TY - JOUR
T1 - Predicting the Second-Order Nonlinear Optical Responses of Organic Materials
T2 - The Role of Dynamics
AU - Castet, Frédéric
AU - Tonnelé, Claire
AU - Muccioli, Luca
AU - Champagne, Benoît
N1 - Funding Information:
The results reported in this Account are the fruit of collaborations with Dr. P. Beaujean, Dr. M. Blanchard-Desce, Dr. E. Botek, C. Bouquiaux, Prof. S. Canuto, Dr. E. Cariati, Dr. M. de Wergifosse, Dr. M. Hidalgo Cardenuto, Dr. L. Lescos, Dr. R. Méreau, Dr. K. Pielak, Dr. J. Quertinmont, Dr. T. N. Ramos, Dr. S. Righetto, Prof. V. Rodriguez, Dr. L. Sanguinet, Dr. J. Seibert. Original calculations were performed on the HPC center of the Institut des Sciences Moléculaires, as well as on the Mésocentre de Calcul Intensif Aquitain of the Université de Bordeaux and of the Université de Pau et des Pays de l’Adour. This work has been supported by funds from the French National Research Agency (grant number ANR-20-CE29-0009-01). CT is supported by DIPC and Gipuzkoa’s council joint program Women and Science.
Publisher Copyright:
© 2022 American Chemical Society. All rights reserved.
PY - 2022/12/20
Y1 - 2022/12/20
N2 - ConspectusThe last 30 years have witnessed an ever-growing application of computational chemistry for rationalizing the nonlinear optical (NLO) responses of organic chromophores. More specifically, quantum chemical calculations proved highly helpful in gaining fundamental insights into the factors governing the magnitude and character of molecular first hyperpolarizabilities (β), be they either intrinsic to the chromophore molecular structure and arising from symmetry, chemical substitution, or π-electron delocalization, or induced by external contributions such as the laser probe or solvation and polarization effects. Most theoretical reports assumed a rigid picture of the investigated systems, the NLO responses being computed solely at the most stable geometry of the chromophores. Yet, recent developments combining classical molecular dynamics (MD) simulations and DFT calculations have evidenced the significant role of structural fluctuations, which may induce broad distributions of NLO responses, and even generate them in some instances.This Account presents recent case studies in which theoretical simulations have highlighted these effects. The discussion specifically focuses on the simulation of the second-order NLO properties that can be measured experimentally either from Hyper-Rayleigh Scattering (HRS) or Electric-Field Induced Second Harmonic Generation (EFISHG). More general but technical topics concerning several aspects of the calculations of hyperpolarizabilities are instead discussed in the Supporting Information.Selected examples include organic chromophores, photochromic systems, and ionic complexes in the liquid phase, for which the effects of explicit solvation, concentration, and chromophore aggregation are emphasized, as well as large flexible systems such as peptide chains and pyrimidine-based helical polymers, in which the relative variations of the responses were shown to be several times larger than their average values. The impact of geometrical fluctuations is also illustrated for supramolecular architectures with the examples of nanoparticles formed by organic dipolar dyes in water solution, whose soft nature allows for large shape variations translating into huge fluctuations in time of their NLO response, and of self-assembled monolayers (SAMs) based on indolino-oxazolidine or azobenzene switches, in which the geometrical distortions of the photochromic molecules, as well as their orientational and positional disorder within the SAMs, highly impact their NLO response and contrast upon switching. Finally, the effects of the rigidity and fluidity of the surrounding are evidenced for NLO dyes inserted in phospholipid bilayers.
AB - ConspectusThe last 30 years have witnessed an ever-growing application of computational chemistry for rationalizing the nonlinear optical (NLO) responses of organic chromophores. More specifically, quantum chemical calculations proved highly helpful in gaining fundamental insights into the factors governing the magnitude and character of molecular first hyperpolarizabilities (β), be they either intrinsic to the chromophore molecular structure and arising from symmetry, chemical substitution, or π-electron delocalization, or induced by external contributions such as the laser probe or solvation and polarization effects. Most theoretical reports assumed a rigid picture of the investigated systems, the NLO responses being computed solely at the most stable geometry of the chromophores. Yet, recent developments combining classical molecular dynamics (MD) simulations and DFT calculations have evidenced the significant role of structural fluctuations, which may induce broad distributions of NLO responses, and even generate them in some instances.This Account presents recent case studies in which theoretical simulations have highlighted these effects. The discussion specifically focuses on the simulation of the second-order NLO properties that can be measured experimentally either from Hyper-Rayleigh Scattering (HRS) or Electric-Field Induced Second Harmonic Generation (EFISHG). More general but technical topics concerning several aspects of the calculations of hyperpolarizabilities are instead discussed in the Supporting Information.Selected examples include organic chromophores, photochromic systems, and ionic complexes in the liquid phase, for which the effects of explicit solvation, concentration, and chromophore aggregation are emphasized, as well as large flexible systems such as peptide chains and pyrimidine-based helical polymers, in which the relative variations of the responses were shown to be several times larger than their average values. The impact of geometrical fluctuations is also illustrated for supramolecular architectures with the examples of nanoparticles formed by organic dipolar dyes in water solution, whose soft nature allows for large shape variations translating into huge fluctuations in time of their NLO response, and of self-assembled monolayers (SAMs) based on indolino-oxazolidine or azobenzene switches, in which the geometrical distortions of the photochromic molecules, as well as their orientational and positional disorder within the SAMs, highly impact their NLO response and contrast upon switching. Finally, the effects of the rigidity and fluidity of the surrounding are evidenced for NLO dyes inserted in phospholipid bilayers.
UR - http://www.scopus.com/inward/record.url?scp=85143638010&partnerID=8YFLogxK
U2 - 10.1021/acs.accounts.2c00616
DO - 10.1021/acs.accounts.2c00616
M3 - Article
C2 - 36469424
AN - SCOPUS:85143638010
SN - 0001-4842
VL - 55
SP - 3716
EP - 3726
JO - Accounts of chemical research
JF - Accounts of chemical research
IS - 24
ER -