The environmental drawbacks of energy production from fossil fuels can be substantially mitigated by transitioning to alternative renewable energy sources. The growing inclination towards renewable energy has amplified the adoption of anaerobic digestion (AD), evident from the surge in AD globally. AD efficiently converts organic waste into biogas, a versatile renewable energy medium, suitable for electricity generation, heating, and vehicle fuel, offering notable economic, environmental, and climatic advantages. In essence, AD involves the biological breakdown of organic materials into biogas, primarily composed of methane (50-70%) and CO2 (30-50%). It is worth noting that the potential of biogas generation is intrinsically linked to certain chemical properties, notably pH, total solids, volatile solids, and nitrogen. Furthermore, the efficiency of methane generation is influenced by waste attributes, operational factors, and reactor designs. In this study, I employed a dual approach involving a carbon brush and a fixed 1% VS dosage of enzyme mixture to examine methane gas production within a thermophilic (water bath) anaerobic digestion system. Four distinct thermophilic anaerobic digesters (TADs) were employed: a standard TAD (TAD-1) without adding any external enzyme and conductive material as a control, enzyme-assisted TAD (TAD-2), carbon electrode-assisted TAD (TAD-3), a combination of electrode and enzyme in TAD (TAD-4), and. The findings highlighted that the combined enzyme and carbon brush-assisted TAD-4 was the most effective in biogas generation, solid waste reduction, and COD removal. Specifically, this approach yielded an impressive 5300 mL of biogas in 10 days, outperforming other methods. Concurrently, reductions in total solids and COD were observed at 59.29% and 65%, respectively, within the same period. In addition, Thermophilic digestion allowed for shorter retention time in anaerobic digesters which was completed in 3 days of this experiment. This research signifies progress in optimizing resource recovery from organic waste through thermal processes