Abstract: We show that optical absorption spectra of polyphenylenes can be explained only within theoretical models that explicitly include the Coulomb interaction among the $pi@-electrons. We also show that the dominant effect of substitution on the electronic structure of polyphenylenes within Coulomb correlated models is broken spatial symmetry, while broken charge conjugation symmetry plays a rather weak role. The broken spatial symmetry has a subtle, and weak, effect on the optical absorption spectrum. Consequently, optical absorption spectra of unsubstituted polyphenylenes and the substituted derivatives are nearly identical. Comparison of theoretical and experimental absorption spectra leads to the conclusion that the exciton binding energy in a long chain of poly(para-phenylenevinylene) is about 0.9 eV. Such a large binding energy would be in agreement with nonlinear spectroscopic measurements and pump-probe experiments. However, the present work also indicates that the experimental polymers actually consist of short chains with the chain length distribution peaking at about 10 phenylene units. The gaps between the energy levels above the calculated continuum threshold are much too large for transport to be an intrachain process. Photoconductivity may be predominantly an interchain process, and probably measures the dissociation energy of the exciton which is different from the exciton binding energy. !20
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机译:摘要:我们表明,仅在理论模型中可以明确解释聚苯撑的光吸收光谱,该理论模型明确包括$ pi @电子之间的库仑相互作用。我们还表明,在库仑相关模型内,取代对聚苯撑电子结构的主要影响是破坏的空间对称性,而破坏的电荷共轭对称性起着相当弱的作用。破碎的空间对称性对光吸收光谱有微妙而微弱的影响。因此,未取代的聚亚苯基和取代的衍生物的光吸收光谱几乎相同。理论和实验吸收光谱的比较得出结论,聚对苯撑乙烯撑长链中的激子结合能约为0.9 eV。如此大的结合能将与非线性光谱测量和泵浦探针实验相符。但是,目前的工作还表明,实验聚合物实际上由短链组成,其链长分布在约10个亚苯基单元处达到峰值。高于计算的连续阈值的能级之间的差距太大,以至于无法进行链内运输。光电导可能主要是一个链间过程,并且可能测量的激子的解离能不同于激子的结合能。 !20
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