Zeller Genrich, Díaz Barrero Desedea, Wiesen Paul, Niemes Simon, Tuchscherer Nancy, Aker Max, Leonhardt Artus M W, Demand Jannik, Valerius Kathrin, Bornschein Beate, Schlösser Magnus, Telle Helmut H
Tritium Laboratory Karlsruhe (TLK), Institute for Astroparticle Physics (IAP), Karlsruhe Institute of Technology (KIT) Hermann-von-Helmholtz-Platz 1 76344 Eggenstein-Leopoldshafen Germany
Departamento de Química Física Aplicada, Universidad Autónoma de Madrid Campus de Cantoblanco 28049 Madrid Spain.
Nanoscale Adv. 2024 Mar 27;6(11):2838-2849. doi: 10.1039/d3na00904a. eCollection 2024 May 29.
In this work, we report on studies of graphene exposed to tritium gas in a controlled environment. The single layer graphene on a SiO/Si substrate was exposed to 400 mbar of T, for a total time of ∼55 h. The resistivity of the graphene sample was measured during tritium exposure using the van der Pauw method. We found that the sheet resistance increases by three orders of magnitude during the exposure, suggesting significant chemisorption of tritium. After exposure, the samples were characterised spatio-chemical mapping with a confocal Raman microscope, to study the effect of tritium on the graphene structure (tritiation yielding T-graphene), as well as the homogeneity of modifications across the whole area of the graphene film. The Raman spectra after tritium exposure were comparable to previously observed results in hydrogen-loading experiments, carried out by other groups. By thermal annealing we also could demonstrate, using Raman spectral analysis, that the structural changes were largely reversible. Considering all observations, we conclude that the graphene film was at least partially tritiated during the tritium exposure, and that the graphene film by and large withstands the bombardment by electrons from the β-decay of tritium, as well as by energetic primary and secondary ions.
在这项工作中,我们报告了在可控环境中对暴露于氚气的石墨烯的研究。将SiO/Si衬底上的单层石墨烯暴露于400毫巴的T₂中,总时长约为55小时。在氚暴露期间,使用范德堡方法测量石墨烯样品的电阻率。我们发现,在暴露过程中,薄层电阻增加了三个数量级,这表明氚发生了显著的化学吸附。暴露后,用共焦拉曼显微镜对样品进行空间化学映射,以研究氚对石墨烯结构的影响(氚化产生T-石墨烯),以及整个石墨烯膜区域改性的均匀性。氚暴露后的拉曼光谱与其他研究小组之前在氢负载实验中观察到的结果相当。通过热退火,我们还能够利用拉曼光谱分析证明,结构变化在很大程度上是可逆的。综合所有观察结果,我们得出结论,在氚暴露过程中,石墨烯膜至少部分被氚化,并且石墨烯膜大体上能够承受来自氚β衰变产生的电子以及高能初级和次级离子的轰击。
