Jazan's Catch Chronicles: A Statistical Exploration of Lethrinus Nebulous and Acanthocybium Solandri Fishing (2012-2022)
DOI:
https://doi.org/10.18034/abcjar.v13i1.719Keywords:
Jazan, Fisheries, Lethrinus Nebulous, Acanthocybium Solandri, Sustainability, Catch Patterns, Species ConservationAbstract
This study delves into the fascinating world of fisheries data, specifically focusing on two commercially important fish species in the Red Sea: The Lethrinus nebulous (cloud emperor) and the Acanthocybium solandri (wahoo). Through the lens of statistics, this study aims to uncover valuable insights into the population dynamics, catch patterns and potential management strategies for these fish species. By analyzing data from "Jazan's Catch Chronicles," from General Administration of Fisheries Resources (Ministry of Environment, Water and Agriculture) -the Statistical Yearbook 2022-, we employ statistical methods to extract meaningful patterns from the data and answer critical questions. This knowledge can then inform fisheries management practices, ensuring the long-term sustainability of these valuable resources. The findings suggest that the diversity of the catch may have increased slightly over the study period. The number of species with a catch of more than 100 tonnes increased from 5 in 2017 to 7 in 2022. The number of species with a catch of more than 10 tonnes also increased from 14 in 2017 to 17 in 2022. However, further statistical analysis, such as a chi-squared test, is needed to determine if this difference is statistically significant. The study also highlights the importance of balancing data disclosure with species conservation. While detailed location data can be valuable for scientific research, it can also pose threats to endangered species. In the case of the IUCN-listed Cheilinus undulatus (humphead wrasse), a decision tree approach was employed to weigh the risks and rewards of disclosing location data. Considering the species' endangered status and declining population, the study recommends restricting data by masking species IDs and areas or restricting information by publishing high-resolution habitat maps without specific location details. This approach helps balance the need for scientific knowledge with protecting vulnerable species. Overall, this study sheds light on the dynamics of fish populations in the Red Sea, emphasizing the need for sustainable management practices and responsible data handling to ensure the long-term health of these vital marine resources.
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Affan, M.A.; Al-Sofyani, A.; Turki, A.J. and Hariri, M.S.B. (2018). Huge Fish Killing after Rain at Jeddah Coast, the Red Sea, Saudi Arabia. Pakistan J. Zool., 50, 2099-2106. https://dx.doi.org/10.17582/journal.pjz/2018.50.6.2099.2106
Al Solami, L.S.; Abdelaty, M. and Zhang, C. (2020). An ecosystem-based fisheries assessment approach and management system for the Red Sea. Fish. Res., 227, 10555. https://doi.org/10.1016/j.fishres.2020.105551
Al-Sultan, M.; Ghanem, A.M. and Alamri, Y. (2018). Estimating technical efficiency on Saudi Arabia fishing methods: A case study of the Red sea. Int. J. Fish. Aquat. Stud., 6, 191-195.
Badr, N. B.; El-Fiky, A. A.; Mostafa, A. R. and Al-Mur, B. A. (2009). Metal pollution records in core sediments of some Red Sea coastal areas, Kingdom of Saudi Arabia. Environ. Monit. Assess., 155, 509–526.
Batang, Z.B.; Alikunhi, N.; Gochfeld, M.; Burger, J.; Al-Jahdali, R.; Al-Jahdali, H.; Aziz, M.A.; Al-Jebreen, D. and Al-Suwailem, A. (2016). Congener-specific levels and patterns of polychlorinated biphenyls in edible fish tissue from the central Red Sea coast of Saudi Arabia. Sci. Total Environ., 572, 915–925.
Bogorodsky, S.V.; Alpermann, T.J.; Mal, A.O. and Gabr, M.H. (2014). Survey of demersal fishes from southern Saudi Arabia, with five new records for the Red Sea. Zootaxa, 3852, 401–437. http://dx.doi.org/10.11646/zootaxa.3852.4.1
Bruckner, A. W.; Faisal, M. and Alnazry, H. H. (2011). A paradigm shift for fisheries management to enhance recovery, resilience, and sustainability of coral reef ecosystems in the Red Sea. Sustainable fisheries: multi-level approaches to a global problem. American Fisheries Society, Maryland, pp 85–111.
Carvalho, S.; Kürten, B.; Krokos, G.; Hoteit, I. and Ellis, J. (2019). The Red Sea, in: World Seas: An Environmental Evaluation. Academic Press, 49-74. https://doi.org/10.1016/B978-0-08-100853-9.00004-X
Kahal, A.; El-Sorogy, A.S.; Qaysi, S.; Almadani, S.; Kassem, O.M. and AlDossari, A. (2020). Contamination and ecological risk assessment of the Red Sea coastal sediments, southwest Saudi Arabia. Mar. Pollut. Bull., 154, 111125.
Leliaert, F. and Coppejans, E. (2003). Seagrasses and Seaweeds, in: Standard Survey Methods for the Red Sea and Gulf of Aden. PERSGA Technical Series No. 10. PERSGA, Jeddah.
MEWA, statistical yearbook (2018). Ministry of Environment Water & agriculture, The Kingdom of Saudi Arabia. https://www.mewa.gov.sa/ar/Information Center/Researchs/Reports/Pages/default.aspx
Spaet, J. L. and Berumen, M. L. (2015). Fish market surveys indicate unsustainable elasmobranch fisheries inthe Saudi Arabian Red Sea. Fish. Res., 161, 356–364
Tesfamichael, D.; Pitcher, T. J. and Pauly, D. (2014). Assessing changes in fisheries using fishers’ knowledge to generate long time series of catch rates: a case study from the Red Sea. Ecol. Soc., 19, 18. http://dx.doi.org/10.5751/ES-06151- 190118
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