环境条件下石墨烯上的二维氯化钠所体现的非常规化学计量晶体的稳定机制

Liuhua Mu, Xuchang Su, Haiping Fang, Lei Zhang
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引用次数: 0

摘要

传统上,人们认为钠、氯和碳等主族元素的非常规化学计量化合物等含有活泼价电子的化合物在环境条件下不稳定,需要在包括超高压环境在内的极端条件下才能保持稳定。最近的发现挑战了这一观念,展示了还原氧化石墨烯(rGO)膜上二维氯化钠和其他非常规化学计量化合物的环境稳定性。以 Na2Cl 晶体为例,我们揭示了一种机制,其中石墨烯芳香环上的电子析出有效缓解了 Na2Cl 的反应性,尤其是抵消了氧诱导的氧化作用--这种现象被称为表面析出诱导电子陷阱(SDIET)机制。理论计算还表明,出现了一个巨大的活化能势垒,阻碍了氧气渗入氯化钠并与之发生反应。实验进一步证明,即使在纯氧环境中长期暴露 9 天,rGO 膜上的氯化钠晶体仍能保持几乎完好无损的状态。所发现的 SDIET 机制是在环境条件下稳定含有活性价电子的化学活性物质方面的一次重大飞跃。它的意义超越了非常规的化学计量化合物,包括主族化合物和过渡元素化合物,可能会对各个科学领域产生影响。
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Stability Mechanisms of Unconventional Stoichiometric Crystals Exampled by Two-Dimensional Na2Cl on Graphene under Ambient Conditions
Compounds harboring active valence electrons, such as unconventional stoichiometric compounds of main group elements including sodium, chlorine, and carbon, have conventionally been perceived as unstable under ambient conditions, requiring extreme conditions including extra-high pressure environments for stability. Recent discoveries challenge this notion, showcasing the ambient stability of two-dimensional Na2Cl and other unconventional stoichiometric compounds on reduced graphene oxide (rGO) membranes. Focusing on the Na2Cl crystal as a case study, we reveal a mechanism wherein electron delocalization on the aromatic rings of graphene effectively mitigates the reactivity of Na2Cl, notably countering oxygen-induced oxidation--a phenomenon termed the Surface Delocalization-Induced Electron Trap (SDIET) mechanism. Theoretical calculations also show a substantial activation energy barrier emerges, impeding oxygen infiltration into and reaction with Na2Cl. The remarkable stability was further demonstrated by the experiment that Na2Cl crystals on rGO membranes remain almost intact even after prolonged exposure to a pure oxygen atmosphere for 9 days. The discovered SDIET mechanism presents a significant leap in stabilizing chemically active substances harboring active valence electrons under ambient conditions. Its implications transcend unconventional stoichiometric compounds, encompassing main group and transition element compounds, potentially influencing various scientific disciplines.
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