Complexation dynamics of CH3SCN and Li+ in acetonitrile studied by two-dimensional infrared spectroscopy
- Authors
- Kwon, YoungAh; Park, Sungnam
- Issue Date
- 2015
- Publisher
- ROYAL SOC CHEMISTRY
- Citation
- PHYSICAL CHEMISTRY CHEMICAL PHYSICS, v.17, no.37, pp.24193 - 24200
- Indexed
- SCIE
SCOPUS
- Journal Title
- PHYSICAL CHEMISTRY CHEMICAL PHYSICS
- Volume
- 17
- Number
- 37
- Start Page
- 24193
- End Page
- 24200
- URI
- https://scholar.korea.ac.kr/handle/2021.sw.korea/96350
- DOI
- 10.1039/c5cp02833g
- ISSN
- 1463-9076
- Abstract
- Ion-molecule complexation dynamics were studied with CH3SCN and Li+ in acetonitrile by vibrationally probing the nitrile stretching vibration of CH3SCN. The nitrile stretching vibration of CH3SCN has a long lifetime (T-1 = similar to 90 ps) and its frequency is significantly blue-shifted when CH3SCN is bound with Li+ ions to form a CH3SCN center dot center dot center dot Li+ complex in acetonitrile. Such spectral properties enable us to distinguish free CH3SCN and the CH3SCN center dot center dot center dot Li+ complex in solutions and measure their dynamics occurring on hundred picosecond timescales. For the complexation between CH3SCN and Li+ in acetonitrile, the change in enthalpy (Delta H = -7.17 kJ mol(-1)) and the change in entropy (Delta S = -34.4 J K-1 mol(-1)) were determined by temperature-dependent FTIR experiments. Polarization-controlled infrared pump-probe (IR PP) spectroscopy was used to measure the population decay and orientational dynamics of free CH3SCN and the CH3SCN center dot center dot center dot Li+ complex. Especially, the orientational relaxation of the CH3SCN center dot center dot center dot Li+ complex was found to be almost 3 times slower than those of free CH3SCN because Li+ ions strongly interact with the neighboring solvents. Most importantly, the complexation dynamics of CH3SCN and Li+ in acetonitrile were successfully measured in real time by 2DIR spectroscopy for the first time and the dissociation and association time constants were directly determined by using the two-species exchange kinetic model. Our experimental results provide a comprehensive overview of the ion-molecule complexation dynamics in solutions occurring under thermal equilibrium conditions.
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