Resonant molecular transitions in second harmonic generation spectroscopy of Fe-octaethylporphyrin adsorbed on Cu(001)

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-15 DOI:arxiv-2409.09801

A. Eschenlohr, R. Shi, J. Chen, P. Zhou, U. Bovensiepen, W. Hübner, G. Lefkidis

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Abstract

Metal-organic molecular adsorbates on metallic surfaces offer the potential to both generate materials for future (spin-)electronics applications as well as a better fundamental understanding of molecule-substrate interaction, provided that the electronic properties of such interfaces can be analyzed and/or manipulated in a targeted manner. To investigate electronic interactions at such interfaces, we measure optical second harmonic generation (SHG) from iron-octaethylporphyrin (FeOEP) adsorbed on Cu(001), and perform electronic structure calculations using coupled cluster methods including optical excitations. We find that the SHG response of FeOEP/Cu(001) is modified at 2.15-2.35 eV fundamental photon energy compared to the bare Cu(001) surface. Our polarization-dependent analysis shows that the $\chi_{zzz}^{(2)}$ non-linear susceptibility tensor element dominates this modification. The first-principles calculations confirm this effect and conclude a resonantly enhanced SHG by molecular transitions at $\hbar\omega \geq 2$ eV. We show that the enhancement of $\chi^{(2)}_{zzz}$ results from a strong charge-transfer character of the molecule-substrate interaction. Our findings demonstrate the suitability of surface SHG for the characterization of such interfaces and the potential to employ it for time-resolved SHG experiments on optically induced electronic dynamics.

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吸附在铜(001)上的八乙基卟啉的二次谐波发生光谱中的共振分子跃迁

金属表面上的金属有机分子吸附剂既有可能为未来的（自旋）电子学应用生成材料，也有可能让人们从根本上更好地理解分子与基底的相互作用，前提是可以有针对性地分析和/或操纵这类界面的电子特性。为了研究这类界面上的电子相互作用，我们测量了吸附在铜（001）上的八乙基卟啉铁（FeOEP）产生的光学二次谐波（SHG），并利用包括光学激发在内的耦合簇方法进行了电子结构计算。我们发现，与裸铜(001)表面相比，FeOEP/Cu(001)的 SHG 响应在 2.15-2.35 eV 基本光子能量处发生了改变。我们的偏振依赖性分析表明，$chi_{zzz}^{(2)}$非线性感性张量元素主导了这种改变。第一原理计算证实了这一效应，并得出结论：在 $\hbar\omega \geq 2$ eV 的分子跃迁会产生共振增强的 SHG。我们的研究结果表明，$\chi^{(2)}_{zzz}$ 的增强源于分子与基底相互作用的强电荷转移特性。我们的研究结果表明，表面 SHG 适用于表征此类界面，并有潜力将其用于光诱导电子动力学的时间分辨 SHG 实验。

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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arXiv - PHYS - Chemical Physics

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