Exploring the time-scale of photo-initiated interfacial electron transfer through first-principles interpretation of ultrafast X-ray spectroscopy (Presentation Recording)

SPIE Optics + Photonics for Sustainable Energy Pub Date : 2015-10-05 DOI:10.1117/12.2190444

D. Prendergast, S. Pemmaraju

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Abstract

With the advent of X-ray free electron lasers and table-top high-harmonic-generation X-ray sources, we can now explore changes in electronic structure on ultrafast time scales -- at or less than 1ps. Transient X-ray spectroscopy of this kind provides a direct probe of relevant electronic levels related to photoinitiated processes and associated interfacial electron transfer as the initial step in solar energy conversion. However, the interpretation of such spectra is typically fraught with difficulty, especially since we rarely have access to spectral standards for nonequilibrium states. To this end, direct first-principles simulations of X-ray absorption spectra can provide the necessary connection between measurements and reliable models of the atomic and electronic structure. We present examples of modeling excited states of materials interfaces relevant to solar harvesting and their corresponding X-ray spectra in either photoemission or absorption modalities. In this way, we can establish particular electron transfer mechanisms to reveal detailed working principles of materials systems in solar applications and provide insight for improved efficiency.

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通过超快x射线光谱学第一性原理解释探索光引发界面电子转移的时间尺度(演示记录)

随着x射线自由电子激光器和台式高谐波x射线源的出现，我们现在可以在超快时间尺度上探索电子结构的变化-在或小于1ps。这种瞬态x射线能谱提供了与光引发过程和相关界面电子转移相关的电子水平的直接探测，作为太阳能转换的第一步。然而，这种光谱的解释通常充满了困难，特别是因为我们很少有机会获得非平衡态的光谱标准。为此，x射线吸收光谱的直接第一性原理模拟可以在测量和可靠的原子和电子结构模型之间提供必要的联系。我们提出了与太阳能收集相关的材料界面激发态的建模示例及其相应的光发射或吸收模式的x射线光谱。通过这种方式，我们可以建立特定的电子转移机制，揭示太阳能应用中材料系统的详细工作原理，并为提高效率提供见解。

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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SPIE Optics + Photonics for Sustainable Energy

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