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Single-femtosecond atomic-resolution observation of a protein traversing a conical intersection
Link to bioRxiv paper:
http://biorxiv.org/cgi/content/short/2020.11.13.382218v1?rss=1
Authors: Hosseinizadeh, A., Breckwoldt, N., Fung, R., Sepehr, R., Schmidt, M., Schwander, P., Santra, R., Ourmazd, A.
Abstract:
The structural dynamics of a molecule are determined by the underlying potential energy landscape. Conical intersections are funnels connecting otherwise separate energy surfaces. Posited almost a century ago [1], conical intersections remain the subject of intense scientific investigation [2-4]. In biology, they play a pivotal role in vision, photosynthesis, and DNA stability [5,6]. In ultrafast radiationless de-excitation [1,7], they are vital to ameliorating photon-induced damage. In chemistry, they tightly couple the normally separable nuclear and electronic degrees of freedom, precluding the Born-Oppenheimer approximation [8]. In physics, they manifest a Berry phase, giving rise to destructive interference between clockwise and anti-clockwise trajectories around the conical intersection [9]. Accurate theoretical methods for examining conical intersections are at present limited to small molecules. Experimental investigations are challenged by the required time resolution and sensitivity. Current structure-dynamical understanding of conical intersections is thus limited to simple molecules with around 10 atoms, on timescales of about 100 fs or longer [10]. Spectroscopy can achieve better time resolution, but provides only indirect structural information. Here, we present single-femtosecond, atomic-resolution movies of a 2,000-atom protein passing through a conical intersection. These movies, extracted from experimental data by geometric machine learning, reveal the dynamical trajectories of de-excitation via a conical intersection, yield the key parameters of the conical intersection controlling the de-excitation process, and elucidate the topography of the electronic potential energy surfaces involved.
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By Multimodal LLCLink to bioRxiv paper:
http://biorxiv.org/cgi/content/short/2020.11.13.382218v1?rss=1
Authors: Hosseinizadeh, A., Breckwoldt, N., Fung, R., Sepehr, R., Schmidt, M., Schwander, P., Santra, R., Ourmazd, A.
Abstract:
The structural dynamics of a molecule are determined by the underlying potential energy landscape. Conical intersections are funnels connecting otherwise separate energy surfaces. Posited almost a century ago [1], conical intersections remain the subject of intense scientific investigation [2-4]. In biology, they play a pivotal role in vision, photosynthesis, and DNA stability [5,6]. In ultrafast radiationless de-excitation [1,7], they are vital to ameliorating photon-induced damage. In chemistry, they tightly couple the normally separable nuclear and electronic degrees of freedom, precluding the Born-Oppenheimer approximation [8]. In physics, they manifest a Berry phase, giving rise to destructive interference between clockwise and anti-clockwise trajectories around the conical intersection [9]. Accurate theoretical methods for examining conical intersections are at present limited to small molecules. Experimental investigations are challenged by the required time resolution and sensitivity. Current structure-dynamical understanding of conical intersections is thus limited to simple molecules with around 10 atoms, on timescales of about 100 fs or longer [10]. Spectroscopy can achieve better time resolution, but provides only indirect structural information. Here, we present single-femtosecond, atomic-resolution movies of a 2,000-atom protein passing through a conical intersection. These movies, extracted from experimental data by geometric machine learning, reveal the dynamical trajectories of de-excitation via a conical intersection, yield the key parameters of the conical intersection controlling the de-excitation process, and elucidate the topography of the electronic potential energy surfaces involved.
Copy rights belong to original authors. Visit the link for more info