Tavernelli Ivano, Gaigeot Marie-Pierre, Vuilleumier Rodolphe, Stia Carlos, Hervé du Penhoat Marie-Anne, Politis Marie-Françoise
Ecole Polytechnique Fédérale de Lausanne, Institut des Sciences et Ingénierie Chimiques, EPFL-BCH, 1015 Lausanne, Switzerland.
Chemphyschem. 2008 Oct 6;9(14):2099-103. doi: 10.1002/cphc.200800177.
The early stages of the Coulomb explosion of a doubly ionized water molecule immersed in liquid water are investigated with time-dependent density functional theory molecular dynamics (TD-DFT MD) simulations. Our aim is to verify that the double ionization of one target water molecule leads to the formation of atomic oxygen as a direct consequence of the Coulomb explosion of the molecule. To that end, we used TD-DFT MD simulations in which effective molecular orbitals are propagated in time. These molecular orbitals are constructed as a unitary transformation of maximally localized Wannier orbitals, and the ionization process was obtained by removing two electrons from the molecular orbitals with symmetry 1B(1), 3A(1), 1B(2) and 2A(1) in turn. We show that the doubly charged H(2)O(2+) molecule explodes into its three atomic fragments in less than 4 fs, which leads to the formation of one isolated oxygen atom whatever the ionized molecular orbital. This process is followed by the ultrafast transfer of an electron to the ionized molecule in the first femtosecond. A faster dissociation pattern can be observed when the electrons are removed from the molecular orbitals of the innermost shell. A Bader analysis of the charges carried by the molecules during the dissociation trajectories is also reported.
采用含时密度泛函理论分子动力学(TD-DFT MD)模拟研究了浸没在液态水中的双电离水分子库仑爆炸的早期阶段。我们的目的是验证一个目标水分子的双电离会直接导致分子库仑爆炸形成原子氧。为此,我们使用了TD-DFT MD模拟,其中有效分子轨道随时间演化。这些分子轨道通过最大局域化万尼尔轨道的酉变换构建,通过依次从对称的1B(1)、3A(1)、1B(2)和2A(1)分子轨道中移除两个电子来实现电离过程。我们表明,双电荷的H(2)O(2+)分子在不到4飞秒的时间内爆炸成其三个原子碎片,无论电离的分子轨道如何,都会形成一个孤立的氧原子。在第一个飞秒内,这个过程伴随着一个电子超快转移到电离分子上。当从最内层壳层的分子轨道中移除电子时,可以观察到更快的解离模式。还报道了对解离轨迹中分子所带电荷的巴德分析。
