Conspectus
The electronic dimensionality
of a material is defined by the number
of spatial degrees of confinement of its electronic wave function.
Low-dimensional semiconductor nanomaterials with at least one degree
of spatial confinement have optoelectronic properties that are tunable
with size and environment (dielectric and chemical) and are of particular
interest for optoelectronic applications such as light detection,
light harvesting, and photocatalysis. By combining nanomaterials of
differing dimensionalities, mixed-dimensional heterojunctions (MDHJs)
exploit the desirable characteristics of their components. For example,
the strong optical absorption of zero-dimensional (0D) materials combined
with the high charge carrier mobilities of two-dimensional (2D) materials
widens the spectral response and enhances the responsivity of mixed-dimensional
photodetectors, which has implications for ultrathin, flexible optoelectronic
devices. MDHJs are highly sensitive to (i) interfacial chemistry because
of large surface area-to-volume ratios and (ii) electric fields, which
are incompletely screened because of the ultrathin nature of MDHJs.
This sensitivity presents opportunities for control of physical phenomena
in MDHJs through chemical modification, optical excitation, externally
applied electric fields, and other environmental parameters. Since
this fast-moving research area is beginning to pose and answer fundamental
questions that underlie the fundamental optoelectronic behavior of
MDHJs, it is an opportune time to assess progress and suggest future
directions in this field.
In this Account, we first outline
the characteristic properties,
advantages, and challenges for low-dimensional materials, many of
which arise as a result of quantum confinement effects. The optoelectronic
properties and performance of MDHJs are primarily determined by dynamics
of excitons and charge carriers at their interfaces, where these particles
tunnel, trap, scatter, and/or recombine on the time scales of tens
of femtoseconds to hundreds of nanoseconds. We discuss several photophysical
phenomena that deviate from those observed in bulk heterojunctions,
as well as factors that can be used to vary, probe, and ultimately
control the behavior of excitons and charge carriers in MDHJ systems.
We then discuss optoelectronic applications of MDHJs, namely, photodetectors,
photovoltaics, and photocatalysts, and identify current performance
limits compared to state-of-the-art benchmarks. Finally, we suggest
strategies to extend the current understanding of dynamics in MDHJs
toward the realization of stimuli-driven responses, particularly with
respect to exciton delocalization, quantum emission, interfacial morphology,
responsivity to external stimuli, spin selectivity, and usage of chemically
reactive materials.
