Two dimensional Fourier transform spectroscopy of resonance energy transfer Jennifer P. Ogilvie, Departments of Physics and Biophysics University of Michigan,

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Presentation transcript:

Two dimensional Fourier transform spectroscopy of resonance energy transfer Jennifer P. Ogilvie, Departments of Physics and Biophysics University of Michigan, Ann Arbor, MI, 48109 How biological molecules harness and control light energy is fundamental to life. In photosynthesis, elaborate antenna arrays gather solar energy and transfer it to photochemical reaction centers with 95% efficiency. Other light-harvesting systems perform essential functions such as DNA repair. Uncovering the design principles of light-harvesting complexes requires making the connection between structure and dynamics. We aim to use two dimensional Fourier transform spectroscopy (2DFTS) to make these connections. In analogy to NMR, a multiple pulse sequence excites the sample, allowing correlations to be made between excitation and detection frequencies. The resulting 2D spectrum reveals couplings and lineshapes that provide insight into electronic structure and energy transfer events. Two noncollinear optical parametric amplifiers provide tunable visible light to explore coupling between a wide array of electronic transitions. wexc (THz) wdet (THz) B A Preliminary 2D spectra of the dye PERY in DMSO at 2=70 fs (A) and 2=315 fs (B). The change in position and lineshape report on solvation dynamics and inhomogeneous broadening. DNA Photolyase Future studies will apply 2DFTS to the DNA repair enzyme DNA Photoylase and other natural light-harvesting systems to test current descriptions of energy transfer.