In Taiwan, the discharge of piggery wastewater (PW) is higher than 110,000 m3. With containing high concentration COD, nitrogen and phosphorus, untreated PW can pose serious environmental and ecological crisis. One conventional way to deal with this issue is three-stage wastewater treatment (including solid-liquid separation, anaerobic digestion (AD) and activated sludge process), where organic waste could be transferred to green biofuel or biofertilizer. In some cases, to increase the biogas production, the different organic matters (such as rice husks and straws) will be introduced in the same digester to enhance the performance of AD. However, several problems of process, such as acidification and long retention time, inhibit the performance and efficiency of biogas production. In view of these issues, this study will develop a novel technique combined with AD and electrochemical system, as known as electricity-assisted anaerobic digestion (EAAD). The mechanism of EAAD is introducing the low current to stimulate and active the microorganisms to significantly improve the productivity of bio-products. The performances were evaluated through the kinetic model to determine the biological parameters (such as lag time and methane production rate). Additionally, life cycle assessment (LCA) was used to quantify the environmental impacts (e.g., carbon footprint) in different scenarios. Future research directions include elucidating the microbial reaction pathways in EAAD and scaling up the engineering of EAAD for application in wastewater treatment plants.In this study, experimental PW was produced in Chiayi, Taiwan. In Preliminary experiment, the adding of medium and sludge has significant effect on biogas production. The production could be more than 110.00 mL/gVS, and the system could be sustained for more than 60 days. The result showed that EAAD had 14.5% higher methane level than the conventional AD, and the best methane yield was 74.9 mL/gVS in the case of EAAD (0:1). The highest hydrogen yield and carbon dioxide were 0.57 mL/gVS and 13.4 mL/gVS, which was account for about 0.3% and 4.8%, respectively. Additionally, the results showed EAAD had better performance at 0.6 V than at 1.2 V. For the effect of co-digestion, it demonstrated that the PW:RH ratio would affect the performance of methane production, and when the ratio was 3:1, it had the best co-digestion effect (45%). The kinetic study showed that the Modified Gompertz model had significant fitness (R2: 0.965-0.997), compared to the first-order kinetic model (R2: 0.894-0.932). Moreover, EAAD was also indicated that could raise the methane productivity, which highest value was 5.23 mL/gVS in the case of EAAD (0:1). On the other hands, LCA was conducted to evaluate the environmental impacts. The results in a lab scale showed the EAAD could reduce the environmental impact by 2.6-14.5%, and demonstrated the optimization of voltage in EAAD was at 0.6 V. Furthermore, the results of the large scale showed the process of manure generation was the main contributor to ecosystem equality (88.1%), and the process of treatment plant was dominant contributor in other damage categories. Dominate bacteria in AD and EAAD were Clostridium sensu stricto 1, Turicibacter, and Terrisporobacter, which were contributed the hydrolysis and acid-forming. Methanosaeta had the highest proportion in kingdom of archaea, and it was known as an acetoclastic methanogen common found in the environment of AD.