Ciabini Lucia, Santoro Mario, Gorelli Federico A, Bini Roberto, Schettino Vincenzo, Raugei Simone
LENS, European Laboratory for Non-Linear Spectroscopy and INFM, Via Carrara 1, I-50019 Sesto Fiorentino, Firenze, Italy.
Nat Mater. 2007 Jan;6(1):39-43. doi: 10.1038/nmat1803. Epub 2006 Dec 10.
Success in designing and tailoring solid-state reactions depends on the knowledge of the mechanisms regulating the reactivity at the microscopic level. In spite of several attempts to rationalize the reactivity of crystals, the question of the existence of a critical distance for a reaction to occur remains unsolved. In this framework, the role of lattice phonons, which continuously tune the relative distance and orientation of the molecules, is still not fully understood. Here, we show that at the onset of the transformation of crystalline benzene to an amorphous hydrogenated carbon the intermolecular C-C distance is always the same (about 2.6 A) once collective motions are taken into account, and it is independent of the pressure and temperature conditions. This conclusion is supported by first-principles molecular-dynamics simulations. This is a clear demonstration of the role of lattice phonons in driving the reactivity in the crystalline phase by fine-tuning of the nearest-neighbour distances. The knowledge of the critical C-C distance can be crucial in planning solid-state reactions at moderate pressure.
成功设计和定制固态反应取决于对微观层面调节反应活性机制的了解。尽管人们多次尝试对晶体的反应活性进行合理化解释,但反应发生时临界距离是否存在的问题仍未得到解决。在此框架下,晶格声子不断调整分子的相对距离和取向,其作用仍未被完全理解。在这里,我们表明,在结晶苯向非晶态氢化碳转变开始时,一旦考虑到集体运动,分子间C-C距离始终相同(约2.6埃),且与压力和温度条件无关。这一结论得到了第一性原理分子动力学模拟的支持。这清楚地证明了晶格声子通过微调最近邻距离在驱动晶相反应活性方面的作用。了解临界C-C距离对于规划中等压力下的固态反应可能至关重要。