模拟氢化石墨烯孔上爆炸物分子的增强吸附

R. Holt, T. Rybolt
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引用次数: 1

摘要

使用计算化学对石墨烯双层纳米传感器检测爆炸分子的可能性进行了建模。在石墨烯双层结构上设计了一个孔,在锯齿状的二维六边形孔的边缘周围构建了三个战略性放置的周边羟基(OH)。使用MM2分子力学参数对这种羟基化孔和各种爆炸分子的模型进行了优化。计算了平坦石墨烯双层上和双层内专门设计的羟基化孔上22个爆炸分子的分子表面相互作用能(结合能)E的值。三硝基甲苯(TNT)的分子表面结合能从平坦石墨烯双层上的17.9kcal/mol增加到羟基化孔上的42.3kcal/mol。由于许多爆炸性分子上存在硝基的共同功能,所研究的其他爆炸性分子基于孔内形成的特定氢键相互作用给出了类似的增强。与平坦双层相比,22个爆炸性吸附质分子中的每一个在双层羟基化孔上显示出增加的分子-表面相互作用。对于22个分子,平坦石墨表面的平均E为15.8kcal/mol,羟基化孔的平均E是33.8kcal/mol。吸附的增强应该使检测装置更加灵敏。基于改性石墨烯表面的纳米传感器可用于检测极低浓度的爆炸分子或爆炸特征分子。
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Modeling Enhanced Adsorption of Explosive Molecules on a Hydroxylated Graphene Pore
The possibility of a graphene bilayer nanosensor for the detection of explosive molecules was modeled using computational chemistry. A pore was designed on a graphene bilayer structure with three strategically placed perimeter hydroxyl (OH) groups built around the edge of an indented, two-dimensional hexagonal pore. This hydroxylated pore and models of various explosive molecules were optimized using MM2 molecular mechanics parameters. Values were calculated for the molecule-surface interaction energy (binding energy), E, for 22 explosive molecules on a flat graphene bilayer and on the specially designed hydroxylated pore within the bilayer. The molecule-surface binding energy for trinitrotoluene (TNT) increased from 17.9 kcal/mol on the flat graphene bilayer to 42.3 kcal/mol on the hydroxylated pore. Due to the common functionality of nitro groups that exist on many explosive molecules, the other explosive molecules studied gave similar enhancements based on the specific hydrogen bonding interactions formed within the pore. Each of the 22 explosive adsorbate molecules showed increased molecule-surface interaction on the bilayer hydroxylated pore as compared to the flat bilayer. For the 22 molecules, the average E for the flat graphite surface was 15.8 kcal/mol and for the hydroxylated pore E was 33.8 kcal/mol. An enhancement of adsorption should make a detection device more sensitive. Nanosensors based on a modified graphene surface may be useful for detecting extremely low concentrations of explosive molecules or explosive signature molecules.
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