Your search keyword '"UNIDIRECTIONAL ROTARY MOTION"' showing total 20 results

1. Molecular Motors in Aqueous Environment

Author

Filippo Tosi, Wiktor Szymanski, Anouk S. Lubbe, Christian Bohmer, Ben L. Feringa, Synthetic Organic Chemistry, and ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE)

Subjects

Models, Molecular, ANTIBACTERIAL ACTIVITY, Molecular Conformation, Cellular level, 010402 general chemistry, Smart material, 01 natural sciences, Micelle, AZOBENZENE PHOTOSWITCHES, Biomimetic Materials, PHOTOSWITCHABLE INHIBITORS, Molecular motor, SINGLE STEREOGENIC CENTER, Nanobiotechnology, THERMAL HELIX INVERSION, PROTEASOME INHIBITORS, UNIDIRECTIONAL ROTARY MOTION, Aqueous solution, Artificial cell, SECONDARY STRUCTURE, 010405 organic chemistry, Chemistry, Molecular Motor Proteins, Organic Chemistry, Water, Molecular machine, 0104 chemical sciences, Solubility, Chemical physics, STRUCTURAL MODIFICATION, REVERSIBLE PHOTOREGULATION

Abstract

Molecular motors are Nature's solution for (supra)molecular transport and muscle functioning and are involved in most forms of directional motion at the cellular level. Their synthetic counterparts have also found a myriad of applications, ranging from molecular machines and smart materials to catalysis and anion transport. Although light-driven rotary molecular motors are likely to be suitable for use in an artificial cell, as well as in bionanotechnology, thus far they are not readily applied under physiological conditions. This results mainly from their inherently aromatic core structure, which makes them insoluble in aqueous solution. Here, the study of the dynamic behavior of these motors in biologically relevant media is described. Two molecular motors were equipped with solubilizing substituents and studied in aqueous solutions. Additionally, the behavior of a previously reported molecular motor was studied in micelles, as a model system for the biologically relevant confined environment. Design principles were established for molecular motors in these media, and insights are given into pH-dependent behavior. The work presented herein may provide a basis for the application of the remarkable properties of molecular motors in more advanced biohybrid systems.

Published

2018

2. Artificial molecular motors

Subjects

DNA WALKER, OVERCROWDED ALKENES, SYNTHETIC SMALL-MOLECULE, SINGLE STEREOGENIC CENTER, BOND ROTATION, INFORMATION RATCHET, VISIBLE-LIGHT, DRIVEN, STRUCTURAL MODIFICATION, UNIDIRECTIONAL ROTARY MOTION

Abstract

Motor proteins are nature's solution for directing movement at the molecular level. The field of artificial molecular motors takes inspiration from these tiny but powerful machines. Although directional motion on the nanoscale performed by synthetic molecular machines is a relatively new development, significant advances have been made. In this review an overview is given of the principal designs of artificial molecular motors and their modes of operation. Although synthetic molecular motors have also found widespread application as (multistate) switches, we focus on the control of directional movement, both at the molecular scale and at larger magnitudes. We identify some key challenges remaining in the field.

Published

2017

3. Ultrafast Excited State Dynamics in Molecular Motors

Author

Stephen R. Meech, Sergey P. Laptenok, Jiawen Chen, Jamie Conyard, Sophie McDonagh, Peter Štacko, Christopher R. Hall, Ben L. Feringa, Wesley R. Browne, Synthetic Organic Chemistry, Molecular Inorganic Chemistry, and ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE)

Subjects

Work (thermodynamics), SURFACE, PHOTOCHEMICAL ISOMERIZATION, FREQUENCY-DEPENDENT FRICTION, 010402 general chemistry, Photochemistry, Rotation, DONOR, 01 natural sciences, Molecular physics, Viscosity, PI-CONJUGATION, Metastability, PHOTOISOMERIZATION, Molecular motor, Physical and Theoretical Chemistry, UNIDIRECTIONAL ROTARY MOTION, 010405 organic chemistry, Chemistry, Relaxation (NMR), Rotation around a fixed axis, DRIVEN, 0104 chemical sciences, Excited state, ROTATION, STRUCTURAL MODIFICATION

Abstract

Photochemically driven molecular motors convert the energy of incident radiation to intramolecular rotational motion. The motor molecules considered here execute four step unidirectional rotational motion. This comprises a pair of successive light induced isomerizations to a metastable state followed by thermal helix inversions. The internal rotation of a large molecular unit required in these steps is expected to be sensitive to both the viscosity of the medium and the volume of the rotating unit. In this work, we describe a study of motor motion in both ground and excited states as a function of the size of the rotating units. The excited state decay is ultrafast, highly non-single exponential, and is best described by a sum of three exponential relaxation components. The average excited state decay time observed for a series of motors with substituents of increasing volume was determined. While substitution does affect the lifetime, the size of the substituent has only a minor effect. The solvent polarity dependence is also slight, but there is a significant solvent viscosity effect. Increasing the viscosity has no effect on the fastest of the three decay components, but it does lengthen the two slower decay times, consistent with them being associated with motion along an intramolecular coordinate displacing a large solvent volume. However, these slower relaxation times are again not a function of the size of the substituent. We conclude that excited state decay arises from motion along a coordinate which does not necessarily require complete rotation of the substituents through the solvent, but is instead more localized in the core structure of the motor. The decay of the metastable state to the ground state through a helix inversion occurs 14 orders of magnitude more slowly than the excited state decay, and was measured as a function of substituent size, solvent viscosity and temperature. In this case neither substituent size nor solvent viscosity influences the rate, which is entirely determined by the activation barrier. This result is different to similar studies of an earlier generation of molecular motors, which suggests different microscopic mechanisms are in operation in the different generations. Finally, the rate of photochemical isomerization was studied for the series of motors, and those with the largest volume substituents showed the highest photochemical cross section.

Published

2017

4. Artificial Molecular Motors

Author

Anouk S. Lubbe, Salma Kassem, Thomas van Leeuwen, Ben L. Feringa, David A. Leigh, and Miriam R. Wilson

Subjects

010405 organic chemistry, Chemistry, OVERCROWDED ALKENES, SYNTHETIC SMALL-MOLECULE, BOND ROTATION, INFORMATION RATCHET, DNA walker, Nanotechnology, Control engineering, General Chemistry, DRIVEN, 010402 general chemistry, 01 natural sciences, Molecular machine, Field (computer science), 0104 chemical sciences, Synthetic molecular motor, DNA WALKER, Molecular level, Molecular motor, SINGLE STEREOGENIC CENTER, VISIBLE-LIGHT, STRUCTURAL MODIFICATION, UNIDIRECTIONAL ROTARY MOTION

Abstract

Motor proteins are nature's solution for directing movement at the molecular level. The field of artificial molecular motors takes inspiration from these tiny but powerful machines. Although directional motion on the nanoscale performed by synthetic molecular machines is a relatively new development, significant advances have been made. In this review an overview is given of the principal designs of artificial molecular motors and their modes of operation. Although synthetic molecular motors have also found widespread application as (multistate) switches, we focus on the control of directional movement, both at the molecular scale and at larger magnitudes. We identify some key challenges remaining in the field.

Published

2017

5. Making molecular machines work

Author

Wesley R. Browne and Ben L. Feringa

Subjects

SURFACE, Elevator, Computer science, Biomedical Engineering, AZOBENZENE MONOLAYER, Bioengineering, Nanotechnology, Molecular nanotechnology, Smart material, Motion (physics), Field (computer science), Brownian motor, Motion, Molecular motor, General Materials Science, Electrical and Electronic Engineering, LINEAR MOTOR-MOLECULES, UNIDIRECTIONAL ROTARY MOTION, AUTONOMOUS MOVEMENT, BROWNIAN MOTOR, Equipment Design, DRIVEN, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Molecular machine, Nanostructures, CATALYTIC NANOMOTORS, LIGHT, Energy Transfer, Systems engineering, STRUCTURAL MODIFICATION

Abstract

In this review we chart recent advances in what is at once an old and very new field of endeavour--the achievement of control of motion at the molecular level including solid-state and surface-mounted rotors, and its natural progression to the development of synthetic molecular machines. Besides a discussion of design principles used to control linear and rotary motion in such molecular systems, this review will address the advances towards the construction of synthetic machines that can perform useful functions. Approaches taken by several research groups to construct wholly synthetic molecular machines and devices are compared. This will be illustrated with molecular rotors, elevators, valves, transporters, muscles and other motor functions used to develop smart materials. The demonstration of molecular machinery is highlighted through recent examples of systems capable of effecting macroscopic movement through concerted molecular motion. Several approaches to illustrate how molecular motor systems have been used to accomplish work are discussed. We will conclude with prospects for future developments in this exciting field of nanotechnology.

Published

2006

6. Making molecular machines work

Subjects

CATALYTIC NANOMOTORS, LIGHT, SURFACE, AUTONOMOUS MOVEMENT, AZOBENZENE MONOLAYER, BROWNIAN MOTOR, DRIVEN, STRUCTURAL MODIFICATION, LINEAR MOTOR-MOLECULES, UNIDIRECTIONAL ROTARY MOTION

Abstract

In this review we chart recent advances in what is at once an old and very new field of endeavour the achievement of control of motion at the molecular level including solid-state and surface-mounted rotors, and its natural progression to the development of synthetic molecular machines. Besides a discussion of design principles used to control linear and rotary motion in such molecular systems, this review will address the advances towards the construction of synthetic machines that can perform useful functions. Approaches taken by several research groups to construct wholly synthetic molecular machines and devices are compared. This will be illustrated with molecular rotors, elevators, valves, transporters, muscles and other motor functions used to develop smart materials. The demonstration of molecular machinery is highlighted through recent examples of systems capable of effecting macroscopic movement through concerted molecular motion. Several approaches to illustrate how molecular motor systems have been used to accomplish work are discussed. We will conclude with prospects for future developments in this exciting field of nanotechnology.

Published

2006

7. Exploring the boundaries of a light-driven molecular motor design

Subjects

CHIRALITY, MUSCLES, SINGLE STEREOGENIC CENTER, ROTOR, COMPLEXES, SWITCHES, MACHINES, GEAR, UNIDIRECTIONAL ROTARY MOTION, TRANSLOCATION

Abstract

Insight in the steric and electronic parameters governing isomerization processes in artificial molecular motors is essential in order to design more advanced motor systems. A subtle balance of steric parameters and the combination of helical and central chirality are key features of light-driven unidirectional rotary molecular motors constructed so far. In an approach to decrease the steric hindrance around the central olefinic bond ( rotary axis) and thereby lowering the energy barrier for helix inversion resulting in an increased rotation rate, the boundaries of our molecular motor design are explored. In a new design of a light-driven molecular motor based on a sterically overcrowded alkene the methyl substituent adjacent to the stereogenic center, which is responsible for the control of the direction of rotation, is shifted one position away from the fjord region of the molecule compared to the second-generation motor systems. In contrast to previously developed light-driven molecular motors, there is a preference for the methyl substituent to adopt a pseudo-equatorial orientation. Nevertheless, this new type of motor is capable of functioning as a rotary molecular motor, albeit not with full unidirectionality. Under the combined influence of light and heat, there is a preferred clockwise rotation of one half of the molecule. Surprisingly, the effect of shifting the methyl substituent on the energy barrier for helix inversion is small and even a slight increase in the barrier is observed.

Published

2004

8. Light-driven molecular motors

Subjects

DESIGN, SINGLE STEREOGENIC CENTER, ROTATION, ROTOR, SPEED, UNIDIRECTIONAL ROTARY MOTION

Abstract

Molecular motors can be defined as molecules that are able to convert any type of energy input (a fuel) into controlled motion. These systems can be categorized into linear and rotary motors, depending on the motion induced. This brief account will discuss the state of affairs of the research on light-driven rotary molecular motors.

Published

2004

9. Molecular stirrers in action

Author

Bernard Feringa, Jiawen Chen, Jort Robertus, Jos C. M. Kistemaker, Synthetic Organic Chemistry, and Stratingh Institute of Chemistry

Subjects

TEMPERATURE DEPENDENCE, Absorption spectroscopy, Light, Rotation, PHOTOCHEMICAL ISOMERIZATION, Entropy, Substituent, Thermodynamics, CIS-TRANS ISOMERIZATION, FREQUENCY-DEPENDENT FRICTION, Kinetic energy, Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Biomimetic Materials, Molecular motor, Organic chemistry, THERMAL-ISOMERIZATION, UNIDIRECTIONAL ROTARY MOTION, VISCOSITY DEPENDENCE, POLAR-SOLVENTS, Chemistry, Viscosity, Molecular Motor Proteins, Rotation around a fixed axis, General Chemistry, Cis trans isomerization, Solvent, Kinetics, STEREOSELECTIVE FORMATION, Proton NMR, Solvents, STRUCTURAL MODIFICATION

Abstract

A series of first-generation light-driven molecular motors with rigid substituents of varying length was synthesized to act as "molecular stirrers". Their rotary motion was studied by H-1 NMR and UV-vis absorption spectroscopy in a variety of solvents with different polarity and viscosity. Quantitative analyses of kinetic and thermodynamic parameters show that the rotary speed is affected by the rigidity of the substituents and the length of the rigid substituents and that the differences in speed are governed by entropy effects. Most pronounced is the effect of solvent viscosity on the rotary motion when long, rigid substituents are present. The alpha values obtained by the free volume model, supported by DFT calculations, demonstrate that during the rotary process of the motor, as the rigid substituent becomes longer, an increased rearranging volume is needed, which leads to enhanced solvent displacement and retardation of the motor.

Published

2014

10. Rotational reorganization of doped cholesteric liquid crystalline films

Author

Rienk Eelkema, Nathalie Katsonis, Javier Vicario, Ben L. Feringa, Dirk J. Broer, Michael M. Pollard, Faculty of Science and Engineering, and Synthetic Organic Chemistry

Subjects

Rotation, Bistability, SURFACE, Surface Properties, MOLECULAR MOTORS, Biochemistry, Catalysis, Condensed Matter::Materials Science, Colloid and Surface Chemistry, Optics, Liquid crystal, Condensed Matter::Superconductivity, Molecular motor, FULGIDE DERIVATIVES, Texture (crystalline), UNIDIRECTIONAL ROTARY MOTION, Fluorenes, Microscopy, Molecular Structure, Condensed matter physics, Dopant, business.industry, Chemistry, Doping, ROTOR, Stereoisomerism, General Chemistry, Orders of magnitude (numbers), DRIVEN, Liquid Crystals, Condensed Matter::Soft Condensed Matter, LIGHT, REVERSIBLE CONTROL, Thermodynamics, Crystallization, business, STRUCTURAL MODIFICATION, Superstructure (condensed matter), SYSTEM

Abstract

In this paper an unprecedented rotational reorganization of cholesteric liquid crystalline films is described. This rotational reorganization results from the conversion of a chiral molecular motor dopant to an isomer with a different helical twisting power, leading to a change in the cholesteric pitch. The direction of this reorganization is correlated to the sign of the change in helical twisting power of the dopant. The rotational reorganization of the liquid crystalline film was used to rotate microscopic objects 4 orders of magnitude larger than the bistable dopants in the film, which shows that molecular motors and switches can perform work. The surface of the doped cholesteric liquid crystalline films was found to possess a regular surface relief, whose periodicity coincides with typical cholesteric polygonal line textures. These surface features originate from the cholesteric superstructure in the liquid crystalline film, which in turn is the result of the presence of the chiral dopant. As such, the presence of the dopant is expressed in these distinct surface structures. A possible mechanism at the origin of the rotational reorganization of liquid crystalline films and the cholesteric surface relief is discussed.

Published

2006

11. In control of chirality, from asymmetric catalysis to nanomachines

Author

Bernard Feringa and Synthetic Organic Chemistry

Subjects

Molecular switch, Stereochemistry, Chemistry, MOLECULAR ROTOR, Enantioselective synthesis, asymmetric catalysis, chirality, Nanotechnology, General Medicine, DRIVEN, ACCELERATION, molecular motors, ENANTIOSELECTIVE CONJUGATE ADDITION, LIGHT, Molecular motor, LIGANDS, HYDROGENATION, GRIGNARD-REAGENTS, Chirality (chemistry), molecular switches, MOTOR, UNIDIRECTIONAL ROTARY MOTION

Abstract

New approaches to achieve control of molecular chirality have enabled the development of methods for asymmetric catalysis and the construction of molecular switches and motors.

Published

2006

12. Exploring the boundaries of a light-driven molecular motor design: new sterically overcrowded alkenes with preferred direction of rotation

Author

van Delden, Richard, ter Wiel, Matthijs, de Jong, Herman, Meetsma, Auke, Feringa, Bernard, Synthetic Organic Chemistry, and Solid State Materials for Electronics

Subjects

CHIRALITY, MUSCLES, SINGLE STEREOGENIC CENTER, ROTOR, COMPLEXES, SWITCHES, MACHINES, GEAR, UNIDIRECTIONAL ROTARY MOTION, TRANSLOCATION

Abstract

Insight in the steric and electronic parameters governing isomerization processes in artificial molecular motors is essential in order to design more advanced motor systems. A subtle balance of steric parameters and the combination of helical and central chirality are key features of light-driven unidirectional rotary molecular motors constructed so far. In an approach to decrease the steric hindrance around the central olefinic bond ( rotary axis) and thereby lowering the energy barrier for helix inversion resulting in an increased rotation rate, the boundaries of our molecular motor design are explored. In a new design of a light-driven molecular motor based on a sterically overcrowded alkene the methyl substituent adjacent to the stereogenic center, which is responsible for the control of the direction of rotation, is shifted one position away from the fjord region of the molecule compared to the second-generation motor systems. In contrast to previously developed light-driven molecular motors, there is a preference for the methyl substituent to adopt a pseudo-equatorial orientation. Nevertheless, this new type of motor is capable of functioning as a rotary molecular motor, albeit not with full unidirectionality. Under the combined influence of light and heat, there is a preferred clockwise rotation of one half of the molecule. Surprisingly, the effect of shifting the methyl substituent on the energy barrier for helix inversion is small and even a slight increase in the barrier is observed.

Published

2004

13. Light-driven molecular motors

Subjects

DESIGN, SINGLE STEREOGENIC CENTER, ROTATION, ROTOR, SPEED, UNIDIRECTIONAL ROTARY MOTION

Abstract

Molecular motors can be defined as molecules that are able to convert any type of energy input (a fuel) into controlled motion. These systems can be categorized into linear and rotary motors, depending on the motion induced. This brief account will discuss the state of affairs of the research on light-driven rotary molecular motors.

Published

2004

14. Light-driven molecular motors

Author

van Delden, RA, Feringa, BL, Kuzmany, H, Fink, J, Mehring, M, Roth, S, and Chemical Biology 2

Subjects

DESIGN, SINGLE STEREOGENIC CENTER, ROTATION, ROTOR, SPEED, UNIDIRECTIONAL ROTARY MOTION

Abstract

Molecular motors can be defined as molecules that are able to convert any type of energy input (a fuel) into controlled motion. These systems can be categorized into linear and rotary motors, depending on the motion induced. This brief account will discuss the state of affairs of the research on light-driven rotary molecular motors.

Published

2004

15. Increased speed of rotation for the smallest light-driven molecular motor

Author

ter Wiel, MKJ, van Delden, RA, Meetsma, A, Delden, Richard A. van, Feringa, Bernard, Chemical Biology 2, Astronomy, Solid State Materials for Electronics, and Synthetic Organic Chemistry

Subjects

Steric effects, chemistry.chemical_classification, Photoisomerization, NOBEL-LECTURE, Chemistry, Alkene, Stereochemistry, ROTOR, General Chemistry, SWITCHES, Ring (chemistry), Biochemistry, Catalysis, Stereocenter, ENERGY, Crystallography, Colloid and Surface Chemistry, CHEMISTRY, Helix, Molecular motor, SINGLE STEREOGENIC CENTER, Molecule, MACHINES, UNIDIRECTIONAL ROTARY MOTION

Abstract

In this paper we present the smallest artificial light-driven molecular motor consisting of only 28 carbon and 24 hydrogen atoms. The concept of controlling directionality of rotary movement at the molecular level by introduction of a stereogenic center next to the central olefinic bond of a sterically overcrowded alkene does not only hold for molecular motors with six-membered rings, but is also applicable to achieve the unidirectional movement for molecular motors having five-membered rings. Although X-ray analyses show that the five-membered rings in the cis- and trans-isomer of the new molecular motor are nearly flat, the energy differences between the (pseudo-)diaxial and (pseudo-)diequatorial conformations of the methyl substituents in both isomers are still large enough to direct the rotation of one-half of the molecule with respect to the other half in a clockwise fashion. The full rotary cycle comprises four consecutive steps: two photochemical isomerizations each followed by a thermal helix inversion. Both photochemical cis-trans isomerizations proceed with a preference for the unstable diequatorial isomers over the stable diaxial isomers. The thermal barriers for helix inversion of this motor molecule have decreased dramatically compared to its six-membered ring analogue, the half-life of the fastest step being only 18 s at room temperature.

Published

2003

16. In control of switching, motion, and organization

Author

Ben L. Feringa, Richard A. van Delden, Matthijs K. J. ter Wiel, Synthetic Organic Chemistry, and Faculty of Science and Engineering

Subjects

General Chemical Engineering, Nanotechnology, MOLECULAR MOTORS, Motion (physics), law.invention, Control theory, law, ALKENES, Molecular motor, SINGLE STEREOGENIC CENTER, MACHINES, SPEED, Control (linguistics), UNIDIRECTIONAL ROTARY MOTION, Molecular switch, Chemistry, Rotor (electric), Rotation around a fixed axis, ROTOR, Control engineering, General Medicine, General Chemistry, Chirality (electromagnetism), CHIRALITY, LIGHT, ROTATION, Rotation (mathematics)

Abstract

Nature’s solutions to control organization, switching, and linear and rotary motion are not only extremely elegant, but fascinating if one considers the design and synthesis of artificial molecular systems with such functions in order to add components to the nanotoolbox. The synthesis of chiroptical molecular switches and their application in the control of the organization of liquid crystalline materials is outlined. The first light-driven unidirectional molecular motor is described, and the second-generation motor as well as approaches to control the speed of the rotary motion are discussed.

Published

2003

17. Controlling the color of cholesteric liquid-crystalline films by photoirradiation of a chiroptical molecular switch used as dopant

Author

Marc B. van Gelder, Bernard Feringa, Richard A. van Delden, R.A.van Delden, Nina P. M. Huck, Npm Huck, Molecular Inorganic Chemistry, Stratingh Institute of Chemistry, Synthetic Organic Chemistry, and Faculty of Science and Engineering

Subjects

Molecular switch, Materials science, Dopant, business.industry, Liquid crystalline, Green is, Doping, Condensed Matter Physics, Photochemistry, COPOLYMERS, PHOTO-OPTICAL PROPERTIES, Electronic, Optical and Magnetic Materials, Biomaterials, Reflection (mathematics), Polymerization, DIACRYLATES, PHOTOISOMERIZATION, Electrochemistry, Optoelectronics, PHOTOSENSITIVE CHIRAL DOPANT, Thin film, AZOBENZENE, business, UNIDIRECTIONAL ROTARY MOTION

Abstract

Using thin films of a cholesteric mixture of acrylates 2 and 3 doped with the chiroptical molecular switch (M)-trans-1, photo-control of the reflection color between red and green is possible. This doped liquid-crystal (LC) film can be used for photoinduced writing, color reading, and photoinduced locking (via polymerization) of chiral, optically written information.

Published

2003

18. Rotational reorganization of doped cholesteric liquid crystalline films

Author

Eelkema, R., M. Pollard, M., Katsonis, N., Vicario, J., J. Broer, D., Feringa, B.L., Eelkema, R., M. Pollard, M., Katsonis, N., Vicario, J., J. Broer, D., and Feringa, B.L.

Abstract

In this paper an unprecedented rotational reorganization of cholesteric liquid crystalline films is described. This rotational reorganization results from the conversion of a chiral molecular motor dopant to an isomer with a different helical twisting power, leading to a change in the cholesteric pitch. The direction of this reorganization is correlated to the sign of the change in helical twisting power of the dopant. The rotational reorganization of the liquid crystalline film was used to rotate microscopic objects 4 orders of magnitude larger than the bistable dopants in the film, which shows that molecular motors and switches can perform work. The surface of the doped cholesteric liquid crystalline films was found to possess a regular surface relief, whose periodicity coincides with typical cholesteric polygonal line textures. These surface features originate from the cholesteric superstructure in the liquid crystalline film, which in turn is the result of the presence of the chiral dopant. As such, the presence of the dopant is expressed in these distinct surface structures. A possible mechanism at the origin of the rotational reorganization of liquid crystalline films and the cholesteric surface relief is discussed.

Published

2006

19. Catalytic molecular motors:fuelling autonomous movement by a surface bound synthetic manganese catalase

Author

Vicario, J, Eelkema, R, Browne, WR, Meetsma, A, Crois, René M. La, Feringa, Bernard, Vicario, J, Eelkema, R, Browne, WR, Meetsma, A, Crois, René M. La, and Feringa, Bernard

Abstract

A molecular approach to the powering of multi-component nano-devices capable of autonomous translational and rotational motion through the conversion of chemical to kinetic energy is reported.

Published

2005

20. Catalytic molecular motors: fuelling autonomous movement by a surface bound synthetic manganese catalase

Author

Ben L. Feringa, Rene M. La Crois, Wesley R. Browne, Rienk Eelkema, Auke Meetsma, Javier Vicario, Molecular Inorganic Chemistry, Stratingh Institute of Chemistry, Synthetic Organic Chemistry, and Solid State Materials for Electronics

Subjects

Models, Molecular, Surface Properties, Chemistry, ROTOR, Metals and Alloys, Rotation around a fixed axis, Nanotechnology, General Chemistry, Catalase, Manganese Catalase, Kinetic energy, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, NANOMOTORS, NANORODS, Chemical physics, Materials Chemistry, Ceramics and Composites, Molecular motor, Microtubule-Associated Proteins, SYSTEM, UNIDIRECTIONAL ROTARY MOTION

Abstract

A molecular approach to the powering of multi-component nano-devices capable of autonomous translational and rotational motion through the conversion of chemical to kinetic energy is reported.

Published

2005