Ni-O-C/LNSP Core-Shell Heterostructure Mimicking Noble Metal-like Activity and Nonenzymatic Electrochemical Lactate Regulation in Human Sweat.

Herein, a core/shell LNSP (lamellar nanosheet-nanoplate) of nickel oxy carbide (Ni-O-C/LNSP) has been synthesized by a solvent-devoid combustion process, which exhibits exceptional oxygen evolution efficiency (OER) performance with an overpotential of 311 mV, a Tafel slope of 116 mV dec, and stability over 8 h with 2.8% potential loss owing to more exposed active sites and high conductivity with the interface effect. The activation energy of 28 kJ/mol was calculated for electrolysis using Ni-O-C/LNSP. The calculated integrated area of 3.70 × 10 AV (Ni-O-C/LNSP) established MOOH* formation with active sites of 4.619 × 10. The ultrastability of Ni-O-C/LNSP for commercial application was shown by durability at 10/100 mA cm for the OER (GC─8 h, 2.8%; NF─100 h, 3.4/4.9%), UOR (60 h, 3.4%), SWO (60 h, 4.1%), MSWO (60 h, 5.6%), and overall water splitting (100 h, 3.9%). The effect of pH with the addition of tetramethylammonium cations (TMA) reveals Ni-O-C/LNSP follows the lattice oxygen mechanism. The solar-driven water electrolysis at 1.58 V shows the effectiveness of Ni-O-C/LNSP for STH conversion. The multiple applications projected Ni-O-C/LNSP as an auspicious catalyst for energy applications. Using Ni-O-C/LNSP, we have generated H effectively with a lower power consumption of 771.08 L kW h than bare NiO (801 L kW h). The as-prepared Ni-O-C/LNSP used for nonenzymatic lactate detection showed a sensitivity of 71.05 μA mM cm at 1.54 V with [lactate] difference in human sweat corroborated under both anaerobic and aerobic exercise conditions using Ni-O-C/LNSP.