Hydrogenated graphene systems: A novel growth and hydrogenation process

IF 3.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Carbon Trends Pub Date : 2024-05-07 DOI:10.1016/j.cartre.2024.100360

Samuel Escobar Veras , Ernesto Espada , Solimar Collazo , Marcel Grau , Rajesh Katiyar , Vladimir I. Makarov , Brad R. Weiner , Gerardo Morell

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Abstract

Octadecylphosphonic acid self-assembled monolayers were used as a combined carbon and hydrogen source to grow graphene films on sapphire substrates via hot filament chemical vapor deposition. The functionalized substrates were sealed with a thin Cu film and heated to 950°C under Ar flow. After synthesis, the Cu was etched away. The graphene samples then underwent a hydrogenation treatment in the same reactor setup, exposed to a CH₄/H₂ gas mixture at 820°C for 2 hours. The structure and properties of the graphene films before and after hydrogenation were characterized. Raman spectroscopy was employed to probe the defect-related bands and C-H bonding. X-ray diffraction provided insights into the crystalline structure and interlayer spacing. The ferromagnetic response was measured using a PPMS system across a range of temperatures and magnetic fields. XPS was used to assess the chemical composition and bonding. This multi-step process enabled a detailed evaluation of the novel synthesis protocol and its effects on the resulting hydrogenated graphene material.

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氢化石墨烯系统：新型生长和氢化工艺

利用十八烷基膦酸自组装单层作为碳氢结合源，通过热丝化学气相沉积在蓝宝石基底上生长石墨烯薄膜。功能化后的基底用一层薄薄的铜膜密封，并在氩气流下加热至 950°C。合成完成后，铜被蚀刻掉。然后，石墨烯样品在相同的反应器装置中进行氢化处理，暴露在 820°C 的 CH4/H2 混合气体中 2 小时。对氢化前后石墨烯薄膜的结构和特性进行了表征。拉曼光谱用于探测与缺陷相关的波段和 C-H 键。X 射线衍射可深入了解晶体结构和层间距。使用 PPMS 系统在一定温度和磁场范围内测量了铁磁响应。XPS 用于评估化学成分和化学键。通过这一多步骤过程，可以详细评估新型合成方案及其对氢化石墨烯材料的影响。

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