Litcius/Paper detail

Measuring the electron temperature and identifying plasma detachment using machine learning and spectroscopy

C. M. Samuell, A. G. Mclean, C. A. Johnson, F. Glass, A. E. Jaervinen

2021Review of Scientific Instruments37 citationsDOIOpen Access PDF

Abstract

A machine learning approach has been implemented to measure the electron temperature directly from the emission spectra of a tokamak plasma. This approach utilized a neural network (NN) trained on a dataset of 1865 time slices from operation of the DIII-D tokamak using extreme ultraviolet/vacuum ultraviolet emission spectroscopy matched with high-accuracy divertor Thomson scattering measurements of the electron temperature, Te. This NN is shown to be particularly good at predicting Te at low temperatures (Te < 10 eV) where the NN demonstrated a mean average error of less than 1 eV. Trained to detect plasma detachment in the tokamak divertor, a NN classifier was able to correctly identify detached states (Te < 5 eV) with a 99% accuracy (an F1 score of 0.96) at an acquisition rate 10× faster than the Thomson scattering measurement. The performance of the model is understood by examining a set of 4800 theoretical spectra generated using collisional radiative modeling that was also used to predict the performance of a low-cost spectrometer viewing nitrogen emission in the visible wavelengths. These results provide a proof-of-principle that low-cost spectrometers leveraged with machine learning can be used to boost the performance of more expensive diagnostics on fusion devices and be used independently as a fast and accurate Te measurement and detachment classifier.

Topics & Concepts

Thomson scatteringDivertorTokamakElectron temperatureSpectrometerSpectroscopyPlasma diagnosticsArtificial intelligenceArtificial neural networkPlasmaSpectral lineRadiative transferScatteringExtreme ultravioletMaterials scienceComputer sciencePlasma parametersTemperature measurementComputational physicsElectronBolometerOpticsMachine learningEmission spectrumClassifier (UML)PhysicsAtomic physicsFusionMagnetic confinement fusionFusion powerMonte Carlo methodMagnetic confinement fusion researchFusion materials and technologiesLaser-induced spectroscopy and plasma