Protection Methods of Marine Ecological Environment Resources from Economic Perspective

Authors:Jing Rao


At present, large-scale and high-intensity marine development activities brings great pressure on the marine ecological environment. Scientific and reasonable development and utilization for the ocean is an inevitable requirement to achieve the sustainable development of marine resources. Therefore, a method of marine biological ecological environment resource protection from the perspective of economy was put forward. It was necessary to coordinate the interest relationship between economic development and environmental protection. Firstly, the monitoring technology of marine biological ecological environment was researched to obtain typical and comprehensive multi-source monitoring data, and thus to figure out the state of marine biological ecological environment. On this basis, ecological compensation was carried out, including the measurement of marine ecological loss, the measurement of marine ecological compensation, and the construction of ecological compensation system dynamics model, so that the optimal scheme of ecological compensation was obtained and marine ecological environment protection was achieved. In order to test the effectiveness of protection method, the coordination degree between the economic development and the environment protection of marine biological ecological resources was calculated. Simulation results show that the coordination degree is more than 0.9 after using the propose method, which is much higher than that before the implementation, so the proposed method can ensure the economic development and protect the marine ecological environment well. The contradiction between economic development and environmental protection is resolved.

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Antonella, D.D., B. Francesco and S. Francesca. 2017.

Environmental quality and hygienic safety of the

Alimini Lakes (Puglia, Italy): 20 years of

monitoring (1995–2014). Rendiconti Lincei, 28 (2):


Bai, S., G. Teng and X. Du. 2017. Design and

implementation on real-time monitoring system of

laying hens environmental comfort based on

LabVIEW. Nongye Gongcheng

Xuebao/transactions of the Chinese Society of

Agricultural Engineering, 33 (15): 237-244.

Chen, Y., Y.Q. Guan and J.Z. Miao. 2017.

Determination of the ecological water-level and

assuring degree in the Lake Gaoyou, northern

Jiangsu with long-term hydrological alteration.

Journal of Lake Sciences, 29 (2): 398-408.

Doug, W., M.Q. Dan and A.F. Robert. 2019. Civilian

science: the potential of participatory

environmental monitoring in areas affected by

armed conflicts. Environmental Monitoring and

Assessment, 191 (10): 618-623.

Edwige, B. 2018. Variation of interspecific

interactions at different ecological levels within an

assemblage of Arctic marine predators. Polar

Biology, 42 (1): 99–113.

Elliott, M., D. Burdon and J.P. Atkins. 2017. “And

dpsir begat dapsi(w)r(m)!” - a unifying framework

for marine environmental management. Marine

Pollution Bulletin, 118 (1-2): 27-40.

Huang, Z.L., Y. Wang and C.L. Zhang. 2017. Strategic study on comprehensive reform for ecological protection and economic development of the upper Yangtze River. Journal of Lake Sciences, 29 (2): 257-265.

Islam, M.A., A. Al-mamun and F. Hossain. 2017. Contamination and ecological risk assessment of trace elements in sediments of the rivers of Sundarban mangrove forest, Bangladesh. Marine Pollution Bulletin, 124 (1): 356-366.

Keunje, Y., K.L. Tae and J.C Eun. 2017. Molecular approaches for the detection and monitoring of microbial communities in bioaerosols: A review. Journal of Environmental Sciences, 29 (1): 234-247.

Liu, H.J., W.J. Liu and J.P. Liu. 2017. Heavy metals concentration and its potential ecological risk assessment of surface seawater in South China Sea. Zhongguo Huanjing Kexue/China Environmental Science, 37 (10): 3891-3898.

Lucie, B., G. Stéphanie and K. Christian. 2017. Ecological equivalence assessment methods: what trade-offs between operationality, scientific basis and comprehensiveness? Environmental Management, 60 (1): 216-230.

Michael, B., Mascia., E. Helen and L.G. Fox. 2017. A novel framework for analyzing conservation impacts: evaluation, theory, and marine protected areas. Annals of the New York Academy of Sciences, 1399 (1): 93-115.

Naama, L.Y., T.K. Anna and V. Lothar. 2018. Fresh water, marine and terrestrial cyanobacteria display distinct allergen characteristics. Science of the Total Environment, 612 (15): 767-774.

Panu, M., S.Y. Zhao and H. Toni. 2018. Environmental noise monitoring using source classification in sensors. Applied Acoustics, 129 (1): 258-267.

Scofield., A. Patricia., Smith., L. Linda, Johnson and N. David. 2017. Oak ridge reservation environmental protection rad neshaps radionuclide inventory web database and rad neshaps source and dose database. Health Physics, 113 (1): 78.

Song, J., R.C. Hue and J.Z. Wu. 2019. Research on oil and gas ecological compensation mechanism. Chemistry and Technology of Fuels and Oils, 55 (3): 85–92.

Vasilijević, A., Đ. Nađ and Mandić. 2017. Coordinated navigation of surface and underwater marine robotic vehicles for ocean sampling and environmental monitoring. IEEE/ASME Transactions on Mechatronics, 22 (3): 1174-1184.

Walls, A.M., R. Kennedy and M.D. Edwards. 2017. Impact of kelp cultivation on the ecological status of benthic habitats and zostera marina seagrass biomass. Marine Pollution Bulletin, 123 (1-2): 19-27.

Wang, Y., J.X. Gao and C.X. Zou. 2017. Study on the ecological protection redlines delimitation and ecological assets dynamics. Zhongguo Huanjing Kexue/China Environmental Science, 37 (6): 2369-2376.

Zuo, M.J. 2018. Monitoring of data acquisition of water pollution based on submarine optical sensor network. Computer simulation, 35 (02): 455-458.


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