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1
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Chem Sci. 2020 Sep 22;11(41):11113-11123. doi: 10.1039/d0sc04747c.
2
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Chem Sci. 2020 Jun 2;11(26):6701-6708. doi: 10.1039/d0sc02286a. eCollection 2020 Jul 14.
3
Detection of the thietane precursor in the UVA formation of the DNA 6-4 photoadduct.
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4
A Unified Experimental/Theoretical Description of the Ultrafast Photophysics of Single and Double Thionated Uracils.
Chemistry. 2020 Jan 2;26(1):336-343. doi: 10.1002/chem.201904541. Epub 2019 Dec 10.
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