The video of the lecture is avaliable at https://media.oregonstate.edu/media/t/0_qdk4epv0

Precision measurement is a hallmark of physics but the small length scale (~nanometer) of elementary biological processes and the thermal fluctuations surrounding them challenge our ability to visualize the motion of biological molecules. In this talk, I will highlight the recent developments in single molecule nanometry where a position of a single fluorescent molecule can be determined with a single nanometer precision, reaching the limit imposed by the shot noise. The relative motion between two molecules can be determined with ~0.3 nm precision at ~ 1 milliseconds time resolution, providing fundamental insights on how motor proteins move on cellular highways. Finally, I will show our recent progress in combining angstrom scale optical tweezers with single molecule fluorescent detection, opening new avenues for multi-dimensional single molecule nanometry for biological physics.

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Professor Ha has achieved many "firsts" in experimental biological physics--the first dectection of dipole-dipole interaction (fluorescence resonance energy transfer, or FRET) between two single molecules; the first observation of "quantum jumps" of single molecules at room temperature; the first detection of the rotation of single molecules; and the first detection of enzyme conformational changes via single-molecule FRET. His most recent work, using single-molecule measurements to understand protein-DNA interactions and enzyme dynamics, has led him to develop novel optical techniques, fluid-handling systems, and surface preparations.