By harvesting a wider range of the
solar spectrum, intermediate
band solar cells (IBSCs) can achieve efficiencies 50% higher than
those of conventional single-junction solar cells. For this, additional
requirements are imposed on the light-absorbing semiconductor, which
must contain a collection of in-gap levels, called intermediate band
(IB), optically coupled to but thermally decoupled from the valence
and conduction bands (VB and CB). Quantum-dot-in-perovskite (QDiP)
solids, where inorganic quantum dots (QDs) are embedded in a halide
perovskite matrix, have emerged as a promising material platform for
developing IBSCs. In this work, QDiP solids with good morphological
and structural quality and strong absorption and emission related
to the presence of in-gap QD levels are synthesized. With them, QDiP-based
IBSCs are fabricated, and by means of temperature-dependent photocurrent
measurements, it is shown that the IB is strongly thermally decoupled
from the valence and conduction bands. The activation energy of the
IB → CB thermal escape of electrons is measured to be 204 meV,
resulting in the mitigation of this detrimental process even under
room-temperature operation, thus fulfilling the first mandatory requisite
to enable high-efficiency IBSCs.