Generation and Analysis of Tritium-Substituted Methane

D. Díaz Barrero; T. L. Le; S. Niemes; S. Welte; M. Schlösser; B. Bornschein; H. H. Telle

doi:dx.doi.org/10.1080/15361055.2023.2194235

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Home / Publications / Journals / Fusion Science and Technology / Volume 80 / Number 3-4

Generation and Analysis of Tritium-Substituted Methane

D. Díaz Barrero, T. L. Le, S. Niemes, S. Welte, M. Schlösser, B. Bornschein, H. H. Telle

Fusion Science and Technology / Volume 80 / Number 3-4 / May 2024 / Pages 530-539

Research Article / dx.doi.org/10.1080/15361055.2023.2194235

Received:December 7, 2022

Accepted:March 16, 2023

Published:April 3, 2024

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An unavoidable category of molecular species in large-scale tritium applications, such as nuclear fusion, are tritium-substituted hydrocarbons, which form by radiochemical reactions in the presence of (circulating) tritium and carbon (mainly from the steel of vessels and tubing). Tritium-substituted methane species, CQ₄ (with Q = H,D,T), are often the precursor for higher-order reaction chains, and thus are of particular interest. Here we describe the controlled production of CQ₄ carried out in the CAPER facility of the Tritium Laboratory Karlsruhe, exploiting catalytic reactions and species enrichment via the CAPER integral permeator. CQ₄ was generated in substantial quantities (>1000 cm³ at ~850 mbar, with CQ₄content of up to ~20%). The samples were analyzed using laser Raman and mass spectrometry to determine the relative isotopologue composition and to trace the generation of tritiated chain hydrocarbons.