posted on 2023-12-07, 18:07authored byAnshu Kumar, Benjamin Thompson, Ritika Gautam, Elisa Tomat, Vanessa Huxter
Radicals and other open-shell molecules play a central
role in
chemical transformations and redox chemistry. While radicals are often
highly reactive, stable radical systems are desirable for a range
of potential applications, ranging from materials chemistry and catalysis
to spintronics and quantum information. Here we investigate the ultrafast
properties of a stable radical system with temperature-dependent spin-tunable
properties. This radical complex, Cu(II) hexaethyl tripyrrin-1,14-dione,
accommodates unpaired electrons localized on both the copper metal
center and the tripyrrolic ligand. The unusual combination of two
unpaired electrons and high stability in this radical molecule enable
switchable temperature-dependent spin coupling. Two-dimensional electronic
spectroscopy measurements of Cu(II) hexaethyl tripyrrin-1,14-dione
were collected at room temperature and at 77 K. At room temperature,
the molecules are present as monomers and have short picosecond lifetimes.
At 77 K, the molecules are present in a dimer form mediated by ferromagnetic
and antiferromagnetic coupling. This reversible spin-driven dimerization
changes the optical properties of the system, generating long-lived
excitonic states.