2022
DOI: 10.1017/s0022377822000654
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Electromagnetic instabilities and plasma turbulence driven by electron-temperature gradient

Abstract: Electromagnetic (EM) instabilities and turbulence driven by the electron-temperature gradient (ETG) are considered in a local slab model of a tokamak-like plasma. Derived in a low-beta asymptotic limit of gyrokinetics, the model describes perturbations at scales both larger and smaller than the electron inertial length $d_e$ , but below the ion Larmor scale $\rho _i$ , capturing both electrostatic and EM regimes of turbulence. The well-known electrostatic i… Show more

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Cited by 9 publications
(26 citation statements)
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References 125 publications
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“…2013; Chen & Boldyrev 2017; Passot, Sulem & Tassi 2017; Loureiro & Boldyrev 2018; Avsarkisov 2020; Adkins et al. 2022; Skoutnev 2022), further bolstering its claim to being a universal physical principle.…”
Section: Halfway Summarymentioning
confidence: 97%
See 1 more Smart Citation
“…2013; Chen & Boldyrev 2017; Passot, Sulem & Tassi 2017; Loureiro & Boldyrev 2018; Avsarkisov 2020; Adkins et al. 2022; Skoutnev 2022), further bolstering its claim to being a universal physical principle.…”
Section: Halfway Summarymentioning
confidence: 97%
“…They are straightforward physically and have been quite convincingly verified both observationally and numerically (pace the 'waves vs. structures' confusion: see § 8.3.1). The CB approach also appears to offer an attractive and credible strategy for dealing with turbulence in wave-carrying systems other than MHD, in both plasmas and hydrodynamics (e.g., Schekochihin et al 2009Schekochihin et al , 2016Nazarenko & Schekochihin 2011;Barnes, Parra & Schekochihin 2011;Boldyrev et al 2013;Chen & Boldyrev 2017;Passot, Sulem & Tassi 2017;Avsarkisov 2020;Adkins et al 2022;Skoutnev 2022), further bolstering its claim to being a universal physical principle.…”
Section: What Can Go Wrong?mentioning
confidence: 99%
“…This conclusion is not exclusive to the collisional model considered in this paper. Starting from (5.10), one can construct an entirely analogous theory for the turbulence driven by the collisionless sETG instability, obtaining a result equivalent to (5.25), which reproduces the scaling (2.6), this time for α = 1 (see Adkins et al 2022).…”
Section: Outer Scale and Scaling Of Heat Fluxmentioning
confidence: 99%
“…These are, respectively, the rate of parallel thermal conduction and the drift frequency associated with the electron-temperature gradient. Note that the dispersion relation (3.13) is quadratic in the frequency ω because the parallel velocity u e is determined instantaneously in terms of the other fields, by (3.3), unlike in collisionless ETG theory (Adkins et al 2022).…”
Section: Collisional Slab Etg Instabilitymentioning
confidence: 99%
“…the poloidal direction in toroidal geometry). One can think of this geometry as that of a Z-pinch (see Ricci et al 2006;Ivanov et al 2020;Adkins et al 2022;Ivanov, Schekochihin & Dorland 2022) due to the assumption of constant magnetic curvature and lack of magnetic shear, which we have implicitly assumed. Under these assumptions, the system of (2.3), (2.8)-(2.10) is homogeneous in space, allowing us to impose periodic boundary conditions in all three spatial dimensions.…”
Section: Gyrokineticsmentioning
confidence: 99%