Environmental Governance through the Utilization of Waste Methane Gas into Renewable Energy

Thuerry Prak Sevann

doi:10.37899/journallalifesci.v2i2.363

Thuerry Prak Sevann Chemistry Department, Royal University of Phnom Penh, Cambodia

DOI: https://doi.org/10.37899/journallalifesci.v2i2.363

Keywords: Methane Gas, Renewable Energy, Environment

Abstract

The purpose of this article is to examine the conversion of waste methane gas to renewable energy through environmental management. Processing organic waste is one kind of alternative energy that may be generated and regenerated. Garbage is a major issue for the majority of people, particularly the vast volume of market garbage. Waste processing and utilization technology is required. Implementing the 3R process of reduce, reuse, and recycle on fresh garbage not only generates useful goods, but also addresses the waste issue and generates revenue for those who wish to manage it. As a result, it is critical to evaluate the design of organic waste burners that convert methane gas to methane and to estimate the rate of combustion and heat produced by organic waste biogas

References

Alkier, R., Milojica, V., & Roblek, V. (2015). A holistic framework for the development of a sustainable touristic model. International Journal of Markets and Business Systems, 1(4), 366-387.

Bacon, C. M., Getz, C., Kraus, S., Montenegro, M., & Holland, K. (2012). The social dimensions of sustainability and change in diversified farming systems. Ecology and Society, 17(4).

Brown, D. P. (2015). Garbage: How population, landmass, and development interact with culture in the production of waste. Resources, Conservation and Recycling, 98, 41-54.

Cardona, O. D. (2013). The need for rethinking the concepts of vulnerability and risk from a holistic perspective: a necessary review and criticism for effective risk management. In Mapping vulnerability (pp. 56-70). Routledge.

Christmann, P. (2000). Effects of “best practices” of environmental management on cost advantage: The role of complementary assets. Academy of Management journal, 43(4), 663-680.

Daily, B. F., & Huang, S. C. (2001). Achieving sustainability through attention to human resource factors in environmental management. International Journal of operations & production management.

Economy, E. C. (2011). The river runs black: the environmental challenge to China's future. Cornell University Press.

Hellawell, J. M. (Ed.). (2012). Biological indicators of freshwater pollution and environmental management. Springer Science & Business Media.

Huang, G., & Zhao, R. (2021). Harmonious discourse analysis: approaching peoples’ problems in a Chinese context. Language Sciences, 85, 101365.

McKinley, D. C., Miller-Rushing, A. J., Ballard, H. L., Bonney, R., Brown, H., Cook-Patton, S. C., ... & Soukup, M. A. (2017). Citizen science can improve conservation science, natural resource management, and environmental protection. Biological Conservation, 208, 15-28.

Merzenich, H., Riccetti, N., Hoffmann, B., Blettner, M., Forastiere, F., & Gianicolo, E. (2021). Air pollution and airport apron workers: A neglected occupational setting in epidemiological research. International journal of hygiene and environmental health, 231, 113649.

Renwick, D. W., Redman, T., & Maguire, S. (2013). Green human resource management: A review and research agenda. International Journal of Management Reviews, 15(1), 1-14.

Rovira, J., Domingo, J. L., & Schuhmacher, M. (2020). Air quality, health impacts and burden of disease due to air pollution (PM10, PM2. 5, NO2 and O3): Application of AirQ+ model to the Camp de Tarragona County (Catalonia, Spain). Science of The Total Environment, 703, 135538.

Singh, R. L., & Singh, P. K. (2017). Global environmental problems. In Principles and Applications of Environmental Biotechnology for a Sustainable Future (pp. 13-41). Springer, Singapore.