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Details of Grant 

EPSRC Reference: EP/J001481/1
Title: International Collaboration in Chemistry: New First Principles Methods for Nonadiabatic Dynamics
Principal Investigator: Shalashilin, Professor D
Other Investigators:
Researcher Co-Investigators:
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Department: Sch of Chemistry
Organisation: University of Leeds
Scheme: Standard Research
Starts: 01 December 2011 Ends: 31 August 2015 Value (£): 366,597
EPSRC Research Topic Classifications:
Gas & Solution Phase Reactions
EPSRC Industrial Sector Classifications:
No relevance to Underpinning Sectors
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Panel History:  
Summary on Grant Application Form
A detailed understanding of the dynamics of electronic excited states and the breakdown of the Born-Oppenheimer approximation around conical intersections is critical in order to model and improve light to energy conversion processes. Such processes are fundamental in light harvesting such as natural and artificial photosynthesis and also may play a role in molecular scale devices with mechanical responses to light (photoisomerization and photoreceptors in both natural and artificial constructs). Although nuclei are heavy particles and usually can be treated classically, the case of photodynamics is a significant exception. Light absorption always creates a coherent initial wave packet which retains its quantum nature on time scales faster than the decoherence time. Therefore ultrafast photochemistry on the timescale below few picoseconds is an essentially quantum process. There are two main challenges in modelling of excited state chemistry. First, the potential energy surfaces (PES) and their nonadiabatic (non-Born-Oppenheimer) couplings are difficult to describe because they require the electronic structure of excited electronic states. In big systems the topology of the PES can be very complicated. Second, the quantum nature of the dynamics requires the solution of the Schrödinger equation for the wave packet in many dimensions. Both problems of PES and wave function complexity are addressed when trajectory guided basis sets are used to describe quantum dynamics. First, ab initio calculations have to be done only along a set of trajectories and, second, the basis set size is minimized because trajectory guided basis covers only the most important part of the system's phase space. Also trajectory guided basis sets with randomly selected initial conditions avoid the so called exponential scaling of quantum mechanics with the number of degrees of freedom. In this project we will develop further two cutting edge trajectory based methods of quantum mechanics, namely ab initio Multiple Spawning (AIMS) and Multiconfigurational Ehrenfest (MCE) dynamics. We will add MCE to the existing AIMS code, compare the two methods, and develop an approach which combines their best features. We will apply the new methods to simulations of excited state dynamics in chemistry and biochemistry. Most importantly we will also develop new related methods. First we will work out semiclassical approximations to the new MCE method and second we will explore the use of trajectory based methods to study the quantum dynamics of Fermions, which would be a completely new direction.
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