Rotational excitation from a molecular mirror: NO scattering from Ru(0001)-(1 × 1)H

PhysChemComm Pub Date : 2001-01-01 DOI:10.1039/B104823F

B. Berenbak, B. Riedmüller, C. Rettner, D. Auerbach, S. Stolte, A. Kleyn

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引用次数: 1

Abstract

The rotational state distributions of NO molecules scattered off the (1 × 1)H-covered Ru(0001) surface have been investigated by resonance enhanced multi-photon ionisation (REMPI). Angular and energy distributions reported earlier for this scattering channel, show an angular spread of only ≃8° (θ i = 60°, E i = 2.1 eV), combined with small translational energy loss in the collision (E f /E i = 0.91). These observations suggest scattering from a very weakly corrugated surface, a ‘molecular mirror’, and a high probability to yield cold rotational distributions. The present experiments, however, reveal substantial rotational excitation, accompanied by rotational rainbows for higher quantum numbers (J > 20). The rotational temperatures increase from = 450 K at an incidence energy E i = 0.32 eV, to = 950 K at E i = 1.50 eV. The kinetic to rotational energy transfer efficacy, appears to be slightly higher than for NO scattering of the fairly inert Ag(111) surface. This system has much wider angular spread and larger translational energy losses. Assuming parallel momentum conservation in the collision the observed rotational excitation would lead to an angular spread that is considerably smaller than that observed for an incoming angle of θ i = 15°.

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分子镜的旋转激发:Ru(0001)-(1 × 1)H的NO散射

用共振增强多光子电离(REMPI)研究了从(1 × 1) h覆盖的Ru(0001)表面散射的NO分子的旋转态分布。该散射通道的角向和能量分布表明，该通道的角向扩散仅为≃8°(θ i = 60°，E i = 2.1 eV)，且碰撞过程中的平动能量损失较小(E f /E i = 0.91)。这些观察结果表明，散射来自一个非常弱的波纹表面，一个“分子镜子”，并且很有可能产生冷旋转分布。然而，目前的实验揭示了大量的旋转激发，并伴随着更高量子数(J > 20)的旋转彩虹。旋转温度从入射能量E i = 0.32 eV时的= 450 K增加到E i = 1.50 eV时的= 950 K。相对于惰性Ag(111)表面的NO散射，其动能到转动的能量传递效率略高。该系统具有更宽的角展和更大的平动能量损失。假设在碰撞中平行动量守恒，观察到的旋转激励将导致的角扩展比θ i = 15°时观察到的角扩展要小得多。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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PhysChemComm

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