Deuterium uptake in boronized ATJ graphite walls of NSTX-U

POSTER

Abstract

We present a study of the role of boron and oxygen in the chemistry of deuterium retention in boronized ATJ graphite irradiated by a deuterium plasma. The experimental results were obtained by the first in vacuo X-ray Photoelectron Spectroscopy (XPS) measurements at the National Spherical Torus Experiment Upgrade (NSTX-U). The subtle interplay of boron, carbon, oxygen and deuterium chemistry is explained by reactive molecular dynamics simulation, verified by quantum-classical molecular dynamics and successfully compared to the measured data. The calculations deciphered the roles of oxygen and boron for the deuterium retention and predict deuterium uptake by a boronized carbon surface of 90{\%} close in value to that previously predicted for a lithiated and oxidized carbon surface.

*CONACyT (JD), USDOE FES Grants (PSK and BK), USDOE BES/FES Grant (JPA and FB)

Authors

  • Javier Dominguez

    • State Univ of NY- Stony Brook

  • F. Bedoya

    • University of Illinois Urbana Champaign
    • University of Illinois Urbana
    • UIUC
    • University of Illinois

  • Predrag Krstic

    • State Univ of NY- Stony Brook

  • J.P. Allain

    • University of Illinois Urbana Champaign
    • University of Illinois Urbana
    • Univesity of Illinois, Center for Plasma Material Interactions, and Micro and Nanotechnology Center, Urbana, IL 61801
    • University of Illinois at Urbana Champaign
    • University of Illinois
    • UIUC

  • Stephan Irle

    • Nagoya University

  • C.H. Skinner

    • Princeton Plasma Physics Laboratory
    • PPPL

  • Robert Kaita

    • Princeton Plasma Physics Laboratory
    • PPPL

  • B.E. Koel

    • Princeton University
    • Department of Chemical & Biological Engineering, Princeton University