.…”

Section: Introductionmentioning

confidence: 99%

“…In Refs. [11,12], a rather different approach is adopted by treating the RRforce as an "effective electric field" which is then added into guiding-center Lagrangian as a time depending perturbation in the vector potential. This is not correct: the RR-force is of dissipative nature and no practical Lagrangian formulation exists within the framework of classical electrodynamics (here we do not discuss the quantum mechanical treatments).…”

Section: Introductionmentioning

confidence: 99%

Guiding-centre transformation of the radiation–reaction force in a non-uniform magnetic field

et al. 2015

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In this paper, we present the guiding-center transformation of the radiation-reaction force of a classical point charge traveling in a nonuniform magnetic field. The transformation is valid as long as the gyroradius of the charged particles is much smaller than the magnetic field nonuniformity length scale, so that the guiding-center Lie-transform method is applicable. Elimination of the gyromotion time scale from the radiation-reaction force is obtained with the Poisson bracket formalism originally introduced by [A. J. Brizard, Phys. Plasmas 11 4429 (2004)], where it was used to eliminate the fast gyromotion from the Fokker-Planck collision operator. The formalism presented here is applicable to the motion of charged particles in planetary magnetic fields as well as in magnetic confinement fusion plasmas, where the corresponding so-called synchrotron radiation can be detected. Applications of the guiding-center radiation-reaction force include tracing of charged particle orbits in complex magnetic fields as well as kinetic description of plasma when the loss of energy and momentum due to radiation plays an important role, e.g., for runaway electron dynamics in tokamaks. * eero.hirvijoki@chalmers.se

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Relativistic Magnetized Electron–Positron Quantum Plasma and Large-Amplitude Solitary Electromagnetic Waves

Nooralishahi

Salem

2021

Braz J Phys

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What is the fate of runaway positrons in tokamaks?

Cited by 16 publications

References 39 publications

Multi-scale full-orbit analysis on phase-space behavior of runaway electrons in tokamak fields with synchrotron radiation

Multi-scale full-orbit analysis on phase-space behavior of runaway electrons in tokamak fields with synchrotron radiation

Guiding-centre transformation of the radiation–reaction force in a non-uniform magnetic field

Relativistic Magnetized Electron–Positron Quantum Plasma and Large-Amplitude Solitary Electromagnetic Waves

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