about
Ionic conductivity, structural deformation, and programmable anisotropy of DNA origami in electric fieldPlasmonic Nanopores for Trapping, Controlling Displacement, and Sequencing of DNA.Water Confined in Cylindrical Pores: A Molecular Dynamics StudyDevelopment of a tuned interfacial force field parameter set for the simulation of protein adsorption to silica glassAdhesion mechanisms of curli subunit CsgA to abiotic surfacesIonic Current Rectification Through Silica NanoporesSlowing DNA Transport Using Graphene-DNA Interactions.Deciphering ionic current signatures of DNA transport through a nanopore.Molecular dynamics study of the behavior of selected nanoscale building blocks in a gel-phase lipid bilayer.Using VMD: an introductory tutorialTribological effects on DNA translocation in a nanochannel coated with a self-assembled monolayer.Modeling Transport Through Synthetic NanoporesSlowing the translocation of double-stranded DNA using a nanopore smaller than the double helix.Lipid bilayer coated Al(2)O(3) nanopore sensors: towards a hybrid biological solid-state nanopore.Control of Nanoscale Environment to Improve Stability of Immobilized Proteins on Diamond Surfaces.Characterizing and controlling the motion of ssDNA in a solid-state nanopore.Atoms-to-microns model for small solute transport through sticky nanochannels.Slowing down DNA translocation through a nanopore in lithium chloride.Modeling Pressure-Driven Transport of Proteins through a Nanochannel.Microscopic Perspective on the Adsorption Isotherm of a Heterogeneous Surface.Surface-water Interface Induces Conformational Changes Critical for Protein Adsorption: Implications for Monolayer Formation of EAS HydrophobinForce fields for simulating the interaction of surfaces with biological moleculesSustained Administration of Hormones Exploiting Nanoconfined Diffusion through Nanochannel MembranesMicroscopic mechanics of hairpin DNA translocation through synthetic nanoporesRegulating the transport of DNA through biofriendly nanochannels in a thin solid membrane.A multiscale MD-FE model of diffusion in composite media with internal surface interaction based on numerical homogenization procedure.Advances in the understanding of nanomaterial-biomembrane interactions and their mathematical and numerical modeling.SDS-assisted protein transport through solid-state nanopores.Simulations of inorganic-bioorganic interfaces to discover new materials: insights, comparisons to experiment, challenges, and opportunities.Modeling and simulation of protein-surface interactions: achievements and challenges.Hydrophobic-induced Surface Reorganization: Molecular Dynamics Simulations of Water Nanodroplet on Perfluorocarbon Self-Assembled Monolayers.Adsorption energy as a metric for wettability at the nanoscaleImproved oil recovery in nanopores: NanoIOR.Influence of capillary bridge formation onto the silica nanoparticle interaction studied by grand canonical Monte Carlo simulations.Simulation of Forces between Humid Amorphous Silica Surfaces: A Comparison of Empirical Atomistic Force Fields.Proton conductivity of SO3 H-functionalized benzene-periodic mesoporous organosilica.Effect of interaction with coesite silica on the conformation of Cecropin P1 using explicit solvent molecular dynamics simulation.Modulation of Molecular Flux Using a Graphene Nanopore Capacitor.Modeling hydroxylated nanosilica: Testing the performance of ReaxFF and FFSiOH force fields.Picomolar Fingerprinting of Nucleic Acid Nanoparticles Using Solid-State Nanopores.
P2860
Q27334951-9FDD56D5-DE6E-4C82-BFFF-2E03546620B4Q27342143-BCD98362-887F-4CCA-A9AD-2B37D1E6C269Q28387871-E08F3C1D-D2E0-41FB-AA49-CAA552C32C23Q28390670-489C0802-8D50-435C-B0D9-F41905C7B8F0Q30398037-2EAE27DD-B9CC-4E31-BE42-C75AA4ECA949Q30486588-3933B883-ABD0-452E-BBE9-C0F2A53DAD50Q30657318-6E2B3E14-04A0-40C2-90C4-6C9BA7C29EABQ34018554-818A57BF-9F0E-4C96-B8AE-5AD6B2A0F474Q34077562-789DEFF0-5777-483D-98EB-5472858A905DQ34275519-D6A743F1-9FCE-42E6-825B-D6CD987D7E31Q34454065-F8CAAC87-CE00-48D8-9F8D-2701B9EE2F09Q35200908-297185A7-3FCA-405D-AB13-9331F34C01D8Q35206610-F218BEDB-8BCC-499E-AE79-C9E7E356FE0FQ35219590-80A54136-32BF-4C1A-95D2-E9FDBA1542BFQ35225373-3FC15EF6-8B51-4566-BE6B-64B7030BB7A3Q35512664-2487F8A8-A3EB-4C2D-BB54-7288B6C69584Q35952114-484D8FF8-4798-4B0C-88B7-1BADE04436FCQ35952123-577F9642-1060-4810-BBDA-CBB4D143B0C4Q35964743-E5D9D836-1CCC-4551-BD30-5B8F75FD3ADAQ35964748-CDE51966-5AB6-4CB4-8859-21072729B4AEQ36280006-82043370-8A94-438B-8B98-17279A4FB2EFQ36390718-748AA6A2-01E1-47F5-8F78-ACEC11E81A96Q36982405-C01823B4-D980-4A33-845C-6DD8CF73BB87Q37277632-682812B0-3A22-4372-B20A-938BFA8A57F5Q37556014-9C3D44A3-08FF-4065-A93A-B082EA4163CCQ37600329-6A761784-F0AA-4734-8F9D-900E71B0A166Q38111404-56B9B6CE-236C-4024-8EB4-B81B64591CE8Q38647051-AC91EDA8-A778-4D0A-BE59-AD4192E049AAQ38691919-AEE95736-C1D6-4D9D-A9B8-A1AA364534CEQ38715169-7034018C-97F9-457A-8DA2-30D558ED9F73Q40782557-AA0614EA-CE7F-4E9F-A4D0-3EF480E39906Q41817191-E1ACFC1D-B058-4616-8F35-5AE6B7750B68Q41824663-748F43CD-9995-4D3A-9AC9-5E34D56AB484Q42659267-73E8B2FA-584B-4BF0-94BA-2DC30495EDC8Q43059030-A1445A56-8529-41AF-B9F7-D223FC0E4303Q43839149-2B16B601-A75B-4158-B524-A04EE9ED7EFCQ45103061-BA9FB047-1DAA-4352-806D-DAD33AAA40E6Q46441187-5AE897EE-9F5A-4693-9946-81D1A2C4D14FQ47428315-F986FD26-4856-4258-B984-44A7343234D8Q48174925-9C706E46-962B-4BFB-A0CD-33859A523F2E
P2860
description
2006 nî lūn-bûn
@nan
2006 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
name
Water-silica force field for simulating nanodevices
@ast
Water-silica force field for simulating nanodevices
@en
Water-silica force field for simulating nanodevices
@nl
type
label
Water-silica force field for simulating nanodevices
@ast
Water-silica force field for simulating nanodevices
@en
Water-silica force field for simulating nanodevices
@nl
prefLabel
Water-silica force field for simulating nanodevices
@ast
Water-silica force field for simulating nanodevices
@en
Water-silica force field for simulating nanodevices
@nl
P2860
P50
P3181
P356
P1476
Water-silica force field for simulating nanodevices
@en
P2860
P304
P3181
P356
10.1021/JP063896O
P407
P577
2006-11-02T00:00:00Z