Your search keyword '"Stindt, Charlotte N."' showing total 6 results

1. Activating a light-driven molecular motor by metal complexation

Author

Stindt, Charlotte N., Crespi, Stefano, Toyoda, Ryojun, Hilbers, Michiel F., Kemmink, Johan, van der Meulen, Pieter, Buma, Wybren Jan, Feringa, Ben L., Stindt, Charlotte N., Crespi, Stefano, Toyoda, Ryojun, Hilbers, Michiel F., Kemmink, Johan, van der Meulen, Pieter, Buma, Wybren Jan, and Feringa, Ben L.

Abstract

Designing increasingly complex, responsive, and dynamic molecular systems, whose actions can be controlled by a combination of cooperative stimuli, is a key challenge toward the development of more advanced functional molecular machines. Herein, we report new photochemically driven molecular motors based on a bis(benzoxazole) ligand. Coordination of the ligand to a metal salt leads to the selective in situ activation of a well-defined motor function, which can be deactivated in the presence of a competing ligand. The rotation speed and absorption wavelength are tuned by the choice of metal, allowing unprecedented control of the molecular system. DFT calculations show that the geometry of the metal center influences the rotational barriers and the possibility to couple the rotary motion with the wagging movement at the metal center. The approach presented here will open new avenues toward more complex, dynamic, and coupled systems.

Published

2023

2. Light-Fueled Transformations of a Dynamic Cage-Based Molecular System

Author

Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, Feringa, Ben L., Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, and Feringa, Ben L.

Abstract

In a chemical equilibrium, the formation of high-energy species-in a closed system-is inefficient due to microscopic reversibility. Here, we demonstrate how this restriction can be circumvented by coupling a dynamic equilibrium to a light-induced E/Z isomerization of an azobenzene imine cage. The stable E-cage resists intermolecular imine exchange reactions that would "open" it. Upon switching, the strained Z-cage isomers undergo imine exchange spontaneously, thus opening the cage. Subsequent isomerization of the Z-open compounds yields a high-energy, kinetically trapped E-open species, which cannot be efficiently obtained from the initial E-cage, thus shifting an imine equilibrium energetically uphill in a closed system. Upon heating, the nucleophile is displaced back into solution and an opening/closing cycle is completed by regenerating the stable all-E-cage. Using this principle, a light-induced cage-to-cage transformation is performed by the addition of a ditopic aldehyde.

Published

2023

3. Light-Fueled Transformations of a Dynamic Cage-Based Molecular System

Author

Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, Feringa, Ben L., Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, and Feringa, Ben L.

Abstract

In a chemical equilibrium, the formation of high-energy species-in a closed system-is inefficient due to microscopic reversibility. Here, we demonstrate how this restriction can be circumvented by coupling a dynamic equilibrium to a light-induced E/Z isomerization of an azobenzene imine cage. The stable E-cage resists intermolecular imine exchange reactions that would "open" it. Upon switching, the strained Z-cage isomers undergo imine exchange spontaneously, thus opening the cage. Subsequent isomerization of the Z-open compounds yields a high-energy, kinetically trapped E-open species, which cannot be efficiently obtained from the initial E-cage, thus shifting an imine equilibrium energetically uphill in a closed system. Upon heating, the nucleophile is displaced back into solution and an opening/closing cycle is completed by regenerating the stable all-E-cage. Using this principle, a light-induced cage-to-cage transformation is performed by the addition of a ditopic aldehyde.

Published

2023

4. Light-Fueled Transformations of a Dynamic Cage-Based Molecular System

Author

Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, Feringa, Ben L., Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, and Feringa, Ben L.

Abstract

In a chemical equilibrium, the formation of high-energy species-in a closed system-is inefficient due to microscopic reversibility. Here, we demonstrate how this restriction can be circumvented by coupling a dynamic equilibrium to a light-induced E/Z isomerization of an azobenzene imine cage. The stable E-cage resists intermolecular imine exchange reactions that would "open" it. Upon switching, the strained Z-cage isomers undergo imine exchange spontaneously, thus opening the cage. Subsequent isomerization of the Z-open compounds yields a high-energy, kinetically trapped E-open species, which cannot be efficiently obtained from the initial E-cage, thus shifting an imine equilibrium energetically uphill in a closed system. Upon heating, the nucleophile is displaced back into solution and an opening/closing cycle is completed by regenerating the stable all-E-cage. Using this principle, a light-induced cage-to-cage transformation is performed by the addition of a ditopic aldehyde.

Published

2023

5. Light-Fueled Transformations of a Dynamic Cage-Based Molecular System

Author

Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, Feringa, Ben L., Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, and Feringa, Ben L.

Abstract

In a chemical equilibrium, the formation of high-energy species-in a closed system-is inefficient due to microscopic reversibility. Here, we demonstrate how this restriction can be circumvented by coupling a dynamic equilibrium to a light-induced E/Z isomerization of an azobenzene imine cage. The stable E-cage resists intermolecular imine exchange reactions that would "open" it. Upon switching, the strained Z-cage isomers undergo imine exchange spontaneously, thus opening the cage. Subsequent isomerization of the Z-open compounds yields a high-energy, kinetically trapped E-open species, which cannot be efficiently obtained from the initial E-cage, thus shifting an imine equilibrium energetically uphill in a closed system. Upon heating, the nucleophile is displaced back into solution and an opening/closing cycle is completed by regenerating the stable all-E-cage. Using this principle, a light-induced cage-to-cage transformation is performed by the addition of a ditopic aldehyde.

Published

2023

6. Light-Fueled Transformations of a Dynamic Cage-Based Molecular System

Author

Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, Feringa, Ben L., Ovalle, Marco, Kathan, Michael, Toyoda, Ryojun, Stindt, Charlotte N., Crespi, Stefano, and Feringa, Ben L.

Abstract

In a chemical equilibrium, the formation of high-energy species-in a closed system-is inefficient due to microscopic reversibility. Here, we demonstrate how this restriction can be circumvented by coupling a dynamic equilibrium to a light-induced E/Z isomerization of an azobenzene imine cage. The stable E-cage resists intermolecular imine exchange reactions that would "open" it. Upon switching, the strained Z-cage isomers undergo imine exchange spontaneously, thus opening the cage. Subsequent isomerization of the Z-open compounds yields a high-energy, kinetically trapped E-open species, which cannot be efficiently obtained from the initial E-cage, thus shifting an imine equilibrium energetically uphill in a closed system. Upon heating, the nucleophile is displaced back into solution and an opening/closing cycle is completed by regenerating the stable all-E-cage. Using this principle, a light-induced cage-to-cage transformation is performed by the addition of a ditopic aldehyde.

Published

2023