師資
個(gè)人簡(jiǎn)介
展鵬助理教授畢業(yè)于阿卜杜拉國(guó)王科技大學(xué)(KAUST),主要研究領(lǐng)域包括海洋(亞)中尺度過(guò)程及其對(duì)氣候和生態(tài)的響應(yīng)與影響、數(shù)據(jù)同化與伴隨模型、基于物理約束的人工智能,主持和作為骨干成員參與國(guó)家級(jí)、國(guó)際合作項(xiàng)目9項(xiàng),相關(guān)研究成果發(fā)表于GRL、JGR、L&OL、ES&T、BAMS等國(guó)際知名期刊。
教育背景
2018 博士 阿卜杜拉國(guó)王科技大學(xué)(KAUST)地球科學(xué)與工程
2013 碩士 阿卜杜拉國(guó)王科技大學(xué)(KAUST)地球科學(xué)與工程
2012 碩士 中國(guó)海洋大學(xué) 物理海洋
2010 本科 中國(guó)海洋大學(xué) 海洋科學(xué)
工作經(jīng)歷
2021至今 助理教授 南方科技大學(xué)
2018-2021 研究科學(xué)家 阿卜杜拉國(guó)王科技大學(xué)(KAUST)與 Scripps海洋研究所聯(lián)合項(xiàng)目
科研項(xiàng)目
1. 深圳市基礎(chǔ)研究(面上項(xiàng)目),大灣區(qū)海洋亞中尺度過(guò)程及其生態(tài)效應(yīng),2025.1-2027.12,30萬(wàn),在研,項(xiàng)目負(fù)責(zé)人
2. 中國(guó)-沙特阿拉伯國(guó)際合作項(xiàng)目,Sea Level Rise and Extremes in the Red Sea and Arabian Gulf,2023.10-2025.9,$50k,在研,項(xiàng)目負(fù)責(zé)人
3. 國(guó)家自然科學(xué)基金面上項(xiàng)目,典型邊緣海亞中尺度過(guò)程的動(dòng)力機(jī)制、能量級(jí)串與輸運(yùn):以紅海為例,2023.1-2026.12,54萬(wàn),在研,項(xiàng)目負(fù)責(zé)人
4. 國(guó)家重點(diǎn)研發(fā)計(jì)劃“海洋環(huán)境安全保障與島礁可持續(xù)發(fā)展”重點(diǎn)專(zhuān)項(xiàng)(青年科學(xué)家項(xiàng)目),抗生素及其抗性基因環(huán)境行為及生態(tài)效應(yīng)評(píng)估技術(shù),2022.12-2025.11,48/200萬(wàn)元,在研,任務(wù)負(fù)責(zé)人
5. KAUST Competitive Research Grants,Detecting, tracking, and forecasting of hazardous spills in the Red Sea,2019.4-2022.3,$200K,結(jié)題,項(xiàng)目核心成員
6. Saudi ARAMCO,Developing pre-operational ocean-atmosphere-wave forecasting systems for the Red Sea and Arabian Gulf,2018.11-2023.9,$2.4m,結(jié)題,項(xiàng)目核心成員
7. KAUST Competitive Research Grants,Control of the Red Sea circulation and stratification by strait hydraulics and internal waves on multiple time scales,2018.4-2021.3,$500K,結(jié)題,項(xiàng)目核心成員
8. Saudi Public Investment Fund,Environmental impact assessment of the Red Sea and NEOM projects,2017.7-2019.6,$700K,結(jié)題,項(xiàng)目核心成員
9. KAUST Strategic Initiative Program,Virtual Red Sea Initiative,2017.5-2020.4,$750k,結(jié)題,項(xiàng)目核心成員
發(fā)表論著
1. Song Y., Y. Lin, Q. Quan, T. Zu, Z. Cai, P. Zhan, Z. Liu, (2024). ENSO-Modulated Variability in Winter Shelf Circulation of the Northern South China Sea. J. Geophys. Res. Oceans.
2. Krokos, G., I. V. P. Cerove?ki, Papadopoulos, P. Zhan, M. C. Hendershott, & I. Hoteit (2024). Seasonal variability of red sea mixed layer depth: The influence of atmospheric buoyancy and momentum forcing. Front. Mar. Sci, 11, 1342137.
3. Chu, F., X. Yu, G. Krokos, I. Hoteit, K. Asfahani, & P. Zhan* (2024). Submesoscale Processes in the Northern Red Sea: Insights From Underwater Glider Observations. J. Geophys. Res. Oceans.
4. Guo, D., P. Zhan, J. Ma, P. Vasou, G. Krokos, H. Alghamdi, & I. Hoteit (2024). Seasonal Variation and Fundamental Characteristics of Baroclinic Tides in the Arabian Gulf. Front. Mar. Sci, 11, 1475593.
5. Sanikommu, S., N. Raboudi, M. El Gharamti, P. Zhan, B. Hadri, & I. Hoteit (2024). Insights from very‐large‐ensemble data assimilation experiments with a high‐resolution general circulation model of the Red Sea. Q. J. R. Meteorol. Soc.
6. Liao, F., K. Yang, Y. Wang, I. Hoteit, & P. Zhan* (2024). Future change in the Vietnam upwelling under a high‐emission scenario. Geophys. Res. Lett., 51(11), e2024GL108305.
7. Zeng, K., E. A. Gokul, H. Gu, I. Hoteit, Y. Huang, and P. Zhan* (2024). Spatiotemporal Expansion of Algal Blooms in Coastal China Seas. Environ. Sci. Technol.
8. Lin, Z, P. Zhan*, J. Li, J. Sasaki, Z. Qiu, C. Chen, S. Zou, X. Yang, & H. Gu (2024), Physical drivers of Noctiluca scintillans (Dinophyceae) blooms outbreak in the northern Taiwan Strait: A numerical study. Harmful Algae: 102586.
9. Liu, K, X. Chen, P. Zhan, L. Da, H. Wang, W. Guo, J. Liu, L. Chen, G. Gao, & D. Tian (2024), Observations of near-inertial internal wave amplification and enhanced mixing after surface reflection. Prog. Oceanogr. 220: 103177.
10. Ma, J., D. Guo, P. Zhan*, & I. Hoteit (2024), Variability and Energy Budget of the Baroclinic Tides in the Arabian Sea. Front. Mar. Sci, 10, 1293814.
11. Sanikommu, S., S. Langodan, H. P. Dasari, P. Zhan, G. Krokos, Y. O. Abualnaja, K. Asfahani, & I. Hoteit (2023), Making the Case for High-Resolution Regional Ocean Reanalyses: An Example with the Red Sea. B.M.A.S., 104(7), E1241-E1264.
12. Hammoud, M. A. E. R., P. Zhan, O. Hakla, O. Knio, & I. Hoteit (2023). Semantic Segmentation of Mesoscale Eddies in the Arabian Sea: A Deep Learning Approach. Remote Sensing, 15(6), 1525.
13. Guo, D., F. Yao, P. Zhan, G. Krokos, & I. Hoteit (2022), Hindrance effect of tides on water exchanges between the Red Sea and the Gulf of Aden, Front. Mar. Sci, 9, 2296-7745.
14. Zhan, P., G. Krokos, J. A. Gittings, D. E. Raitsos, D. Guo, N. Papagiannopoulos, & I. Hoteit (2022). Physical forcing of phytoplankton dynamics in the Al‐Wajh lagoon (Red Sea). Limnol. Oceanogr. Letters.
15. Liao, F., G. Gao, P. Zhan, & Y. Wang (2022). Seasonality and trend of the global upper-ocean vertical velocity over 1998–2017. Prog. Oceanogr., 204, 102804.
16. Zhan, P*., D. Guo, G. Krokos, J. Dong, R. Duran, I. Hoteit (2022), Submesoscale Processes in the Upper Red Sea, J. Geophys. Res. Oceans, 127, 1-17.
17. Wang, Y., D. E. Raitsos., G. Krokos, P. Zhan, & I. Hoteit (2022). A Lagrangian model-based physical connectivity atlas of the Red Sea coral reefs. , Front. Mar. Sci, 2192.
18. Zhan, P., G. Krokos, S. Langodan, D. Guo, H. Dasari, V.P. Papadopoulos, P.F. Lermusiaux, O.M. Knio, & I. Hoteit (2021). Coastal circulation and water transport properties of the Red Sea Project lagoon. Ocean Modelling, 161, p.101791.
19. Mittal, H. V. R., S. Langodan, P. Zhan, S. Li, O.M. Knio, & I. Hoteit (2021). Hazard assessment of oil spills along the main shipping lane in the Red Sea. Sci. Rep., 11(1), 1-14.
20. Toye, H., P. Zhan, F. Sana, S. Sanikommu, N. Raboudi, & I. Hoteit (2021). Adaptive ensemble optimal interpolation for efficient data assimilation in the red sea. J. Comput. Sci., 51, 101317.
21. Ma, J., D. Guo, P. Zhan & I. Hoteit (2021). Seasonal M2 Internal Tides in the Arabian Sea. Remote Sens., 13(14), p.2823.
22. Guo, D., P. Zhan & I. Hoteit (2021). Three‐Dimensional Simulation of Shoaling Internal Solitary Waves and Their Influence on Particle Transport in the Southern Red Sea. , J. Geophys. Res. Oceans, 126(4), p.e2020JC016335.
23. Zhan, P., D. Guo, & I. Hoteit (2020). Eddy‐Induced Transport and Kinetic Energy Budget in the Arabian Sea. Geophys. Res. Lett., 47(23), p.e2020GL090490.
24. Kheireddine, M., G. Dall'Olmo, M. Ouhssain, G. Krokos, H. Claustre, C. Schmechtig, A. Poteau, P. Zhan, I. Hoteit, and B. H. Jones (2020). Organic carbon export and loss rates in the Red Sea. Global Biogeochemical Cycles: e2020GB006650.
25. Hoteit, I. et al. (2020) Towards an End-to-End Analysis and Prediction System for Weather, Climate, and Marine Applications in the Red Sea, B.M.A.S.: 1-61.
26. Sanikommu, S., T. Habib, P. Zhan, S. Langodan, G. Krokos, O. Knoi., & I. Hoteit. (2020). Impact of Atmospheric and Model Physics Perturbations on a High-Resolution Ensemble Data Assimilation System of the Red Sea, J. Geophys. Res. Oceans, 125.8.
27. M. Doshi, C.S. Kulkarni, W. H. Ali, A. Gupta, P. FJ Lermusiaux, P. Zhan, I. Hoteit, and O. Knio. Flow maps and coherent sets for characterizing residence times and connectivity in Lagoons and coral reefs: The case of the Red Sea.In OCEANS 2019 MTS/IEEE SEATTLE, pp. 1-8. IEEE, 2019.
28. Zhan, P., G. Krokos, D. Guo, and I. Hoteit (2019), Three-Dimensional Signature of the Red Sea Eddies and Eddy-induced Transport, Geophys. Res. Letters. 46.4: 2167-2177.
29. Wang Y., D. E. Raitsos, G. Krokos, J. A. Gittings, P. Zhan, and I. Hoteit (2019), Physical connectivity simulations reveal dynamic linkages between coral reefs in the southern Red Sea and the Indian Ocean, Sci. Rep., 9(1), 1-11.
30. Zhan, P., G, Gapalakrishnan, A. C. Subramanian, D. Guo, & I. Hoteit (2018). Sensitivity studies of the Red Sea eddies using adjoint method, J. Geophys. Res. Oceans, 123, 1-17
31. Guo, D., A. Kartadikaria, P. Zhan, J. Xie, M. Li, I. Hoteit (2018), Baroclinic tides simulation in the Red Sea: comparison to observations and basic characteristics, J. Geophys. Res. Oceans, 123.12: 9389-9404.
32. Toye. H., S., Krotas, P. Zhan, and I. Hoteit (2018), A fault-tolerant HPC scheduler extension for large and operational ensemble data assimilation: Application to the Red Sea. J. Comput. Sci., 27, 46-56.
33. Raitsos. E. D., R. J.W. Brewin, P. Zhan, D. Dreano, Y. Pradhan, N. Gerrit, I. Hoteit (2017), Sensing coral reef connectivity pathways from space, Sci. Rep., 7(1), 1-10.
34. Toye. H., P. Zhan, G, Gapalakrishnan, A. R. Kartadikaris, H. Huang, I. Hoteit (2017), Ensemble data assimilation in the Red Sea: sensitivity to ensemble selection and atmospheric forcing, Ocean Dynamics, 67 (7), 915-933
35. Guo, D., T. R. Akylas, P. Zhan, A. Kartadikaria, and I. Hoteit (2016), On the generation and evolution of internal solitary waves in the southern Red Sea, J. Geophys. Res. Oceans, 121
36. Zhan, P., A. C. Subramanian, F. Yao, A. R. Kartadikaria, D. Guo, and I. Hoteit (2016), The eddy kinetic energy budget in the Red Sea, J. Geophys. Res. Oceans, 121, 4732–4747
37. Papadopoulos, V.P., Zhan, P., Sofianos, S.S., Raitsos, D.E., Qurban, M., Abualnaja, Y., Bower, A., Kontoyiannis, H., Pavlidou, A., Asharaf, T.M. and Zarokanellos, N., (2015). Factors governing the deep ventilation of the Red Sea. J. Geophys. Res. Oceans, 120(11), pp.7493-7505.
38. Zhan, P., et al. (2015) Far-Field Ocean Conditions and Concentrate Discharges Modeling Along the Saudi Coast of the Red Sea. In: Missimer T., Jones B., Maliva R. (eds) Intakes and Outfalls for Seawater Reverse-Osmosis Desalination Facilities. Environmental Science and Engineering. Springer, Cham
39. Nanninga, G. B., P. Saenz-Agudelo, P. Zhan, I. Hoteit, and M. L. Berumen (2015). Not finding Nemo: limited reef-scale retention in a coral reef fish, Coral Reefs: 1-10
40. Zhan, P., A. C. Subramanian, F. Yao, and I. Hoteit (2014), Eddies in the Red Sea: A statistical and dynamical study, J. Geophys. Res. Oceans, 119, 3909–3925
41. H., Thomas, A. Magdy, P. Zhan, G. Chen, G. Gopalakrishnan, I. Hoteit, C. D. Hansen, and M. Hadwiger (2014), Ovis: A framework for visual analysis of ocean forecast ensembles, IEEE Transactions on Visualization and Computer Graphics, vol.20, no.8, pp.1114-1126
42. Chen, X., P. Zhan*, J. Chen, & H. Qian (2011). Numerical study of current fields near the Yangtze Estuary and impact of Quick-EnKF assimilation. Acta Oceanologica Sinica, 30(5), 33-44