Your search keyword '"VandeVondele, Joost"' showing total 6 results

1. Chasing charge localization and chemical reactivity following photoionization in liquid water.

Author

Marsalek, Ondrej, Elles, Christopher G., Pieniazek, Piotr A., Pluharˇová, Eva, VandeVondele, Joost, Bradforth, Stephen E., and Jungwirth, Pavel

Subjects

CHEMICAL reactions, PHOTOIONIZATION, MOLECULAR dynamics, FEMTOSECOND lasers, RADIATION chemistry, SIMULATION methods & models, QUANTUM theory, WATER

Abstract

The ultrafast dynamics of the cationic hole formed in bulk liquid water following ionization is investigated by ab initio molecular dynamics simulations and an experimentally accessible signature is suggested that might be tracked by femtosecond pump-probe spectroscopy. This is one of the fastest fundamental processes occurring in radiation-induced chemistry in aqueous systems and biological tissue. However, unlike the excess electron formed in the same process, the nature and time evolution of the cationic hole has been hitherto little studied. Simulations show that an initially partially delocalized cationic hole localizes within ∼30 fs after which proton transfer to a neighboring water molecule proceeds practically immediately, leading to the formation of the OH radical and the hydronium cation in a reaction which can be formally written as H2O+ + H2O → OH + H3O+. The exact amount of initial spin delocalization is, however, somewhat method dependent, being realistically described by approximate density functional theory methods corrected for the self-interaction error. Localization, and then the evolving separation of spin and charge, changes the electronic structure of the radical center. This is manifested in the spectrum of electronic excitations which is calculated for the ensemble of ab initio molecular dynamics trajectories using a quantum mechanics/molecular mechanics (QM/MM) formalism applying the equation of motion coupled-clusters method to the radical core. A clear spectroscopic signature is predicted by the theoretical model: as the hole transforms into a hydroxyl radical, a transient electronic absorption in the visible shifts to the blue, growing toward the near ultraviolet. Experimental evidence for this primary radiation-induced process is sought using femtosecond photoionization of liquid water excited with two photons at 11 eV. Transient absorption measurements carried out with ∼40 fs time resolution and broadband spectral probing across the near-UV and visible are presented and direct comparisons with the theoretical simulations are made. Within the sensitivity and time resolution of the current measurement, a matching spectral signature is not detected. This result is used to place an upper limit on the absorption strength and/or lifetime of the localized H2O+(aq) species. [ABSTRACT FROM AUTHOR]

Published

2011

2. Aligning Electronic and Protonic Energy Levels of Proton-Coupled Electron Transfer in Water Oxidation on Aqueous TiO2.

Author

Cheng, Jun, Liu, Xiandong, Kattirtzi, John A., VandeVondele, Joost, and Sprik, Michiel

Subjects

PHOTOELECTROCHEMICAL cells, CHARGE exchange, CHEMICAL reactions, PROTONS, ELECTRONICS

Abstract

The high overpotential in water oxidation on anodes is a limiting factor for the large-scale application of photoelectrochemical cells. To overcome this limitation, it is essential to understand the four proton-coupled electron transfer (PCET) steps in the reaction mechanism and their implications to the overpotential. Herein, a simple scheme to compute the energies of the PCET steps in water oxidation on the aqueous TiO2 surface using a hybrid density functional is described. An energy level diagram for fully decoupled electron- and proton-transfer reactions in which both electronic and protonic levels are placed on the same potential scale is also described. The level diagram helps to visualize the electronic and protonic components of the overpotential, and points out what are needed to improve. For TiO2, it is found that its catalytic activity is due to aligning the protonic energy levels in the PCET steps, while improving the activity requires also aligning the electronic levels. [ABSTRACT FROM AUTHOR]

Published

2014

3. Accelerating Rare Reactive Events by Means of a Finite Electronic Temperature.

Author

VandeVondele, Joost and Rothlisberger, Ursula

Subjects

*ELECTRONIC structure, *CHEMICAL reactions, *ISOMERIZATION

Abstract

Studies the use of electronic structure of the reactive system to enhance the sampling of rare chemical events in complex systems. Introduction of a finite electronic temperature; Prototypical chemical reactions in gas and in condensed phase; Cis-trans isomerization of an acid in an aqueous solution at room temperature.

Published

2002

4. Frontispiz: Aligning Electronic and Protonic Energy Levels of Proton-Coupled Electron Transfer in Water Oxidation on Aqueous TiO2.

Author

Cheng, Jun, Liu, Xiandong, Kattirtzi, John A., VandeVondele, Joost, and Sprik, Michiel

Subjects

CHEMICAL reactions, ENERGY levels (Quantum mechanics)

Abstract

The high overpotential in water oxidation on anodes is a limiting factor for the large ‐ scale application of photoelectrochemical cells. To overcome this limitation, it is essential to understand the four proton ‐ coupled electron transfer (PCET) steps in the reaction mechanism and their implications to the overpotential. Herein, a simple scheme to compute the energies of the PCET steps in water oxidation on the aqueous TiO2 surface using a hybrid density functional is described. An energy level diagram for fully decoupled electron ‐ and proton ‐ transfer reactions in which both electronic and protonic levels are placed on the same potential scale is also described. The level diagram helps to visualize the electronic and protonic components of the overpotential, and points out what are needed to improve. For TiO2, it is found that its catalytic activity is due to aligning the protonic energy levels in the PCET steps, while improving the activity requires also aligning the electronic levels. Bei der Berechnung der Thermochemie des protongekoppelten Elektronentransfers (PCET) an Grenzflächen können analog zu elektronischen Energieniveaus auch protonische Energieniveaus genutzt werden, um die PCET ‐ Thermodynamik zu beschreiben. Die resultierenden Diagramme veranschaulichen die elektronischen und protonischen Beiträge zu thermodynamischen Überpotentialen in der Photokatalyse. [ABSTRACT FROM AUTHOR]

Published

2014

5. Aligning Electronic and Protonic Energy Levels of Proton-Coupled Electron Transfer in Water Oxidation on Aqueous TiO2.

Author

Cheng, Jun, Liu, Xiandong, Kattirtzi, John A., VandeVondele, Joost, and Sprik, Michiel

Subjects

*PHOTOELECTROCHEMICAL cells, *CHARGE exchange, *CHEMICAL reactions, *PROTONS, *ELECTRONICS

Abstract

The high overpotential in water oxidation on anodes is a limiting factor for the large-scale application of photoelectrochemical cells. To overcome this limitation, it is essential to understand the four proton-coupled electron transfer (PCET) steps in the reaction mechanism and their implications to the overpotential. Herein, a simple scheme to compute the energies of the PCET steps in water oxidation on the aqueous TiO2 surface using a hybrid density functional is described. An energy level diagram for fully decoupled electron- and proton-transfer reactions in which both electronic and protonic levels are placed on the same potential scale is also described. The level diagram helps to visualize the electronic and protonic components of the overpotential, and points out what are needed to improve. For TiO2, it is found that its catalytic activity is due to aligning the protonic energy levels in the PCET steps, while improving the activity requires also aligning the electronic levels. [ABSTRACT FROM AUTHOR]

Published

2014

6. Frontispiz: Aligning Electronic and Protonic Energy Levels of Proton-Coupled Electron Transfer in Water Oxidation on Aqueous TiO2.

Author

Cheng, Jun, Liu, Xiandong, Kattirtzi, John A., VandeVondele, Joost, and Sprik, Michiel

Subjects

*CHEMICAL reactions, *ENERGY levels (Quantum mechanics)

Abstract

The high overpotential in water oxidation on anodes is a limiting factor for the large ‐ scale application of photoelectrochemical cells. To overcome this limitation, it is essential to understand the four proton ‐ coupled electron transfer (PCET) steps in the reaction mechanism and their implications to the overpotential. Herein, a simple scheme to compute the energies of the PCET steps in water oxidation on the aqueous TiO2 surface using a hybrid density functional is described. An energy level diagram for fully decoupled electron ‐ and proton ‐ transfer reactions in which both electronic and protonic levels are placed on the same potential scale is also described. The level diagram helps to visualize the electronic and protonic components of the overpotential, and points out what are needed to improve. For TiO2, it is found that its catalytic activity is due to aligning the protonic energy levels in the PCET steps, while improving the activity requires also aligning the electronic levels. Bei der Berechnung der Thermochemie des protongekoppelten Elektronentransfers (PCET) an Grenzflächen können analog zu elektronischen Energieniveaus auch protonische Energieniveaus genutzt werden, um die PCET ‐ Thermodynamik zu beschreiben. Die resultierenden Diagramme veranschaulichen die elektronischen und protonischen Beiträge zu thermodynamischen Überpotentialen in der Photokatalyse. [ABSTRACT FROM AUTHOR]

Published

2014