Luminescent
solar concentrators (LSCs) show promise because of
their potential for low-cost, large-area, and high-efficiency energy
harvesting. Stokes shift engineering of luminescent quantum dots (QDs)
is a favorable approach to suppress reabsorption losses in LSCs; however,
the use of highly toxic heavy metals in QDs constitutes a serious
concern for environmental sustainability. Here, we report LSCs based
on cadmium-free InP/ZnO core/shell QDs with type-II band alignment
that allow for the suppression of reabsorption by Stokes shift engineering.
The spectral emission and absorption overlap was controlled by the
growth of a ZnO shell on an InP core. At the same time, the ZnO layer
also facilitates the photostability of the QDs within the host matrix.
We analyzed the optical performance of indium-based LSCs and identified
the optical efficiency as 1.45%. The transparency, flexibility, and
cadmium-free content of the LSCs hold promise for solar window applications.
Light-induced stimulation of neurons via photoactive surfaces offers rich opportunities for the
development of therapeutic methods and high-resolution retinal prosthetic
devices. Quantum dots serve as an attractive building block for such
surfaces, as they can be easily functionalized to match the biocompatibility
and charge transport requirements of cell stimulation. Although indium-based
colloidal quantum dots with type-I band alignment have attracted significant
attention as a nontoxic alternative to cadmium-based ones, little
attention has been paid to their photovoltaic potential as type-II
heterostructures. Herein, we demonstrate type-II indium phosphide/zinc
oxide core/shell quantum dots that are incorporated into a photoelectrode
structure for neural photostimulation. This induces a hyperpolarizing
bioelectrical current that triggers the firing of a single neural
cell at 4 μW mm–2, 26-fold lower than the
ocular safety limit for continuous exposure to visible light. These
findings show that nanomaterials can induce a biocompatible and effective
biological junction and can introduce a route in the use of quantum
dots in photoelectrode architectures for artificial retinal prostheses.
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