about
Unidirectional molecular motor on a gold surfaceChemical consequences of mechanical bonding in catenanes and rotaxanes: isomerism, modification, catalysis and molecular machines for synthesisAggregation-induced emission behavior of a pH-controlled molecular shuttle based on a tetraphenylethene moiety.Electrostatic barriers in rotaxanes and pseudorotaxanes.Artificial Molecular Machines.Efficient production of [n]rotaxanes by using template-directed clipping reactions.Photo-driven molecular devices.Biological and biomimetic molecular machines.QnAs with Fraser Stoddart.Supramolecular assembly/reassembly processes: molecular motors and dynamers operating at surfaces.High hopes: can molecular electronics realise its potential?Light to investigate (read) and operate (write) molecular devices and machines.Solid surface vs. liquid surface: nanoarchitectonics, molecular machines, and DNA origami.Wholly Synthetic Molecular Machines.Materials learning from life: concepts for active, adaptive and autonomous molecular systems.Understanding Surface and Interfacial Chemistry in Functional Nanomaterials via Solid-State NMR.Mastering the non-equilibrium assembly and operation of molecular machines.Artificial molecular motors.Surveying macrocyclic chemistry: from flexible crown ethers to rigid cyclophanes.How molecular motors work - insights from the molecular machinist's toolbox: the Nobel prize in Chemistry 2016.Covalent functionalization of dipole-modulating molecules on trilayer graphene: an avenue for graphene-interfaced molecular machines.Light operated molecular machines.A unidirectional open-close mechanism of metal-ion-driven molecular hinges with adjustable amplitude.Thermodynamic forecasting of mechanically interlocked switches.General mechanism for inchworm nanoscale track walkers: analytical theory and realistic simulation.Reversible mechanical protection: building a 3D "suit" around a T-shaped benzimidazole axle.Impact of mechanical bonding on the redox-switching of tetrathiafulvalene in crown ether-ammonium [2]rotaxanes.Bistable or oscillating state depending on station and temperature in three-station glycorotaxane molecular machines.Rise of the Molecular Machines.Induced-fit binding of pi-electron-donor substrates to macrocyclic aromatic ether imide sulfones: a versatile approach to molecular assembly.Evaluation of weak interactions in [2]pseudorotaxanes.Spin state modulation of iron spin crossover complexes via hydrogen-bonding self-assembly.A metal-organic framework replete with ordered donor-acceptor catenanes.Autonomous propulsion of carbon nanotubes powered by a multienzyme ensemble.Molecular photoswitches mediating the strain-driven disassembly of supramolecular tubules.Artificial muscle-like function from hierarchical supramolecular assembly of photoresponsive molecular motors.Selective synthesis of iridium(iii)-derived molecular Borromean rings, [2]catenane and ring-in-ring macrocycles via coordination-driven self-assembly.A Cucurbit[7]uril Based Molecular Shuttle Encoded by Visible Room-Temperature Phosphorescence.Pseudorotaxane capped mesoporous silica nanoparticles for 3,4-methylenedioxymethamphetamine (MDMA) detection in water.A pH-Dependent, Mechanically Interlocked Switch: Organometallic [2]Rotaxane vs. Organic [3]Rotaxane.
P2860
Q27104079-38FB0155-DAEC-471A-8B2B-1E7B62638D2EQ29040277-957A5B3D-C948-4BF9-9FD4-D89FC06654F9Q30987901-38D181C3-2154-4DEC-8F8F-64EA4392FE7BQ33875409-9D37392B-F6B7-45C8-BF9B-024761C7FE86Q34089221-D79C6F28-C06E-47DE-8F15-17A99CFEA5D6Q36141338-1937C082-CFD7-4407-969E-C91253519D4DQ36685913-2931E64D-9B43-41DA-8432-665F7FD79DD5Q37130509-1B02EF9F-FB8E-4E10-BAAC-CED6FAC7F30DQ37589861-202776BB-65AF-4CBB-BAEF-267BAD20BFC9Q37847062-FE0B39A2-CE6F-4E0B-8AC8-280527DECD9DQ38014727-8F9FDD9B-FEB7-406E-9045-816E411D71BCQ38192910-C2EDE457-37F8-4F1F-A302-FCB0C7ECF916Q38662155-3D74CEC1-2D37-41E4-BF63-36508D86ED12Q38718952-CCD52621-0CF9-4AC3-BD55-D760680C0629Q39108934-6C57ECB8-2A11-45F3-9DE9-5DA727DB7D7AQ39155973-ED0E2569-14C9-4E7D-A5DF-4958C437A9AEQ39198172-870BC58D-D3FB-40C1-B1DB-F0D996393446Q39251922-2206E95D-E898-4EFD-8E4C-CE6592C72126Q39277880-773C58A4-156C-473F-BE13-A1C47EE53E76Q39345217-F5BD44B4-BD48-4F42-8CE4-8FFE0EBA7B1FQ39411869-64E42027-EE14-431E-B9B7-697E9C6ECB4BQ39808771-F1E771EC-CD46-421D-939C-B1BFAD8B6623Q39933226-8E6CACBE-6590-4EEE-ADF6-34686996CBACQ39938526-CD43F7F2-B0AE-435F-8FB4-858CCC0220DEQ40197091-F3DFDFA7-6764-40C3-80BD-6911DFF1AF23Q42211345-09C79F97-DCF0-4235-B7D7-3BD217752210Q42279081-9372842B-91F9-4845-909A-4D2F70633DDBQ42979654-D43E2C2B-19C8-4025-9E50-6EFA7F718AD6Q43042696-E3402B02-A656-43B4-A9B8-E8E04E654A5CQ43235853-3AAA8927-8329-46BC-B322-CA9691F931ADQ43524780-B02B4224-990D-4BC7-809B-23270743716DQ43545327-B5F26351-1B24-4D26-9C81-71DF58B5FC61Q46556562-0EE273F8-7542-42D4-9500-F7B460F13937Q46691426-618ACAA6-E0F7-4D14-A863-E342DCDE29ACQ47566367-FC91E5D6-3917-4015-919E-5DC7452DD3EFQ47705244-F51E64CA-2DFD-4D07-A64E-A3C46B470390Q48051916-00A5A2B6-0AF3-4631-AD8F-3D22774245FDQ48107518-D30917C8-6B72-4B6B-AF27-154866544038Q48135841-01C3B1F9-5B11-4989-A660-AB5D6DB23F92Q48167866-F08BEF6D-C20C-4843-8728-E204DAC71F5F
P2860
description
im Juni 1991 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в червні 1991
@uk
name
A molecular shuttle
@en
A molecular shuttle
@nl
type
label
A molecular shuttle
@en
A molecular shuttle
@nl
prefLabel
A molecular shuttle
@en
A molecular shuttle
@nl
P356
P1476
A molecular shuttle
@en
P2093
Neil Spencer
Pier Lucio Anelli
P304
P356
10.1021/JA00013A096
P407
P577
1991-06-01T00:00:00Z