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Electrocatalytic water splitting presents an exciting opportunity to produce environmentally benign hydrogen fuel to power human activities. Earth abundant Ni5P4 has emerged as an efficient catalyst for the hydrogen evolution reaction (HER) and its activity can be enhanced by admixing synergistic metals to modify the surface affinity and consequently kinetics of HER. Computational studies suggest that the HER activity of Ni5P4 can be improved by Zn doping, causing a chemical pressure-like effect on Ni3 hollow sites. Herein, we report a facile colloidal route to produce Ni5-xZnxP4 nanocrystals (NCs) with control over structure, morphology, and composition and investigate their composition-dependent HER activity in alkaline solutions. Ni5-xZnxP4 NCs retain the hexagonal structure and solid spherical morphology of binary Ni5P4 NCs with a notable size increase from 9.2-28.5 nm for x = 0.00-1.27 compositions. Elemental maps affirm the homogeneous ternary alloy formation with no evidence of Zn segregation. Surface analysis of Ni5-xZnxP4 NCs indicates significant modulation of the surface polarization upon Zn incorporation resulting in a decrease in Niδ+ and an increase in Pδ- charge. Although all compositions followed a Volmer-Heyrovsky HER mechanism, the modulated surface polarization enhances the reaction kinetics producing lower Tafel slopes for Ni5-xZnxP4 NCs (82.5-101.9 mV/dec for x = 0.10-0.84) compared to binary Ni5P4 NCs (109.9 mV/dec). Ni5-xZnxP4 NCs showed higher HER activity with overpotentials of 131.6-193.8 mV for x = 0.02-0.84 in comparison to Ni5P4 NCs (218.1 mV) at a current density of -10 mA/cm2. Alloying with Zn increases the material’s stability with only a ~10% increase in overpotential for Ni4.49Zn0.51P4 NCs at -50 mA/cm2, whereas a ~33% increase was observed for Ni5P4 NCs. At current densities above -40 mA/cm2, bimetallic NCs with x = 0.10, 0.29, and 0.51 compositions outperformed the benchmark Pt/C catalyst, suggesting that hexagonal alloyed Ni5-xZnxP4 NCs are excellent candidates for practical applications that necessitate lower HER overpotentials at higher current densities.more » « lessFree, publicly-accessible full text available September 12, 2024
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Group IV alloy nanocrystals (NCs) are a class of direct energy gap semiconductors that show high elemental abundance, low to non-toxicity, and composition-tunable absorption and emission properties. These properties have distinguished Ge1-xSnx NCs as an intriguing material for near-infrared (IR) optical studies. Achieving a material with efficient visible emission requires a modified class of Group IV alloys and the computational studies suggest that this can be achieved with Ge1-x-ySiySnx NCs. Herein, we report a colloidal strategy for the synthesis of bulk-like (10.3 ± 2.5 – 25.5 ± 5.3 nm) and quantum-confined (3.2 ± 0.6 – 4.2 ± 1.1 nm) Ge1-x-ySiySnx alloys that show strong size confinement effects and composition-tunable visible to near IR absorption and emission properties. This synthesis produces a homogeneous alloy with diamond cubic Ge structure and tunable Si (0.9 – 16.1%) and Sn (1.8 – 14.9%) compositions, exceeding the equilibrium solubility of Sn (<1%) in crystalline Si and Ge. Raman spectra of Ge1-x-ySiySnx alloys show a prominent redshift of the Ge-Ge peak and the emergence of a Ge-Si peak with increasing Si/Sn, suggesting the growth of homogeneous alloys. The smaller Ge1-x-ySiySnx NCs exhibit absorption onsets from 1.21 to 1.94 eV for x = 1.8 – 6.8% and y = 0.9 – 16.1% compositions, which are blueshifted from those reported for Ge1-x-ySiySnx bulk alloy films and Ge1-xSnx alloy NCs, indicating the influence of Si incorporation and strong size confinement effects. Solid-state photoluminescence (PL) spectra reveal core-related PL maxima from 1.77 – 1.97 eV in agreement with absorption onsets, consistent with the energy gaps calculated for ~3–4 nm alloy NCs. With facile low-temperature solution synthesis and direct control over physical properties, this methodology presents a noteworthy advancement in the synthesis of bulk-like and quantum-confined Ge1-x-ySiySnx alloys as versatile materials for future optical and electronic studies.more » « lessFree, publicly-accessible full text available November 14, 2024