Simulation of Dispersal and Growth of Panulirus Ornatus Larvae in Coastal Ocean in Central Vietnam
Main Article Content
Abstract
This study analyzes the characteristics of wind, surface currents, temperature, salinity fields, and dispersal patterns of Panulirus Ornatus larvae in the Central coastal waters of Vietnam. The wind data were obtained from ERA5, while surface currents, temperature, and salinity were gathered from CMEMS, and the distribution of Panulirus Ornatus larvae was simulated using the OpenDrift model. El Niño and La Niña years were simulated and then compared with neutral years. The distribution results show that Panulirus Ornatus larvae tend to be dispersed northward during El Niño year, while during La Niña year, they were transported further offshore into the offshore area of the East Vietnam Sea. In neutral years, the larvae were predominantly dispersed northward, with a smaller portion drifting toward the offshore area, similar to the pattern observed during La Niña year. Additionally, the growth of the larvae was analyzed based on time and depth, revealing weight and size growth. These findings provide insights into the dispersal and growth of Panulirus Ornatus larvae. This information can inform sustainable management and exploitation of Panulirus Ornatus resources in Vietnam.
Keywords:
Spiny lobster, Central Vietnam, OpenDrift, ENSO.
References
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[7] H. Torrado, B. Mourre, N. Raventos, C. Carreras, J. Tintoré, M. Pascual, E. Macpherson, Impact of Individual Early Life Traits in Larval Dispersal: A Multispecies Approach Using Backtracking Models, Progress in Oceanography, Vol. 192, 2021, pp. 102518, https://doi.org/10.1016/j.pocean.2021.102518.
[8] L. V. Tho, L. N. Thao, P. D. Dang, H. N. Dien, H. D. Dat, Species Composition and Distributional Characteristics of Panulirus White, 1847 (Palinuridae) in Cu Lao Cham Marine Protected Area, Quang Nam Province, Academia Journal of Biology, Vol. 36, No. 2, 2014, pp. 140-146, https://doi.org/10.15625/0866-7160/v36n2.5112 (in Vietnamese).
[9] K. C. Williams, Spiny Lobster Ecology and Exploitation in the South China Sea Region, Aciar Proceedings, Nha Trang, Vietnam, Vol. 120, 2004, 73pp.
[10] R. Vennell, M. Scheel, S. Weppe, B. Knight, M. Smeaton, Fast Lagrangian Particle Tracking in Unstructured Ocean Model Grids, Ocean Dynamics, Vol. 71, 2021, pp. 423-437, https://doi.org/10.1007/s10236-020-01436-7.
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[12] C. R. Norrie, B. J. Dunphy, M. Roughan, S. Weppe, C. Lundquist, Spill-Over from Aquaculture May Provide a Larval Subsidy for the Restoration of Mussel Reefs, Aquaculture Environment Interactions, Vol. 12, 2020,
pp. 231-249, http://dx.doi.org/10.3354/aei00363.
[13] G. Romagnoni, K. O. Kvile, K. F. Dagestad, A. M. Eikeset, T. Kristiansen, N. C. Stenseth, O. Langangen, Influence of Larval Transport and Temperature on Recruitment Dynamics of North Sea Cod (Gadus Morhua) Across Spatial Scales of Observation, Fisheries Oceanography, Vol. 29,
No. 4, 2020, pp. 324-339, https://doi.org/10.1111/fog.12474.
[14] V. V. Nha, Cage Culture Techniques for Lobster and Disease Management Measures, Agriculture Publishing House, Hanoi, 2006, https://khuyennongvn.gov.vn/portals/0/tailieu/2014/12/host/kythuat_nuoi_tomhum.pdf (accessed on: October 21st, 2024) (in Vietnamese).
[15] S. Sundby, A One-Dimensional Model for the Vertical Distribution of Pelagic Fish Eggs in the Mixed Layer, Deep Sea Research Part A. Oceanographic Research Papers, Vol. 30, 1983,
pp. 645-661, https://doi.org/10.1016/0198-0149(83)90042-0.
[16] NOAA, Cold & Warm Episodes by Season, https://origin.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ONI_v5.php (accessed on: October 21st, 2024).
[17] Student Channel, Discover How Lobsters Reproduce, https://kenhsinhvien.vn/t/kham-pha-tom-hum-sinh-san-nhu-the-nao.804431/ (accessed on: October 21st, 2024) (in Vietnamese).
[18] Tepbac, Lobster, https://tepbac.com/species/full/35/Tom-hum.htm (accessed on: October 21st, 2024) (in Vietnamese).
[19] C. Chen, Z. Lai, R. C. Beardley, Q. Xu, H. Lin, N. T. Viet, Current Separation and Upwelling Over the Southeast Shelf of Vietnam in the South China Sea, Journal of Geophysical Research: Oceans, Vol. 117, 2012, pp. C003033, https://doi.org/10.1029/2011JC007150.
[20] M. Herrmann, T. T. Duy, C. Estournel, Intraseasonal Variability of the South Vietnam Upwelling, South China Sea: Influence of Atmospheric Forcing and Ocean Intrinsic Variability, Ocean Science, Vol. 19, No. 2, 2023, pp. 453-467, https://doi.org/10.5194/os-19-453-2023.
[21] T. T. Duy, M. Herrmann, C. Estournel, P. Marsaleix, T. Duhaut, L. B. Hong, N. T. Bich, The Role of Wind, Mesoscale Dynamics, and Coastal Circulation in the Interannual Variability of the South Vietnam Upwelling, South China Sea – Answers from A High-Resolution Ocean Model, Ocean Science, Vol. 18, 2022, pp. 1131-1161, https://doi.org/10.5194/os-18-1131-2022.
[22] Technical Document on Lobster (Panulirus) Cage Farming, https://luanvan.net.vn/luan-van/tai-lieu-ky-thuat-nuoi-tom-hum-panulirus-trong-long-65205/ (accessed on: October 21st, 2024) (in Vietnamese).