Nanometal Surface Energy Transfer in Optical Rulers, Breaking the FRET Barrier
University of California, Santa Barbara · Florida State University
Abstract
Optical-based distance measurements are essential for tracking biomolecular conformational changes, drug discovery, and cell biology. Traditional Forster resonance energy transfer (FRET) is efficient for separation distances up to 100 A. We report the first successful application of a dipole-surface type energy transfer from a molecular dipole to a nanometal surface that more than doubles the traditional Forster range (220 A) and follows a 1/R(4) distance dependence. We appended a 1.4 nm Au cluster to the 5' end of one DNA strand as the energy acceptor and a fluorescein (FAM) to the 5' end of the complementary strand as the energy donor. Analysis of the energy transfer on DNA lengths (15, 20, 30, 60bp),…
Citation impact
- FWCI
- 27.25
- Percentile
- 100%
- References
- 25
Authors
9- CSC. Steven YunCorresponding
University of California, Santa Barbara, Florida State University
- AMAlmudena Muñoz Javier
Florida State University, University of California, Santa Barbara
- TLTravis L. Jennings
University of California, Santa Barbara, Florida State University
- MPMatthew P. A. Fisher
University of California, Santa Barbara, Florida State University
- SMSteven M. Hira
Florida State University, University of California, Santa Barbara
Topics & keywords
- Chemistry
- Förster resonance energy transfer
- Energy transfer
- Chemical physics
- Surface (topology)
- Transfer (computing)
- Nanotechnology
- Photochemistry
- Affordable and clean energy