AI Article Synopsis
- Using single molecules, specifically suspended DNA, as templates for nanodevices shows potential in advancing nanotechnology.
- The superconducting two-nanowire devices created from these DNA templates are extremely thin and prone to thermal fluctuations, leading to nonzero resistance at various temperatures.
- A unique quantum interference phenomenon occurs in these devices, differing from typical Little-Parks oscillations, influenced by strong phase gradients due to an applied magnetic field.
Article Abstract
The application of single molecules as templates for nanodevices is a promising direction for nanotechnology. We used a pair of suspended DNA molecules as templates for superconducting two-nanowire devices. Because the resulting wires are very thin, comparable to the DNA molecules themselves, they are susceptible to thermal fluctuations typical for one-dimensional superconductors and exhibit a nonzero resistance over a broad temperature range. We observed resistance oscillations in these two-nanowire structures that are different from the usual Little-Parks oscillations. Here, we provide a quantitative explanation for the observed quantum interference phenomenon, which takes into account strong phase gradients created in the leads by the applied magnetic field.
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| http://dx.doi.org/10.1126/science.1111307 | DOI Listing |
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