57 St?ren E N, Dahl S O, Nesje A, et al.2010. Identifying the sedimentary imprint of high-frequency Holocene river floods in lake sediments: development and application of a new method[J]. Quaternary Science Reviews, 29(23-24): 3021-3033.
[2]
58 Thorndycraft V R, Benito G, Rico M, et al.2005. A long-term flood discharge record derived from slackwater flood deposits of the Llobregat River, NE Spain[J]. Journal of Hydrology, 313(1-2): 16-31.
[3]
59 Vannière B, Magny M, Joannin S, et al.2013. Orbital changes, variation in solar activity and increased anthropogenic activities: controls on the Holocene flood frequency in the Lake Ledro area, Northern Italy[J]. Climate of the Past, 9(3): 1193-1209.
[4]
60 Vasskog K, Nesje A, St?ren E N, et al.2011. A Holocene record of snow-avalanche and flood activity reconstructed from a lacustrine sedimentary sequence in Oldevatnet, western Norway[J]. the Holocene, 21(4): 597-614.
[5]
61 Viglione A, Chirico G B, Woods R, et al.2010. Generalised synthesis of space-time variability in flood response: an analytical framework[J]. Journal of Hydrology, 394(1-2): 198-212.
[6]
62 Waylen P R, Caviedes C N. 1986. El Ni?o and annual floods on the north Peruvian littoral[J]. Journal of Hydrology, 89(1-2): 141-156.
[7]
63 Wells L E. 1990. Holocene history of the El Ni?o phenomenon as recorded in flood sediments of northern coastal Peru[J]. Geology, 18(11): 1134-1137.
[8]
64 Wilhelm B, Arnaud F, Enters D, et al.2012. Does global warming favour the occurrence of extreme floods in European Alps? first evidences from a NW Alps proglacial lake sediment record[J]. Climatic Change, 113(3-4): 563-581.
[9]
65 Wirth S B. 2013. The Holocene flood history of the central Alps reconstructed from lacustrine sediments: frequency, intensity and controlling climate factors[D]. Zürich, Switzerian: ETH Zürich.
[10]
66 Wirth S B, Gilli A, Simonneau A, et al.2013. A 2000 year long seasonal record of floods in the southern European Alps[J]. Geophysical Research Letters, 40(15): 4025-4029.
[11]
67 Wirth S B, Glur L, Gilli A, et al.2013. Holocene flood frequency across the Central Alps: solar forcing and evidence for variations in North Atlantic atmospheric circulation[J]. Quaternary Science Reviews, 80: 112-128.
[12]
68 Wolfe B B, Hall R I, Last W M, et al.2006. Reconstruction of multi-century flood histories from oxbow lake sediments, Peace-Athabasca Delta, Canada[J]. Hydrological Processes, 20(19): 4131-4153.
[13]
69 Xia Z K, Wang Z H, Zhao Q C. 2004. Extreme flood events and climate change around 3500 a BP in the Central Plains of China[J]. Science in China D: Earth Sciences, 47(7): 599-606.
[14]
70 Zhang Q, Chen J Q, Becker S. 2007. Flood/drought change of last millennium in the Yangtze Delta and its possible connections with Tibetan climatic changes[J]. Global and Planetary Change, 57(3-4): 213-221.
[15]
71 Zhang Q, Zhu C, Cheng J. 2002. Preliminary study on the flooding and drought calamity during past 1500 years in the Hai'an region, Jiangsu Province[J]. Chinese Geographical Science, 12(2): 146-151.
[16]
72 Zhou A F, Sun H L, Chen F H, et al.2010. High-resolution climate change in mid-late Holocene on Tianchi Lake, Liupan Mountain in the Loess Plateau in central China and its significance[J]. Chinese Science Bulltin, 55(20): 2118-2121.
[17]
55 Sui J Y, Koehler G. 2001. Rain-on-snow induced flood events in southern Germany[J]. Journal of Hydrology, 252(1-4): 205-220.
[18]
56 Swierczynski T, Lauterbach S, Dulski P, et al.2013. Late Neolithic Mondsee culture in Austria: living on lakes and living with flood risk[J]. Climate of the Past, 9(4): 1601-1612.
[19]
1 沈吉, 薛滨, 吴敬禄, 等. 2010. 湖泊沉积与环境演化[M]. 北京: 科学出版社. [Shen J, Xue B, Wu J L, et al.2010. Lake sediments and environment changes[M]. Beijing, China: Science Press. ]
[20]
2 杨达源, 谢悦波. 1997. 古洪水平流沉积[J]. 沉积学报, 15(3): 29-32. [Yang D Y, Xie Y B. 1997. Paleoflood slack-water deposits[J]. Acta Sedimentologica Sinica, 15(3): 29-32. ]
[21]
3 周爱锋. 2007. 晚全新世苏干湖年纹层沉积及其环境记录[D]. 兰州: 兰州大学. [Zhou A F. 2007. Varve chronology and late Holocene environmental changes in Sugan Lake, Northern Qaidam Basin[D]. Lanzhou, China: Lanzhou University. ]
[22]
4 朱诚, 宋健, 尤坤元, 等. 1996. 上海马桥遗址文化断层成因研究[J]. 科学通报, 41(2): 148-152. [Zhu C, Song J, You K Y, et al.1996. Middle and late Holocene environmental changes of Maqiao, Shanghai[J]. Chinese Science Bulletin, 41(2): 148-152. ]
[23]
5 Arnaud F, Lignier V, Revel M, et al.2002. Flood and earthquake disturbance of 210Pb geochronology (Lake Anterne, NW Alps)[J]. Terra Nova, 14(4): 225-232.
[24]
6 Arnaud F, Revel M, Chapron E, et al.2005. 7200 years of Rh?ne river flooding activity in Lake Le Bourget, France: a high-resolution sediment record of NW Alps hydrology[J]. the Holocene, 15(3): 420-428.
[25]
7 Baker V R. 1983. Paleoflood hydrologic techniques for the extension of streamflow records[C]//Naomi Kassabian. Improving estimates from flood stufies. Washington, DC:Transportation Research Record: 18-23.
[26]
8 Baker V R. 1987. Paleoflood hydrology and extraordinary flood events[J]. Journal of Hydrology, 96(1-4): 79-99.
[27]
9 Baker V R. 2008. Paleoflood hydrology: origin, progress, prospects[J]. Geomorphology, 101(1-2): 1-13.
[28]
10 Benito G, Thorndycraft V R. 2005. Palaeoflood hydrology and its role in applied hydrological sciences[J]. Journal of Hydrology, 313(1-2): 3-15.
[29]
11 B?e A G, Dahl S O, Lie ?, et al.2006. Holocene river floods in the upper Glomma catchment, southern Norway: a high-resolution multiproxy record from lacustrine sediments[J]. the Holocene, 16(3): 445-455.
[30]
12 Bussmann F, Anselmetti F S. 2010. Rossberg landslide history and flood chronology as recorded in Lake Lauerz sediments (central Switzerland)[J]. Swiss Journal of Geosciences, 103(1): 43-59.
[31]
13 Cuven S, Francus P, Lamoureux S F. 2010. Estimation of grain size variability with micro X-ray fluorescence in laminated lacustrine sediments, Cape Bounty, Canadian High Arctic[J]. Journal of Paleolimnology, 44(3): 803-817.
[32]
14 Czymzik M, Dulski P, Plessen B, et al.2010. A 450 year record of spring-summer flood layers in annually laminated sediments from Lake Ammersee (southern Germany)[J]. Water Resources Research, 46(11): W11528.
[33]
15 Czymzik M, Brauer A, Dulski P, et al.2013. Orbital and solar forcing of shifts in mid- to late Holocene flood intensity from varved sediments of pre-alpine Lake Ammersee (southern Germany)[J]. Quaternary Science Reviews, 61: 96-110.
[34]
16 Dana J D. 1882. The flood of the Connecticut River valley from the melting of the Quaternary glacier[J]. American Journal of Science, 23: 179-202.
[35]
17 Ely L L, Enzel Y, Baker V R, et al.1993. A 5000-year record of extreme floods and climate change in the southwestern United States[J]. Science, 262: 410-412.
[36]
18 Giguet-Covex C, Arnaud F, Enters D, et al.2012. Frequency and intensity of high-altitude floods over the last 3.5ka in northwestern French Alps (Lake Anterne)[J]. Quaternary Research, 77(1): 12-22.
[37]
19 Gilli A, Anselmetti F S, Ariztegui D, et al.2003. A 600-year sedimentary record of flood events from two sub-alpine lakes(Schwendiseen, Northeastern Switzerland)[M]//Beres M, Scheidhauer M, Marillier F. Lake systems from the Ice Age to Industrial Time. Birkh?user Verlag, Basel: Spring, 49-58.
[38]
42 Osleger D A, Heyvaert A C, Stoner J S, et al.2009. Lacustrine turbidites as indicators of Holocene storminess and climate: Lake Tahoe, California and Nevada[J]. Journal of Paleolimnology, 42(1): 103-122.
[39]
43 Palmer T N, R?is?nen J. 2002. Quantifying the risk of extreme seasonal precipitation events in a changing climate[J]. Nature, 415(6871): 512-514.
[40]
44 Parris A S, Bierman P R, Noren A J, et al.2010. Holocene paleostorms identified by particle size signatures in lake sediments from the northeastern United States[J]. Journal of Paleolimnology, 43(1): 29-49.
[41]
45 Revel-Rolland M, Arnaud F, Chapron E, et al.2005. Sr and Nd isotopes as tracers of clastic sources in Lake Le Bourget sediment (NW Alps, France) during the Little Ice Age: palaeohydrology implications[J]. Chemical Geology, 224(4): 183-200.
[42]
46 Schillereff D N, Chiverrell R C, Macdonald N, et al.2014. Flood stratigraphies in lake sediments: a review[J]. Earth-Science Reviews, 135: 17-37.
[43]
47 Schlolaut G, Brauer A, Marshall M H, et al.2014. Event layers in the Japanese Lake Suigetsu 'SG06' sediment core: description, interpretation and climatic implications[J]. Quaternary Science Reviews, 83: 157-170.
[44]
48 Schnellmann M, Anselmetti F S, Giardini D, et al.2006. 15000 Years of mass-movement history in Lake Lucerne: Implications for seismic and tsunami hazards[J]. Eclogae Geologicae Helvetiae, 99(3): 409-428.
[45]
49 Simonneau A, Chapron E, Vannière B, et al.2013. Mass-movement and flood-induced deposits in Lake Ledro, southern Alps, Italy: implications for Holocene palaeohydrology and natural hazards[J]. Climate of the Past, 9(2): 825-840.
[46]
50 Sletten K, Blikra L H, Ballantyne C K, et al.2003. Holocene debris flows recognized in a lacustrine sedimentary succession: sedimentology, chronostratigraphy and cause of triggering[J]. the Holocene, 13(6): 907-920.
[47]
51 Springer G S, Kite J S. 1997. River-derived slackwater sediments in caves along Cheat River, West Virginia[J]. Geomorphology, 18(2): 91-100.
[48]
52 Stewart J E, Bodhaine G L. 1961. Floods in the Skagit River Basin, Washington[R]. Water-supply paper. Washington, DC: United States Department of the Interior, Geological Survey: 66.
[49]
53 Stoffel M, Bollschweiler M. 2008. Tree-ring analysis in natural hazards research-an overview[J]. Natural Hazards and Earth System Science, 8(2): 187-202.
[50]
54 Sturm M, Matter A. 1978. Turbidites and varves in Lake Brienz (Switzerland): deposition of clastic detritus by density currents[M]//Matter A, Tucker M E. Modern and ancient lake sediments. Oxford, UK: Blackwell Publishing Ltd.
[51]
20 Gilli A, Anselmetti F S, Glur L, et al.2013. Lake sediments as archives of recurrence rates and intensities of past flood events[M]//Schneuwly-Bollschweiler M, Stoffel M, Rudolf-Miklau F. Dating torrential processes on fans and Cones. Netherlands: Springer, 225-242.
[52]
21 Giovanoli F. 1990. Horizontal transport and sedimentation by interflows and turbidity currents in Lake Geneva[M]//Tilzer M M, Serruya C. Large Lakes. Verlag Berlin Heidelberg: Springer, 175-195.
[53]
22 Glur L, Wirth S B, Büntgen U, et al.2013. Frequent floods in the European Alps coincide with cooler periods of the past 2500 years[J]. Scientific Reports, 3: 2770.
[54]
23 Heine K. 2004. Flood reconstructions in the Namib Desert, Namibia, and Little Ice Age climatic implications: evidence from slackwater deposits and desert soil sequences[J]. Journal of the Geological Society of India, 64(4): S535-S548.
[55]
24 Huang C C, Pang J L, Zha X C, et al.2007. Impact of monsoonal climatic change on Holocene overbank flooding along Sushui River, middle reach of the Yellow River, China[J]. Quaternary Science Reviews, 26(17-18): 2247-2264.
[56]
25 Jenny J P, Wilhelm B, Arnaud F, et al.2014. A 4D sedimentological approach to reconstructing the flood frequency and intensity of the Rh?ne River (Lake Bourget, NW European Alps)[J]. Journal of Paleolimnology, 51(4): 469-483.
[57]
26 Kiem A S, Franks S W, Kuczera G. 2003. Multi-decadal variability of flood risk[J]. Geophysical Research Letters, 30(2): 1035.
[58]
27 Knox J C. 1993. Large increases in flood magnitude in response to modest changes in climate[J]. Nature, 361(6411): 430-432.
[59]
28 Kochel R C, Baker V R. 1982. Paleoflood hydrology[J]. Science, 215: 353-361.
[60]
29 Kundzewicz Z W. 2003. Extreme precipitation and floods in the changing world[C]//Bl?schl G, Franks S, Kumagai M. Water resources systems-hydrological risk, management and development[C]. Wallingford, USA: IAHS Press, 32-39.
[61]
30 Kylander M E, Ampel L, Wohlfarth B, et al.2011. High-resolution X-ray fluorescence core scanning analysis of Les Echets (France) sedimentary sequence: new insights from chemical proxies[J]. Journal of Quaternary Science, 26(1): 109-117.
[62]
31 Lambert A, Hsü K J. 1979. Non-annual cycles of varve-like sedimentation in Walensee, Switzerland[J]. Sedimentology, 26(3): 453-461.
[63]
32 Lamoureux S. 2000. Five centuries of interannual sediment yield and rainfall-induced erosion in the Canadian High Arctic recorded in lacustrine varves[J]. Water Resources Research, 36(1): 309-318.
[64]
33 Li Y F, Guo Y, Yu G. 2013. An analysis of extreme flood events during the past 400 years at Taihu Lake, China[J]. Journal of Hydrology, 500: 217-225.
[65]
34 Loukas A, Vasiliades L, Dalezios N R. 2000. Flood producing mechanisms identification in southern British Columbia, Canada[J]. Journal of Hydrology, 227(1-4): 218-235.
[66]
35 Macklin M G, Lewin J. 2003. River sediments, great floods and centennial-scale Holocene climate change[J]. Journal of Quaternary Science, 18(2): 101-105.
[67]
36 Manners R B, Magilligan F J, Goldstein P S. 2007. Floodplain development, El Ni?o, and cultural consequences in a Hyperarid Andean environment[J]. Annals of the Association of American Geographers, 97(2): 229-249.
[68]
37 Milly P C, Wetherald R T, Dunne K A, et al.2002. Increasing risk of great floods in a changing climate[J]. Nature, 415(6871): 514-517.
[69]
38 Morellón M, Valero-Garcés B, Vegas-Vilarrúbia T, et al.2009. Lateglacial and Holocene palaeohydrology in the western Mediterranean region: the Lake Estanya record (NE Spain)[J]. Quaternary Science Reviews, 28(25-26): 2582-2599.
[70]
39 Moreno A, Valero-Garcés B L, González-Sampériz P, et al.2008. Flood response to rainfall variability during the last 2000 years inferred from the Taravilla Lake record (Central Iberian Range, Spain)[J]. Journal of Paleolimnology, 40(3): 943-961.
[71]
40 Nomade J, Chapron E, Desmet M, et al.2005. Reconstructing historical seismicity from lake sediments (Lake Laffrey, Western Alps, France)[J]. Terra Nova, 17(4): 350-357.
[72]
41 Noren A J, Bierman P R, Steig E J, et al.2002. Millennial-scale storminess variability in the northeastern United States during the Holocene epoch[J]. Nature, 419(6909): 821-824.
