Mikhail V. Vaganov, Nicolas Suaud, Francois Lambert, Benjamin Cahier, Christian Herrero, Regis Guillot, Anne-Laure Barra, Nathalie Guihery, Talal Mallah, Arzhang Ardavan, Junjie Liu
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Chemical tuning of quantum spin-electric coupling in molecular nanomagnets
Controlling quantum spins using electric rather than magnetic fields promises
significant architectural advantages for developing quantum technologies. In
this context, spins in molecular nanomagnets offer tunability of spin-electric
couplings (SEC) by rational chemical design. Here we demonstrate systematic
control of SECs in a family of Mn(II)-containing molecules via chemical
engineering. The trigonal bipyramidal (tbp) molecular structure with C3
symmetry leads to a significant molecular electric dipole moment that is
directly connected to its magnetic anisotropy. The interplay between these two
features gives rise to significant experimentally observed SECs, which can be
rationalised by wavefunction theoretical calculations. Our findings guide
strategies for the development of electrically controllable molecular spin
qubits for quantum technologies.
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