Control of nanopore wetting by a photochromic spiropyran: a light-controlled valve and electrical switch.
about
Visible light guided manipulation of liquid wettability on photoresponsive surfacesBiochemically responsive smart surfaceLight responsive polymer membranes: a review.Biosensing with nanofluidic diodes.Bioinspired integrated nanosystems based on solid-state nanopores: "iontronic" transduction of biological, chemical and physical stimuli.Photo-switchable two-dimensional nanofluidic ionic diodes.Preparation of light-responsive membranes by a combined surface grafting and postmodification processSpiropyran-conjugated pluronic as a dual responsive colorimetric detector.Electrical conductance of hydrophobic membranes or what happens below the surface."Uphill" cation transport: A bioinspired photo-driven ion pump.Biological stimuli and biomolecules in the assembly and manipulation of nanoscale polymeric particles.ATRP-based synthesis and characterization of light-responsive coatings for transdermal delivery systems.Photo-response behavior of electrospun nanofibers based on spiropyran-cyclodextrin modified polymer.Biomimetic smart nanopores and nanochannels.Photo-actuation of liquids for light-driven microfluidics: state of the art and perspectives.Spiropyran-based dynamic materials.Photo-responsive polymeric micelles.Free-Blockage Mesoporous Anticancer Nanoparticles Based on ROS-Responsive Wetting Behavior of Nanopores.Smart Bioinspired Nanochannels and their Applications in Energy-Conversion Systems.Bioinspired Energy Conversion in Nanofluidics: A Paradigm of Material Evolution.Nanofluidics in two-dimensional layered materials: inspirations from nature.Photoswitchable nanoparticles for triggered tissue penetration and drug delivery.A free-blockage controlled release system based on the hydrophobic/hydrophilic conversion of mesoporous silica nanopores.An Artificial CO2 -Driven Ionic Gate Inspired by Olfactory Sensory Neurons in Mosquitoes.Presence of electrolyte promotes wetting and hydrophobic gating in nanopores with residual surface charges.Highly Efficient Gating of Electrically Actuated Nanochannels for Pulsatile Drug Delivery Stemming from a Reversible Wettability Switch.Bioinspired smart asymmetric nanochannel membranes.A novel generation of hybrid photochromic vinylidene-naphthofuran silica nanoparticles through fine-tuning of surface chemistry.Light-Controlled Ion Transport through Biomimetic DNA-Based Channels.Malachite green derivative-functionalized single nanochannel: light-and-pH dual-driven ionic gating.Nanoporous membranes with electrochemically switchable, chemically stabilized ionic selectivity.A temperature, pH and sugar triple-stimuli-responsive nanofluidic diode.Fabrication of "Plug and Play" Channels with Dual Responses by Host-Guest Interactions.From symmetric to asymmetric design of bio-inspired smart single nanochannels.Photo-induced current amplification in L-histidine modified nanochannels based on a highly charged photoacid in solution.The opposite gating behaviors of solid-state nanochannels modified with long and short polymer chains.Desalination of water by vapor-phase transport through hydrophobic nanopores
P2860
Q30847516-00F83DC2-C324-4195-BFD6-594B878B2659Q33602834-5F13B521-17D3-4E76-9926-12ED71F458F6Q33615204-6948DAFD-3D22-431D-8E0E-82C6411C0C66Q33641004-AB965D68-390C-48D0-AB2D-DE8843DA06A7Q33749703-C918B697-DA3A-404F-B1B8-2B07DE35FDDDQ33804927-5F58DFF1-DA47-412F-9D77-788A34BC6625Q34140075-895F842D-264C-40FE-9BB8-D86D0CDD3F23Q34386241-68C9A666-294E-4143-A9CB-F612B2F8EEF0Q36857906-C26C45F5-194A-4E58-B825-ADE87559A88BQ37353471-2F56BD08-7C2C-440C-A13C-FBD573076470Q37396540-23FF093F-C133-4CBD-B110-6335EF28EE0EQ37400032-ED094A80-8139-4664-BCBD-E863CC3DC571Q37640930-D8D59A07-B207-4241-AB48-42D4AA6A2D78Q37838728-A6679B7E-B0F7-4B1E-BA8C-7174026614BFQ38032145-018E3C65-E4C1-4B9C-AA42-79C081852F02Q38131712-F00AD164-B7C6-47D0-9C2D-127CA811BC0EQ38232193-B5528CC1-0312-423D-B0C0-62CE0FBFDFADQ38637226-309851E9-F2A3-4B10-A7B7-1AC5A3D18A1CQ38638224-5F852F87-C8D5-4508-B927-6E93A31DECB3Q38644578-D251B5BF-6B10-4461-912B-8F4EAE9373D6Q38655407-EF06334C-C041-4823-B634-3B0B4D6896F9Q39386667-E44073E2-8EE5-4672-AB40-CC1537DAE6DDQ41600610-5355E39C-0EB5-4B83-B0A1-6246E5BC236DQ44161096-F2FE659F-CF42-450F-A490-731B3CC4A72DQ46704988-7884F5A1-46A8-47AE-95F6-241E1DEB6F05Q47273693-ED594788-DE85-49DB-BB5E-907FBF0B030CQ47751920-5C900A28-8F49-4F0F-8185-76FF7D54D1E9Q48737962-9D85B2D9-41B6-44DD-B67D-2EF84C838FD9Q50214897-34BE68F6-23C4-4D41-9527-08525F16CF11Q50489996-4367879D-FA15-4640-B879-BB461463B043Q50930897-7D4BB5FC-4E28-4500-B782-1AD3487A8C82Q51020404-69A6DCDB-8F60-43F4-A2D2-2B9F887288BAQ51339949-9C8B75C2-7409-4168-9217-47BAEE7A6898Q51783096-339748E9-E744-46F4-98B5-63CA0ADB1A19Q53124076-B2528E81-3255-40AF-8461-BA0442D648F6Q53493250-0B0A2710-57F1-4A62-91CA-4CB1925A806DQ56567784-9EB2CF48-FEFA-4081-B50D-40E7D6A5E496
P2860
Control of nanopore wetting by a photochromic spiropyran: a light-controlled valve and electrical switch.
description
2006 nî lūn-bûn
@nan
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
2006年论文
@zh
2006年论文
@zh-cn
name
Control of nanopore wetting by ...... d valve and electrical switch.
@en
type
label
Control of nanopore wetting by ...... d valve and electrical switch.
@en
prefLabel
Control of nanopore wetting by ...... d valve and electrical switch.
@en
P2093
P2860
P356
P1433
P1476
Control of nanopore wetting by ...... d valve and electrical switch.
@en
P2093
Choong-Do Park
Devens Gust
Ivan Vlassiouk
Sean A Vail
Sergei Smirnov
P2860
P304
P356
10.1021/NL060313D
P407
P577
2006-05-01T00:00:00Z