[1]Kerr J B, McElroy C T. Evidence for large upward trends of ultraviolet- B radiation linked to ozone depletion[J]. Science, 1993, 262: 1 032- 1 034.
[2]
[2]Carreto J I, Carignan M O, Daleo G, et al. Occurrence of mycosporine- like amino acids in the red tide dinoflagellate Alexandrium excavatum UV- photoprotective compounds [J]. J Plankton Res, 1990, 12: 909- 921.
[3]
[3]Cullen J J, Neale P J and Lesser M P. Biological weighting function for the inhibition of phytoplankton photosynthesis by ultraviolet radiation[J]. Science, 1992, 258: 646- 650.
[4]
[4]Smith R C, Pré zelin B B, Baker K S, et al. Ozone de- pletion: ultraviolet radiation and phytoplankton biology in Antarctic waters[J]. Science, 1992, 255: 952- 959.
[5]
[5]Karentz D, et al. Impact of UV- B radiation on pelagic freshwater ecosystem: Report of working group on bacteria and phytoplankton[J]. Arch Hydrobiol Beih Ergebn Limnol, 1994, 43: 31- 69.
[6]
[6]Karanas J J, Van Dyke H, Worrest R C. Midultraviolet (UV- B) sensitivity of Acartia clausii Giesbrecht (Copepoda) [J]. Limnol Oceanogr, 1979, 24: 1 104- 1 116.
[7]
[7]Damkaer D M, Dey D B, Heron G A, et al. Effects of UV- B radiation on near- surface zooplankton of Puget Sound[J]. Oecologia, 1980, 44: 149- 158.
[8]
[8]Piazena H, Perez- Rodrigues E, H der D- P, et al. Penetration of solar radiation into the water column of the central subtropical Atlantic Ocean- optical properties and possible biological consequences[J]. Deep- Sea ResⅡ,2002, 49: 3 512- 3 528.
[9]
[9]Kuhn P, Browman H I, St- Pierre J F et al. Penetration of ultraviolet radiation in the waters of the estuary and Gulf of St. Lawrence[J]. Limnol Oceanogr, 1999, 44: 710- 716.
[10]
[10]Mostajir B, Demers S, de Mora S, et al. Experimental test of the effect of ultraviolet- B radiation in a planktonic community[J]. Limnol Oceanogr, 1999, 44(3): 586- 596.
[11]
[11]Jerlov N G. Ultra- violet radiation in the sea[J]. Nature, 1950, 166: 111- 112.
[12]
[12]Sivalingam P M, Nisizawa K. Ozone hole and its correla- tion with the characteristic UV- absorbing substance in marine algae[J]. Japan J Phycol, 1990, 39: 365- 370.
[13]
[13]Maegawa M, Kunieda M, Kida W. The influence of ul- traviolet radiation on the photosynthetic activity of several red algae from different depths[J]. Japan J Phycol, 1993, 41: 207- 214.
[14]
[14]Karentz D, Lutze L H. Evaluation of biologically harmful ultraviolet radiation in Antarctica with a biological dosimeter designed for aquatic environments[J]. Limnol Oceanogr, 1990, 35(3): 549- 561.
[15]
[15]Elofsson R. The nauplius eye and fontal organs of the non- Malacostraca (Crustacea) [J]. Sarsia, 1966, 25: 1- 128.
[16]
[16]Schulyer Q, Sullivan K B. Light responses and diel mi- gration of scyphomedusa chrysaora quinquecirrha in mesocosms[J]. J Plankton Res, 1997, 19(10): 1 417- 1 428.
[17]
[17]Yoshida M, Millot N. Light sensitive nerves in an echi- noid[J]. Experientia, 1959, 15: 13- 14.
[18]
[18]Cronin T W, Marshall N J, Quinn C A, et al. Ultraviolet photoreception in mantis shrimp[J]. Vision Res, 1994, 34: 1 443- 1 452.
[19]
[19]Frank T M, Widder E A. UV light in the deep- sea: in situ measurements of downwelling irradiance in relation to the visual threshold sensitivity of UV- sensitive crus- taceans[J]. Mar Freshw Behav Physiol, 1996, 27: 189- 197.
[20]
[20]Sweatt A J, Forward R. Spectral sensitivity of the chaetognath Sagitta hispida conant[J]. Biol Bull, 1985, 168: 32- 38.
[21]
[21]Smith K C, Macagno E R. UV photoreceptors in com- pound eye of Daphnia magna (Crustacea, Branchiopoda). A forth spectral class in single ommatidia[J]. J Comp Physiol A, 1990, 166: 597- 606.
[22]
[22]Forward R B. Diel vertical migration: zooplankton pho- tobiology and behaviour[J]. Oceanogr Mar Biol Annu Res, 1988, 26: 361- 393.
[23]
[23]Frank T M, Widder E A. The correlation of downwelling irradiance and staggered vertical migration patterns of zooplankton in Wilkinson Basin (Bay of Biscay) [J]. J Plankton Res, 1997, 19: 1 975- 1 991.
[24]
[24]Esterly C O. Specificity in behavior and the relation be- tween habits in nature and reactions in laboratory[J]. Univ Calif Pub Zool, 1917, 16: 381- 392.
[25]
[25]Stearns D E, Forward R B. Photosensitivity of the cala- noid copepod Acartia tonsa[J]. Mar Biol, 1984, 82: 85- 89.
[26]
[26]Brooker Klugh A. The effect of the ultra- violet compo nent of sunlight on certain marine organisms[J]. Can J Res, 1929, 1: 100- 109.
[27]
[27]Dey D B, Damkaer D M, Heron G A. UV- B dose/ dose- rate responses of seasonally abundant copepods of Puget Sound[J]. Oecologia, 1988, 76: 321- 329.
[28]
[28]Williamson C E, Zagarese H E, Schulze P C, et al. The impact of short- term exposure to UV- B radiation on zooplankton communities in north temperate lakes[J]. J Plankton Res, 1994, 16: 205- 218.
[29]
[29]Horacio E Z, Margarita Feldman, Craig E W. UV- B- induced damage and photoreactivation in three species of Boeckella (Copepoda, Calanoida) [J]. J Plankton Res, 1997, 19(3): 357- 367.
[30]
[30]Storz U C & Paul R J. Phototaxis in water fleas (Daphnia magna) is differently influenced by visible and UV light [J]. J Comp Physiol, 1998, 41: 1 024- 1 034.
[31]
[31]Christa L S, Stephen M B and Sean R A. The effect of ultraviolet radiation on the vertical distribution and mor- tality of estuarine zooplankton[J]. J Plankton Res, 2000, 22(12): 2 325- 2 350.
[32]
[32]Araseth K A, Schram T A. Wavelength- specific be- havior in Lepeophtheirus salmonis and Calanus finma- rchicus to ultraviolet and visible light in laboratory experiments (Crustacea: Copepoda) [J]. Mar Ecol Prog Ser, 1999, 186: 211- 217.
[33]
[33]Leech D M, Williamson C E. In situ exposure to ultravi- olet radiation alters the depth distribution of Daphnia[J]. Limnol Oceanogr, 2001, 46(2): 416- 420.
[34]
[34]Hairston N G, Jr. Photoprotection by carotenoid pigments in the copepod Diaptomus nevadensis[J]. Proc Natl Acad Sci USA, 1976, 73: 971- 974.
[35]
[35]Cullen J J, Neale P J. Ultraviolet radiation, ozone de- pletion, and marine photosynthesis[J]. Photosynth Res, 1994, 39: 303- 320.
[36]
[36]Karanas J J, Worrest R C, Van Dyke H. Impact of UV- B radiation on the fecundity of the copepod Acartia clausii [J]. Mar Biol, 1981, 65: 125- 133.
[37]
[37]Chalker- Scott L. Survival and sex ratios of the intertidal copepod, Tigriopus californicus, following ultraviolet- B (290- 320 nm) radiation exposure[J]. Mar Biol, 1995, 123: 799- 804.
[38]
[38]Naganuma T, Inoue T, Uye S. Photoreactivation of UV- induced damage to embryos of a planktonic copepod[J]. J Plankton Res, 1997, 19: 783- 787.
[54]Haney J F, Craggy A, Kimball K, et al. Light control of evening vertical migrations by Chaoborus punctipennis larvae[J]. Limnol Oceanogr, 1990, 35(5): 1 068- 1 078.
[41]
[55]Rhode S C, Pawlowski M, Tollrian R. The impact of ultraviolet radiation on the vertical distribution of zoo- plankton of the genus Daphnia[J]. Nature, 2001, 412: 69- 72.
[57]Wang R, Li C, Wang K, et al. Feeding activities of zooplankton in Bohai Sea[J]. Fish Oceanogr, 1998, 7 (3/4): 265- 271.
[44]
[58]齐雨藻,邹景忠,梁松 ,等.中国沿海赤潮 [M].北京:科学出版社, 2003. 99.
[45]
[59]Strom S L. Light- aided digestion, grazing and growth in herbivorous protists[J]. Aquat Microb Ecol, 2001, 23: 253- 261.
[46]
[60]Schulze H. Uber die Bedeutung des Lichtes in Leben niederer Kredse (Nach versuchen in Daphniden) [J]. Zeit f Verlgl Physiol, 1928, 7: 488.
[47]
[61]Uye S, Huang C & Onbe T. Ontogenetic diel vertical migration of the planktonic copepod Calanus sinicus in the Inland Sea of Japan[J]. Mar Biol, 1990, 104: 389- 396.
[48]
[62]Atkinson A, Ward P, Murphy E J. Diel periodicity of subantarctic copepods: relationship between vertical mi- gration, gut fullness and gut evacuation rate[J]. J Plankton Res, 1996, 18(8): 1 387- 1 405.
[49]
[63]Rodriguez C A, Browman H I., Runge J A, et al. Impact of solar ultraviolet radiation on hatching of a marine copepod, Calanus finmarchicus[J]. Mar Ecol Prog Ser, 2000, 193: 85- 93.
[50]
[64]Saito H, Taguchi S. Influence of UVB radiation on hatching success of marine copepod Paracalanus Parvus s. l[J]. J Exp Mar Biol Ecol, 2003, 282: 135- 147.
[51]
[39]Cabrera S, L?pez M, Tartarotti B. Phytoplankton and zooplankton response to ultraviolet radiation in a high- altitude Andean lake: Short- versus long- term effects [J]. J Plankton Res, 1997, 19(11): 1 565- 1 582.
[52]
[40]Kouwenberg H M, Browman H I, Runge J A, et al. Bi ological weighting of ultraviolet (280- 400 nm) induced mortality in marine zooplankton and fish.Ⅱ.Calanus finmarchicus (Copepoda) eggs[J]. Mar Biol, 1999, 134: 285- 293.
[53]
[41]Malloy K D, Holman M A, Mitchell D, et al. Solar UVB induced DNA damage and photoenzymatic DNA repair in Antarctic zooplankton[J]. Proc natn Acad Sci USA, 1997, 94: 1 258- 1 263.
[54]
[42]Ewald W F. ü ber Orientierung Lokomotion und Lichtreaktionen einiger Cladoceren und deren Bedeutung fü r die Theorie der Tropismen[J]. Biol Zbl, 1910, 30: 1- 16.
[55]
[43]Zhou M, Nordhausen W, Huntley M. ADCP measure- ments of the distribution and abundance of euphausiids near the Antarctic Peninsula in winter[J]. Deep- Sea Res, 1994, 41: 1 425- 1 445.
[56]
[44]Ringelberg J. Changes in light intensity and diel vertical migration: a comparison of marine and freshwater envi- ronments[J]. J Mar Biol Ass UK, 1995, 75:15- 25.
[57]
[45]Heywood K J. Diel vertical migration of zooplankton in the Northeast Atlantic[J]. J Plankton Res, 1996, 18: 163- 184.
[58]
[46]Luo J, Ortner P B, Forcucci D, et al. Diel vertical mi- gration of zooplankton and mesopelagic fish in the Arabian Sea[J]. Deep- Sea Res II. 2000, 47: 1 451- 1 473.
[59]
[47]Russell F S. The vertical distribution of marine macro- plankton. 4. The apparent importance of light intensity as a controlling factor in the behaviour of certain species in the Plymouth area. 12. some observations on the vertical distribution of Calanus finmarchicus in relation to light intensity[J]. J Mar Biol Ass UK, 1926, 1934, 14: 415- 440; 19: 569- 584.
[60]
[48]Boden B P, Kampa E M. The influence of natural light on the vertical migrations of an animal community in the sea[J]. Symp Zool Soc Lond, 1967, 19: 15- 26.
[61]
[49]Clarke G L. Diurnal migration of plankton in the Gulf of Maine and its correlation with changes in submarine illu- mination[J]. Biol Bull, 1933, 33: 402- 436.
[62]
[50]Ringelberg J. The positively phototactic reaction of Daphnia magna Straus, a contribution to the understanding of diurnal vertical migration[J]. Neth J Sea Res, 1964, 2: 319- 406.
[63]
[51]Daan N, Ringelberg J. Further studies on the positive and negative phototactic reaction of Daphnia magna Straus[J]. Neth J Zool, 1969, 19: 525- 540.
[64]
[52]Buchanan C, Haney J F. Vertical migration of zooplankton in the arctic. A test of environmental controls[J]. Am Soc Limnol Oceanogr Spec Symp, 1980, 3: 66- 79.
