Publications
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged graphene." Nature Communications 5:5171 (2014).
"Smooth DNA Transport through a Narrowed Pore Geometry." Biophysical Journal 107:2381-2393 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Modeling thermophoretic effects in solid-state nanopores." Journal of Computational Electronics 13:826-838 (2014).
"Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling." The Journal of Physical Chemistry C 118:9809-9819 (2014).