Solid-state nanopores are an emerging class of single-molecule sensors. Whereas most studies so far focused on doublestranded
DNA (dsDNA) molecules, exploration of single-stranded DNA (ssDNA) is of great interest as well, for example to employ
such a nanopore device to read out t
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Solid-state nanopores are an emerging class of single-molecule sensors. Whereas most studies so far focused on doublestranded
DNA (dsDNA) molecules, exploration of single-stranded DNA (ssDNA) is of great interest as well, for example to employ
such a nanopore device to read out the sequence. Here, we study the translocation of long random-sequence ssDNA through nanopores.
Using atomic force microscopy, we observe the ssDNA to hybridize into a random coil, forming blobs of around 100 nm in diameter
for 7 kb ssDNA. These large entangled structures have to unravel, when they arrive at the pore entrance. Indeed, we observe strong
blockade events with a translocation time that is exponentially dependent on voltage, ¿ ~ e-V/V0. Interestingly, this is very different
than for dsDNA, for which ¿ ~ 1/V. We report translocations of ssDNA but also of ssDNA-dsDNA constructs where we compare the
conductance-blockade levels for ssDNA versus dsDNA as a function of voltage.@en