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Enhancement of irradiation effects on cancer cells by cross-linked dextran-coated iron oxide (CLIO) nanoparticles.High Performance Transparent Transistor Memory Devices Using Nano-Floating Gate of Polymer/ZnO Nanocomposites.Oligosaccharide Carbohydrate Dielectrics toward High-Performance Non-volatile Transistor Memory Devices.Conjugated fluorene based rod-coil block copolymers and their PCBM composites for resistive memory switching devices.Solution-shear-processed quaterrylene diimide thin-film transistors prepared by pressure-assisted thermal cleavage of swallow tails.Diketopyrrolopyrrole-thiophene-based acceptor-donor-acceptor conjugated materials for high-performance field-effect transistors.Multilevel nonvolatile flexible organic field-effect transistor memories employing polyimide electrets with different charge-transfer effects.Electrochemical study on screen-printed carbon electrodes with modification by iron nanoparticles in Fe(CN)(6) (4-/3-) redox system.Nonvolatile organic thin film transistor memory devices based on hybrid nanocomposites of semiconducting polymers: gold nanoparticles.Effects of chain architectures on the surface structures of conjugated rod-coil block copolymer brushes.Intrinsically Stretchable Nanostructured Silver Electrodes for Realizing Efficient Strain Sensors and Stretchable Organic Photovoltaics.Stretchable Polymer Dielectrics for Low-Voltage-Driven Field-Effect Transistors.RGB-Switchable Porous Electrospun Nanofiber Chemoprobe-Filter Prepared from Multifunctional Copolymers for Versatile Sensing of pH and Heavy Metals.S,N-Heteroacene-Based Copolymers for Highly Efficient Organic Field Effect Transistors and Organic Solar Cells: Critical Impact of Aromatic Subunits in Ladder π-System.Well-defined star-shaped donor-acceptor conjugated molecules for organic resistive memory devices.Non-volatile organic transistor memory devices using the poly(4-vinylpyridine)-based supramolecular electrets.Single-crystal C60 needle/CuPc nanoparticle double floating-gate for low-voltage organic transistors based non-volatile memory devices.Conjugated donor-acceptor-acceptor (D-A-A) molecule for organic nonvolatile resistor memory.High-k polymer-graphene oxide dielectrics for low-voltage flexible nonvolatile transistor memory devices.Improving the characteristics of an organic nano floating gate memory by a self-assembled monolayer.A poly(fluorene-thiophene) donor with a tethered phenanthro[9,10-d]imidazole acceptor for flexible nonvolatile flash resistive memory devices.Supramolecular block copolymers: graphene oxide composites for memory device applications.A supramolecular approach on using poly(fluorenylstyrene)-block-poly(2-vinylpyridine):PCBM composite thin films for non-volatile memory device applications.Non-volatile memory devices based on polystyrene derivatives with electron-donating oligofluorene pendent moieties.Network structures of polyhedral oligomeric silsesquioxane based nanocomposites: a Monte Carlo study.Bio-Based Transparent Conductive Film Consisting of Polyethylene Furanoate and Silver Nanowires for Flexible Optoelectronic DevicesThermoresponsive Luminescent Electrospun Fibers Prepared From Poly(DMAEMA-co-SA-co-StFl) Multifunctional Random CopolymersHigh-Performance Nonvolatile Transistor Memories of Pentacence Using the Green Electrets of Sugar-based Block Copolymers and Their SupramoleculesHigh-Efficiency Polymer Solar Cells Achieved by Doping Plasmonic Metallic Nanoparticles into Dual Charge Selecting Interfacial Layers to Enhance Light TrappingNon-halogenated solvents for environmentally friendly processing of high-performance bulk-heterojunction polymer solar cellsToward High-Performance Semi-Transparent Polymer Solar Cells: Optimization of Ultra-Thin Light Absorbing Layer and Transparent Cathode ArchitectureEffective interfacial layer to enhance efficiency of polymer solar cells via solution-processed fullerene-surfactantsEvaluation of structure–property relationships of solution-processible fullerene acceptors and their n-channel field-effect transistor performanceImproved Charge Transport and Absorption Coefficient in Indacenodithieno[3,2-b]thiophene-based Ladder-Type Polymer Leading to Highly Efficient Polymer Solar CellsHigh-Mobility Air-Stable Solution-Shear-Processed n-Channel Organic Transistors Based on Core-Chlorinated Naphthalene DiimidesHigh-Performance Air-Stable n-Type Organic Transistors Based on Core-Chlorinated Naphthalene Tetracarboxylic DiimidesThin film morphologies of pi-conjugated rod-coil block copolymers with thermoresponsive property: a combined experimental and molecular simulation studyUniform Luminous Perovskite Nanofibers with Color-Tunability and Improved Stability Prepared by One-Step Core/Shell ElectrospinningRealization of Intrinsically Stretchable Organic Solar Cells Enabled by Charge-Extraction Layer and Photoactive Material EngineeringDonor-Acceptor Core-Shell Nanoparticles and Their Application in Non-Volatile Transistor Memory Devices
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Q33519889-FE3F19A2-9C79-4C81-B535-2CBE68CA0013Q36527813-7DFD96B8-968C-44A7-86B6-ABCD4A302B73Q38968151-F7BB9D5D-09B4-4FC6-A43E-E50EE996A76CQ40002857-C118F471-60AF-4143-BFD0-DA3FFBDC6877Q44055007-70F64832-B1F1-4297-A9C2-D21280BFBA7EQ44370617-A0F10B4E-1F3C-49EC-915D-3CC79BC739E9Q46110215-2657558B-85F6-424A-9F6D-DB26FD5DE842Q46681845-4BCA8D44-7A7B-4D91-BF98-EF6295A9DC98Q46734304-1A43C0A1-293F-4039-AEFC-10A1A847A8B6Q47753822-FBC94FB6-82F4-4C46-B479-0DCB9F80394FQ47859802-7BC31BE1-8E67-461E-96C7-C9BA829B768BQ47971145-CF37AE9A-D893-4C43-938A-3E1F22934E36Q48062955-323CD081-6913-4AFB-BBCB-DD91BD9CEA20Q48150472-553E5447-F725-4F4A-A0BB-17EF37E26F24Q50716962-C359C6DF-C9CB-44B3-B17A-523937AAC198Q50759567-C5D11E5C-7015-4C41-AB9A-FBEE7E37E401Q50773254-EAD621A6-CA02-4CB2-B367-B3DAA6049AF1Q50778578-5F1353B6-2BBB-4C50-8920-DA1AC802D6D6Q50860913-C157F6D2-2914-4963-BEC8-5AFA9749B059Q50937791-B9FEF667-6BB1-49B6-B714-7CA9B82A5E4FQ50947579-7AAF5D1C-E1BA-49C4-BBE5-3174F421B502Q50983278-FE5400DE-BBE2-4BD9-9D35-F522C32FE6D7Q51015600-9DDB7CB2-C142-4AF2-B92C-985DBA642441Q51060404-1C3629D3-5393-419B-B445-77A11A0592F3Q51582725-97DEC5D4-D74F-4164-A599-B79429BF305FQ57212280-7DE4F1C3-02EB-4D3C-9761-AC8167D7333DQ57359416-0936AAF4-80D0-42D9-9E80-248F9C40AFBBQ58063452-D05E11C0-FC61-42D0-94CF-10073C49FD29Q59739080-37A49F81-4878-47BA-8061-6D5E15FEB684Q59739082-FE5656CB-F8FB-46F2-A200-B1499E22231BQ59739098-82B4A86F-1DF3-4D85-9F4F-FBFBD6BE3AA7Q59739106-90830446-9A6A-47FA-B73C-6EAE45DD4987Q59739114-4B8C6896-A749-441E-95BC-1D526D20D202Q59739122-0DD582A6-92C1-47AE-881A-8D6A884504C3Q59909663-89AECB22-5B62-4FBB-B5C9-61721F4F0910Q59909715-6EAE1EE9-730C-47C1-8DA9-29EF20CF6C44Q84363332-6A89064B-108F-467A-A1F6-1B740A493920Q88513490-2F71FF7E-8603-418A-A4E6-2849536EEC5BQ88971381-3C7FB455-0EF8-4F9D-B5B0-7605E4896DCCQ90301618-D113613D-1578-4421-9751-949582EFC7E5
P50
description
researcher ORCID ID = 0000-0003-3170-7220
@en
wetenschapper
@nl
name
Wen-Chang Chen
@ast
Wen-Chang Chen
@en
Wen-Chang Chen
@es
Wen-Chang Chen
@nl
type
label
Wen-Chang Chen
@ast
Wen-Chang Chen
@en
Wen-Chang Chen
@es
Wen-Chang Chen
@nl
prefLabel
Wen-Chang Chen
@ast
Wen-Chang Chen
@en
Wen-Chang Chen
@es
Wen-Chang Chen
@nl
P1153
23979570300
P31
P496
0000-0003-3170-7220