铝、碳或硅植入中的竞争性细胞内氢纳米载体:利用密度泛函理论研究的新型环保储能技术

IF 1.4 4区 化学 Q4 PHYSICS, ATOMIC, MOLECULAR & CHEMICAL Russian Journal of Physical Chemistry B Pub Date : 2024-07-22 DOI:10.1134/S1990793124700131
F. Mollaamin
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引用次数: 0

摘要

摘要 本研究提出,可以通过在原始氮化硼纳米电池(B5N10_NC)上掺杂金属、非金属和金属类化合物来研究金属、非金属和金属类化合物作为半导体的吸附潜力,从而设计出储能装置。使用密度泛函理论研究了掺杂 X(X=Al、C、Si)的 B5N10_NC 对氢的吸附。偏态密度可以评估氢分子与 X-B4N10_NC 之间确定的电荷组合,这表明金属(Al)、非金属(C)、金属类/半导体(Si)的主要复合物之间存在竞争。根据核四极共振分析,B5N10_NC 上掺碳的电势波动最小,掺杂原子(包括 C、Si 和 Al)的负原子电荷最高,在 H2@C-B4N10_NC、H2@Si-B4N10_NC 和 H2@Al-B4N10_NC 中分别为 0.1167、1.0620 和 1.1541 库仑,可以作为吸附过程中接受电子倾向最高的合适选择。此外,所报告的核磁共振光谱结果表明,通过吸附 H2 在 X-B4N10_NC 上掺杂原子接受电子的产率可排序为Si ≈ Al > C,显示了铝、碳、硅和氢原子之间共价键的强度。事实上,H2 分子的吸附会在 X-B4N10_NC 上引入自旋极化,这表明这些表面可用作磁性吸附剂表面。在红外光谱方面,H2@Si-B4N10_NC≈H2@Al-B4N10_NC &ggt;H2@C-B4N10_NC的掺杂纳米电池对氢分子的吸附波动最大,吸附倾向最高,这可以解决电荷载体(氢分子-纳米电池)以及掺杂原子对整体结构的单独影响的具体问题。根据本研究中的\(\Delta G_{R}^{^\circ }\) 量结果,B5N10_NC掺杂Al、C、Si原子对氢分子的最大吸附效率取决于氢原子之间的共价键,X-B4N10_NC是一种有效的储氢传感器。最后,原子掺杂的氮化硼纳米电池对 H2 分子的吸附具有高选择性:H2@Si-B4N10_NC > H2@Al-B4N10_NC \( \gg \) H2@C-B4N10_NC。我们的研究结果为 X(X = Al、C、Si)-B4N10 纳米电池在氢基储能方法中的应用潜力提供了重要的展望。结果表明,H2@X-B4N10_NC 是稳定的化合物,最稳定的吸附位点是笼环的中心。
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Competitive Intracellular Hydrogen-Nanocarrier Among Aluminum, Carbon, or Silicon Implantation: a Novel Technology of Eco-Friendly Energy Storage using Research Density Functional Theory

This work proposes that metallic, nonmetallic, metalloid as a semiconductor can be examined through doping on the pristine boron nitride nanocell (B5N10_NC) for ameliorating the adsorption potential of the nanosurface towards designing the energy storage device. Hydrogen adsorption by using X (X=Al, C, Si)-doped B5N10_NC have been investigated using density functional theory. The partial density of states can evaluate a determined charge assembly between hydrogen molecules and X–B4N10_NC which indicates the competition among dominant complexes of metallic (Al), nonmetallic (C), metalloid/semiconductor (Si). Based on nuclear quadrupole resonance analysis, carbon-doped on B5N10_NC has shown the lowest fluctuation in electric potential and the highest negative atomic charge on doping atoms including C, Si, and Al including 0.1167, 1.0620, and 1.1541 coulomb in H2@C–B4N10_NC, H2@Si–B4N10_NC, and H2@Al–B4N10_NC, respectively, can be an appropriate option with the highest tendency for electron accepting in the adsorption process. Furthermore, the reported results of nuclear magnetic resonance spectroscopy have exhibited that the yield of electron accepting for doping atoms on the X–B4N10_NC through H2 adsorption can be ordered as: Si ≈ Al > C that exhibits the strength of covalent bond between aluminum, carbon, silicon, and hydrogen atoms. In fact, the adsorption of H2 molecules can introduce spin polarization on the X–B4N10_NC which specifies that these surfaces may be employed as magnetic adsorbent surface. Regarding IR spectroscopy, doped nanocells of H2@Si–B4N10_NC ≈ H2@Al–B4N10_NC > H2@C–B4N10_NC, respectively, have the most fluctuations and the highest adsorption tendency for hydrogen molecules which can address specific questions on the individual effect of charge carriers (hydrogen molecule-nanocell), as well as doping atoms on the overall structure. Based on the results of \(\Delta G_{R}^{^\circ }\) amounts in this research, the maximum efficiency of Al, C, Si atoms doping of B5N10_NC for H2 molecules adsorption depends on the covalent bond between hydrogen atoms and X–B4N10_NC as a potent sensor for hydrogen storage. Finally, high selectivity of atom-doped on boron nitride nanocell for H2 molecules adsorption has been resulted as: H2@Si–B4N10_NC > H2@Al–B4N10_NC \( \gg \) H2@C–B4N10_NC. Our findings prepare important visions into the potential of employing X (X = Al, C, Si)–B4N10 nanocells in hydrogen-based energy-storage approaches. The results denote that H2@X–B4N10_NC are stable compounds, with the most stable adsorption site being the center of the cage ring.

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来源期刊
Russian Journal of Physical Chemistry B
Russian Journal of Physical Chemistry B 化学-物理:原子、分子和化学物理
CiteScore
2.20
自引率
71.40%
发文量
106
审稿时长
4-8 weeks
期刊介绍: Russian Journal of Physical Chemistry B: Focus on Physics is a journal that publishes studies in the following areas: elementary physical and chemical processes; structure of chemical compounds, reactivity, effect of external field and environment on chemical transformations; molecular dynamics and molecular organization; dynamics and kinetics of photoand radiation-induced processes; mechanism of chemical reactions in gas and condensed phases and at interfaces; chain and thermal processes of ignition, combustion and detonation in gases, two-phase and condensed systems; shock waves; new physical methods of examining chemical reactions; and biological processes in chemical physics.
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