David Sean
David Sean
University of Ottawa
Bestätigte E-Mail-Adresse bei - Startseite
Zitiert von
Zitiert von
ESPResSo 4.0–an extensible software package for simulating soft matter systems
F Weik, R Weeber, K Szuttor, K Breitsprecher, J de Graaf, M Kuron, ...
The European Physical Journal Special Topics 227, 1789-1816, 2019
Modeling the separation of macromolecules: A review of current computer simulation methods
GW Slater, C Holm, MV Chubynsky, HW de Haan, A Dubé, K Grass, ...
Electrophoresis 30 (5), 792-818, 2009
Simulations of ionization equilibria in weak polyelectrolyte solutions and gels
J Landsgesell, L Nová, O Rud, F Uhlík, D Sean, P Hebbeker, C Holm, ...
Soft Matter 15 (6), 1155-1185, 2019
Interfacing solid‐state nanopores with gel media to slow DNA translocations
M Waugh, A Carlsen, D Sean, GW Slater, K Briggs, H Kwok, ...
Electrophoresis 36 (15), 1759-1767, 2015
Free energy of a polymer in slit-like confinement from the Odijk regime to the bulk
JS Leith, A Kamanzi, D Sean, D Berard, AC Guthrie, CMJ McFaul, ...
Macromolecules 49 (23), 9266-9271, 2016
Translocation of a polymer through a nanopore starting from a confining nanotube
D Sean, HW de Haan, GW Slater
Electrophoresis 36 (5), 682-691, 2015
Using a Péclet number for the translocation of a polymer through a nanopore to tune coarse-grained simulations to experimental conditions
HW de Haan, D Sean, GW Slater
Physical Review E 91 (2), 022601, 2015
Modeling gel swelling equilibrium in the mean field: From explicit to poisson-boltzmann models
J Landsgesell, D Sean, P Kreissl, K Szuttor, C Holm
Physical Review Letters 122 (20), 208002, 2019
Computer simulations of static and dynamical properties of weak polyelectrolyte nanogels in salty solutions
D Sean, J Landsgesell, C Holm
Gels 4 (1), 2, 2017
Highly driven polymer translocation from a cylindrical cavity with a finite length
D Sean, GW Slater
The Journal of Chemical Physics 146 (5), 054903, 2017
Physical confinement signals regulate the organization of stem cells in three dimensions
SV Hadjiantoniou, D Sean, M Ignacio, M Godin, GW Slater, AE Pelling
Journal of The Royal Society Interface 13 (123), 20160613, 2016
Reducing the variance in the translocation times by stretching the polymer
HW de Haan, D Sean, GW Slater
Physical Review E 98 (2), 022501, 2018
Electrophoretic mobility of partially denatured DNA in a gel: Qualitative and semiquantitative differences between bubbles and split ends
D Sean, GW Slater
Electrophoresis 33 (9‐10), 1341-1348, 2012
Langevin dynamcis simulations of driven polymer translocation into a cross‐linked gel
D Sean, GW Slater
Electrophoresis 38 (5), 653-658, 2017
Rotation-induced macromolecular spooling of DNA
TN Shendruk, D Sean, D Berard, J Wolf, J Dragoman, S Battat, GW Slater, ...
Physical Review X 7 (3), 031005, 2017
Physical interpretation of the Lr parameter in the theory for the gel electrophoresis of partially denatured DNA
D Sean, GW Slater
Electrophoresis 31 (20), 3446-3449, 2010
Influence of weak groups on polyelectrolyte mobilities
D Sean, J Landsgesell, C Holm
Electrophoresis 40 (5), 799-809, 2019
Gel electrophoresis of DNA partially denatured at the ends: What are the dominant conformations?
D Sean, GW Slater
Electrophoresis 34 (5), 745-752, 2013
Can gel concentration gradients improve two‐dimensional DNA displays?
D Sean, YE Wang, GW Slater
Electrophoresis 35 (5), 736-745, 2014
Erratum: Modeling Gel Swelling Equilibrium in the Mean Field: From Explicit to Poisson-Boltzmann Models [Phys. Rev. Lett. 122, 208002 (2019)]
J Landsgesell, D Sean, P Kreissl, K Szuttor, C Holm
Physical Review Letters 124 (11), 119901, 2020
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