Progress of Research on Aeolian Sediment Transport Influenced by Tide

He Yanyu; Liu Jianhui; Cai Feng; Li Bailiang; Wang Lihui; Ning Qingqian

doi:10.7522/j.issn.1000-694X.2017.00024

Journal of Desert Research >

2018 , Vol. 38 >Issue 3: 455 - 463

DOI: https://doi.org/10.7522/j.issn.1000-694X.2017.00024

Progress of Research on Aeolian Sediment Transport Influenced by Tide

He Yanyu ,
Liu Jianhui ,
Cai Feng ,
Li Bailiang ,
Wang Lihui ,
Ning Qingqian

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1. Fuzhou University, Fuzhou 350000, China;
2. Island Research Center, State Oceanic Administration, Pingtan 350400, Fujian, China;
3. Xi'an Jiaotong-Livepool University, Suzhou 215024, Jiangsu, China

Received date: 2017-02-24

Revised date: 2017-04-06

Online published: 2018-11-06

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Abstract

Alternate wetting and drying beachface induced by tide is one of the most important process influencing beach aeolian sediment transport. From the aspects of temporal and spatial variabilities of surface moisture content and cyclical variation of wind fetch length, as well as their own effect on beach aeolian sediment transport in the environment of alternate wetting and drying induced by tide, this paper summarizes the main progress and achievements of beach aeolian sediment transport influenced by tide. The main conclusions of this review are shown as:(1) The relationship between surface moisture variabilities and tidal oscillation is nonlinear, which is separated by a double hysteresis effect induced by watertable and capillary fringe; (2) A positive correlation between aeolian sediment transport threshold and surface moisture has been found in the case of surface moisture less than critical moisture threshold and the beach aeolian transport system will nearly shut down once surface moisture greater than critical moisture threshold; (3) The correlation between aeolian mass flux and fetch length can be divided into three stages according to the equilibrium state of sediment transport:positive before equilibrium state, negative after equilibrium state and irrelevant during equilibrium state. Finally, some necessary future research directions in China are put forward, according to the present research situation of beach aeolian sediment transport influenced by tide.

Key words： tidal process; beach; aeolian sediment transport; surface moisture; wind fetch

Cite this article

He Yanyu , Liu Jianhui , Cai Feng , Li Bailiang , Wang Lihui , Ning Qingqian . Progress of Research on Aeolian Sediment Transport Influenced by Tide[J]. Journal of Desert Research, 2018 , 38(3) : 455 -463 . DOI: 10.7522/j.issn.1000-694X.2017.00024

References

[1] 吴正.风沙地貌学[M].北京:科学出版社,1987.
[2] 陈方.海坛岛海岸风沙特征及其发育[J].海洋科学,1994,18(6):46-50.
[3] 王颖,朱大奎.海岸沙丘成因的讨论[J].中国沙漠,1987,7(3):29-40.
[4] 刘建辉,郭占荣,雷怀彦,等.福建长乐东部海岸沙丘风蚀坑研究[J].应用海洋学学报,2008,27(2):230-236.
[5] 吴正.华南海岸风沙地貌研究[M].北京:科学出版社,1995.
[6] 陈方,朱大奎.闽江口海岸沙丘的形成与演化[J].中国沙漠,1996,16(3):227-233.
[7] 陈方,贺辉扬.海岸沙丘沙运动特征若干问题的研究——以闽江口南岸为例[J].中国沙漠,1997,17(4):355-361.
[8] 刘建辉.长乐东部海岸沙丘的沉积与移动特征研究[D].厦门:厦门大学,2007.
[9] 董玉祥,马骏.风速对海岸风沙流中不同粒径沙粒垂向分布的影响[J].中山大学学报:自然科学版,2008,47(5):98-103.
[10] 董玉祥,马骏.输沙量对海岸沙丘表面风沙流中不同粒径沙粒垂向分布的影响[J].中山大学学报:自然科学版,2009,48(3):102-108.
[11] 董玉祥,黄德全,马骏.海岸沙丘表面不同部位风沙流中不同粒径沙粒垂向分布的变化[J].地理科学,2010,15(3):391-397.
[12] 董玉祥.海岸现代风成砂粒度参数特征的研究——以中国温带海岸为例[J].沉积学报,2002,20(4):656-662.
[13] 董玉祥.波浪-海滩-沙丘相互作用模式研究述评[J].中国沙漠,2010,30(4):796-800.
[14] 董玉祥,黄德全,张雪琴.海岸爬坡沙丘形态对台风响应——以2014年"麦德姆"台风为例[J].中国沙漠,2016,36(4):865-870.
[15] 张雪琴,董玉祥,杨林,等.海岸沙丘近表层粒度对台风的响应[J].中国沙漠,2016,36(6):1519-1526.
[16] Heiss J W,Ullman W J,Michael H A.Swash zone moisture dynamics and unsaturated infiltration in two sandy beach aquifers[J].Estuarine Coastal & Shelf Science,2014,143(3):20-31.
[17] Namikas S L,Edwards B L,Bitton M C A,et al.Temporal and spatial variabilities in the surface moisture content of a fine-grained beach[J].Geomorphology,2010,114(3):303-310.
[18] Wiggs G F S,Baird A J,Atherton R J.The dynamic effects of moisture on the entrainment and transport of sand by wind[J].Geomorphology,2004,59(1/2/3/4):13-30.
[19] Davidson-Arnott R G D,Yang Y,Ollerhead J,et al.The effects of surface moisture on aeolian sediment transport threshold and mass flux on a beach[J].Earth Surface Processes & Landforms,2008,33(1):55-74.
[20] Atherton R J,Wiggs G F S.Inter-tidal dynamics of surface moisture content on a meso-tidal beach[J].Journal of Coastal Research,2001,17(2):482-489.
[21] Darke I,Neuman M K.Field study of beach water content as a guide to wind erosion potential[J].Journal of Coastal Research,2008,24(5):1200-1208.
[22] Emery K O,Foster J F.Water tables in marine beaches[J].Journal of Marine Research,1948,7:644-654.
[23] Emery K O,Gale J F.Swash and swash mark[J].Eos Transactions American Geophysical Union,1951,32(1):31-36.
[24] Lanyon J A,Eliot I G,Clarke D J.Observations of shelf waves and bay seiches from tidal and beach groundwater-level records[J].Marine Geology,1982,49(1/2):23-42.
[25] Lanyon J A,Eliot I G,Clarke D J.Groundwater-level variation during semidiurnal spring tidal cycles on a sandy beach[J].Marine & Freshwater Research,1982,33(3):377-400.
[26] Turner I.The total water content of sandy beaches[J].Journal of Coastal Research,1993,15(15):11-26.
[27] Turner I.Water table outcropping on macro-tidal beaches:a simulation model[J].Marine Geology,1993,115(3/4):227-238.
[28] Raubenheimer B,Guza R T,Elgar S.Tidal water table fluctuations in a sandy ocean beach[J].Water Resources Research,1999,35(8):2313-2320.
[29] Horn D P.Beach groundwater dynamics[J].Geomorphology,2002,48(1/2/3):121-146.
[30] Ericksen N J.Measurement of tide induced change to water table profiles in coarse and fine sand beaches along Pegasus Bay,Canterbury[J]. Earth Science Journal,1970,4(1):24-31.
[31] Nielsen P.Tidal dynamics of the water table in beaches[J].Water Resources Research,1990,26(9):2127-2134.
[32] Hegge B J,Masselink G.Groundwater-table responses to wave run-up-an experimental-study from western Australia[J].Journal of Coastal Research,1991,7(3):623-634.
[33] Masselink G,Short A D.The effect of tide range on beach morphodynamics and morphology:a conceptual beach model[J].Journal of Coastal Research,1993,9(3):785-800.
[34] Oblinger A,Anthony E J.Surface Moisture Variations on a Multibarred Macrotidal Beach:implications for Aeolian Sand Transport[J].Journal of Coastal Research,2009,24:1194-1199.
[35] Turner I L,Nielsen P.Rapid water table fluctuations within the beach face:implications for swash zone sediment mobility?[J].Coastal Engineering,1997,32(1):45-59.
[36] Dingman S L.Fluvial Hydrology[M].San Francisco,USA:Freeman,1984.
[37] Akiba M.The threshold wind speed of sand grains on a wetted sand surface[J].Journal of Agricultural Engineering in Japan,1933,5:157-174.
[38] Bisal F,Hsieh J.Influence of moisture on erodibility of soil by wind[J].Soil Science,1966,102(3):143-146.
[39] Belly P Y.Sand Movement by Wind[R].Army Coastal Engineering Research Center Bibliography,1964.
[40] Azizov A.Influence of soil moisture on the resistance of soil to wind erosion[J].Soviet Soil Science,1977,9:105-108.
[41] Logie M.Influence of roughness elements and soil moisture on the resistance of sand to wind erosion[C]//Acidic Soils and Geomorphic Processes:Proceedings of the International Conference of the International Society of Soil Science.Jerusalem,Israel,1981.
[42] Mckennaneuman C,Nickling W G.A theoretical and wind tunnel investigation of the effect of capillary water on the entrainment of sediment by wind[J].Canadian Journal of Soil Science,1989,69(69):79-96.
[43] 韩庆杰,屈建军,廖空太,等.海岸湿沙表面风沙传输特征的风洞实验研究[J].中国沙漠,2012,32(6):1512-1521.
[44] Neuman M K,Scott M M.A wind tunnel study of the influence of pore water on aeolian sediment transport[J].Journal of Arid Environments,1998,39(3):403-419.
[45] Dong Z B,Liu X P,Wang X M.Wind initiation threshold of the moistened sand[J].2002,29(12):25-31.
[46] 韩庆杰,屈建军,张克存,等.华南热带湿润海滩风蚀模数的风洞研究[J].水土保持学报,2010,24(1):37-40.
[47] 韩庆杰,屈建军,张克存,等.海滩湿润沙面起动摩阻风速的风洞实验[J].中国沙漠,2011,31(6):1373-1379.
[48] Svasek J N,Terwindt J H J.Measurements of sand transport by wind on a natural beach[J].Sedimentology,1974,21(21):311-322.
[49] Jackson N L,Nordstrom K F.Effects of time-dependent moisture content of surface sediments on aeolian transport rates across a beach,Wildwood,New Jersey,U.S.A.[J].Earth Surface Processes & Landforms,1997,22(7):611-621.
[50] Wiggs G F S,Atherton R J,Baird A J.Thresholds of aeolian sand transport:establishing suitable values[J].Sedimentology,2004,51(1):95-108.
[51] Stout J E,Zobeck T M.Establishing the threshold condition for soil movement in wind-eroding fields[C]//Proceedings of the International Conference on Air Pollution from Agricultural Operations.Kansas City,USA.1996.
[52] Bauer B O,Davidson-Arnott R G D,Hesp P A,et al.Aeolian sediment transport on a beach:surface moisture,wind fetch,and mean transport[J].Geomorphology,2009,105(1):106-116.
[53] Delgado-Fernandez I.A review of the application of the fetch effect to modelling sand supply to coastal foredunes[J].Aeolian Research,2010,2(2):61-70.
[54] Bauer B O,Davidson-Arnott R G D.A general framework for modeling sediment supply to coastal dunes including wind angle,beach geometry,and fetch effects[J].Geomorphology,2002,49(1):89-108.
[55] Nordstrom K F,Jackson N L.The role of wind direction in aeolian transport on a narrow sandy beach[J].Earth Surface Processes & Landforms,1993,18(8):675-685.
[56] Jackson D W T,Cooper J A G.Beach fetch distance and aeolian sediment transport[J].Sedimentology,1999,46(3):517-522.
[57] Lynch K,Jackson D,Cooper A.The fetch effect on aeolian sediment transport on a sandy beach:a case study from Magilligan Strand,Northern Ireland[J].Earth Surface Processes & Landforms,2016,41(8):1129-1135.
[58] Dong Z B,Wang H T,Liu X P,et al.The blown sand flux over a sandy surface:a wind tunnel investigation on the fetch effect[J].Geomorphology,2004,57(1):117-127.
[59] Dong Z B,Mu Q S,Liu X P.Defining the threshold wind velocity for moistened sediments[J].Journal of Geophysical Research Atmospheres,2007,112(112):119-120.

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