Journal
PHYSICAL REVIEW E
Volume 105, Issue 5, Pages -Publisher
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevE.105.054503
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Funding
- National Science Foundation [NNCI-2025233]
- NSF [DMR1351283]
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In this study, zero-time-averaged alternating electric fields were applied to DNA molecules in a cross-shaped nanofluidic slit. A net drift of DNA molecules was observed, with the magnitude dependent on the square of the electric field amplitude. By analyzing the rate of DNA accumulation at the center of the device, an estimate for the second-order electrophoretic mobility, mu(2), was derived. The absence of focusing at a dipole rotation frequency >20 Hz suggests a dependence of mu(2) on the frequency of the alternating fields, raising the possibility of frequency-dependent electrophoretic DNA separation by length without the need for a sieving matrix.
We have applied zero-time-averaged alternating electric fields to DNA molecules in a cross-shaped nanofluidic slit. We observed a net drift of DNA molecules, the magnitude of which depends on the square of the electric field amplitude. From the rate of accumulation of DNA at the center of the device, we derive an estimate for the second-order electrophoretic mobility, mu(2). We observe that focusing is absent at a dipole rotation frequency >20 Hz, which suggests that mu(2) depends on the frequency of the alternating fields. The observation of a nonzero mu(2) raises the possibility of frequency-dependent electrophoretic DNA separation by length achievable in the absence of a sieving matrix.
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