Ab initio nonadiabatic molecular dynamics of wet-electrons on the TiO(2) surface.

The electron transfer (ET) dynamics of wet-electrons on a TiO(2) surface is investigated using state-of-the-art ab initio nonadiabatic (NA) molecular dynamics (MD). The simulations directly mimic the time-resolved experiments [Science 2005, 308, 1154] and reveal the nature of ET in the wet-electron system. Focusing on the partially hydroxylated TiO(2) surface with 1-monolayer water coverage, and including electronic evolution, phonon motions, and electron-phonon coupling, the simulations indicate that the ET is sub-10 fs, in agreement with the experiment. Despite the large role played by low frequency vibrational modes, the ET is fast due to the strong coupling between the TiO(2) surface and water. The average ET for the system has equal contributions from the adiabatic and NA mechanisms, even though a very broad range of individual ET events is seen in the simulated ensemble. Thermal phonon motions induce a large fluctuation of the wet-electron state energy, generate frequent crossings of the donor and acceptor states, and drive the adiabatic mechanism. The rapid phonon-assisted NA tunneling from the wet-electron state to the TiO(2) surface is facilitated by the strong water-TiO(2) electronic interaction. The motions of molecular water have a greater effect on the ET dynamics than the hydroxyl vibrations. The former contribute to both the wet-electron state energy and the water-TiO(2) electronic coupling, while the latter changes only the energy and not the coupling. Delocalized over both water and TiO(2), wet-electrons are supported by a new type of state that is created at the interface due to the strong water-TiO(2) interaction and that cannot exist separately in either material. Similar states are present in a number of other systems with strong interfacial coupling, including certain dye-sensitized semiconductors and metal-liquid interfaces. The ET dynamics involving such interfacial states share many universal features, such as an ultrashort time scale and weak-dependence on temperature, surface defects, and other system details.

[1]  Hisao Nakamura,et al.  First-Principle Calculations of Solvated Electrons at Protic Solvent−TiO2 Interfaces with Oxygen Vacancies , 2009 .

[2]  Jinlong Yang,et al.  The electronic structure of oxygen atom vacancy and hydroxyl impurity defects on titanium dioxide (110) surface. , 2009, The Journal of chemical physics.

[3]  Walter R. Duncan,et al.  Photoinduced electron dynamics at the chromophore-semiconductor interface: A time-domain ab initio perspective , 2009 .

[4]  Á. Rubio,et al.  A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice-Metal Interfaces , 2009 .

[5]  S. Hammes-Schiffer,et al.  Development of electron-proton density functionals for multicomponent density functional theory. , 2008, Physical review letters.

[6]  U. Bovensiepen,et al.  A surface science approach to ultrafast electron transfer and solvation dynamics at interfaces. , 2008, Chemical Society reviews.

[7]  Walter R. Duncan,et al.  Temperature independence of the photoinduced electron injection in dye-sensitized TiO2 rationalized by ab initio time-domain density functional theory. , 2008, Journal of the American Chemical Society.

[8]  A. Chakraborty,et al.  Inclusion of explicit electron-proton correlation in the nuclear-electronic orbital approach using Gaussian-type geminal functions. , 2008, The Journal of chemical physics.

[9]  C. Cramer,et al.  A universal approach to solvation modeling. , 2008, Accounts of chemical research.

[10]  Thomas W. Hamann,et al.  New architectures for dye-sensitized solar cells. , 2008, Chemistry.

[11]  Anusorn Kongkanand,et al.  Quantum dot solar cells. Tuning photoresponse through size and shape control of CdSe-TiO2 architecture. , 2008, Journal of the American Chemical Society.

[12]  Walter R. Duncan,et al.  Dynamics of the photoexcited electron at the chromophore-semiconductor interface. , 2008, Accounts of chemical research.

[13]  Walter R. Duncan,et al.  Time-domain ab initio study of charge relaxation and recombination in dye-sensitized TiO2. , 2007, Journal of the American Chemical Society.

[14]  J. Roscioli,et al.  Quantum Structure of the Intermolecular Proton Bond , 2007, Science.

[15]  Walter R. Duncan,et al.  Theoretical studies of photoinduced electron transfer in dye-sensitized TiO2. , 2007, Annual review of physical chemistry.

[16]  P. Kamat Meeting the Clean Energy Demand: Nanostructure Architectures for Solar Energy Conversion , 2007 .

[17]  Jin Zhao,et al.  Solvated electrons on metal oxide surfaces. , 2006, Chemical reviews.

[18]  Bin Li,et al.  Interplay between hydrogen bonding and electron solvation on hydrated TiO2(110) , 2006 .

[19]  Jinlong Yang,et al.  Ultrafast Interfacial Proton-Coupled Electron Transfer , 2006, Science.

[20]  V. Batista,et al.  Influence of thermal fluctuations on interfacial electron transfer in functionalized TiO2 semiconductors. , 2005, Journal of the American Chemical Society.

[21]  Walter R. Duncan,et al.  Trajectory surface hopping in the time-dependent Kohn-Sham approach for electron-nuclear dynamics. , 2005, Physical review letters.

[22]  Walter R. Duncan,et al.  Nonadiabatic molecular dynamics study of electron transfer from alizarin to the hydrated Ti4+ ion. , 2005, The journal of physical chemistry. B.

[23]  Peter J Rossky,et al.  Characterization of Excess Electrons in Water-Cluster Anions by Quantum Simulations , 2005, Science.

[24]  Evgeniy M. Myshakin,et al.  Spectral Signatures of Hydrated Proton Vibrations in Water Clusters , 2005, Science.

[25]  Jinlong Yang,et al.  Wet Electrons at the H2O/TiO2(110) Surface , 2005, Science.

[26]  Walter R. Duncan,et al.  Ab initio nonadiabatic molecular dynamics of the ultrafast electron injection across the alizarin-TiO2 interface. , 2005, Journal of the American Chemical Society.

[27]  C. Isborn,et al.  Factors controlling the barriers to degenerate hydrogen atom transfers. , 2005, Journal of the American Chemical Society.

[28]  D. Neumark,et al.  Observation of Large Water-Cluster Anions with Surface-Bound Excess Electrons , 2005, Science.

[29]  Mark A. Johnson,et al.  How Do Small Water Clusters Bind an Excess Electron? , 2004, Science.

[30]  Ding-Shyue Yang,et al.  Electrons in Finite-Sized Water Cavities: Hydration Dynamics Observed in Real Time , 2004, Science.

[31]  D. Neumark,et al.  Hydrated Electron Dynamics: From Clusters to Bulk , 2004, Science.

[32]  Haobin Wang,et al.  Theoretical study of ultrafast heterogeneous electron transfer reactions at dye–semiconductor interfaces , 2004 .

[33]  K. Jordan,et al.  Infrared Signature of Structures Associated with the H+(H2O)n (n = 6 to 27) Clusters , 2004, Science.

[34]  X. Zhu Charge transport at metal-molecule interfaces: A spectroscopic view , 2004 .

[35]  Huijun Zhao,et al.  Kinetic study of photocatalytic oxidation of adsorbed carboxylic acids at TiO2 porous films by photoelectrolysis , 2004 .

[36]  Chuncheng Chen,et al.  Efficient degradation of toxic organic pollutants with Ni2O3/TiO(2-x)Bx under visible irradiation. , 2004, Journal of the American Chemical Society.

[37]  J. Tour,et al.  Structure-dependent charge transport and storage in self-assembled monolayers of compounds of interest in molecular electronics: effects of tip material, headgroup, and surface concentration. , 2004, Journal of the American Chemical Society.

[38]  E. Hendry,et al.  Electron transport in TiO2 probed by THz time-domain spectroscopy , 2004 .

[39]  K. Jordan,et al.  Theory of dipole-bound anions. , 2003, Annual review of physical chemistry.

[40]  Ruchuan Liu,et al.  Single-molecule spectroscopy of interfacial electron transfer. , 2003, Journal of the American Chemical Society.

[41]  L. Rego,et al.  Quantum dynamics simulations of interfacial electron transfer in sensitized TiO2 semiconductors. , 2003, Journal of the American Chemical Society.

[42]  M. Parrinello,et al.  First-principles molecular-dynamics simulations of a hydrated electron in normal and supercritical water. , 2003, Physical review letters.

[43]  M. Ratner,et al.  Electron Transport in Molecular Wire Junctions , 2003, Science.

[44]  C. Nuckolls,et al.  Cruciform pi-systems for molecular electronics applications. , 2003, Journal of the American Chemical Society.

[45]  C. Harris,et al.  Electron Solvation in Two Dimensions , 2002, Science.

[46]  William Stier,et al.  Nonadiabatic Molecular Dynamics Simulation of Light-Induced Electron Transfer from an Anchored Molecular Electron Donor to a Semiconductor Acceptor † , 2002 .

[47]  Jacques-E. Moser,et al.  Real-time observation of photoinduced adiabatic electron transfer in strongly coupled dye/semiconductor colloidal systems with a 6 fs time constant , 2002 .

[48]  A. Nozik Quantum dot solar cells , 2001 .

[49]  John B. Asbury,et al.  Ultrafast Electron Transfer Dynamics from Molecular Adsorbates to Semiconductor Nanocrystalline Thin Films , 2001 .

[50]  G. Kresse,et al.  From ultrasoft pseudopotentials to the projector augmented-wave method , 1999 .

[51]  P. Rossky,et al.  RELATIONSHIP BETWEEN QUANTUM DECOHERENCE TIMES AND SOLVATION DYNAMICS IN CONDENSED PHASE CHEMICAL SYSTEMS , 1998, quant-ph/9804004.

[52]  Carlos Silva,et al.  Femtosecond Solvation Dynamics of the Hydrated Electron , 1998 .

[53]  Harris,et al.  Femtosecond dynamics of electron localization at interfaces , 1998, Science.

[54]  P. Rossky,et al.  Evaluation of quantum transition rates from quantum-classical molecular dynamics simulations , 1997 .

[55]  S. Heifets,et al.  First observations of a "fast beam-ion instability" at the ALS , 1997, Proceedings of the 1997 Particle Accelerator Conference (Cat. No.97CH36167).

[56]  K. Burke,et al.  Generalized Gradient Approximation Made Simple [Phys. Rev. Lett. 77, 3865 (1996)] , 1997 .

[57]  Burke,et al.  Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.

[58]  G. Kresse,et al.  Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set , 1996 .

[59]  Lee,et al.  The nature of a wet electron. , 1996, Physical review letters.

[60]  P. Kamat,et al.  Photochemistry on Surfaces. Intermolecular Energy and Electron Transfer Processes between Excited Ru(bpy)32+ and H-Aggregates of Cresyl Violet on SiO2 and SnO2 Colloids , 1995 .

[61]  A. Staib,et al.  Molecular dynamics simulation of an excess charge in water using mobile Gaussian orbitals , 1995 .

[62]  Blöchl,et al.  Projector augmented-wave method. , 1994, Physical review. B, Condensed matter.

[63]  Thayer,et al.  Angle-resolved inverse-photoemission study of the nearly perfect TiO2(110) surface. , 1993, Physical review. B, Condensed matter.

[64]  M. Grätzel,et al.  A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO2 films , 1991, Nature.

[65]  H. W. Sarkas,et al.  Photoelectron spectroscopy of hydrated electron cluster anions, (H2O)−n=2–69 , 1990 .

[66]  B. Berne,et al.  Behavior of the hydrated electron at different temperatures: structure and absorption spectrum , 1988 .

[67]  U. Landman,et al.  Electron localization in water clusters. II. Surface and internal states , 1988 .

[68]  Schnitker,et al.  A priori calculation of the optical absorption spectrum of the hydrated electron. , 1988, Physical review letters.

[69]  L. Kevan,et al.  Solvated electron structure in glassy matrixes , 1981 .

[70]  J. Boag,et al.  ABSORPTION SPECTRUM OF THE HYDRATED ELECTRON IN WATER AND IN AQUEOUS SOLUTIONS , 1962 .

[71]  T. Lian,et al.  Ultrafast electron transfer at the molecule-semiconductor nanoparticle interface. , 2005, Annual review of physical chemistry.

[72]  V. May,et al.  Femtosecond spectroscopy of heterogeneous electron transfer: Extraction of excited-state population dynamics from pump-probe signals , 2003 .

[73]  John M. Zachara,et al.  Metal Oxide Surfaces and Their Interactions with Aqueous Solutions and Microbial Organisms. , 1999, Chemical reviews.