Sequestration of carbon dioxide from the atmosphere in coastal ecosystems: Quantification, analysis, and planning

Authors

DIngding Yang, Zhejiang Ocean University
Yujia Qin, Zhejiang Ocean University
Yuanrui Xu, Zhejiang Ocean University
Kexin Xing, Zhejiang Ocean University
Yujie Chen, Beijing Institute of Petro-chemical Technology
Xiaoping Jia, Qingdao University of Science and Technology
Kathleen B. Aviso, De La Salle University, Manila
Raymond Girard R. Tan, De La Salle University, Manila
Bohong Wang, Zhejiang Ocean University

College

Gokongwei College of Engineering

Department/Unit

Chemical Engineering

Document Type

Article

Source Title

Sustainable Production and Consumption

Volume

47

First Page

413

Last Page

424

Publication Date

2024

Abstract

Many countries have come to a consensus that they need to reduce carbon dioxide (CO2) emissions and promote low-carbon development. Mangrove forests, seagrass beds, and coral reefs are important coastal ecosystems that can effectively sequester CO2 from the atmosphere. In this study, the Carbon Emission Pinch Analysis (CEPA) approach was applied to develop a method of comparing strategies for maximising CO2 sequestration while minimising the economic cost. The proposed method replaces the emission factors and carbon emissions in CEPA with the economic cost and carbon sequestration amount to better suit the objectives of this study. The proposed method was applied to a case study on the coastal areas of Hainan Island in China. Four scenarios were considered concerning to the planting area, carbon sink, and economic cost. Scenarios 1 (increase the carbon sink by 10 %), Scenario 2 (increase the carbon sink by 10 % while limiting the planting area to 30 km2), and Scenario 3 (increase the carbon sink by 11 %) were all considered feasible at an economic cost of < 10 million EUR. However, Scenario 4 (increase the carbon sink by 12 %) exceeded the specified limit (10 million EUR in adjustment costs) by 2.55 million EUR. The study shows that Scenario 3 is optimal because it achieves the target of increasing carbon sinks by 11 % (increasing the annual carbon sequestration by 78.7423 million kg) within the constraints of planting area and economic costs. The study also shows that coral reefs are ideal for carbon sequestration.

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Recommended Citation

Yang, D., Qin, Y., Xu, Y., Xing, K., Chen, Y., Jia, X., Aviso, K. B., Tan, R. R., & Wang, B. (2024). Sequestration of carbon dioxide from the atmosphere in coastal ecosystems: Quantification, analysis, and planning. Sustainable Production and Consumption, 47, 413-424. Retrieved from https://animorepository.dlsu.edu.ph/faculty_research/14018

Disciplines

Chemical Engineering

Keywords

Carbon sequestration

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