[1] Quetin LB, Ross RM, Frazer TK, et al. Factors affecting distribution and abundance of zooplankton, with an emphasis on Antarctic krill, Euphausia superba// Ross RM, Hofmann EE, Quetin LB, eds. Foundations for Ecological Research West of the Antarctic Peninsula. Washington DC: American Geophysical Union, 1996,70: 357-371 [2] Siegel V. Distribution and population dynamics of Euphausia superba: Summary of recent findings. Polar Biology, 2005, 29: 1-22 [3] Marr JWS. The natural history and geography of the Antarctic krill (Euphausia superba Dana). Discovery Reports, 1962, 32: 33-464 [4] Hamner WM, Hamner PP, Strand SW, et al. Behavior of Antarctic krill, Euphausia superba: Chemoreception, feeding, schooling, and molting. Science, 1983, 220: 433-435 [5] Murphy EJ, Morris DJ, Watkins JL, et al. Scales of interaction between Antarctic krill and the environment//Sahrhage D, ed. Antarctic Ocean and Resources Variability. Berlin: Springer-Verlag, 1988: 120-130 [6] Mauchline J. The biology of mysids and euphausiids. Advance in Marine Biology, 1980, 18: l-681 [7] Watkins JL, Morris DJ, Ricketts C, et al. Differences between swarms of Antarctic krill and some implications for sampling krill populations. Marine Biology, 1986, 93: 137-146 [8] Parrish JK, Edelstein-Keshet L. Complexity, pattern, and evolutionary trade-offs in animal aggregation. Science, 1999, 284: 99-101 [9] Nemoto T. Net sampling and abundance assessment of euphausiids. Biological Oceanography, 1983, 2: 211-226 [10] O’Brien DP. Description of escape responses of Krill (Crustacea: Euphausiacea), with particular reference to swarming behavior and the size and proximity of the predator. Journal of Crustacean Biology, 1987, 7(3): 449-457 [11] Ritz DA. Social aggregation in pelagic einvertebrates. Advances in Marine Biology, 1994, 30(6): 155-216 [12] Ross RM, Hofmann EE, Lascara CM. Distribution of Antarctic Krill and dominant Zooplankton west of the Antarctic Peninsula. In: Ross RM, Hofmann EE, Quetin LB, Eds. Foundations for Ecological Research West of the Antarctic Peninsula. Washington DC: Ameri-can Geophysical Union, 1996,70: 199-217 [13] Hamner WM. Aspects of schooling in Euphausia superba. Journal of Crustacean Biology, 1984, 4: 67-74 [14] Watkins JL, Murray AWA. Layers of Antarctic krill, Euphausia superba: Are they just long krill swarms? Marine Biology, 1998, 131: 237-247 [15] Nicol S. Krill and currents-physical and biological intera-ctions influencing the distribution of Euphausia superba. Ocean and Polar Research, 2003, 25: 633-644 [16] Hamner WM, Hamner PP. Behavior of Antarctic krill (Euphausia superba): Schooling, foraging. Canadian Journal of Fisheries & Aquatic Sciences, 2011, 57: 192-202 [17] Kawaguchi S, King R, Meijers R, et al. An experimental aquarium for observing the schooling behaviour of Antarctic krill (Euphausia superba). Deep-Sea Research Part Ⅱ, 2010, 57: 683-692 [18] Regnard P. A device for measuring the conversion speed of fish moving in water. Comptes Rendus des Seances de la Societe de Biologie et de Ses, 1893, 9: 81-84 [19] Nicol S, Endo Y. Krill fisheries of the world. FAO Fishe-ries Technical Paper, 1997: 367 [20] Kanda K, Takagi K, Seki Y. Movement of the larger swarms of Antarctic krill Euphausia superba population off Ender by Land during 1976-1977 season. Journal of the Tokyo University of Fisheries, 1982, 68: 25-42 [21] Stretch JJ, Hamner PP, Hamner WM, et al. Foraging behavior of Antarctic krill Euphausia superba on sea ice microalgae. Marine Ecology Progress Series, 1988, 44: 131-139 [22] Kils U. Swimming behaviour, swimming performance and energy balance of Antarctic krill Euphausia superba. Biomass Scientific Series, 1981, 3: 1-121 [23] Aleyev YG. Nekton. The Hague: Dr. W. Junk Publi-shers, 1977 [24] Murphy DW, Webster DR, Kawaguchi S, et al. Metachronal swimming in Antarctic krill: Gait kinematics and system design. Marine Biology, 2011, 158: 2541-2554 [25] Alben S, Spears K, Garth S, et al. Coordination of multiple appendages in drag-based swimming. Journal of the Royal Society Interface, 2010, 7: 1545-1557 [26] Hessler RR. Swimming in Crustacea. Earth and Environmental Science Transactions of the Royal Society of Edinburgh, 1985, 76: 115-122 [27] Johnson M, Tarling G. Influence of individual state on swimming capacity and behaviour of Antarctic krill Euphausia superba. Marine Ecology Progress Series, 2008, 366: 99-110 [28] Catton KB, Webster DR, Kawaguchi S, et al. The hydrodynamic disturbances of two species of krill: Implications for aggregation structure. Journal of Experimental Biology, 2011, 214: 1845-1856 [29] Ikeda T, Mitchell AW. Oxygen uptake, ammonia excretion and phosphate excretion by krill and other Antarctic zooplankton in relation to their body size and chemical composition. Marine Biology, 1982, 71: 283-298 [30] Ikeda T. Nutritional ecology of marine zooplankton. Memoirs of the Graduate School of Fisheries Sciences, Hokkaido University, 1974, 22: 1-97 [31] Mauchline J, Fisher LR. Advance in Marine Biology. 18. The Biology of Euphausiids. London: Academic Press, 1969 [32] Kawaguchi K, Ishikawa S, Matsuda O. The overwintering strategy of Antarctic krill Euphausia superba under the coastal fast ice off the Ongul islands in Lützow-Holm Bay, Antarctica. Memoirs of National Institute of Polar Research, 1986, 44: 67-85 [33] Quetin LB, Ross RM. Behavioral and physiological chara-cteristics of the Antarctic krill, Euphausia superba. American Zoologist, 1991, 31: 49-63 [34] Torres JJ, Aarset AV, Donnelly J, et al. Metabolism of Antarctic micronektonic crustacea as a function of depth of occurrence and season. Marine Ecology Progress Series, 1994, 113: 207-219 [35] Marschall HP. The overwintering strategy of Antarctic krill under the pack-ice of the Weddell Sea. Polar Biology, 1988, 9: 129-135 [36] Atkinson A, Snyder R. Krill-copepod interactions at South Georgia, Antarctica I. Omnivory by Euphausia superba. Marine Ecology Progress Series, 1997, 160: 63-76 [37] Huntley ME, Nordhausen W, Lopez MDG. Elemental composition, metabolic activity and growth of Antarctic krill Euphausia superba during winter. Marine Ecology Progress Series, 1994, 107: 23-40 [38] Opalinski KW. Respiratory metabolism and metabolic adaptations of Antarctic krill Euphausia superba. Polskie Archiwum Hydrobiologii, 1991, 38: 183-263 [39] Quetin LB, Ross RM, Clarke A. Krill energetics: Seasonal and environmental aspects of the physiology of Euphausia superba// El-Sayed SZ, ed. Southern Ocean Ecology: The Biomass Perspective. Cambridge, UK: Cambridge University Press, 1994: 165-184 [40] Saborowski R, Buchholz F. Internal current generation in respiration chambers. Helgoländer Meeresuntersuchungen, 1998, 52:103-109 [41] Ikeda T, Mitchell AW. Oxygen uptake, ammonia excretion and phosphate excretion by krill and other Antarctic zooplankton in relation to their body size and chemical composition. Marine Biology, 1982, 71: 283-298 [42] Meyer B, Oettl B. Effects of short-term starvation on composition and metabolism of larval Antarctic krill Euphausia superba. Marine Ecology Progress Series, 2005, 292: 263-270 [43] Meyer B, Auerswald L, Siegel V, et al. Seasonal variation in body composition, metabolic activity, feeding, and growth of adult krill Euphausia superba in the Lazarev Sea. Marine Ecology Progress Series, 2010, 398: 47-51 [44] Meyer B, Fuentes V, Guerra C, et al. Physiology, growth, and development of larval krill Euphausia superba in autumn and winter in the Lazarev Sea, Antarctica. Limnology & Oceanography, 2009, 54: 1595-1614 [45] Ikeda T, Bruce B. Metabolic activity and elemental composition of krill and other zooplankton from Prydz Bay, Antarctica, during early summer. Marine Biology, 1986, 92: 545-555 [46] Mitchell DE. Short-term Temperature Influences on Respiration Rate and Citrate Synthase Activity of Antarctic krill (Euphausia superba). Master thesis. Hobart, Australia: University of Tasmania, 2016: 26 [47] Teschke M, Kawguchi S, Meyer B. Simulated light regimes affect feeding and metabolism of Antarctic krill, Euphausia superba. Limnology & Oceanography, 2007, 52: 1046-1054 [48] Clarke A, Morris DJ. Towards an energy budget for krill: The physiology and biochemistry of Euphausia superba, Dana. Polar Biology, 1983, 2: 69-86 [49] Swadling KM, Ritz DA, Nicol S, et al. Respiration rate and cost of swimming for Antarctic krill, Euphausia superba, in large groups in the laboratory. Marine Biology, 2005, 146: 1169-1175 [50] Nicol S. The age-old problem of krill longevity. Bio-science, 1990, 40: 833- 836 [51] Buchholz F. Drach’s molt staging system adapted for euphausiids. Marine Biology, 1982, 66: 301-305 [52] Buchholz F. Moult cycle and growth of Antarctic krill Euphausia superba in the laboratory. Marine Ecology Progress Series, 1991, 69: 217-229 [53] Nicol S, Stolp M. A refinement of the moult-staging technique for Antarctic krill (Euphasia superba). Marine Biology, 1990, 104: 169-173 [54] Arnold KH, Shreeve RS, Atkinson A, et al. Growth rates of Antarctic krill, Euphausia superba: Comparison of the instantaneous growth rate method with nitrogen and phosphorus stoichiometry. Limnology & Oceanography, 2004, 49: 2152-2161 [55] Tarling GA, Shreeve RS, Hirst AG, et al. Natural growth rates in Antarctic krill (Euphausia superba): I. Improving methodology and predicting intermolt period. Limnology & Oceanography, 2006, 51: 959-972 [56] Quetin LB, Ross RM, Frazer TK, et al. Growth of larval krill, Euphausia superba, in fall and winter west of the Antarctic Peninsula. Marine Biology, 2003, 143: 833-843 [57] Ikeda T, Thomas PG. Longevity of the Antarctic krill (Euphausia superba Dana) based on a laboratory experiment. Proceedings of the NIPR Symposium on Polar Biology, 1987, 1: 56-62 [58] Nicol S. Understanding krill growth and aging: The contribution of experimental studies. Canadian Journal of Fisheries and Aquatic Sciences, 2000, 57: 168-177 [59] Ross RM, Quetin LB, Baker KS, et al. Growth limitation in young Euphausia superba under field conditions. Limnology & Oceanography, 2000, 45: 31-43 [60] Zhu G-P(朱国平). Population biology of Antarctic krill (Euphausia superba) I. age, growth and mortality. Acta Hydrobiologica Sinica (水生生物学报), 2011, 35(5): 862-868 (in Chinese) [61] Brown M, Kawaguchi S, Candy S, et al. Temperature effects on the growth and maturation of Antarctic krill (Euphausia superba). Deep Sea Research Part II: Topical Studies in Oceanography, 57: 672-682 [62] Tarling GA, Shreeve RS, Hirst AG, et al. Natural growth rates in Antarctic krill (Euphausia superba): Ⅱ. Predictive models based on food, temperature, body length, sex, and maturity stage. Limnology & Oceano-graphy, 2006, 51: 959-972 [63] Melvin JE, Kawaguchi S, King R, et al. The carapace matters: Refinement of the instantaneous growth rate method for Antarctic krill Euphausia superba Dana, 1850 (Euphausiacea). Journal of Crustacean Biology, 2018, 38: 689-696 [64] Elser JJ, O’Brien WJ, Dobberfuhl DR, et al. The evolution of ecosystem processes: Growth rate and elemental stoichiometry of a key herbivore in temperate and arctic habitats. Journal of Evolutionary Biology, 2000, 13: 845-853 [65] Main TM, Dobberfuhl DR, Elser JJ. N:P stoichiometry and ontogeny of crustacean zooplankton: A test of the growth rate hypothesis. Limnology & Oceanography, 1997, 42: 1474-1478 [66] Elser JJ, Sterner RW, Gorokhova E, et al. Biological stoichiometry from genes to ecosystems. Ecology Letters, 2000, 3: 540-550 |