posted on 2022-09-23, 20:25authored byBenoît Sklénard, Gabriel Mugny, Bilal Chehaibou, Christophe Delerue, Arthur Arnaud, Jing Li
PbS quantum dots (QDs), among the most mature nanocrystals
obtained
by colloidal chemistry, are promising candidates in optoelectronic
applications at various operational frequencies. QD device performances
are often determined by charge transport, either carrier injection
before photoemission or charge detection after photoabsorption, which
is significantly influenced by the dielectric environment. Here, we
present the electronic structure and the optical gap of PbS QDs versus
size for various solvents calculated using ab initio methods including the many-body perturbation approaches. This study
highlights the importance of the dielectric environment, pointing
out (1) the non-negligible shift of the electronic structure due to
the ground state polarization and (2) a substantial impact on the
electronic bandgap. The electron–hole binding energy, which
varies largely with the QD size and solvent, is well-described by
an electrostatic model. This study reveals the fundamental physics
of size and solvation effects, which could be useful to design PbS
QD-based optoelectronic devices.