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Appointment
  • Lecturer in Physical Chemistry
  • Dept of Chemistry
  • Faculty of Maths & Physical Sciences
Biography

Rebecca Ingle completed her PhD under the supervision of Professor Mike Ashfold at the University of Bristol, during which she was award two fellowships (Japan Society for the Promotion of Science Pre-Doctoral award and a Bristol-Kyoto fellowship) to work with Professor Toshinori Suzuki at Kyoto University. In October 2017, she started a postdoctoral research position with Professor Majed Chergui at EPFL, Switzerland developing techniques for multidimensional spectroscopy and using X-Ray methods for monitoring the excited-state dynamics of molecules. In January 2020, she moved to UCL as a Lecturer in Physical Chemistry to establish her own research group. Her research interests include using a variety of spectroscopic techniques, including multidimensional optical spectroscopy and time-resolved X-ray spectroscopy, to understand photoinduced processes in the solution and gas phase.

Research Summary

Absorption of light by a molecule can trigger a wealth of photoinduced processes. Bond breaking, bond formation, large changes in the molecular structure… these are just some of the new realms of chemical and physical processes opened by light. The challenge is capturing and understanding these processes that often occur on the timescale of femtoseconds. They key motivation for my research is developing tools and techniques that allow us to do just this in the field of ultrafast spectroscopy.

Development of ultrafast spectroscopic techniques

One of the challenges of studying light-initiated processes is that they occur in a regime where the Born-Oppenheimer approximation breaks down, making it impossible to separate the molecular electronic and nuclear degrees of freedom. This means that, to successfully map all aspects of a photoinduced process experimentally, the technique of choice must be sensitive to both the electronic and nuclear changes the molecule undergoes.

Ultrafast optical techniques have excellent time-resolution and sensitivity to the evolution of the valence electronic structure. Of this family of techniques, multidimensional electronic spectroscopy (2D-ES) makes it possible to gain unprecedented levels of detail about the energy relaxation dynamics and behaviour of coherences even in large, complex molecular systems. This is because with 2D-ES it is possible to frequency-resolve both excitation and detection signals, avoiding the spectral congestion issues found with more widely used approaches such as transient electronic absorption (TEA) spectroscopy.

While the valence electronic structure of a molecule is dependent on its nuclear configuration, it can be challenging to retrieve structural information directly from optical experiments. For this, time-resolved X-ray techniques are better suited. By studying transitions from the tightly-bound core electrons, element-specific, localised information can be retrieved on both local changes in electronic structure and structural information such as bond angles and lengths. A variety of detection methods, including absorption, emission and photoelectrons, can be used in the X-ray domain to recover that maximum amount of chemical information.

Applications to complex molecular systems

My motivation for developing the aforementioned experimental techniques is to make it possible to study a wider range of complex molecular systems, including porphyrin complexes for photodynamic therapy, and inorganic and organic compounds for photocatalysis. As well as being excellent candidates for developing our knowledge of photophysical behaviour, there are key scientific questions concerning their energy relaxation pathways, and how chemical substitution and local environment influence these. Understanding this is key for driving future molecular design for applications. 

Combining Experiment and Theory

Developments in excited state electronic structure methods over the last decade have meant that it is possible to directly simulate the observed signals in ultrafast experiments. Using ab initio methods alongside experiments makes it possible to gain deeper insight into the exact mechanisms of energy relaxation and can aid in the interpretation of complex experimental spectra. We perform a variety of such calculations here at UCL and in collaboration with several international groups, particularly for benchmarking and testing new methodological approaches for the simulation of experimental spectra. 

Teaching Summary

CHEM0021 - Reaction Dynamics
Member of the CHEM0058/9 SARPIC Panel
Physical and Computational Chemistry Labs

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