Authors : J. Merlin Rosia

Volume/Issue : Volume 10 - 2025, Issue 9 - September

Google Scholar : https://tinyurl.com/3pzuup22

Scribd : https://tinyurl.com/27r6yn4t

DOI : https://doi.org/10.38124/ijisrt/25sep325

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Abstract : There are many sources of carbon emissions which includesindustries,thermal powerplants, Vehicles etc.The goal of low carbon emission technologies is to cut down on or completely eradicate greenhouse gas emissions brought on by the production and use of energy. Some strategies to capture carbon emissions for low-carbon development in the energy sector, as well as in the steel and non-ferrous metals industries, include carbon sequestration and green energy. It meets the needs of averting global warming, cutting greenhouse gas emissions, and adjusting to a low-carbon economy. On the one hand, the development of a low-carbon economy depends on low-carbon technologies. However, it’s also a major way to address the energy issue, climate change, and sustainable development. The development of low- carbon technologies requires a number of laws, regulations, and processes. Now that can also be applicable with AI technology

Keywords : Carbon Footprint, Low-Carbon Emission Technologies, Green Energy, Carbon Sequestration, Greenhouse Gas Emissions, Low-Carbon Economy, Climate Warming, AI Technology.

References :

1. Sun, L. M., McIntyre, S. R., Iacomi, P., Everden, K., Williams, P. T., Zong, S., Liu, X., Zhu, X., Yang, Y.,  Li,  S.,  Wu,  G.,  Huang,  F.,  Liu,  L.,  Yuan,  X., Zhang, H., Zhang, J., Yang, H., Chen, W., Sun, H., . . .  Wu, C. (2025). Biochar production, activation, and applications: A comprehensive technical review. Carbon Capture Science amp; Technology, 16, 100421. https://doi.org/10.1016/j.ccst.2025.100421
2. Parvin, K., Tabandeh, A., Hossain, M. J., Hannan, M. A. (2025). Optimized hybrid energy systems for sustainable net-zero communities: Modelling, Framework Design and Performance Analysis. International Journal of Hydrogen Energy, 160, 150559. https://doi.org/10.1016/j.ijhydene.2025.150559
3. Helmi, M. E., Mohammed, I., Rezk, M. G., Gbadamosi, A. O., Raza, A., Mahmoud, M. (2025). Unlocking the potential of CO2 storage in Saline Aquifers: Challenges, knowledge gaps, and future directions for large-scale storage. Carbon Capture Science amp; Technology, 16, 100460. https://doi.org/10.1016/j.ccst.2025.100460
4. Helmi, M. E., Mohammed, I., Rezk, M. G., Gbadamosi, A. O., Raza, A., Mahmoud, M. (2025). Unlocking the potential of CO2 storage in Saline Aquifers: Challenges, knowledge  gaps,  and  future  directions  for  large-scale storage. Carbon Capture Science amp; Technology, 16, 100460. https://doi.org/10.1016/j.ccst.2025.100460
5. Aceituno, D., Zhang, X., Hao, H. (2025). A comprehensive review on carbon utilization pathways in concrete from conventional to improved strategies. Carbon Capture Science amp; Technology, 16, 100467. https://doi.org/10.1016/j.ccst.2025.100467
6. Helmi, M. E., Mohammed, I., Rezk, M. G., Gbadamosi, A. O., Raza, A., Mahmoud, M. (2025). Unlocking the potential of CO2 storage in Saline Aquifers: Challenges, knowledge gaps, and future directions for large-scale storage. Carbon Capture Science amp; Technology, 16, 100460.   https://doi.org/10.1016/j.ccst.2025.100460  
7. Symonds, R., Shokrollahi, M., Hughes, R., Navarri, P., Modler, R. (2025). Systematic approach to the design, modeling, and Techno-Economic-environmental analysis of CO2 Capture Technologies as part of the National CCUS Assessment Framework (NCAF). Carbon Capture Science amp; Technology, 16, 100439. https://doi.org/10.1016/j.ccst.2025.100439
8. Anekwe, I. M., Akpasi, S. O., Tetteh, E. K., Joel, A. S., Mustapha, S. I., Isa, Y. M. (2025). Progress in heterogeneous catalysis for renewable energy and petrochemical production from biomass. Fuel Processing Technology, 276, 108267. https://doi.org/10.1016/j.fuproc.2025.108267
9. Michie, E. A. H., Agosta, F., Smeraglia, L., Allshorn, S. L. (2025). Fault permeability in carbonate-marl multilayers: Implications for faulted CO2 Storage Site Assessment. International Journal of Greenhouse Gas Control, 146, 104427.  https://doi.org/10.1016/j.ijggc.2025.104427 
10. Hosseinzadeh, B., Amour, F., Hajiabadi, M. R., Ferreira, C. A. S., Abdollahi, A., Nick, H. M. (2025). Validated thermo- hydro-mechanical modeling framework for CO2 storage in chalk reservoirs: A case study from the Harald East Field. International Journal of Greenhouse Gas Control, 146, 104426. https://doi.org/10.1016/j.ijggc.2025.104426
11. Fang, Z., Yang, C., Wang, R. (2025). Monitoring Technologies for CO storage in coal seams and enhanced coalbed methane recovery: A review of field applications. Fuel Processing Technology, 276, 108274. https://doi.org/10.1016/j.fuproc.2025.108274
12. Ding, D., Liu, B., Chang, M. (2022). Carbon Emissions and TCFD aligned climate-related information disclosures. Journal of Business Ethics, 182(4), 967–1001. https://doi.org/10.1007/s10551-022-05292-x