TY - JOUR
T1 - Raman spectroscopy of carbon dust samples from NSTX
AU - Raitses, Y.
AU - Skinner, C. H.
AU - Jiang, F.
AU - Duffy, T. S.
N1 - Funding Information:
The authors would like to thank Angus Pacala for his assistance in arc experiments and Raman measurements. The authors gratefully acknowledge Professor Robert J. Cava of Princeton University for the use of high vacuum furnace for heat treatment of graphite samples in his laboratory, and Tyrel McQueen for conducting this heat treatment. This work was partially supported by US DOE Grant No. DE-AC02-76CH03073.
PY - 2008/4/30
Y1 - 2008/4/30
N2 - The Raman spectrum of dust particles exposed to the NSTX plasma is different from the spectrum of unexposed particles scraped from an unused graphite tile. For the unexposed particles, the high energy G-mode peak (Raman shift ∼ 1580 cm-1) is much stronger than the defect-induced D-mode peak (Raman shift ∼ 1350 cm-1), a pattern that is consistent with Raman spectrum for commercial graphite materials. For dust particles exposed to the plasma, the ratio of G-mode to D-mode peaks is lower and becomes even less than 1. The Raman measurements indicate that the production of carbon dust particles in NSTX involves modifications of the physical and chemical structure of the original graphite material. These modifications are shown to be similar to those measured for carbon deposits from atmospheric pressure helium arc discharge with an ablating anode electrode made from a graphite tile material. We also demonstrate experimentally that heating to 2000-2700 K alone cannot explain the observed structural modifications indicating that they must be due to higher temperatures needed for graphite vaporization, which is followed either by condensation or some plasma-induced processes leading to the formation of more disordered forms of carbon material than the original graphite.
AB - The Raman spectrum of dust particles exposed to the NSTX plasma is different from the spectrum of unexposed particles scraped from an unused graphite tile. For the unexposed particles, the high energy G-mode peak (Raman shift ∼ 1580 cm-1) is much stronger than the defect-induced D-mode peak (Raman shift ∼ 1350 cm-1), a pattern that is consistent with Raman spectrum for commercial graphite materials. For dust particles exposed to the plasma, the ratio of G-mode to D-mode peaks is lower and becomes even less than 1. The Raman measurements indicate that the production of carbon dust particles in NSTX involves modifications of the physical and chemical structure of the original graphite material. These modifications are shown to be similar to those measured for carbon deposits from atmospheric pressure helium arc discharge with an ablating anode electrode made from a graphite tile material. We also demonstrate experimentally that heating to 2000-2700 K alone cannot explain the observed structural modifications indicating that they must be due to higher temperatures needed for graphite vaporization, which is followed either by condensation or some plasma-induced processes leading to the formation of more disordered forms of carbon material than the original graphite.
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U2 - 10.1016/j.jnucmat.2008.01.012
DO - 10.1016/j.jnucmat.2008.01.012
M3 - Article
AN - SCOPUS:41549089928
SN - 0022-3115
VL - 375
SP - 365
EP - 369
JO - Journal of Nuclear Materials
JF - Journal of Nuclear Materials
IS - 3
ER -