<p>The synthesis of a manganese-based MOF (Mn-MOF) was accomplished via a sonochemical approach and directly coated onto a platinum electrode to construct a binder-free electrocatalyst for hydrogen and oxygen evolution in alkaline solution. FT-IR analysis confirmed the bidentate coordination of the carboxylate groups to Mn<sup>2+</sup> through the asymmetric (1604&#xa0;cm<sup>-</sup>¹) and symmetric (1426&#xa0;cm<sup>-</sup>¹) stretching vibrations, while PXRD patterns indicated high crystallinity. The Mn–O bond was detected at 661&#xa0;cm<sup>-</sup>¹. BET analysis revealed a large surface area of 1106.65 m<sup>2</sup> g<sup>-</sup>¹ and a pore size of 3.27&#xa0;nm, confirming its mesoporous structure. SEM analyses demonstrated uniformly distributed nanosheets (14–21&#xa0;nm), while TGA confirmed good thermal stability up to 347&#xa0;°C. In 1.0&#xa0;M NaOH, the Mn-MOF/Pt electrode revealed impressive HER activity with an overpotential of 83 mV at 10&#xa0;mA·cm<sup>-2</sup> and a Tafel slope of 70 mV·dec<sup>-</sup>¹, following a Volmer–Tafel mechanism. For OER, it required an overpotential of 593 mV at 10&#xa0;mA·cm<sup>-2</sup>, with a Tafel slope of 196 mV·dec<sup>-</sup>¹. EIS results revealed low charge transfer resistances (67.7 Ω for HER, 970.9 Ω for OER), indicating efficient charge transport. The catalyst exhibited outstanding durability over 54,000&#xa0;s for both HER and OER, maintaining stable current density. These results demonstrate that the Mn-MOF’s high porosity, large active surface area, and redox-active Mn sites collectively contribute to its superior bifunctional electrocatalytic activity and stability, establishing it as a Potential candidate for sustainable water-splitting applications.</p>

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Tailoring a Manganese-Based Metal–Organic Framework for High-Performance Water Splitting Applications

  • Ayman S. Eliwa,
  • Yasmeen G. Abou El-Reash,
  • Gehad G. Mohamed,
  • Mohamed A. Abdelwahab

摘要

The synthesis of a manganese-based MOF (Mn-MOF) was accomplished via a sonochemical approach and directly coated onto a platinum electrode to construct a binder-free electrocatalyst for hydrogen and oxygen evolution in alkaline solution. FT-IR analysis confirmed the bidentate coordination of the carboxylate groups to Mn2+ through the asymmetric (1604 cm-¹) and symmetric (1426 cm-¹) stretching vibrations, while PXRD patterns indicated high crystallinity. The Mn–O bond was detected at 661 cm-¹. BET analysis revealed a large surface area of 1106.65 m2 g-¹ and a pore size of 3.27 nm, confirming its mesoporous structure. SEM analyses demonstrated uniformly distributed nanosheets (14–21 nm), while TGA confirmed good thermal stability up to 347 °C. In 1.0 M NaOH, the Mn-MOF/Pt electrode revealed impressive HER activity with an overpotential of 83 mV at 10 mA·cm-2 and a Tafel slope of 70 mV·dec-¹, following a Volmer–Tafel mechanism. For OER, it required an overpotential of 593 mV at 10 mA·cm-2, with a Tafel slope of 196 mV·dec-¹. EIS results revealed low charge transfer resistances (67.7 Ω for HER, 970.9 Ω for OER), indicating efficient charge transport. The catalyst exhibited outstanding durability over 54,000 s for both HER and OER, maintaining stable current density. These results demonstrate that the Mn-MOF’s high porosity, large active surface area, and redox-active Mn sites collectively contribute to its superior bifunctional electrocatalytic activity and stability, establishing it as a Potential candidate for sustainable water-splitting applications.