about
Light-powered, artificial molecular pumps: a minimalistic approachA Focus on Triazolium as a Multipurpose Molecular Station for pH-Sensitive Interlocked Crown-Ether-Based Molecular MachinesArtificial Molecular MachinesChallenges and breakthroughs in recent research on self-assemblyMaking molecular machines workRadical-cation dimerization overwhelms inclusion in [N]pseudorotaxanes.Chemically controlled self-assembly of [2]pseudorotaxanes based on 1,2-bis(benzimidazolium)ethane cations and 24-crown-8 macrocycles.Photo-driven molecular devices.Rise of the nanomachine: the evolution of a revolution in medicine.An Artificial Molecular Transporter.Multivalency as a chemical organization and action principle.Recent advances towards azobenzene-based light-driven real-time information-transmitting materialsFunctional interlocked systems.Ferrocene-containing non-interlocked molecular machines.Multicavity macrocyclic hosts.Efficient Self-Assembly of Di-, Tri-, Tetra-, and Hexavalent Hosts with Predefined Geometries for the Investigation of Multivalency.Coupled molecular switching processes in ordered mono- and multilayers of stimulus-responsive rotaxanes on gold surfaces.First principle investigation of the linker length effects on the thermodynamics of divalent pseudorotaxanes.Synthesis of multivalent host and guest molecules for the construction of multithreaded diamide pseudorotaxanes.E pluribus unum: isolation, structure determination, network analysis and DFT studies of a single metastable structure from a shapeshifting mixture of 852 bullvalene structural isomers.Fluorescence modulation in tribranched switchable [4]rotaxanes.Remote electrochemical modulation of pKa in a rotaxane by co-conformational allostery.Investigation of monovalent and bivalent enantioselective molecular recognition by electrospray ionization-mass spectrometry and tandem mass spectrometry.A design strategy for motion control systems with identical binding sites.Conformational analysis and UV/Vis spectroscopic properties of a rotaxane-based molecular machine in acetonitrile dilute solution: when simulations meet experiments.Dynamic Molecular Invasion into a Multiply Interlocked Catenane.Making and Operating Molecular Machines: A Multidisciplinary Challenge.Colorimetric and luminescent bifunctional Ru(II) complexes for rapid and highly sensitive recognition of cyanide.Energy transfer and concentration-dependent conformational modulation: a porphyrin-containing [3]rotaxane.Allosteric and Chelate Cooperativity in Divalent Crown Ether/Ammonium Complexes with Strong Binding Enhancement.Theoretical and experimental investigation of crown/ammonium complexes in solution.Assembly of Multi-Phthalocyanines on a Porphyrin Template by Fourfold Rotaxane Formation.Five-state molecular switching of a [3]rotaxane in response to weak and strong acid and base stimuli.Molecular, Supramolecular, and Macromolecular Motors and Artificial MusclesA switchable [2]rotaxane with two active alkenyl groupsSyntheses of dibenzo-18-crown-6 lariat isomers and their complexation with lanthanoid nitratesLuminescent Carbonyl Hydrido Ruthenium(II) Diimine Coordination Compounds: Structural, Photophysical, and Electrochemical Properties
P2860
Q26776004-07FD105E-F658-4866-A711-F386FFEA8B57Q26780526-CA81DAA3-E943-4301-ABE3-6CF92E279586Q26783064-081E4F28-3E75-458B-B005-DC19DA9825E6Q28279677-5EDCB9F9-DAEE-4058-A6AC-4AE8D81AAD44Q29302602-467DEF39-69ED-48AA-ACC9-B4083224143FQ30815832-3F6CDD94-BC9B-4D96-8BB6-2AC5ECDDBA22Q31117646-C7B6EE26-B2C1-4CD9-ADE9-7DBB5880A0ACQ36685913-B5656417-C8E3-46DD-8255-A2A5CE4EF405Q36917938-77DE39C0-1186-4D27-B3E6-690EA6B5EC78Q37000765-BC73F32B-BAAC-4C1F-A284-1B48B9733376Q38041060-F10727C5-8B95-44AB-A097-44608DC52171Q38047282-E4FE43B9-EA6E-49A7-908A-DC7A74F7C2F8Q38144664-F253F533-9D28-4633-BB80-D4C32767069AQ38688208-5E4533AF-8984-4088-956F-FAA394A19389Q38927506-9D139D7C-B791-405B-9A52-954D6A19AEE7Q38981693-2944E872-53BF-4006-B1F7-5609D646BDC5Q39982982-F6DE13C1-5F92-4E4A-AB6B-9E5DE6022F89Q42525823-EEE9FABB-F5CB-43AF-9D4D-5D9A8F7BF38BQ42584440-DA1652E5-FE6A-451A-8F5F-83DFD5F9209FQ43789115-7339784D-F945-4C6F-B660-4917C7D92057Q46077535-4CD4B086-EAE7-4919-83C1-C383B282F9F0Q46237112-258311DA-325A-4538-93B0-C6919B6939BFQ46436609-EF31CA97-2FCE-4ABE-9C00-60C47B66ADA9Q46589017-E6B2C5F9-EEE4-4034-9A0C-102202906536Q47402209-575F3D40-6563-4351-A833-C0A28A22D3D7Q48341386-1B40B66B-EC35-4FC5-9BB6-FD7D1A3AE1E8Q49882701-DB30C8C3-ADCE-484B-8F14-14AC89C8450CQ50426595-B5DDF57B-6921-40C5-9D4E-6C7FD2980359Q50507145-64F4087B-9D82-4BA3-8294-C2357F017ECCQ52847794-E652012D-58E1-411C-B073-F23204A0311CQ52867732-79A383A6-D6A2-4D72-B78C-26C965121419Q52991499-6C621EFF-70C0-4EED-9644-574DCFCDDD13Q53676564-66034CBE-E60C-4F97-AB0B-3179DC779507Q57536234-D3AAD8B2-5335-418D-A95F-13E1BE0A0D39Q58795064-8013ED80-3830-4EFF-B2B5-4C634E39EE78Q58875474-6012A932-5CA1-41B2-A309-B6D052B48B0FQ59165507-3D75A8C4-DE73-4937-A895-72054C9501B9
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
2006年學術文章
@zh-hant
name
Operating molecular elevators.
@en
Operating molecular elevators.
@nl
type
label
Operating molecular elevators.
@en
Operating molecular elevators.
@nl
prefLabel
Operating molecular elevators.
@en
Operating molecular elevators.
@nl
P2093
P50
P356
P1476
Operating molecular elevators
@en
P2093
Alberto Credi
Célia M Ronconi
Jovica D Badjic
P304
P356
10.1021/JA0543954
P407
P577
2006-02-01T00:00:00Z