1. Risk assessment and mitigation for seawall wave overtopping in the context of climate change (主持人, S$ 627,200, Building and Construction Authority, 2018.4-2021.8)
2. Eco-engineering Singapore’s seawalls for enhancing biodiversity (参与者, S$ 819,318.38, National Research Foundation, MSRDP program, 2016.10-2021.4)
3. On sediment transport in wave-current benthic boundary layer (参与者, S$ 755,376, Ministry of Education, Tier-2, 2019.5-2022.5)
4. Full-scale experimental study of sediment transport by oscillatory flows and currents (主持人, S$ 180,000, Singapore-MIT Alliance for Research and Technology, 2015.4-2017.3, 已结题)
5. Sheet-flow sediment transport in the coastal environment (主持人, S$ 150,000, Ministry of Education, Tier-1, 2015.3-2018.8, 已结题)
6. Sediment transport rates in combined wave-current flows (主持人, S$ 167,417, Singapore-MIT Alliance for Research and Technology, 2013.9-2015.3, 已结题)
7. Turbulent bottom boundary layers under random waves (主持人, S$179,900, Ministry of Education, NUS faculty member start-up fund, 2013.10-2016.10, 已结题)
学术期刊:
corresponding author*, Supervised PhD. Student, Supervised Post-doc fellow
1. Yuan, J.* and O.S. Madsen (2014), Experimental study of turbulent oscillatory boundary layers in an oscillating water tunnel. Coastal Engineering. 89: p. 63-84 doi: http://dx.doi.org/10.1016/j.coastaleng.2014.03.007.
2. Yuan, J.* and O.S. Madsen (2015), Experimental and theoretical study of wave–current turbulent boundary layers. Journal of Fluid Mechanics. 765: p. 480-523 doi: https://doi.org/10.1017/jfm.2014.746.
3. Yuan, J.*, Turbulent boundary layers under irregular waves and currents: experiments and the equivalent-wave concept (2016). Journal of Geophysical Research: Oceans. 121(4): p. 2616-2640 doi: 10.1002/2015JC011551.
4. Yuan, J.* and S.M. Dash (2017), Experimental investigation of turbulent wave boundary layers under irregular coastal waves. Coastal Engineering. 128: p. 22-36 doi: https://doi.org/10.1016/j.coastaleng.2017.07.005.
5. Yuan, J.*, Z. Li, and O.S. Madsen (2017), Bottom-slope-induced net sheet-flow sediment transport rate under sinusoidal oscillatory flows. Journal of Geophysical Research: Oceans. 122(1): p. 236-263 doi: 10.1002/2016JC011996.
6. Yuan, J.* and W. Tan (2018), Modeling net sheet-flow sediment transport rate under skewed and asymmetric oscillatory flows over a sloping bed. Coastal Engineering. 136: p. 65-80 doi: https://doi.org/10.1016/j.coastaleng.2018.02.004.
7. Yuan, J.* and D. Wang (2018), Experimental investigation of total bottom shear stress for oscillatory flows over sand ripples. Journal of Geophysical Research: Oceans. 123(9): p. 6481-6502 doi:10.1029/2018JC013953.
8. Wang, D. and J. Yuan* (2018), Bottom‐slope‐induced net sediment transport rate under oscillatory flows in the rippled‐bed regime. Journal of Geophysical Research: Oceans, 123, 7308–7331. doi:10.1029/2018JC013810.
9. Önder, A. and J. Yuan (2019), Turbulent dynamics of sinusoidal oscillatory flow over a wavy bottom. Journal of Fluid Mechanics, 858, 264-314. doi:10.1017/jfm.2018.754
10. Zhao, K., J. Yuan*, et al. (2019), Modelling surface temperature of granite seawalls in Singapore, Case Studies in Thermal Engineering 13: 100395.
11. Tan, W., and J. Yuan* (2019), Experimental study of sheet-flow sediment transport under nonlinear oscillatory flow over a sloping bed, Coastal Engineering, 147, 1-11. doi:https://doi.org/10.1016/j.coastaleng.2019.01.002.
12. Wang, D., and J. Yuan* (2019), Geometric characteristics of coarse-sand ripples generated by oscillatory flows: A full-scale experimental study. Coastal Engineering, 147, 159-174. doi:https://doi.org/10.1016/j.coastaleng.2019.02.007.
13. Yuan, J.*, and Wang, D. ( 2019), An experimental investigation of acceleration‐skewed oscillatory flow over vortex ripples. Journal of Geophysical Research: Oceans, 124., https://doi.org/10.1029/2019JC015487
14. Wang, D. and J. Yuan* (2020), Modelling of net sediment transport rate due to wave-driven oscillatory flows over vortex ripples Applied Ocean Research, vol. 94, p. 101979, doi: https://doi.org/10.1016/j.apor.2019.101979.
15. Wang, D. and J. Yuan* (2020), Measurements of net sediment transport rate under asymmetric oscillatory flows over wave-generated sand ripples, Coastal Engineering, vol. 155, p. 103583, doi: https://doi.org/10.1016/j.coastaleng.2019.103583
16. Cao, D., Chen, H*., & Yuan, J. (2021). Inline force on human body due to non-impulsive wave overtopping at a vertical seawall. Ocean Engineering, 219(October 2020), 108300. https://doi.org/10.1016/j.oceaneng.2020.10830
17. Cao, D., Yuan, J.*, Chen, H., Zhao, K., & Li-Fan Liu, P. (2021). Wave overtopping flow striking a human body on the crest of an impermeable sloped seawall. Part I: physical modeling. Coastal Engineering, 167(September 2020), 103891. https://doi.org/10.1016/j.coastaleng.2021.103891
18. Chen, H., Yuan, J*., Cao, D., & Liu, P. (2021). Wave overtopping flow striking a human body on the crest of an impermeable sloped seawall. Part II: Numerical modelling. Coastal Engineering, 103892. https://doi.org/https://doi.org/10.1016/j.coastaleng.2021.103892
19. Tan, W., and Yuan, J* (2021). A two-layer numerical model for coastal sheet-flow sediment transport. Journal of Geophysical Research: Oceans, 126, e2021JC017241.
20. Cao, D., Chen, H, Yuan, J.* (2021). Towards modeling wave-induced forces on an armour layer unit of rubble mound coastal revetments. Ocean Engineering (Accepted).
会议:
1. Yuan, J., and O.S. Madsen (2010), On choice of random wave simulations in the surf zone processes, the 32nd international conference on coastal engineering, Shanghai, China, 2010
2. Yuan, J., E. S. Chan, and O.S. Madsen (2012), Experimental study of turbulent oscillatory boundary layers in a new oscillatory water tunnel, the 33rd international conference on coastal engineering, Santander, Spain, 2012
3. Yuan, J., and O.S. Madsen (2014), Experimental determination of bottom shear stress for turbulent oscillatory flows in oscillatory water tunnels, the 34th international conference on coastal engineering, Seoul, South Korea, 2014.
4. Yuan, J., D. Wang and O.S. Madsen (2017), A laser-based bottom profiler system for measuring net sediment transport rates in an oscillatory water tunnel, Coastal Dynamics, 2017, Helsingør, Denmark, pp. 1495-1505.
5. Yuan, J., and D. Wang (2018), Form drag and equivalent sand-grain roughness for wave-generated sand ripples, the 36th international conference on coastal engineering, Baltimore, MD, U.S, 2018.
6. Wang, D. and J. Yuan (2018), Geometric characteristics of wave-generated sand ripples: a full-scale experimental study, the 36th international conference on coastal engineering, Baltimore, MD, U.S, 2018.
7. Zhao K., J. Yuan, et al. (2018), Modeling tide’s influence on seawall’s surface temperature in tropical regions, the 36th international conference on coastal engineering, Baltimore, MD, U.S, 2018.
8. Tan W. and J. Yuan (2019), A process-based sediment transport model for sheet flows with the pickup layer resolved in an empirical way, in: International Conference on Asian and Pacific Coasts, Springer. pp. 385-392.
水利工程系
