Abstract
Agricultural tractors powered by thermally efficient and economically viable diesel engines play a pivotal role in the mechanization farming operations. However, these engines emit harmful pollutants such as carbon monoxide (CO), hydrocarbons (HC), nitrogen oxides (NO(x)), total suspended particles (TSP), and sulfur dioxide (SO(2)), all of which pose significant risks to human, animal, and plant health. In addition, these emissions also contribute to air pollution, global warming. This study builds upon our previous simulation-based research by implementing two novel exhaust gas treatment prototypes directly onto agricultural tractors under real-world field conditions. The first prototype was filled with activated carbon impregnated with magnesium oxides at a 7:0.5 ratio, whereas the second was coated with a nickel-carbon nanotube (Ni-CNTs) composite at a 0.2% concentration. Field experiments were conducted during plowing operations using a nine-shank chisel plow at a fixed depth, with gas measurements taken at intervals between 10 and 40 min. The Ni-CNTs-based prototype achieved superior adsorption efficiencies: 85.1% for CO, 55.21% for HC, 33.71% for TSP, 90.8% for NO(x), and 76.1% for SO(2). In comparison, the AC-MgO prototype achieved removal efficiencies of 84.68% for CO, 50.0% for HC, 25.0% for TSP, 87.24% for NO(x), and 67.39% for SO(2).These findings underscore the promising potential of nanomaterial-integrated systems-particularly Ni-CNTs-in enhancing diesel exhaust treatment performance and promoting environmentally sustainable agricultural machinery.