about
Mechanochromic luminescence and aggregation induced emission for a metal-free β-diketone.Development and application of multiple-probe scanning probe microscopes.Yield strength of glued Langmuir-Blodgett films determined by friction force microscopy.Enhanced luminescence of CaMoO₄:Eu by core@shell formation and its hyperthermia study after hybrid formation with Fe₃O₄: cytotoxicity assessment on human liver cancer cells and mesenchymal stem cells.Light-Mediated Manufacture and Manipulation of Actuators.Paradigm shift from self-assembly to commanded assembly of functional materials: recent examples in porphyrin/fullerene supramolecular systems.Enzyme nanoarchitectonics: organization and device application.Self-assembly of semiconductor/insulator interfaces in one-step spin-coating: a versatile approach for organic field-effect transistors.25th anniversary article: reversible and adaptive functional supramolecular materials: "noncovalent interaction" matters.25th anniversary article: what can be done with the Langmuir-Blodgett method? Recent developments and its critical role in materials science.Polymeric Thin Films for Organic Electronics: Properties and Adaptive Structures.Solid surface vs. liquid surface: nanoarchitectonics, molecular machines, and DNA origami.Artificial Molecular Machine Immobilized Surfaces: A New Platform To Construct Functional Materials.Bidirectional Photomodulation of Surface Tension in Langmuir Films.Dynamically Tunable Cell Culture Platforms for Tissue Engineering and Mechanobiology.Hydrogen-bond-driven 'homogeneous intercalation' for rapid, reversible, and ultra-precise actuation of layered clay nanosheets.Twisted D-π-A solid emitters: efficient emission and high contrast mechanochromism.Mechanical stimulation and solid seeding trigger single-crystal-to-single-crystal molecular domino transformations.Amphiphile nanoarchitectonics: from basic physical chemistry to advanced applications.Multi-functional bis(alkynyl)gold(iii) N⁁C complexes with distinct mechanochromic luminescence and electroluminescence properties.A supramolecular assembly based on an engineered hemoprotein exhibiting a thermal stimulus-driven conversion to a new distinct supramolecular structure.Polyelectrolyte multilayer-cushioned fluid lipid bilayers: a parachute model.Platinum(II) Metallomesogens: New External-Stimuli-Responsive Photoluminescence Materials.Dynamic Phosphorescent Probe for Facile and Reversible Stress Sensing.Nanoarchitectonics from Molecular Units to Living-Creature-Like Motifs.Reversible biomechano-responsive surface based on green fluorescent protein genetically modified with unnatural amino acids.Thermal or mechanical stimuli-induced photoluminescence color change of a molecular assembly composed of an amphiphilic anthracene derivative in water.Stimuli-responsive folding and unfolding of a polymer bearing multiple cerium(IV) bis(porphyrinate) joints: mechano-imitation of the action of a folding ruler.Aggregation-induced emission rotors: rational design and tunable stimuli response.Aggregation-Induced Emission Rotors: Rational Design and Tunable Stimuli Response.Mechanochromic behavior of aryl-substituted buta-1,3-diene derivatives with aggregation enhanced emission.Mechanochromic luminescence of copper iodide clusters.A chloride capturing system via proton-induced structure transformation between opened- and closed-forms of dodecavanadates.Unique piezochromic fluorescence behavior of dicyanodistyrylbenzene based donor-acceptor-donor triad: mechanically controlled photo-induced electron transfer (eT) in molecular assemblies.Highlights from the latest articles in technical and technological advancements in nanotherapeutics.Electrostatic Mechanophores in Tuneable Light-Emitting Piezopolymer Nanowires.Regulating the piezofluorochromism of 9,10-bis(butoxystyryl)anthracenes by isomerization of butyl groups.Polymorphism as an emerging design strategy for high performance organic electronicsSmart Portable Devices Suitable for Cultural Heritage: A ReviewMaterials self-assembly and fabrication in confined spaces
P2860
Q30300896-F6C2ABD2-709D-4BEF-8838-DA8300A4501BQ34179610-736C9256-7223-4FA0-A231-45B1E7FF7608Q34817902-319C4313-B757-4FB5-9906-1BA09A3919C7Q35056249-C603E003-9B10-4180-A218-379CD9ECC237Q36082164-9E62F754-5D1D-44EA-B115-74FF83267387Q37399732-7730505F-F474-4E04-9813-E750EDAC85B9Q38076649-7EF75025-AB31-475A-8E54-432117D0D9ADQ38094959-3FCF456C-F4B5-456F-BE69-B2253D8C0495Q38137885-B0BF1DD0-E0A2-473B-9D1A-CB284A90C2C3Q38168492-AC63E8DF-AAF2-4C70-BF86-FF7FCD8D4A75Q38624081-734CAB62-0BF7-4220-BF2D-5445E94430B7Q38662155-FB102813-7B2E-4750-A50D-823B77B6A82BQ38683092-583B852B-225C-4EE9-B5BA-880C6B170618Q39102443-16F62ED3-D44F-4FA6-90E9-73329EF314FBQ39316740-89B1742A-6514-4096-A208-3CF56D3A1CDAQ43685064-4648A538-79CA-46FF-9834-9235E5543FBDQ44320607-8E66FC7C-F752-4A05-91A3-E4E4B09B2B95Q45016177-163799C4-44FA-4637-994F-DE58EA021BCDQ46804711-B9D66CD0-169C-4469-B1EF-AD1879CCC55CQ47095010-E67349C8-87BD-4711-860A-EFE6817FBB02Q48027010-716EE162-51F7-4EF4-B865-56529E1DED19Q48122140-4CDD035D-F8B5-4055-9C9F-7FEC0993B6DAQ48209694-DA7456B3-222E-4852-B06B-43CFAA6EE1D6Q48566123-88E24055-91C2-41DA-AAAE-2EAD12DEAF20Q48581174-EAEC71BE-2A2E-466B-8ED9-724A412A03EEQ50445782-64F7D3AE-3136-43BA-8985-41088236A088Q50452712-9E6F833C-786F-404C-AA4D-ABD0A3C1A689Q50500284-09F139F8-38C1-4EA9-8AAC-5D7A15245E61Q51036602-19DAFF61-5998-4690-B3DC-474AB1400C03Q51037083-47F740FE-A7A8-4131-BD67-3CD584D53D3BQ51075305-E55F83BC-37AF-4F60-B0BF-E5F04816083DQ52658029-CB25FE99-6791-4D63-9BED-482F9C8485D0Q53115279-36F1951E-C37E-41BF-A8E2-C56A64034618Q53147349-21BE6206-B05F-4B59-86C2-91263A468D9FQ53248613-144DC3C2-990D-48FF-A640-DE10C75E9EE9Q53252863-B4822BE9-D9C6-411E-B654-306797D24776Q53328866-CB68DCC7-AF9E-4AC0-BC5F-0FA81225A993Q56813262-A12EEC44-B112-41B9-A30E-AEE9F8BD2A58Q57103087-636894E8-59E8-443F-AAC2-77186481F56AQ57364166-7463836B-0083-4AB4-8E64-EDE543156D69
P2860
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
2011年论文
@zh
2011年论文
@zh-cn
name
Mechanical control of nanomaterials and nanosystems.
@en
type
label
Mechanical control of nanomaterials and nanosystems.
@en
prefLabel
Mechanical control of nanomaterials and nanosystems.
@en
P2860
P356
P1433
P1476
Mechanical control of nanomaterials and nanosystems.
@en
P2093
Taizo Mori
P2860
P304
P356
10.1002/ADMA.201102617
P407
P577
2011-09-27T00:00:00Z