Vibrational solvatochromism
Vibrational solvatochromism refers to changes in the vibrational frequencies of molecules due to variations in the solvent environment. Solvatochromism is a broader term that describes changes in the electronic or vibrational properties of a molecule in response to changes in the solvent polarity or composition. In the context of vibrational solvatochromism, researchers study how the vibrational spectra of a molecule, which represent the different vibrational modes of its chemical bonds, are influenced by the properties of the solvent.
Understanding vibrational solvatochromism helps researchers to characterize molecular environments and study molecular dynamics in different solvents and biological environments.[1]
Dielectric continuum model
[edit]By considering the intermolecular interaction of the solute molecule with a dielectric continuum solvent,[2][3][4] one can obtain a general relationship between the vibrational frequency and intermolecular interaction potential. This relationship is given by the sum of three contributions: (1) Coulombic term describing an interaction between the permanent dipole moment of the molecule and electric field, (2) induction term describing interaction with the induced dipole moment, (3) electric field-correction term which arises from the change of the electric field along the normal coordinate of the vibration. When we consider only the linear terms with respect to the Onsagar reaction field, , the frequency shift for the jth normal mode can be given as[1]
where and are the effective gas-phase and solvent-induced vibrational dipole moment, respectively. Despite the limited validity due to the approximate nature of the dielectric continuum solvent model, researchers still often use this theory for vibrational solvatochromism, especially when a more refined model is challenging to implement.[5]
Electrostatic Effect: Distributed Multipole Analysis
[edit]The solvent electric field experienced by a given solute molecule in solution is highly nonuniform in space.[6][7] For a realistic description of vibrational solvatochromism, one should consider the local electric potential created by surrounding solvent molecules. Assuming that the solute-solvent intermolecular interaction potential can be fully described by the distributed charges, dipoles, and high-order multipoles interacting with solvent electric potential and its gradients, it was shown that the vibrational solvatochromic frequency shift is given as[1][8][9]
Here, the vibrational solvatochromic charge (), dipole (), quadrupole (), and octupole () terms can be determined using any distributed multipole expansion method.[10][5] The above Equation can be interpreted as a type of vibrational spectroscopic map.
Quantum chemistry calculations conducted for various IR probes have revealed that terms up to vibrational solvatochromic quadrupoles are essential for adequately describing the vibrational frequency shift.[1][11]
Electrostatic Effect: Semiempirical Approaches
[edit]The vibrational frequency shift, denoted as , for the jth normal mode is defined as the difference between the actual vibrational frequency of the mode in a solution and the frequency in the gas phase.
An early approach aimed to express the solvation-induced vibrational frequency shift in terms of the solvent electric potentials evaluated at distributed atomic sites on the target solute molecule.[12] This method involves calculating the solvent electric potentials at these specific solute sites through the utilization of atomic partial charges from surrounding solvent molecules. The vibrational frequency shift of the solute molecule, denoted as , for the jth vibrational mode with an atomic configuration of the solvent molecules can be represented as
Here, represents the vibrational frequency of the jth normal mode in solution, signifies the vibrational frequency in the gas phase, denotes the number of distributed sites on the solute molecule, denotes the solvent electric potential at the kth site of the solute molecule, and are the parameters to be determined through least-square fitting to a training database comprising clusters containing a solute and multiple solvent molecules. This method provides a means to quantify the impact of solvation on the vibrational frequencies of the solute molecule.
Another widely used model for characterizing vibrational solvatochromic frequency shifts involves expressing the frequency shift in terms of solvent electric fields evaluated at distributed sites on the target solute molecule.[13][14] This model is represented by the equation:
Here, is the mth Cartesian component of the solvent electric field at the kth site on the solute molecule, and represent parameters to be determined through least-square fitting to a training database of clusters containing a solute and multiple solvent molecules. This approach provides a framework for quantifying the influence of solvent electric fields on the vibrational frequencies of the solute molecule.
General solute-solvent interaction effects
[edit]Buckingham[15][16][17] developed the general theory describing the vibrational frequency shifts of a spatially localized normal mode in solution based on the intermolecular interaction potential. Cho[8][9] later generalized this theory to any arbitrary normal mode. Solvation-induced vibrational frequencies and the resulting new set of normal modes of the solute molecule in solution can be directly obtained by diagonalizing the Hessian matrix derived from an effective Hamiltonian for the solute in the presence of a molecular environment.[9][18] In the limiting case that the vibrational couplings of the normal mode of interest with other vibrational modes are relatively weak, the vibrational frequency shift is given by[9][15]
where and are the electric anharmonicity (EA) and mechanical anharmonicity (MA), respectively, defined as
and
where is the cubic anharmonic constant. There exist cases in which the weak coupling approximation cannot be acceptable, for example, when normal modes are coupled and delocalized. In those cases, an additional term describing the mode coupling contribution to the frequency shift should be included.[1]
See also
[edit]References
[edit]- ^ a b c d e Baiz, Carlos R.; Błasiak, Bartosz; Bredenbeck, Jens; Cho, Minhaeng; Choi, Jun-Ho; Corcelli, Steven A.; Dijkstra, Arend G.; Feng, Chi-Jui; Garrett-Roe, Sean; Ge, Nien-Hui; Hanson-Heine, Magnus W. D.; Hirst, Jonathan D.; Jansen, Thomas L. C.; Kwac, Kijeong; Kubarych, Kevin J. (2020-08-12). "Vibrational Spectroscopic Map, Vibrational Spectroscopy, and Intermolecular Interaction". Chemical Reviews. 120 (15): 7152–7218. doi:10.1021/acs.chemrev.9b00813. ISSN 0009-2665. PMC 7710120. PMID 32598850.
- ^ Kirkwood, John G. (1934-11-01). "On the Theory of Strong Electrolyte Solutions". The Journal of Chemical Physics. 2 (11): 767–781. Bibcode:1934JChPh...2..767K. doi:10.1063/1.1749393. ISSN 0021-9606.
- ^ Kirkwood, John G. (1939-10-01). "The Dielectric Polarization of Polar Liquids". The Journal of Chemical Physics. 7 (10): 911–919. Bibcode:1939JChPh...7..911K. doi:10.1063/1.1750343. ISSN 0021-9606.
- ^ Onsager, Lars (August 1, 1936). "Electric Moments of Molecules in Liquids". Journal of the American Chemical Society. 58 (8): 1486–1493. doi:10.1021/ja01299a050. ISSN 0002-7863.
- ^ Schkolnik, Gal; Utesch, Tillmann; Salewski, Johannes; Tenger, Katalin; Millo, Diego; Kranich, Anja; Zebger, Ingo; Schulz, Claudia; Zimányi, László; Rákhely, Gábor; Mroginski, Maria Andrea; Hildebrandt, Peter (2012). "Mapping local electric fields in proteins at biomimetic interfaces". Chem. Commun. 48 (1): 70–72. doi:10.1039/C1CC13186A. ISSN 1359-7345. PMID 22080181.
- ^ Fried, Stephen D.; Wang, Lee-Ping; Boxer, Steven G.; Ren, Pengyu; Pande, Vijay S. (2013-12-19). "Calculations of the Electric Fields in Liquid Solutions". The Journal of Physical Chemistry B. 117 (50): 16236–16248. doi:10.1021/jp410720y. ISSN 1520-6106. PMC 4211882. PMID 24304155.
- ^ Fried, Stephen D.; Boxer, Steven G. (2015-04-21). "Measuring Electric Fields and Noncovalent Interactions Using the Vibrational Stark Effect". Accounts of Chemical Research. 48 (4): 998–1006. doi:10.1021/ar500464j. ISSN 0001-4842. PMC 4667952. PMID 25799082.
- ^ a b Cho, Minhaeng (2003-02-22). "Correlation between electronic and molecular structure distortions and vibrational properties. I. Adiabatic approximations". The Journal of Chemical Physics. 118 (8): 3480–3490. Bibcode:2003JChPh.118.3480C. doi:10.1063/1.1536979. ISSN 0021-9606.
- ^ a b c d Cho, Minhaeng (2009-03-07). "Vibrational solvatochromism and electrochromism: Coarse-grained models and their relationships". The Journal of Chemical Physics. 130 (9). Bibcode:2009JChPh.130i4505C. doi:10.1063/1.3079609. ISSN 0021-9606. PMID 19275407.
- ^ Błasiak, Bartosz; Lee, Hochan; Cho, Minhaeng (2013-07-28). "Vibrational solvatochromism: Towards systematic approach to modeling solvation phenomena". The Journal of Chemical Physics. 139 (4): 044111. Bibcode:2013JChPh.139d4111B. doi:10.1063/1.4816041. ISSN 0021-9606. PMID 23901964.
- ^ Kim, Heejae; Cho, Minhaeng (2013-08-14). "Infrared Probes for Studying the Structure and Dynamics of Biomolecules". Chemical Reviews. 113 (8): 5817–5847. doi:10.1021/cr3005185. ISSN 0009-2665. PMID 23679868.
- ^ Ham, Sihyun; Kim, Joo-Hee; Lee, Hochan; Cho, Minhaeng (2003-02-22). "Correlation between electronic and molecular structure distortions and vibrational properties. II. Amide I modes of NMA–nD2O complexes". The Journal of Chemical Physics. 118 (8): 3491–3498. doi:10.1063/1.1536980. ISSN 0021-9606.
- ^ Corcelli, S. A.; Lawrence, C. P.; Skinner, J. L. (2004-05-01). "Combined electronic structure/molecular dynamics approach for ultrafast infrared spectroscopy of dilute HOD in liquid H2O and D2O". The Journal of Chemical Physics. 120 (17): 8107–8117. doi:10.1063/1.1683072. ISSN 0021-9606. PMID 15267730.
- ^ Schmidt, J. R.; Corcelli, S. A.; Skinner, J. L. (2004-11-08). "Ultrafast vibrational spectroscopy of water and aqueous N-methylacetamide: Comparison of different electronic structure/molecular dynamics approaches". The Journal of Chemical Physics. 121 (18): 8887–8896. Bibcode:2004JChPh.121.8887S. doi:10.1063/1.1791632. ISSN 0021-9606. PMID 15527353.
- ^ a b Buckingham, A. D. (1960). "Solvent effects in vibrational spectroscopy". Transactions of the Faraday Society. 56: 753. doi:10.1039/tf9605600753. ISSN 0014-7672.
- ^ Buckingham, A. D. (1958-11-11). "Solvent effects in infra-red spectroscopy". Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences. 248 (1253): 169–182. Bibcode:1958RSPSA.248..169B. doi:10.1098/rspa.1958.0237. ISSN 0080-4630. S2CID 97510562.
- ^ Buckingham, A. D. (1960-03-22). "A theory of frequency, intensity and band-width changes due to solvents in infra-red spectroscopy". Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences. 255 (1280): 32–39. Bibcode:1960RSPSA.255...32B. doi:10.1098/rspa.1960.0046. ISSN 0080-4630. S2CID 95330195.
- ^ Jeon, Jonggu; Yang, Seongeun; Choi, Jun-Ho; Cho, Minhaeng (2009-09-15). "Computational Vibrational Spectroscopy of Peptides and Proteins in One and Two Dimensions". Accounts of Chemical Research. 42 (9): 1280–1289. doi:10.1021/ar900014e. ISSN 0001-4842. PMID 19456096.
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