Validating Simulations of Multi-Scale Plasma Turbulence in ITER-Relevant, Alcator C-Mod Plasmas

Similar documents
Validation Study of gyrokinetic simulation (GYRO) near the edge in Alcator C-Mod ohmic discharges

2017 US/EU Transport Task Force Workshop April 26 th 2017 Williamsburg, VA

Multi-scale turbulence, electron transport, and Zonal Flows in DIII-D

Reduction of Turbulence and Transport in the Alcator C-Mod Tokamak by Dilution of Deuterium Ions with Nitrogen and Neon Injection

Observations of Rotation Reversal and Fluctuation Hysteresis in Alcator C-Mod Plasmas

Dependence of non-local effects on plasma parameters during cold-pulse experiments in Alcator C-Mod

Reduced Electron Thermal Transport in Low Collisionality H-mode Plasmas in DIII-D and the Importance of Small-scale Turbulence

Gyrokine.c Analysis of the Linear Ohmic Confinement Regime in Alcator C- Mod *

Observation of Reduced Core Electron Temperature Fluctuations and Intermediate Wavenumber Density Fluctuations in H- and QH-mode Plasmas

TRANSPORT PROGRAM C-MOD 5 YEAR REVIEW MAY, 2003 PRESENTED BY MARTIN GREENWALD MIT PLASMA SCIENCE & FUSION CENTER

C-Mod Transport Program

Perturbative thermal diffusivity from partial sawtooth crashes in Alcator C-Mod

GA A26866 REDUCED ELECTRON THERMAL TRANSPORT IN LOW COLLISIONALITY H-MODE PLASMAS IN DIII-D AND THE IMPORTANCE OF SMALL-SCALE TURBULENCE

Studies of Turbulence and Transport in Alcator C- Mod H-Mode Plasmas with Phase Contrast Imaging and Comparisons with GYRO*

Particle transport results from collisionality scans and perturbative experiments on DIII-D

Towards Multiscale Gyrokinetic Simulations of ITER-like Plasmas

International Workshop on the Frontiers of Modern Plasma Physics July On the Nature of Plasma Core Turbulence.

Perturbative Thermal Diffusivity from Partial Sawtooth Crashes in Alcator C-Mod

ECH Density Pumpout and Small Scale Turbulence in DIII-D

Low-collisionality density-peaking in GYRO simulations of C-Mod plasmas

Transport Improvement Near Low Order Rational q Surfaces in DIII D

Validation studies on local gyrokinetic simulations of tokamak ITG-TEM driven turbulent transport

ITB Transport Studies in Alcator C-Mod. Catherine Fiore MIT Plasma Science and Fusion Center Transport Task Force March 26th Boulder, Co

Density Peaking At Low Collisionality on Alcator C-Mod

Electron Transport and Improved Confinement on Tore Supra

OVERVIEW OF THE ALCATOR C-MOD PROGRAM. IAEA-FEC November, 2004 Alcator Team Presented by Martin Greenwald MIT Plasma Science & Fusion Center

Tests of Profile Stiffness Using Modulated Electron Cyclotron Heating

Validation of Nonlinear Gyrokinetic Simulations of L- and I-mode Plasmas on Alcator C-Mod

W.M. Solomon 1. Presented at the 54th Annual Meeting of the APS Division of Plasma Physics Providence, RI October 29-November 2, 2012

Gyrokinetic Transport Driven by Energetic Particle Modes

ITER Predictions Using the GYRO Verified and Experimentally Validated TGLF Transport Model

Coupled radius-energy turbulent transport of alpha particles

C-Mod Core Transport Program. Presented by Martin Greenwald C-Mod PAC Feb. 6-8, 2008 MIT Plasma Science & Fusion Center

Progress and Plans on Physics and Validation

Bounce-averaged gyrokinetic simulations of trapped electron turbulence in elongated tokamak plasmas

Characterizing electron temperature gradient turbulence via numerical simulation

Turbulent Transport Analysis of JET H-mode and Hybrid Plasmas using QuaLiKiz, TGLF and GLF23

TURBULENT TRANSPORT THEORY

Co-existence and interference of multiple modes in plasma turbulence: Some recent GENE results

GA A25566 COUPLED ITG/TEM-ETG GYROKINETIC SIMULATIONS

NSTX. Investigation of electron gyro-scale fluctuations in the National Spherical Torus Experiment. David Smith. Advisor: Ernesto Mazzucato

Controlling H-Mode Particle Transport with Modulated Electron Heating in DIII-D and Alcator C-Mod via TEM Turbulence

in tokamak plasmas Istvan Pusztai 1 Jeff Candy 2 Punit Gohil 2

Correlation Between Plasma Rotation and Electron Temperature Gradient Scale Length in LOC/SOC Transition at Alcator C-Mod

Plasma Science and Fusion Center

Multispecies density peaking in gyrokinetic turbulence simulations of low collisionality Alcator C-Mod plasmas

MHD Pedestal Paradigm (Conventional Wisdom)

Synergistic Cross-Scale Coupling of Turbulence in a Tokamak Plasma

Gyrokinetic Simulations of Tokamak Microturbulence

Electron Transport Stiffness and Heat Pulse Propagation on DIII-D

Variation of Turbulence and Transport with the Te/Ti Ratio in H-Mode Plasmas

ITER operation. Ben Dudson. 14 th March Department of Physics, University of York, Heslington, York YO10 5DD, UK

GTC Simulation of Turbulence and Transport in Tokamak Plasmas

Theory Work in Support of C-Mod

OV/2-5: Overview of Alcator C-Mod Results

Turbulence and Transport The Secrets of Magnetic Confinement

Connections between Particle Transport and Turbulence Structures in the Edge and SOL of Alcator C-Mod

The gyrokinetic turbulence code GENE - Numerics and applications

GA A26874 ITER PREDICTIONS USING THE GYRO VERIFIED AND EXPERIMENTALLY VALIDATED TGLF TRANSPORT MODEL

Energetic-Ion-Driven MHD Instab. & Transport: Simulation Methods, V&V and Predictions

Possible Experimental Tests of Pedestal Width/ Structure, Motivated by Theory/Modeling

Enhanced Energy Confinement Discharges with L-mode-like Edge Particle Transport*

High fusion performance at high T i /T e in JET-ILW baseline plasmas with high NBI heating power and low gas puffing

Drift-Driven and Transport-Driven Plasma Flow Components in the Alcator C-Mod Boundary Layer

Multiscale, multiphysics modeling of turbulent transport and heating in collisionless, magnetized plasmas

Non-local Heat Transport in Alcator C-Mod Ohmic L-mode Plasmas

Investigation of Intrinsic Rotation Dependencies in Alcator C-Mod

Local Plasma Parameters and H-Mode Threshold in Alcator C-Mod

Validation of Theoretical Models of Intrinsic Torque in DIII-D and Projection to ITER by Dimensionless Scaling

Particle-in-cell simulations of electron transport from plasma turbulence: recent progress in gyrokinetic particle simulations of turbulent plasmas

Relating the L-H Power Threshold Scaling to Edge Turbulence Dynamics

Direct drive by cyclotron heating can explain spontaneous rotation in tokamaks

INTRODUCTION TO GYROKINETIC AND FLUID SIMULATIONS OF PLASMA TURBULENCE AND OPPORTUNITES FOR ADVANCED FUSION SIMULATIONS

Ohmic and RF Heated ITBs in Alcator C-Mod

DPG School The Physics of ITER Physikzentrum Bad Honnef, Energy Transport, Theory (and Experiment) Clemente Angioni

GA A25853 FAST ION REDISTRIBUTION AND IMPLICATIONS FOR THE HYBRID REGIME

Measurements of Core Electron Temperature Fluctuations in DIII-D with Comparisons to Density Fluctuations and Nonlinear GYRO Simulations

Development and Validation of a Predictive Model for the Pedestal Height (EPED1)

Non-local Heat Transport, Core Rotation Reversals and Energy Confinement Saturation in Alcator C-Mod Ohmic L-mode Plasmas

On the ρ Scaling of Intrinsic Rotation in C-Mod Plasmas with Edge Transport Barriers

Influence of Beta, Shape and Rotation on the H-mode Pedestal Height

ICRF Mode Conversion Flow Drive on Alcator C-Mod and Projections to Other Tokamaks

PSFC/JA D.R. Ernst, N. Basse, W. Dorland 1, C.L. Fiore, L. Lin, A. Long 2, M. Porkolab, K. Zeller, K. Zhurovich. June 2006

Overview of Tokamak Rotation and Momentum Transport Phenomenology and Motivations

Role of Density Gradient Driven Trapped Electron Mode Turbulence in the H-mode Inner Core with Electron Heating a)

Understanding and Predicting Profile Structure and Parametric Scaling of Intrinsic Rotation. Abstract

GA A23114 DEPENDENCE OF HEAT AND PARTICLE TRANSPORT ON THE RATIO OF THE ION AND ELECTRON TEMPERATURES

Microtearing Simulations in the Madison Symmetric Torus

GA A27933 TURBULENCE BEHAVIOR AND TRANSPORT RESPONSE APPROACHING BURNING PLASMA RELEVANT PARAMETERS

Saturation rules for ETG transport in quasilinear transport models

Gyrokinetic simulations including the centrifugal force in a strongly rotating tokamak plasma

David R. Smith UW-Madison

Predicting the Rotation Profile in ITER

Gyrokinetic Turbulence in Tokamaks and Stellarators

GA A27235 EULERIAN SIMULATIONS OF NEOCLASSICAL FLOWS AND TRANSPORT IN THE TOKAMAK PLASMA EDGE AND OUTER CORE

UCIrvine. Gyrokinetic Studies of Turbulence Spreading IAEA-CN-116/TH1-4

ELMs and Constraints on the H-Mode Pedestal:

Overview of Gyrokinetic Theory & Properties of ITG/TEM Instabilities

Observation of Neo-Classical Ion Pinch in the Electric Tokamak*

Measurements of Plasma Turbulence in Tokamaks

Transcription:

Validating Simulations of Multi-Scale Plasma Turbulence in ITER-Relevant, Alcator C-Mod Plasmas Nathan Howard 1 with C. Holland 2, A.E. White 1, M. Greenwald 1, J. Candy 3, P. Rodriguez- Fernandez 1, and A. Creely 1 1 MIT Plasma Science and Fusion Center Cambridge, MA 02139 2 University of California San Diego La Jolla, CA 92093 3 General Atomics San Diego, CA 92121 IAEA Technical Meeting on Fusion Data Processing, Validation, and Analysis May 30 th June 2 nd, 2017 1

Interactions Between Short and Long Wavelength Turbulence Can Play an Important Role in Core Transport Anomalous ion and electron heat transport is often attributed to long wavelength, ion-scale turbulence. - ITG/TEM assumed dominant at ion-scales (k q r s < 1.0) - ETG at electron-scales (k q r s > 1.0) is often ignored However, there is both theoretical and experimental evidence for an important role of ETG is some plasma conditions - Theory/simulation predicts formation of ETG streamers - High-k scattering reports fluctuations at electron-scales Simulations which capture both ion and electron scale turbulence and their coupling are extremely computational expensive. Cross-scale coupling plays an important role in reproducing L-mode exp. Only ~2 quantitative comparisons between multi-scale simulation and experiment have made to date [N.T. Howard NF 2016, C. Holland NF 2017] 2

Interactions Between Short and Long Wavelength Turbulence Can Play an Important Role in Core Transport Anomalous ion and electron heat transport is often attributed to long wavelength, ion-scale turbulence. - ITG/TEM assumed dominant at ion-scales (k q r s < 1.0) - ETG at electron-scales (k q r s > 1.0) is often ignored However, there is both theoretical and experimental evidence for an important role of ETG is some plasma conditions - Theory/simulation predicts formation of ETG streamers - High-k scattering reports fluctuations at electron-scales Simulations Gyrokinetic which capture simulations both ion capturing and electrons all scale relevant turbulence turbulence and their scales coupling are extremely computational expensive. must be validated against experiment to better understand the Cross-scale required coupling physics plays an important for prediction role in reproducing of ITER and L-mode beyond exp. Only ~2 quantitative comparisons between multi-scale simulation and experiment have made to date [N.T. Howard NF 2016, C. Holland NF 2017] 3

Understanding Coupling of Ion and Electron-Scale Turbulence Requires Multi-Scale Simulation Multi-Scale Gyrokinetic Simulation - Captures both long and shortwavelengths (ITG/TEM/ETG) - k q r s up to ~60.0 = k q r e ~ 1.0 - Extremely expensive - Must resolve electron spatiotemporal scales and ion-scales : A handful ever - Almost all previous work used reduced electron-mass. - Should not be compared with experiment Electron mass ratio: m = (m D /m e ).5 = 60.0 For a deuterium plasma - Reduced-mass approximation insufficient in some conditions - [N.T. Howard PPCF 2015] 4 4

Previous Work Demonstrated the Role of Cross-Scale Coupling Using Multi-Scale Simulation of Alcator C-Mod L-mode Discharges Key features of cross-scale interactions were identified: 1.) Ion-scale turbulence (& ion heat flux) is enhanced by the presence of electron-scale turbulence. - Due to modification of zonal flow shear and energy transfer in conditions with marginal ionscale turbulence 2.) ETG streamers were observed to coexist with ITG turbulence and drive up to 70% exp. Q e in near marginal conditions Standard ion-scale simulation ~20k CPU hours Multi-scale simulation ~20M CPU hours 3.) Strongly driven ( >> marginal) ion-scale turbulence was found to destroy electron-scale ETG streamers 5

Previous Work Demonstrated the Role of Cross-Scale Coupling Using Multi-Scale Simulation of Alcator C-Mod L-mode Discharges Key features of cross-scale interactions were identified: 1.) Ion-scale turbulence (& ion heat flux) is enhanced by the presence of electron-scale turbulence. - Due to modification of zonal flows and energy transfer in conditions with marginal ion-scale turbulence 2.) ETG streamers were observed to coexist with ITG turbulence and drive up to 70% exp. Q e in near marginal conditions Standard ion-scale simulation ~20k CPU hours Multi-scale simulation ~20M CPU hours 3.) Strongly driven ( >> marginal) ion-scale turbulence was found to destroy electron-scale ETG streamers Cross-scale coupling played a dominant role in reproducing exp. L-mode results. In this work we attempt to extend multi-scale simulation to high performance plasma regimes which may have more reactor relevance. 6

An Alcator C-Mod ELM-y H-mode Condition Has Been Studied Using Multi-Scale Gyrokinetic Simulation Similar to operational scenarios for ITER: - Approx. ITER density - ITER B-field (5.4T) - Intrinsically rotating - Predominately electron heated (ICRF+Ohmic) - Well coupled ions and electrons: T e ~ T i Linear stability analysis indicates: - ITG is dominant at ion-scales (k q r s <1.0) - High-k TEM/ETG is present at electron-scales (k q r s > 1.0) Open questions are: 1.) Does cross-scale coupling play an important role in ITER-like H-mode conditions? 2.) Do the mechanisms of cross-scale coupling look similar to L-mode? 3.) What are the implications of cross-scale coupling for prediction of H-mode plasmas? 7

Using GYRO, Realistic Mass, Ion and Multi-Scale Simulations Have Been Performed on a C-Mod ELM-y H-mode Discharge Simulations were performed at r/a = 0.6 using the GYRO code - High physics fidelity : - All experimental inputs - 3 gyrokinetic species (deuterium, electrons, impurities) - Electro-magnetic turbulence (f & A ) - Rotation effects (ExB shear, etc.) - Electron-ion and ion-ion collisions - Realistic electron mass: µ = (m i /m e ).5 = 60.0 - Simulation box size of 71 x 55r s - 2132 radial grid points (for multi-scale simulation) - 366 toroidal modes (for multi-scale simulation) - Ion-scale simulations capture ITG/TEM up to k q r s up to ~1.1 - Multi-scale simulations capture (ITG/TEM/ETG) up to k q r s up to ~42.0 = k q r e ~ 0.7 - Utilized ~22k cores. Approximately 20-25M CPU hours per multi-scale simulation. - Results from 3 multi-scale simulations are presented here. 8

Ion-Scale Sims Reveal that Low-k Transport is Extremely Stiff With Experiment Just Above the ITG Critical Gradient Tiny a/l Ti changes (2%), dramatically increase driven heat flux are. - Implies extremely stiff heat transport (~10x a corresponding L-mode) - Note that Q i, exp ~ Q e,exp & Q/Q GB ~ 1.85 implying very marginal conditions Experimentally relevant levels of ion heat flux are obtained just 2% above the ITG critical gradient. 9

Within Uncertainties in the Simulation (~10%) and Experiment, Ion-Scale Simulation Can Reproduce Experimental Heat Fluxes When uncertainties are considered, agreement is found between ionscale simulation and experiment For the condition with a/l Ti increased 10% above experiment, ion-scale simulation reproduces experimental Q i and Q e within uncertainties Does this imply the ion-scale model is that multi-scale turbulence is unimportant? 10

The Multi-Scale Simulation Base Case is Able to Reproduce Experimental Q i & Q e Within Uncertainties Both ion & multi-scale simulation can reproduce experimental heat fluxes within simulation and experimental uncertainties. Agreement occurs at a lower value of a/l Ti (+8% for multi versus +10% for ion) For these conditions, experimental heat fluxes are insufficient to distinguish between the ion & multi-scale sim. Additional quantities are needed to discriminate between models 11

Signatures of Cross-Scale Coupling are Observed in Multi- Scale Simulation That Are Similar to the L-mode Results Small (~10%) of multi-scale Q e from high-k turbulence. However, clear signatures of crossscale coupling are observed with same a/l Ti input. There is a clear enhancement of the low-k turbulence as result of the coupling. This leads to 80% increases in the low-k driven heat transport. 12

Incremental Diffusivities Can Be Used to Discriminate Between Ion and Multi-Scale Results Similar comparisons were made in L-mode conditions [N.T Howard NF 2016] Partial sawtooth heat pulses used to determine the incremental electron diffusivity [A. Creely NF 16] - Obtained via simulation by measuring slope of Q e versus Using 3 ECE channels around of r/a = 0.6 we can measure the % change in a/l Te - Up to a 20% increase in the local value of a/l Te occurs during a partial sawtooth. Measured value of incremental diffusivity is: c inc = 1.8 +/- 0.3 m 2 /s 13

Partial Sawteeth in the ELM-y H-Mode Can Produce a 20% Increase in the Local Value of a/l Te Similar comparisons were made in L-mode conditions [N.T Howard NF 2016] Partial sawtooth heat pulses used to determine the incremental electron diffusivity [A. Creely NF 16] - Obtained via simulation by measuring slope of Q e versus Using 3 ECE channels around of r/a = 0.6 we can measure the % change in a/l Te - Up to a 20% increase in the local value of a/l Te occurs during a partial sawtooth. Measured value of incremental diffusivity is: c inc = 1.8 +/- 0.3 m 2 /s 14

To Evaluate the Incremental c, an Additional Multi-Scale Simulation was Performed with a +20% Increase in a/l Te Multi-scale simulation predicts significantly higher values of c inc 2.5x increase is found from ion to multi-scale simulation Both ion and multi-scale under-predict the c inc outside of error bars Different from previous L-mode work, where multi-scale simulation could reproduce Q i, Q e, and c inc What physics is missing from the multi-scale simulation that could explain the experiment? 15

To Evaluate the Incremental c, an Additional Multi-Scale Simulation was Performed with a +20% Increase in a/l Te Multi-scale simulation predicts significantly higher values of c inc 2.5x increase is found from ion to multi-scale simulation Both ion and multi-scale under-predict the c inc outside of error bars Different from previous L-mode work, where multi-scale simulation could reproduce Q i, Q e, and c inc What physics is missing from the multi-scale simulation that could explain the experiment? 16

To Evaluate the Incremental c, an Additional Multi-Scale Simulation was Performed with a +20% Increase in a/l Te Multi-scale simulation predicts significantly higher values of c inc 2.5x increase is found from ion to multi-scale simulation Both ion and multi-scale under-predict the c inc outside of error bars Different from previous L-mode work, where multi-scale simulation could reproduce Q i, Q e, and c inc What physics is missing from the multi-scale simulation that could explain the experiment? 17

Extreme Stiffness of Ion-Scale Turbulence + Cross-Scale Coupling, May Explain Large c inc Values Recall that these conditions are extremely close to marginal and exhibit extremely stiff low-k transport driven by ITG (+2% a/l Ti drives 50% more Q e ) Ion-scale simulations ITG drives both ion and electron heat transport. The propagation of a heat pulse in the electron temperature (from which c inc is measured) is dictated by the local electron heat flux. Exp. Increases in both & will drive significant electron heat transport Two processes can generate changes in a/l Ti during a heat pulse: 1.) Electron-ion equilibration - Can account for a 1% change in a/l Ti 2.) Ion heat pulse generated by sawtooth a few % change in a/l Ti (modeled via TRANSP) 18

Preliminary: A Multi-Scale Simulation with a 2% Increase in a/l Ti & 20% Increase in a/l Te Reproduces the Exp. c inc To test this theory, we have begun a multi-scale simulation which attempts to better reproduce the conditions under which the heat pulse propagates. Includes +20% a/l Te and +2% a/l Ti above base multi-scale simulation. Simulation is still in progress, but current values from the simulation indicate c inc =1.6 m 2 /s, in quantitative agreement with the measured value. 19

Prediction of ITER-like Conditions Will Likely Require the Physics of Cross-Scale Coupling ; Multi-Scale Simulation Posses A Real Challenge for Model Validation Cross-scale coupling was found to enhance long-wavelength turbulence significantly in ELM-y H-mode conditions. To discriminate between the models, comparisons with c inc measurements were made. - Cross-scale coupling plays an important role in enhancing c inc but does not alone explain the measured incremental diffusivities. The extreme stiffness, characteristic of high performance discharges, appears to demonstrate that experimentally relevant perturbations to a/l Ti and a/l Te can explain measured values of c inc Because of the extreme computational requirements (75M CPU hours), this study was only able to probe very limited simulation sensitivities and uncertainties in inputs. - Validation of multi-scale simulation needs more intelligent approaches for validation. It may be the development of reduced models (TGLF, Qualikiz) based on multi-scale results is the best way to probe uncertainties in simulation and experiment 20

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback