Disorder is an intrinsic attribute of any realistic molecular
system.
It is known to lead to localization, which hampers efficient transport.
It was recently proposed that in molecular ensembles strongly coupled
to photonic cavities, moderate disorder leads to delocalization and
increases of the transport and chemical reaction rates. Vibrational
polaritons involve molecular vibrations hybridized with an infrared
cavity. When the coupling strength largely exceeds the molecular inhomogeneity,
polaritons are unaffected by disorder. However, in many experiments,
such a homogeneous limit does not apply. We investigated vibrational
polaritons involving molecular ensembles with systematically modified
disorder. Counterintuitively, moderate disorder leads to an increase
in Rabi splitting and the modification of the polariton bandwidths.
Experimental spectroscopic data agree with a Tavis–Cummings-like
model that suggests enhanced delocalization of the reservoir states
occurs via the admixture of the cavity mode. Our results provide new
insights into the paradigm of disorder-induced cavity-assisted delocalization
in molecular polaritons.