A high-mobility electron-transporting polymer for printed transistors
about
Machine Learning Strategy for Accelerated Design of Polymer Dielectrics.Macroscopic and high-throughput printing of aligned nanostructured polymer semiconductors for MHz large-area electronics.Control of charge transport in a semiconducting copolymer by solvent-induced long-range order.Personal electronics printing via tapping mode composite liquid metal ink delivery and adhesion mechanism.Molecular and electronic-structure basis of the ambipolar behavior of naphthalimide-terthiophene derivatives: implementation in organic field-effect transistors.Understanding Solidification of Polythiophene Thin Films during Spin-Coating: Effects of Spin-Coating Time and Processing AdditivesToward electron-deficient pyrene derivatives: construction of pyrene tetracarboxylic diimide containing five-membered imide rings.Crystallisation-enhanced bulk hole mobility in phenothiazine-based organic semiconductors.Injection-modulated polarity conversion by charge carrier density control via a self-assembled monolayer for all-solution-processed organic field-effect transistors.Dynamic-template-directed multiscale assembly for large-area coating of highly-aligned conjugated polymer thin filmsRational design of ambipolar organic semiconductors: is core planarity central to ambipolarity in thiophene-naphthalene semiconductors?Effect of UV/ozone treatment on polystyrene dielectric and its application on organic field-effect transistors.Fluorene-based macromolecular nanostructures and nanomaterials for organic (opto)electronics.Outlook and emerging semiconducting materials for ambipolar transistors.Excellent spin transport in spin valves based on the conjugated polymer with high carrier mobility.Knitting up 2,7-disubstituted carbazole based oligomers through supramolecular interactions for their application in organic thin film transistors.Amorphous oxide alloys as interfacial layers with broadly tunable electronic structures for organic photovoltaic cells.Conductance of a single flexible molecular wire composed of alternating donor and acceptor units.Experimental evidence that short-range intermolecular aggregation is sufficient for efficient charge transport in conjugated polymers"Capillary-Bridge Lithography" for Patterning Organic Crystals toward Mode-Tunable Microlaser Arrays.Flexible, highly efficient all-polymer solar cells.Ultra-high gain diffusion-driven organic transistor.Solution-Processed Donor-Acceptor Polymer Nanowire Network Semiconductors For High-Performance Field-Effect TransistorsChain conformations dictate multiscale charge transport phenomena in disordered semiconducting polymersN-type organic electrochemical transistors with stability in water.Electrical/optical dual-function redox potential transistorOptically transparent semiconducting polymer nanonetwork for flexible and transparent electronics.Supramolecular n/p-heterojunction photosystems with oriented multicolored antiparallel redox gradients (OMARG-SHJs).Side-chain modulation of dithienofluorene-based copolymers to achieve high field-effect mobilities.Simultaneous Improvement of Hole and Electron Injection in Organic Field-effect Transistors by Conjugated Polymer-wrapped Carbon Nanotube Interlayers.Pi-conjugated molecules with fused rings for organic field-effect transistors: design, synthesis and applications.Recent progress in n-channel organic thin-film transistors.Electron transporting semiconducting polymers in organic electronics.Paper electronics.Dual-gate thin-film transistors, integrated circuits and sensors.Recent advances in inkjet dispensing technologies: applications in drug discovery.Multi-functional integration of organic field-effect transistors (OFETs): advances and perspectives.Electric-double-layer field-effect transistors with ionic liquids.Toward printed integrated circuits based on unipolar or ambipolar polymer semiconductors.Polymers for electronics and spintronics.
P2860
Q30384472-5CB93920-E104-4E1D-B0E5-01FAB99F2406Q30400843-B1B364C2-2BC4-480B-A270-D1C3E6C5CCC9Q30446266-F0BE141D-3727-4A28-9599-57224439F8E3Q30575432-AFCCD52E-77BB-4D37-8937-BB350503F4BAQ30657817-EC652111-EDC5-4FB6-A786-48B077E5705CQ30662259-CDA686D8-BBF6-4F2F-B833-675853DA7E5FQ30979256-4F994646-E2AD-43F8-90FD-D76685625BE4Q33555545-11E32C97-60A7-4F5E-96D4-2BC8E3722B59Q33556934-D5BA4829-79F3-441B-B85E-4DE231244108Q33906392-79D6EBE0-468F-4538-B648-BA703CAC8D1CQ34097317-A0D12891-D8E4-4B07-9497-31B0DFE1FBC6Q34182451-D4881D96-C619-4202-B5BA-062D9008AD34Q34977503-5C7921C9-5511-4E3F-BAC5-18D8F9D82DFCQ35109845-BD34FB72-A02B-48C8-AE50-3BDCA5C1E6EBQ35206350-CF06867C-89F1-4C8B-95E3-47C9386EA957Q35544934-774A16A0-2743-4ECD-A8D3-3801FE9A1367Q35818820-8F6B9A1F-B1BC-493D-BB6A-EBDB21AD9502Q35864991-3C702398-745F-40DA-9D1C-86F838203F81Q36008335-6769FB46-B040-4AB8-B13E-CD78491738FDQ36181121-B5618568-8FE8-486F-8EA3-27AB08DB19FEQ36250400-07471815-149E-4E28-8DCB-911B04A52916Q36541289-B248805A-77E2-4C91-9C6D-48B3FC0891ACQ36810106-20FB9D42-D2AC-48D9-A674-94660D1741E5Q37236510-E3F2A642-4F37-4C6F-930A-EA2637D743AFQ37330794-9E3F2130-7B44-4A70-B7AF-E13BEA22404CQ37369613-4AA8EF4F-D13F-47EE-B35C-B42016C5668CQ37514944-8B0B9F21-CA65-4C8A-847D-87990E70C452Q37659953-8DEFEE04-F02F-46ED-8CDC-4ACC8E6B5C61Q37733935-D45719FC-0026-4EC3-8032-1F1C8D314421Q37734468-55D307A2-3910-4963-BB63-70900E649802Q37737083-59F395BB-4B07-45A0-9586-77821A46A1ABQ37741133-20463797-C701-4A6C-8801-8CBC18104096Q37853417-A55862E5-3E91-4CCD-A2BA-3D199BC43393Q37857067-55760902-3200-4165-B207-5EE07E0301A5Q37889242-59265946-F89B-4F29-A163-B612BE8B2094Q38020878-6A162D61-F1AC-4F09-B4C2-7DDE6E723A04Q38032262-1FF283E3-FEE7-4C31-8E27-FE5913CA95CEQ38105885-14D9BC7E-AC0F-4F51-9E3B-090CDC9A3777Q38114006-E8CCD0A7-E03F-4887-A414-480160B9237EQ38137004-339CB632-F79C-4262-AE97-9557AF9E9A71
P2860
A high-mobility electron-transporting polymer for printed transistors
description
article publié dans la revue scientifique Nature
@fr
scientific article published in Nature
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в Nature в січні 2009
@uk
name
A high-mobility electron-transporting polymer for printed transistors
@en
A high-mobility electron-transporting polymer for printed transistors
@nl
type
label
A high-mobility electron-transporting polymer for printed transistors
@en
A high-mobility electron-transporting polymer for printed transistors
@nl
prefLabel
A high-mobility electron-transporting polymer for printed transistors
@en
A high-mobility electron-transporting polymer for printed transistors
@nl
P2093
P356
P1433
P1476
A high-mobility electron-transporting polymer for printed transistors
@en
P2093
Antonio Facchetti
Christopher Newman
Florian Dötz
Jordan R Quinn
Marcel Kastler
Zhihua Chen
P2888
P304
P356
10.1038/NATURE07727
P407
P50
P577
2009-01-21T00:00:00Z
P6179
1021987958