N.J. Richner scite author profile

In [K Imada et al. Nucl. Fusion 59 (2019) 046016] a new 4D drift kinetic nonlinear theory, valid in the limit of a low beta, small inverse aspect ratio, circular cross section, toroidal geometry, to describe the plasma response to the neoclassical tearing mode (NTM) magnetic perturbation is derived. In [A V Dudkovskaia et al. Plasma Phys. Control. Fusion 63 (2021) 054001] this theory is reduced in a low collisionality limit, which allows a dimensionality reduction to a 3D problem to efficiently resolve the collisional dissipation layer in the vicinity of the trapped-passing boundary. [A V Dudkovskaia et al. Plasma Phys. Control. Fusion 63 (2021) 054001] adopts an improved model for the magnetic drift frequency, which reduces the threshold magnetic island half-width from $8.73 \rho_{b i}$, where $\rho_{b i}$ is the trapped ion banana orbit width, to $1.46 \rho_{b i}$, making it in a closer agreement with experimental observations for the large aspect ratio tokamak equilibrium. In the present paper, the theory is extended to a high beta, arbitrary tokamak geometry to capture the plasma shaping effects on the NTM threshold physics with the focus on the non-zero triangularity discharges that are known to have a strong impact on the plasma MHD stability. First, it is found that the higher triangularity plasma is more prone to NTMs which is in agreement with the $2/1$ tearing mode onset relative frequency measurements in DIII-D. Second, the NTM threshold dependence on the tokamak inverse aspect ratio obtained in [A V Dudkovskaia et al. Plasma Phys. Control. Fusion 63 (2021) 054001] is refined and extended to a finite aspect ratio limit. Third, the NTM threshold dependence on poloidal beta is obtained and benchmarked against the EAST threshold island width measurements.

show abstract

Performance characteristics of atomic layer functionalized microchannel plates

Siegmund

Richner

Gunjala

et al. 2013

View full text Add to dashboard Cite

Non-inductively driven tokamak plasmas at near-unity βt in the Pegasus toroidal experiment

Reusch

Bodner

Fonck

et al. 2018

View full text Add to dashboard Cite

A major goal of the spherical tokamak (ST) research program is accessing a state of low internal inductance ℓi, high elongation κ, and high toroidal and normalized beta (βt and βN) without solenoidal current drive. Local helicity injection (LHI) in the Pegasus ST [Garstka et al., Nucl. Fusion 46, S603 (2006)] provides non-solenoidally driven plasmas that exhibit these characteristics. LHI utilizes compact, edge-localized current sources for plasma startup and sustainment. It results in hollow current density profiles with low ℓi. The low aspect ratio (R0/a∼1.2) of Pegasus allows access to high κ and high normalized plasma currents (IN=Ip/aBT>14). Magnetic reconnection during LHI provides auxiliary ion heating. Together, these features provide access to very high βt plasmas. Equilibrium analyses indicate that βt up to ∼100% is achieved. These high βt discharges disrupt at the ideal no-wall β limit at βN∼7.

show abstract

Initiation and sustainment of tokamak plasmas with local helicity injection as the majority current drive

et al. 2018

View full text Add to dashboard Cite

Local helicity injection (LHI) is a non-solenoidal current drive capable of achieving high- tokamak startup with non-invasive current injectors in the plasma scrape-off layer. The choice of injector location within the edge region is flexible but has a profound influence on the nature of the current drive in LHI discharges. New experiments on the Pegasus ST with injection in the high-field-side, lower divertor region produce plasmas dominated by helicity injection current drive, static plasma geometry, and negligible inductive drive. Peak plasma current up to 200 kA, and a sustained plasma current of 100 kA for up to 18 ms, is demonstrated. Maximum achievable plasma current is found to scale approximately linearly with the effective loop voltage from LHI. A newly-observed MHD regime for LHI-driven plasmas in which large-amplitude fluctuations at 20–50 kHz are abruptly reduced on the outboard side results in improved current drive. A simultaneous increase in high frequency fluctuations (>400 kHz) inside the plasma edge suggests short wavelength turbulence as an important current drive mechanism during LHI.

show abstract

Advancing local helicity injection for non-solenoidal tokamak startup

et al. 2019

View full text Add to dashboard Cite

Robust non-solenoidal startup methods may simplify the cost and complexity of next-step burning plasma devices, and especially STs. Experiments on the ~ 1 Pegasus ST are advancing the physics and technology basis of Local Helicity Injection (LHI). LHI creates high tokamak plasmas by injecting helicity with small current sources in the plasma edge. Its hardware can be withdrawn before a fusion plasma enters a nuclear burn phase. Flexible injector placement offers tradeoffs between physics and engineering goals. They are tested with LHI systems on the low-field-side (LFS) and the high-field-side (HFS) of Pegasus, producing plasmas predominantly driven by non-solenoidal induction and DC helicity drive (~), respectively. Record LHI plasmas with = 0.225 MA, > 100 eV, and ~ 10 19 m-3 are attained. A predictive 0D power-balance model describes experimental () and partitions the active current drive sources. Analysis of experimental discharges with the model confirms the dominance of non-solenoidal induction in LFS LHI and DC helicity drive in HFS LHI. Studies of HFS scenarios find favorable, positive scalings of with and with. High-frequency MHD activity is found to be present during LHI current drive, in addition to = 1 modes previously found in NIMROD simulation and experiment. A new regime of reduced MHD activity was discovered where = 1 activity is suppressed, LHI CD efficiency improves, and long-pulse plasmas are sustained with ~ 0. LHI facilitates access to favorable ST regimes with non-solenoidal sustainment, high , low ℓ , and high. Low LHI operation has led to record = 100%, high , and a minimum-| | well that may positively affect turbulence, transport, and fast particle confinement. Major facility upgrades are planned to extend LHI to higher , , and pulse length.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

N.J. Richner

Drift kinetic theory of the NTM magnetic islands in a finite beta general geometry tokamak plasma

Performance characteristics of atomic layer functionalized microchannel plates

Non-inductively driven tokamak plasmas at near-unity βt in the Pegasus toroidal experiment

Initiation and sustainment of tokamak plasmas with local helicity injection as the majority current drive

Advancing local helicity injection for non-solenoidal tokamak startup

Contact Info

Product

Resources

About