New Mechanisms and New Systems of Hole Formation in Spectral Hole Burning

K. Horie
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Abstract

A variety of studies on persistent spectral hole burning (PSHB) have been carried out for the last twenty years [1-4], since the discovery of this phenomenon in 1974. The elucidation of electron-phonon interaction, the nature of a zero-phonon line and spectral diffusion in PSHB have been studied intensively together with the research aiming at its possible applicability to ultra-high density optical storage. However, as for the PSHB materials, most of the works have been carried out with porphyrins, phthalocyanines, and quinizarin including their derivatives, several organic dyes, samarium and some other inorganic ions. The number of molecules reported to show hole formation so far is restricted compared to a wide variety of chemical structure of organic molecules. This would be because it is usually thought that for the hole formation the existence of a zero-phonon line in guest molecules for SHB should be accompanied by the occurrence of some photochemical reaction of the guest molecules. A well-known exception on this point is the so-called non-photochemical hole burning (NPHB) [4]. Recently triplet-triplet energy transfer of guest molecule to a host photo-reactive matrix has been reported to be a new family [5] of PSHB systems with new mechanism.
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光谱烧孔形成的新机制和新体系
自1974年发现持续光谱空穴燃烧(PSHB)以来,在过去的20年里进行了各种各样的研究[1-4]。对PSHB中电子-声子相互作用的解释、零声子线的性质和光谱扩散进行了深入的研究,并针对其在超高密度光存储中的可能应用进行了研究。然而,对于PSHB材料,大部分的工作都是用卟啉、酞菁和奎尼萨林及其衍生物、几种有机染料、钐和其他一些无机离子进行的。与有机分子的多种化学结构相比,迄今为止报道的显示孔洞形成的分子数量有限。这可能是因为通常认为,对于空穴的形成,SHB客体分子中零声子线的存在应该伴随着客体分子的某些光化学反应的发生。在这一点上,一个众所周知的例外是所谓的非光化学孔燃烧(NPHB)[4]。近年来,客体分子向宿主光反应基质的三重态-三重态能量转移被报道为具有新机制的PSHB系统的新家族[5]。
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