Humanath Poudel, Pathick Halder Shaon and David M. Leitner*,
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引用次数: 0
摘要
要想控制附着在质子纳米粒子上的分子发生化学反应,就必须了解振动能量流的信息。我们从量子力学角度计算了附着在质子纳米粒子上的 5 种取代苯硫醇(包括 4-硝基苯硫醇 (NBT))的能量流以及向周围环境的能量传输率。计算得出的拉曼活性模式的寿命与实验测量值相吻合,并且发现这主要是分子内振动能量再分配的结果。分子间寿命的变化源于不同化学基团对共振的调谐。NBT 的 NO 伸展在被激发后可促进反应,其寿命的计算结果接近测量值,主要取决于涉及其他 3 种模式的共振。我们发现,与最近的皮秒时间分辨测量结果相比,质子共振将能量转移到激发电子态,然后迅速在内部转换到基态并振动冷却。
Vibrational Energy Flow in Molecules Attached to Plasmonic Nanoparticles
The ability to control chemical reactions involving molecules attached to plasmonic nanoparticles requires information about vibrational energy flow. We compute the energy flow quantum mechanically in 5 substituted benzenethiols, including 4-nitrobenzenethiol (NBT), attached to plasmonic nanoparticles as well as rates of energy transfer to the surroundings. The lifetimes computed for Raman-active modes match those measured experimentally and are found to mainly result from intramolecular vibrational energy redistribution. Variation in lifetimes among the molecules arises from the tuning of resonances via different chemical groups. The lifetime of the NO stretch of NBT, which when excited can facilitate reaction, is computed to be close to the measured value and depends largely on resonances involving 3 other modes. We find that, upon comparison with the results of recent picosecond time-resolved measurements, the plasmonic resonance transfers energy to an excited electronic state, followed by rapid internal conversion to the ground state and vibrational cooling.
期刊介绍:
The Journal of Physical Chemistry A/B/C is devoted to reporting new and original experimental and theoretical basic research of interest to physical chemists, biophysical chemists, and chemical physicists.
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