This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Bell, R. & Kirtman , B. (2018). Seasonal forecasting of winds, waves and currents in the north pacific. Journal of Operational Oceanography 11(1): 11–26.BellR.KirtmanB.2018Seasonal forecasting of winds, waves and currents in the north pacific111112610.1080/1755876X.2018.1438342Search in Google Scholar
Bi, F. (2013). Study on the influence of waves on the circulation transport and the dissipation characteristics of the swell wave. Unpublished doctoral dissertation. Ocean University of China.BiF.2013Unpublished doctoral dissertationOcean University of ChinaSearch in Google Scholar
Breivik, Ø., Janssen, P. A. & Bidlot, J.R. (2014). Approximate Stokes drift profiles in deep water. Journal of Physical Oceanography 44(9): 2433–2445.BreivikØ.JanssenP. A.BidlotJ.R.2014Approximate Stokes drift profiles in deep water4492433244510.1175/JPO-D-14-0020.1Search in Google Scholar
Breivik, Ø., Mogensen, K., Bidlot, J.R., Balmaseda, M.A. & Janssen, P.A. (2015). Surface wave effects in the NEMO ocean model: Forced and coupled experiments. Journal of Geophysical Research: Oceans 120(4): 2973–2992.BreivikØ.MogensenK.BidlotJ.R.BalmasedaM.A.JanssenP.A.2015Surface wave effects in the NEMO ocean model: Forced and coupled experiments12042973299210.1002/2014JC010565Search in Google Scholar
Breivik, Ø., Bidlot, J.R. & Janssen, P.A. (2016). A Stokes drift approximation based on the Phillips spectrum. Ocean Modelling 100: 49–56.BreivikØ.BidlotJ.R.JanssenP.A.2016A Stokes drift approximation based on the Phillips spectrum100495610.1016/j.ocemod.2016.01.005Search in Google Scholar
Chelton, D.B. & Freilich, M.H. (2005). Scatterometer-based assessment of 10-m wind analyses from the operational ecmwf and ncep numerical weather prediction models. Monthly Weather Review 133(2): 409–429.CheltonD.B.FreilichM.H.2005Scatterometer-based assessment of 10-m wind analyses from the operational ecmwf and ncep numerical weather prediction models133240942910.1175/MWR-2861.1Search in Google Scholar
Chen, G., Chapron, B., Ezraty, R. & Vandemark, D. (2002). A global view of swell and wind sea climate in the ocean by satellite altimeter and scatterometer. Journal of Atmospheric and Oceanic Technology 19(11): 1849–1859.ChenG.ChapronB.EzratyR.VandemarkD.2002A global view of swell and wind sea climate in the ocean by satellite altimeter and scatterometer19111849185910.1175/1520-0426(2002)019<1849:AGVOSA>2.0.CO;2Search in Google Scholar
Craik, A.D. & Leibovich, S. (1976). A rational model for Langmuir circulations. Journal of Fluid Mechanics 73(3): 401–426.CraikA.D.LeibovichS.1976A rational model for Langmuir circulations73340142610.1017/S0022112076001420Search in Google Scholar
Craik, A.D.D. (1977). The generation of Langmuir circulations by an instability mechanism. Journal of Fluid Mechanics 81(2): 209–223.CraikA.D.D.1977The generation of Langmuir circulations by an instability mechanism81220922310.1017/S0022112077001980Search in Google Scholar
Deng, Z., Wu K. & Yu T. (2007). Wave transport in the eastern boundary of the Pacific Ocean. Acta Oceanologica Sinica 29(6): 1–9.DengZ.WuK.YuT.2007Wave transport in the eastern boundary of the Pacific Ocean29619Search in Google Scholar
Deng, Z., Xie, L., Han, G., Zhang, X. & Wu, K. (2012). The effect of Coriolis-Stokes forcing on upper ocean circulation in a two-way coupled wave-current model. Chinese journal of oceanology and limnology 30(2): 321–335.DengZ.XieL.HanG.ZhangX.WuK.2012The effect of Coriolis-Stokes forcing on upper ocean circulation in a two-way coupled wave-current model30232133510.1007/s00343-012-1069-zSearch in Google Scholar
Deng, B. (2015). Research on the influence of ocean waves on the upper ocean. Unpublished doctoral dissertation. PLA University of Science and Technology.DengB.2015Unpublished doctoral dissertationPLA University of Science and TechnologySearch in Google Scholar
Elfouhaily, T., Chapron, B., Katsaros, K. & Vandemark, D. (1997). A unified directional spectrum for long and short wind-driven waves. Journal of Geophysical Research: Oceans 102(C7): 15781–15796.ElfouhailyT.ChapronB.KatsarosK.VandemarkD.1997A unified directional spectrum for long and short wind-driven waves102C7157811579610.1029/97JC00467Search in Google Scholar
Hasselmann, K. (1970). Wave-driven inertial oscillations. Geophysical and Astrophysical Fluid Dynamics 1(3–4): 463–502.HasselmannK.1970Wave-driven inertial oscillations13–446350210.1080/03091927009365783Search in Google Scholar
Huang, N.E. (1979). On surface drift currents in the ocean. Journal of Fluid Mechanics 91(1): 191–208.HuangN.E.1979On surface drift currents in the ocean91119120810.1017/S0022112079000112Search in Google Scholar
Huang, C., Qiao, F. & Song Z. (2008). The effect of the wave-induced mixing on the upper ocean temperature in a climate model. Acta Oceanol. 27(3): 104–111.HuangC.QiaoF.SongZ.2008The effect of the wave-induced mixing on the upper ocean temperature in a climate model273104111Search in Google Scholar
Jordi, A. & Wang, D. (2012). sbPOM: A parallel implementation of Princenton Ocean Model. Environmental Modelling & Software 38: 59–61.JordiA.WangD.2012sbPOM: A parallel implementation of Princenton Ocean Model38596110.1016/j.envsoft.2012.05.013Search in Google Scholar
Kara, A.B. & Hurlburt, H.E. (2006). Daily inter-annual simulations of SST and MLD using atmospherically forced OGCMs: Model evaluation in comparison to buoy time series. Journal of Marine Systems 62(1–2): 95–119.KaraA.B.HurlburtH.E.2006Daily inter-annual simulations of SST and MLD using atmospherically forced OGCMs: Model evaluation in comparison to buoy time series621–29511910.1016/j.jmarsys.2006.04.004Search in Google Scholar
Kenyon, K.E. (1970). Stokes transport. Journal of Geophysical Research 75(6): 1133–1135.KenyonK.E.1970Stokes transport7561133113510.1029/JC075i006p01133Search in Google Scholar
Langmuir, I. (1938). Surface motion of water induced by wind. Science 87(2250): 119–123.LangmuirI.1938Surface motion of water induced by wind87225011912310.1126/science.87.2250.11917742995Search in Google Scholar
Lewis, D.M. & Belcher, S.E. (2004). Time-dependent, coupled, Ekman boundary layer solutions incorporating Stokes drift. Dynamics of Atmospheres and Oceans 37(4): 313–351.LewisD.M.BelcherS.E.2004Time-dependent, coupled, Ekman boundary layer solutions incorporating Stokes drift37431335110.1016/j.dynatmoce.2003.11.001Search in Google Scholar
Li, J. & Heap, A.D. (2011). Environmental modelling & software. Ecological Informatics 6(5): 228–241.LiJ.HeapA.D.2011Environmental modelling & software6522824110.1016/j.ecoinf.2010.12.003Search in Google Scholar
Li, M., Zahariev, K. & Garrett, C. (1995). Role of Langmuir circulation in the deepening of the ocean surface mixed layer. Science 270(5244): 1955–1957.LiM.ZaharievK.GarrettC.1995Role of Langmuir circulation in the deepening of the ocean surface mixed layer27052441955195710.1126/science.270.5244.1955Search in Google Scholar
Li, M., Garrett, C. & Skyllingstad, E. (2005). A regime diagram for classifying turbulent large eddies in the upper ocean. Deep Sea Research Part I: Oceanographic Research Papers 52(2): 259–278.LiM.GarrettC.SkyllingstadE.2005A regime diagram for classifying turbulent large eddies in the upper ocean52225927810.1016/j.dsr.2004.09.004Search in Google Scholar
Li, S., Song J. & Sun Q. (2008). Effect of Stokes drift on upper ocean mixing. Acta Oceanologica Sinica 27(2): 11–20.LiS.SongJ.SunQ.2008Effect of Stokes drift on upper ocean mixing2721120Search in Google Scholar
Li, S., Song, J. & Fan, W. (2013). Effect of Langmuir circulation on upper ocean mixing in the South China Sea. Acta Oceanologica Sinica 32(3): 28–33.LiS.SongJ.FanW.2013Effect of Langmuir circulation on upper ocean mixing in the South China Sea323283310.1007/s13131-013-0285-5Search in Google Scholar
Liu Z., Shi J. & Jiang G. (2017). Effects of sea wave mixing on surface temperature simulation of tropical oceans. Journal of Tropical Oceanography 36(4): 77–86.LiuZ.ShiJ.JiangG.2017Effects of sea wave mixing on surface temperature simulation of tropical oceans3647786Search in Google Scholar
Longuet-Higgins, M.S. (1953). Mass transport in water waves. Phil. Trans. R. Soc. Lond. A 245(903): 535–581.Longuet-HigginsM.S.1953Mass transport in water waves24590353558110.1098/rsta.1953.0006Search in Google Scholar
Mellor, G.L. (1998). A Three Dimensional, Primitive Equation, Numerical Ocean Model (Users Guide). Available on the Princeton Ocean Model web site: http://www.aos.princeton.edu/WWWPUBLIC/htdocs.pomMellorG.L.1998Available on the Princeton Ocean Model web sitehttp://www.aos.princeton.edu/WWWPUBLIC/htdocs.pomSearch in Google Scholar
McPhaden, M.J. (1995). The tropical atmosphere ocean array is completed. Bulletin of the American Meteorological Society 76(5): 739–744.McPhadenM.J.1995The tropical atmosphere ocean array is completed76573974410.1175/1520-0477-76.5.739Search in Google Scholar
McWilliams, J.C., Sullivan, P.P. & Moeng, C.H. (1997). Langmuir turbulence in the ocean. Journal of Fluid Mechanics 334: 1–30.McWilliamsJ.C.SullivanP.P.MoengC.H.1997Langmuir turbulence in the ocean33413010.1017/S0022112096004375Search in Google Scholar
McWilliams, J.C. & Restrepo, J.M. (1999). The wave-driven ocean circulation. Journal of Physical Oceanography 29(10): 2523–2540.McWilliamsJ.C.RestrepoJ.M.1999The wave-driven ocean circulation29102523254010.1175/1520-0485(1999)029<2523:TWDOC>2.0.CO;2Search in Google Scholar
McWilliams, J.C., Restrepo, J.M. & Lane, E.M. (2004). An asymptotic theory for the interaction of waves and currents in coastal waters. Journal of Fluid Mechanics 511: 135–178.McWilliamsJ.C.RestrepoJ.M.LaneE.M.2004An asymptotic theory for the interaction of waves and currents in coastal waters51113517810.1017/S0022112004009358Search in Google Scholar
Murphy, A.H. (1995). The coefficients of correlation and determination as measures of performance in forecast verification. Weather and forecasting 10(4): 681–688.MurphyA.H.1995The coefficients of correlation and determination as measures of performance in forecast verification10468168810.1175/1520-0434(1995)010<0681:TCOCAD>2.0.CO;2Search in Google Scholar
Phillips, O.M. (1977). The dynamics of the upper ocean. Cambridge: Cambridge University Press.PhillipsO.M.1977CambridgeCambridge University PressSearch in Google Scholar
Polton, J.A., Lewis, D.M. & Belcher, S.E. (2005). The role of wave-induced Coriolis–Stokes forcing on the wind-driven mixed layer. Journal of Physical Oceanography 35(4): 444–457.PoltonJ.A.LewisD.M.BelcherS.E.2005The role of wave-induced Coriolis–Stokes forcing on the wind-driven mixed layer35444445710.1175/JPO2701.1Search in Google Scholar
Polton, J.A. & Belcher, S.E. (2007). Langmuir turbulence and deeply penetrating jets in an unstratified mixed layer. Journal of Geophysical Research: Oceans 112(C9).PoltonJ.A.BelcherS.E.2007Langmuir turbulence and deeply penetrating jets in an unstratified mixed layer112C910.1029/2007JC004205Search in Google Scholar
Qiao, F., Yuan, Y., Ezer, T., Xia, C., Yang, Y. et al. (2010). A three-dimensional surface wave–ocean circulation coupled model and its initial testing. Ocean Dynamics 60(5): 1339–1355.QiaoF.YuanY.EzerT.XiaC.YangY.et al2010A three-dimensional surface wave–ocean circulation coupled model and its initial testing6051339135510.1007/s10236-010-0326-ySearch in Google Scholar
Rascle, N., Ardhuin, F., Queff eulou, P. & Croizé-Fillon, D. (2008). A global wave parameter database for geophysical applications. Part 1: Wave-current–turbulence interaction parameters for the open ocean based on traditional parameterizations. Ocean Modelling 25(3–4): 154–171.RascleN.ArdhuinF.Queff eulouP.Croizé-FillonD.2008A global wave parameter database for geophysical applications. Part 1: Wave-current–turbulence interaction parameters for the open ocean based on traditional parameterizations253–415417110.1016/j.ocemod.2008.07.006Search in Google Scholar
Rascle, N. & Ardhuin, F. (2013). A global wave parameter database for geophysical applications. Part 2: Model validation with improved source term parameterization. Ocean Modelling 70: 174–188.RascleN.ArdhuinF.2013A global wave parameter database for geophysical applications. Part 2: Model validation with improved source term parameterization7017418810.1016/j.ocemod.2012.12.001Search in Google Scholar
Restrepo, J.M. & Mcwilliams, J.C. (2007). Wave current interaction: a comparison of radiation-stress and vortex-force representations. Journal of Physical Oceanography 37(5): 1122.RestrepoJ.M.McwilliamsJ.C.2007Wave current interaction: a comparison of radiation-stress and vortex-force representations375112210.1175/JPO3043.1Search in Google Scholar
Reynolds, R.W., Smith, T.M., Liu, C., Chelton, D.B., Casey, K.S. et al. (2007). Daily high-resolution-blended analyses for sea surface temperature. Journal of Climate 20(22): 5473–5496.ReynoldsR.W.SmithT.M.LiuC.CheltonD.B.CaseyK.S.et al2007Daily high-resolution-blended analyses for sea surface temperature20225473549610.1175/2007JCLI1824.1Search in Google Scholar
Shi, J., Zhou, L. & Yang, L.Y. (2013). Influence of sea spray droplets on drag coefficient in high wind speed. Acta Physica Sinica 62(3): 039201–039209.ShiJ.ZhouL.YangL.Y.2013Influence of sea spray droplets on drag coefficient in high wind speed62303920103920910.7498/aps.62.039201Search in Google Scholar
Skyllingstad, E.D. & Denbo, D.W. (1995). An ocean large-eddy simulation of Langmuir circulations and convection in the surface mixed layer. Journal of Geophysical Research: Oceans 100(C5): 8501–8522.SkyllingstadE.D.DenboD.W.1995An ocean large-eddy simulation of Langmuir circulations and convection in the surface mixed layer100C58501852210.1029/94JC03202Search in Google Scholar
Smith, J.A. (1998). Evolution of Langmuir circulation during a storm. Journal of Geophysical Research: Oceans 103(C6): 12649–12668.SmithJ.A.1998Evolution of Langmuir circulation during a storm103C6126491266810.1029/97JC03611Search in Google Scholar
Song, Z., Qiao, F. & Yang, Y. (2006). Improvement of cold tongue simulation in the coupled model of ocean-atmosphere in the tropical Pacific by wave-induced mixing. Advances in Natural Science 16(9): 1138–1145.SongZ.QiaoF.YangY.2006Improvement of cold tongue simulation in the coupled model of ocean-atmosphere in the tropical Pacific by wave-induced mixing16911381145Search in Google Scholar
Song, Z., Qiao, F., & Song, Y. (2012). Response of the equatorial basin-wide SST to non-breaking surface wave-induced mixing in a climate model: An amendment to tropical bias. Journal of Geophysical Research: Oceans 117(C11).SongZ.QiaoF.SongY.2012Response of the equatorial basin-wide SST to non-breaking surface wave-induced mixing in a climate model: An amendment to tropical bias117C1110.1029/2012JC007931Search in Google Scholar
Stokes, G.G. (1847). On the theory of oscillatory waves. Transaction of the Cambridge Philosophical Society 8: 441–455.StokesG.G.1847On the theory of oscillatory waves844145510.1017/CBO9780511702242.013Search in Google Scholar
Sun, F., Zhang, C. & Shang, S.(2007). Preliminary verification of sea surface temperature of AVHRR, TMI and MODIS remote sensing in some parts of the western Pacific Ocean. Journal of Xiamen University: Natural Science 46(s1): 1–5.SunF.ZhangC.ShangS.2007Preliminary verification of sea surface temperature of AVHRR, TMI and MODIS remote sensing in some parts of the western Pacific Ocean46s115Search in Google Scholar
Sun, F., Gao, S., Wang, W. & Qian, C. (2004). Wave-induced stress and estimation of its driven effect on currents. Science in China Ser. D: Earth Sciences 47(12): 1147–1154.SunF.GaoS.WangW.QianC.2004Wave-induced stress and estimation of its driven effect on currents47121147115410.1360/02yd0292Search in Google Scholar
Swail, V.R. & Cox, A.T. (2000). On the use of ncep–ncar reanalysis surface marine wind fields for a long-term north atlantic wave hindcast. Journal of Atmospheric & Oceanic Technology 17(17): 532–545.SwailV.R.CoxA.T.2000On the use of ncep–ncar reanalysis surface marine wind fields for a long-term north atlantic wave hindcast171753254510.1175/1520-0426(2000)017<0532:OTUONN>2.0.CO;2Search in Google Scholar
Tamura, H., Miyazawa, Y. & Oey, L.Y. (2012). The Stokes drift and wave induced-mass flux in the North Pacific. Journal of Geophysical Research: Oceans 117(C8).TamuraH.MiyazawaY.OeyL.Y.2012The Stokes drift and wave induced-mass flux in the North Pacific117C810.1029/2012JC008113Search in Google Scholar
Tolman, H.L. & Chalikov, D. (1996). Source terms in a third-generation wind wave model. Journal of Physical Oceanography 26(11): 2497–2518.TolmanH.L.ChalikovD.1996Source terms in a third-generation wind wave model26112497251810.1175/1520-0485(1996)026<2497:STIATG>2.0.CO;2Search in Google Scholar
Tolman, H.L. (2009). User manual and system documentation of WAVEWATCH III TM version 3.14. Technical note, MMAB Contribution, 276, 220.TolmanH.L.2009Technical note, MMAB Contribution, 276, 220Search in Google Scholar
Wang, Z. (2012). Study on the influence of Stokes-drift on the upper ocean. Unpublished doctoral dissertation. Ocean University of China.WangZ.2012Unpublished doctoral dissertationOcean University of ChinaSearch in Google Scholar
Wang, Z., Wu, K., Dong, S., Deng, Z.A. & Zhang, X. (2015). Effect of wave-induced Stokes drift on the dynamics of ocean mixed layer. Chinese journal of oceanology and limnology 33(1): 233–242.WangZ.WuK.DongS.DengZ.A.ZhangX.2015Effect of wave-induced Stokes drift on the dynamics of ocean mixed layer33123324210.1007/s00343-015-4036-7Search in Google Scholar
Webb, A. & Fox-Kemper, B. (2011). Wave spectral moments and Stokes drift estimation. Ocean modelling 40(3–4): 273–288.WebbA.Fox-KemperB.2011Wave spectral moments and Stokes drift estimation403–427328810.1016/j.ocemod.2011.08.007Search in Google Scholar
Webb, A. & Fox-Kemper, B. (2015). Impacts of wave spreading and multidirectional waves on estimating Stokes drift. Ocean Modelling 96: 49–64.WebbA.Fox-KemperB.2015Impacts of wave spreading and multidirectional waves on estimating Stokes drift96496410.1016/j.ocemod.2014.12.007Search in Google Scholar
Weber, J.E. (1983). Attenuated wave-induced drift in a viscous rotating ocean. Journal of Fluid Mechanics 137: 115–129.WeberJ.E.1983Attenuated wave-induced drift in a viscous rotating ocean13711512910.1017/S0022112083002311Search in Google Scholar
Wu, J. (1982). Wind-stress coefficients over sea surface from breeze to hurricane. Journal of Geophysical Research Oceans 87(C12): 9704–9706.WuJ.1982Wind-stress coefficients over sea surface from breeze to hurricane87C129704970610.1029/JC087iC12p09704Search in Google Scholar
Xu, Z. & Bowen, A. J. (1994). Wave- and Wind-Driven Flow in Water of Finite Depth. Journal of Physical Oceanography 24: 1850–1866.XuZ.BowenA. J.1994Wave- and Wind-Driven Flow in Water of Finite Depth241850186610.1175/1520-0485(1994)024<1850:WAWDFI>2.0.CO;2Search in Google Scholar
Yan, M., Song, Q., Lin, M. (2016). Cross-alignment analysis of sea surface temperature data of multi-source microwave radiometer in the Northwest Pacific Ocean. Acta Oceanica Sinica 38(7): 32–47.YanM.SongQ.LinM.2016Cross-alignment analysis of sea surface temperature data of multi-source microwave radiometer in the Northwest Pacific Ocean3873247Search in Google Scholar
Zhang, J., Wang, W. & Guan, C. (2011). Analysis of the global swell distributions using ECMWF Re-analyses wind wave data. Journal of Ocean University of China 10(4): 325–330.ZhangJ.WangW.GuanC.2011Analysis of the global swell distributions using ECMWF Re-analyses wind wave data10432533010.1007/s11802-011-1859-5Search in Google Scholar
Zhang, K., Wu, K. & Hu, B. (2009). Seasonal changes in the North Pacific wave transport and the western boundary flow. Ocean Limae Bulletin (4): 17–24.ZhangK.WuK.HuB.2009Seasonal changes in the North Pacific wave transport and the western boundary flow41724Search in Google Scholar
Zhang, X., Wang, Z., Wang, B., Wu, K., Han, G. et al. (2014). A numerical estimation of the impact of Stokes drift on upper ocean temperature. Acta Oceanologica Sinica 33(7): 48–55.ZhangX.WangZ.WangB.WuK.HanG.et al2014A numerical estimation of the impact of Stokes drift on upper ocean temperature337485510.1007/s13131-014-0507-5Search in Google Scholar
Zhang, X., Wang, Z. & Wang, B. (2015). Study on the temporal and spatial distribution characteristics of global Stokes drifting. Marine Sciences 39(1): 93–103.ZhangX.WangZ.WangB.2015Study on the temporal and spatial distribution characteristics of global Stokes drifting39193103Search in Google Scholar
Zhang, Y. (2013). Study on the influence of wave on energy input and mass transport in Ekman layer. Unpublished doctoral dissertation. Ocean University of China.ZhangY.2013Unpublished doctoral dissertationOcean University of ChinaSearch in Google Scholar
Zheng, C., Zhou, L., Shi, W., Li, X. & Huang, C. (2015). Decadal variability of global ocean significant wave height. Journal of Ocean University of China 14(5): 778–782.ZhengC.ZhouL.ShiW.LiX.HuangC.2015Decadal variability of global ocean significant wave height14577878210.1007/s11802-015-2484-5Search in Google Scholar