Sustainable Agriculture and Renewable Energy Integration

Authors

DOI:

https://doi.org/10.55938/wlp.v1i2.107

Keywords:

Renewable Energy, Bio-Organic Greenhouses, Climate Change, Biogas, Biofuel Conversion, Fossil Fuels

Abstract

Studies emphasize the significance of renewable energy in fostering economic gains and augmenting functionality. On the other hand, minimal study has been done on the planning and execution of renewable energy systems that incorporate ecosystem biodiversity—which sustains the local flora, fauna, and human populations—into account. The study addresses the creation of a robust greenhouse model with cutting-edge energy technologies, such as solar panels and fuel cells, which encountered challenges with their local application since they consumed both heat and electrical energy. Compared to traditional methods, modern agriculture utilizes more energy and is largely dependent on fossil fuels for operations like heating, machinery operation, fertilizer production, and grain drying. This leads to a significant increase in greenhouse gas emissions, of which 35% originate in developing countries. Combining retrofitting and an energy audit, this study identified ways to reduce the amount of energy consumed and greenhouse gas emissions on an agricultural property. To optimize renewable energy output, four alternative energy systems—including solar and bio-energy—were identified after load profiles were examined and retrofits were put into operation. The article investigates the advantages, drawbacks, and prospects for employing renewable energy in agriculture as a substitute of conventional energy. For stakeholders and academics interested in sustainable energy methods, it provides an in-depth examination of alternative energy sources and their applicability for energy management. The analysis highlights the necessity of enhancing energy management through a more comprehensive strategic approach. Despite the many advantages of low-carbon energy, this article explores the rewards and difficulties associated with renewable energy projects in rural regions and makes policy recommendations to support this transition.

References

1. Bathaei, A., &Štreimikienė, D. (2023). Renewable Energy and Sustainable Agriculture: Review of Indicators. Sustainability, 15(19), 14307.

2. Maican, E., Vlãdut, V., Vîlcu, C., Soricã, C., Dorian, M., Mirea, D. P., &Bogãþeanu, R. (2019). Hybrid renewable energy systems for isolated farms. A review.

3. Minoofar, A., Gholami, A., Eslami, S., Hajizadeh, A., Gholami, A., Zandi, M., ... & Kazem, H. A. (2023). Renewable energy system opportunities: A sustainable solution toward cleaner production and reducing carbon footprint of large-scale dairy farms. Energy Conversion and Management, 293, 117554.

4. Pombo-Romero, J., Langeveld, H., & Fernández-Redondo, M. (2023). Diffusion of renewable energy technology on Spanish farms: drivers and barriers. Environment, Development and Sustainability, 25(10), 11769-11787.

5. Paris, B., Vandorou, F., Balafoutis, A. T., Vaiopoulos, K., Kyriakarakos, G., Manolakos, D., & Papadakis, G. (2022). Energy use in open-field agriculture in the EU: A critical review recommending energy efficiency measures and renewable energy sources adoption. Renewable and Sustainable Energy Reviews, 158, 112098.

6. Aschilean, I., Rasoi, G., Raboaca, M. S., Filote, C., &Culcer, M. (2018). Design and concept of an energy system based on renewable sources for greenhouse sustainable agriculture. Energies, 11(5), 1201.

7. Gorjian, S., Fakhraei, O., Gorjian, A., Sharafkhani, A., &Aziznejad, A. (2022). Sustainable food and agriculture: employment of renewable energy technologies. Current Robotics Reports, 3(3), 153-163.

8. Pestisha, A., Gabnai, Z., Chalgynbayeva, A., Lengyel, P., & Bai, A. (2023). On-farm renewable energy systems: A systematic review. Energies, 16(2), 862.

9. Dhunny, A. Z., Allam, Z., Lobine, D., &Lollchund, M. R. (2019). Sustainable renewable energy planning and wind farming optimization from a biodiversity perspective. Energy, 185, 1282-1297.

10. Lin, X., Sun, X., Manogaran, G., & Rawal, B. S. (2021). Advanced energy consumption system for smart farm based on reactive energy utilization technologies. Environmental Impact Assessment Review, 86, 106496.

11. Streimikiene, D., Baležentis, T., Volkov, A., Morkūnas, M., Žičkienė, A., &Streimikis, J. (2021). Barriers and drivers of renewable energy penetration in rural areas. Energies, 14(20), 6452.

12. Doshi, M., & Varghese, A. (2022). Smart agriculture using renewable energy and AI-powered IoT. In AI, edge and IoT-based smart agriculture (pp. 205-225). Academic Press.

13. Sharma, H., Haque, A., & Jaffery, Z. A. (2019). Maximization of wireless sensor network lifetime using solar energy harvesting for smart agriculture monitoring. Ad Hoc Networks, 94, 101966.

14. Das, G. P., Gould, I., Zarafshan, P., Heselden, J., Badiee, A., Wright, I., & Pearson, S. (2022). Applications of robotic and solar energy in precision agriculture and smart farming. In Solar energy advancements in agriculture and food production systems (pp. 351-390). Academic Press.

15. Palys, M. J., Wang, H., Zhang, Q., & Daoutidis, P. (2021). Renewable ammonia for sustainable energy and agriculture: vision and systems engineering opportunities. Current opinion in chemical engineering, 31, 100667.

16. Ymeri, P., Gyuricza, C., & Fogarassy, C. (2020). Farmers’ attitudes towards the use of biomass as renewable energy—A case study from southeastern europe. Sustainability, 12(10), 4009.

17. Uchman, W., Kotowicz, J., & Sekret, R. (2022). Investigation on green hydrogen generation devices dedicated for integrated renewable energy farm: Solar and wind. Applied Energy, 328, 120170.

18. Tomaszewska, B., Akkurt, G. G., Kaczmarczyk, M., Bujakowski, W., Keles, N., Jarma, Y. A., ... & Kabay, N. (2021). Utilization of renewable energy sources in desalination of geothermal water for agriculture. Desalination, 513, 115151.

19. Rahman, M. M., Khan, I., Field, D. L., Techato, K., &Alameh, K. (2022). Powering agriculture: Present status, future potential, and challenges of renewable energy applications. Renewable Energy, 188, 731-749.

20. Rikkonen, P., Tapio, P., & Rintamäki, H. (2019). Visions for small-scale renewable energy production on Finnish farms–A Delphi study on the opportunities for new business. Energy Policy, 129, 939-948.

21. Majeed, Y., Khan, M. U., Waseem, M., Zahid, U., Mahmood, F., Majeed, F., ... & Raza, A. (2023). Renewable energy as an alternative source for energy management in agriculture. Energy Reports, 10, 344-359.

22. Saleem, M. (2022). Possibility of utilizing agriculture biomass as a renewable and sustainable future energy source. Heliyon, 8(2).

Published

2024-11-21

How to Cite

Sinha, A., Thapliyal, S., & Sharma, M. (2024). Sustainable Agriculture and Renewable Energy Integration. Wisdom Leaf Press, 1(2), 24–30. https://doi.org/10.55938/wlp.v1i2.107

Similar Articles

1 2 3 4 > >> 

You may also start an advanced similarity search for this article.