Reversible anion-templated self-assembly of [2+2] and [3+3] metallomacrocycles containing a new dicopper(I) motif

A new dicopper(i) complex is reported that can be incorporated into extended architectures through multitopic carboxylate linkers; reversible carboxylate templation under pH control led to the formation of [2+2] and [3+3] metallomacrocycles

Simultaneous and coordinated rotational switching of all molecular rotors in a network

cited By 9International audienceA range of artificial molecular systems has been created that can exhibit controlled linear and rotational motion. In the further development of such systems, a key step is the addition of communication between molecules in a network. Here, we show that a two-dimensional array of dipolar molecular rotors can undergo simultaneous rotational switching when applying an electric field from the tip of a scanning tunnelling microscope. Several hundred rotors made from porphyrin-based double-decker complexes can be simultaneously rotated when in a hexagonal rotor network on a Cu(111) surface by applying biases above 1 V at 80 K. The phenomenon is observed only in a hexagonal rotor network due to the degeneracy of the ground-state dipole rotational energy barrier of the system. Defects are essential to increase electric torque on the rotor network and to stabilize the switched rotor domains. At low biases and low initial rotator angles, slight reorientations of individual rotors can occur, resulting in the rotator arms pointing in different directions. Analysis reveals that the rotator arm directions are not random, but are coordinated to minimize energy via crosstalk among the rotors through dipolar interactions

Design and Synthesis of a Nano-winch

International audienceTechnical progress in the field of Scanning Probe Microscopy (SPM) has opened the way for the development of new surface-mounted artificial molecular machines, which can be addressed at the single molecule scale. In this context, a ruthenium-based molecular motor has been shown to undergo controlled unidirectional and reversible rotation when fueled with electrons delivered by the tip of a Scanning Tunneling Microscope. In this chapter, we report our efforts towards a deeper understanding of the mechanical properties of this molecular motor. In view of complementary force measurements to be performed at the single molecule scale using SPM techniques, the organometallic structure of the motor has been derivatized to append a long chain terminated by a hook. We detail here the design of this nano-winch architecture and the modular synthesis of a first prototype dedicated to Atomic Force Microscopy-based Single Molecule Force Spectroscopy experiments