Abstract
Epitaxially grown nanowires have shown promise for photovoltaic applications due to their nanophotonic properties. Moreover, the mechanical properties of nanowires can reduce crystallographic defect formation at interfaces to help enable new material combinations for photovoltaics. One material that stands to benefit from the nanowire morphology is zinc phosphide (Zn(3)P(2)), which, despite promising optoelectronic properties, has experienced limited applicability due to challenges achieving heteroepitaxy, stemming from its incompatible lattice parameter and coefficient of thermal expansion. Herein, we identify the requirements for successful epitaxy of Zn(3)P(2) nanowires using metalorganic chemical vapor deposition and the impact on interface structure and defect formation. Furthermore, using high-throughput optical spectroscopy, we were able to demonstrate shifts in the photoluminescence intensity and energy by tuning the V/II ratio during growth, highlighting the compositional tunability of the optoelectronic properties of Zn(3)P(2) nanowires.