ABSTRACT
Herein, the synthesis of three nickel(II) dithiophosphonate complexes of the type [Ni{S2 P(OR)(4-C6 H4 OMe)}2 ] [R=H (1), C3 H7 (2)] and [Ni{S2 P(OR)(4-C6 H4 OEt}2 ] [R=(C6 H5 )2 CH (3)] is described; their structures were confirmed by single-crystal X-ray studies. These complexes were subjected to surfactant/solvent reactions at 300 °C for one hour as flexible molecular precursors to prepare either nickel sulfide or nickel phosphide particles. The decomposition of complexâ 2 in tri-octylphosphine oxide/1-octadecene (TOPO/ODE), TOPO/tri-n-octylphosphine (TOP), hexadecylamine (HDA)/TOP, and HDA/ODE yielded hexagonal NiS, Ni2 P, Ni5 P4 , and rhombohedral NiS, respectively. Similarly, the decomposition of complexâ 1 in TOPO/TOP and HDA/TOP yielded hexagonal Ni2 P and Ni5 P4 , respectively, and that of complexâ 3 in similar solvents led to hexagonal Ni5 P4 , with TOP as the likely phosphorus provider. Hexagonal NiS was prepared from the solvent-less decomposition of complexesâ 1 and 2 at 400 °C. NiS (rhom) had the best specific supercapacitance of 2304â F g-1 at a scan rate of 2â mV s-1 followed by 1672â F g-1 of Ni2 P (hex). Similarly, NiS (rhom) and Ni2 P (hex) showed the highest power and energy densities of 7.4â kW kg-1 and 54.16â W kg-1 as well as 6.3â kW kg-1 and 44.7â W kg-1 , respectively. Ni5 P4 (hex) had the lowest recorded overpotential of 350â mV at a current density of 50â mA cm-2 among the samples tested for the oxygen evolution reaction (OER). NiS (hex) and Ni5 P4 (hex) had the lowest overpotentials of 231 and 235â mV to achieve a current density of 50â mA cm-2 , respectively, in hydrogen evolution reaction (HER) examinations.