An in situ phosphorus source for the synthesis of Cu_3P and the subsequent conversion to Cu_3PS_4 nanoparticle clusters

The search for alternative earth abundant semiconducting nanocrystals for sustainable energy applications has brought forth the need for nanoscale syntheses beyond bulk synthesis routes. Of particular interest are metal phosphides and derivative I–V–VI chalcogenides including copper phosphide (Cu_3P) and copper thiophosphate (Cu_3PS_4). Herein, we report a one-pot, solution-based synthesis of Cu_3P nanocrystals utilizing an in situ phosphorus source: phosphorus pentasulfide (P_2S_5) in trioctylphosphine. By injecting this phosphorus source into a copper solution in oleylamine, uniform and size controlled Cu_3P nanocrystals with a phosphorous-rich surface are synthesized. The subsequent reaction of the Cu_3P nanocrystals with decomposing thiourea forms nanoscale Cu_3PS_4 particles having p-type conductivity and an effective optical band gap of 2.36 eV. The synthesized Cu_3PS_4 produces a cathodic photocurrent during photoelectrochemical measurements, demonstrating its application as a light-absorbing material. Our process creates opportunities to explore other solution-based metal-phosphorus systems and their subsequent sulfurization for earth abundant, alternative energy materials.

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