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Details of Grant 

EPSRC Reference: EP/R019509/1
Title: Attosecond X-ray Spectroscopy of Ultrafast Dynamics in the Condensed Phase
Principal Investigator: Marangos, Professor J
Other Investigators:
Bakulin, Dr A Tisch, Professor J
Researcher Co-Investigators:
Project Partners:
Newcastle University
Department: Physics
Organisation: Imperial College London
Scheme: Standard Research
Starts: 01 June 2018 Ends: 30 November 2022 Value (£): 1,230,885
EPSRC Research Topic Classifications:
Atoms & Ions Scattering & Spectroscopy
EPSRC Industrial Sector Classifications:
No relevance to Underpinning Sectors
Related Grants:
Panel History:
Panel DatePanel NameOutcome
13 Dec 2017 EPSRC Physical Sciences - December 2017 Announced
Summary on Grant Application Form
We are all familiar with the idea that X-rays can "see" inside matter, after all this is the basis of much imaging technology from medical X-rays to Superman's astounding vision. We plan to use new sources of X-rays with the unique property that they are in pulses of duration less than 1 femtosecond (1 fs= 10^-15 s that is a millionth of a billionth of a second) to allow us, for the first time, to take snapshots and even make movies of some of the fastest events that occur within matter.

Our ability to produce and use such short pulses of X-rays has come out of our research over the past six years (funded by an ERC Advanced Grant and an EPSRC Programme Grant). We showed that high harmonic generation (HHG) based sources of ~0.3 fs pulse duration could be generated from 150 - 600 eV, an unprecedented achievement for ultrafast X-ray sources. Combined with the ultra-thin liquid sheet jets that we have recently invented and few-femtosecond optical pulses available in our laboratory that can start the clock by electronic excitation of the material, we have now in place the tools that enable a new kind of ultrafast X-ray spectroscopy that can be applied to any system whether it is in gas, liquid or solid state. We now want to advance this research in new directions by using this method to investigate some of the fastest processes in physics and chemistry.

In parallel with our laser research we have been working with international teams to develop the methods of using X-ray free electron laser facilities to make measurements on the few-femtosecond timescale. This has included work with LCLS (SLAC, California) in a two-pulse/two-colour mode with ~ 3 fs temporal resolution. Later this year it is anticipated that LCLS will produce the first FEL based sub-femtosecond X-ray pulses of extreme brightness (> 10^6 times greater than our HHG source). We plan to use this new capability to develop a new concept in X-ray non-linear spectroscopy that will allow us to precisely follow electron motions in matter at atomic spatial resolution and with time-scales faster than a femtosecond.

What will we investigate with these remarkable new tools? The answer is the fundamental dynamical events in physics, such as exciton formation and charge migration, and key processes in chemistry, such as electron transfer and bond-breaking/making. These can occur within 10 fs of initial electronic excitation and have hitherto not been accessible to direct measurement. Moreover with our tools we can track the dynamics of microscopic systems across the boundary in the temporal domain between quantum and classical behaviour. In condensed phase systems, where the quantum coherence of the initial state is lost in a few 10's of femtoseconds, this will allow us to see into a new quantum regime of dynamics. In particular we will focus on structures containing delocalised electrons (pi-conjugated systems) as in this case the electrons are highly mobile and so can display the very fastest dynamics. Additionally pi-conjugated molecules are the building blocks of polymers and molecular complexes of great interest in photochemistry and solar-energy conversion. Not only will our measurements capture the ultrafast electronic motion in these systems they will also allow us to measure the structural dynamics associated with isomerization, ring opening and other chemical changes.

Our research will extend the frontier of science's measurement capability in the time domain with the likelihood of measuring physical processes at timescales 100 times faster than before. This will lead to new breakthroughs in our understanding of quantum dynamical processes in nature and technology.

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