Journal of Ornithology

, Volume 147, Issue 2, pp 202–211

Birds: blowin’ by the wind?

Review

Abstract

Migration is a task that implies a route, a goal and a period of time. To achieve this task, it requires orientation abilities to find the goal and energy to cover the distance. Completing such a journey by flying through a moving airspace makes this relatively simple task rather complex. On the one hand birds have to avoid wind drift or have to compensate for displacements to reach the expected goal. On the other hand flight costs make up a large proportion of energy expenditure during migration and, consequently, have a decisive impact on the refuelling requirements and the time needed for migration. As wind speeds are of the same order of magnitude as birds’ air speeds, flight costs can easily be doubled or, conversely, halved by wind effects. Many studies have investigated how birds should or actually do react to winds aloft, how they avoid additional costs or how they profit from the winds for their journeys. This review brings together numerous theoretical and empirical studies investigating the flight behaviour of migratory birds in relation to the wind. The results of these studies corroborate that birds select for favourable wind conditions both at departure and aloft to save energy and that for some long-distance migrants a tail-wind is an indispensable support to cover large barriers. Compensation of lateral wind drift seems to vary between age classes, depending on their orientation capacities, and probably between species or populations, due to the variety of winds they face en route. In addition, it is discussed how birds might measure winds aloft, and how flight behaviour with respect to wind shall be tested with field data.

Keywords

Bird migration Flight behaviour Flight costs Wind drift Wind influence Migratory strategies 

References

  1. Alerstam T (1978) A graphical illustration of pseudodrift. Oikos 30:409–412CrossRefGoogle Scholar
  2. Alerstam T (1979a) Wind as a selective agent in bird migration. Ornithol Scand 10:76–93CrossRefGoogle Scholar
  3. Alerstam T (1979b) Optimal use of wind by migrating birds: combined drift and overcompensation. J Theor Biol 79:341–353CrossRefGoogle Scholar
  4. Alerstam T (1990) Bird migration. Cambridge University Press, CambridgeGoogle Scholar
  5. Alerstam T, Gudmundsson GA (1999) Migration patterns of tundra birds: tracking radar observations along the northeast passage. Arctic 52:346–371Google Scholar
  6. Alerstam T, Hedenström A (1998) The development of bird migration theory. J Avian Biol 29:343–369CrossRefGoogle Scholar
  7. Alerstam T, Lindström A (1990) Optimal bird migration: the relative importance of time, energy, and safety. In: Gwinner E (ed) Bird migration: physiology and ecophysiology. Springer, Berlin Heidelberg, pp 331–351Google Scholar
  8. Bäckman J, Alerstam T (2003) Orientation scatter of free-flying nocturnal passerine migrants: components and causes. Anim Behav 65:987–996CrossRefGoogle Scholar
  9. Battley PF (1997) The northward migration of arctic waders in New Zealand: departure behaviour, timing and possible migration routes of Red Knots and Bar-tailed Godwits from Farewell Spit, North–West Nelson. Emu 97:108–120CrossRefGoogle Scholar
  10. Baumgartner M (1997) Wetterabhängigkeit des nächtlichen Vogelzuges im Herbst über Süddeutschland. University of Basel, Basel, SwitzerlandGoogle Scholar
  11. Beekman JH, Nolet BA, Klaassen M (2002) Skipping swans: fuelling rates and wind conditions determine differential use of migratory stopover sites of bewick’s swans Cygnus bewickii. Ardea 90:437–460Google Scholar
  12. Bolshakov CV, Rezvyi SP (1998) Time of nocturnal flight initiation (take-off activity) in the European Robin Erithacus rubecula during spring migration: visual observations between sunset and darkness. Avian Ecol Behav 1:37–49Google Scholar
  13. Brodeur S, Décarie E, Bird DM, Fuller M (1996) Complete migration cycle of Golden Eagles breeding in northern Quebec. Auk 113:293–299Google Scholar
  14. Brown RE, Fedde MR (1993) Airflow sensors in the avian wing. J Exp Biol 179:13–30Google Scholar
  15. Bruderer B (1978) Effects of Alpine topography and winds on migrating birds. In: Schmidt-Koenig K (ed) Animal, migration, navigation, and homing. Springer, Berlin Heidelberg New York, pp 252–265Google Scholar
  16. Bruderer B, Liechti F (1995) Variation in density and height distribution of nocturnal migration in the south of Israel. Isr J Zool 41:477–487Google Scholar
  17. Bruderer B, Underhill LG, Liechti F (1995) Altitude choice of night migrants in a desert area predicted by meteorological factors. Ibis 137:44–55Google Scholar
  18. Butler RW (2000) Stormy seas for some North American songbirds: are declines related to severe storms during migration? Auk 117:518–522CrossRefGoogle Scholar
  19. Butler RW, Williams TD, Warnock N, Bishop MA (1997) Wind assistance: a requirement for migration of shorebirds? Auk 114:456–466Google Scholar
  20. Carmi N, Pinshow B, Porter WP, Jaeger J (1992) Water and energy limitations on flight duration in small migrating birds. Auk 109:268–276Google Scholar
  21. Chernetsov NS, Skutina EA, Bulyuk VN, Tsvey AL (2004) Optimal stopover decisions of migrating birds under variable stopover quality: model predictions and the field data. Zh Obsh Biol 65:166–172Google Scholar
  22. Clark CW, Butler RW (1999) Fitness components of avian migration: a dynamic model of Western Sandpiper migration. Evol Ecol Res 1:443–457Google Scholar
  23. Cochran WW (1972) Long-distance tracking of birds. In: Galler SR, Schmidt-Koenig K, Jacobs GJ, Belleville RE (eds) Animal orientation and navigation. NASA SP 262 U.S. Government Printing Office, Washington, D.C., pp 39–59Google Scholar
  24. Dänhardt J, Lindström A (2001) Optimal departure decisions of songbirds from an experimental stopover site and the significance of weather. Anim Behav 62:235–243CrossRefGoogle Scholar
  25. Dau CP (1992) The fall migration of pacific flyway Brent Branta bernicla in relation to climatic conditions. Wildfowl 43:80–95Google Scholar
  26. Desholm M (2003) How much do small-scale changes in flight direction increase overall migration distance? J Avian Biol 34:155–158CrossRefGoogle Scholar
  27. Elkins N (1988) Can high-altitude migrants recognize optimum flight levels? Ibis 130:562–563Google Scholar
  28. Erni B, Liechti F, Underhill LG, Bruderer B (2002) Wind and rain govern the intensity of nocturnal bird migration in central Europe – a log-linear regression analysis. Ardea 90:155–166Google Scholar
  29. Erni B, Liechti F, Bruderer B (2005) The role of wind in passerine autumn migration between Europe and Africa. Behav Ecol 16:732–740CrossRefGoogle Scholar
  30. Evans PR (1966) Migration and orientation of passerine night migrants in northeast England. J Zool 150:319–369CrossRefGoogle Scholar
  31. Forchhammer MC, Post E, Stenseth NC (2002) North Atlantic Oscillation timing of long- and short-distance migration. J Anim Ecol 71:1002–1014CrossRefGoogle Scholar
  32. Gauthreaux SA (1978) Importance of the daytime flights of nocturnal migrants: redetermined migration following displacement. In: Schmidt-Koenig K (ed) Animal migration, navigation and homing. Springer, Berlin Heidelberg New York, pp 219–227Google Scholar
  33. Gauthreaux SA Jr (1991) The flight behavior of migrating birds in changing wind fields: radar and visual analyses. Am Zool 31:187–204Google Scholar
  34. Gauthreaux SA, Belser CG (1999) Bird migration in the region of the Gulf of Mexico. In: Adams N, Slotow R (eds) Proc Int Ornithol Congr. Durban, pp 1931–1947Google Scholar
  35. Gill RE, Piersma T, Hufford G, Servranckx R, Riegen A (2005) Crossing the ultimate ecological barrier: evidence for an 11,000-km-long nonstop flight from Alaska to New Zealand and eastern Australia by Bar-tailed Godwits. Condor 107:1–20CrossRefGoogle Scholar
  36. Glutz von Blotzheim UN, Bauer KM, Bezzel E (1971) Handbuch der Vögel Mitteleuropas. Akademische Verlagsgesellschaft, Frankfurt am MainGoogle Scholar
  37. Green M (2001) Is wind drift in migrating barnacle and Brent Geese, Branta leucopsis and Branta bernicla, adaptive or non-adaptive? Behav Ecol Sociobiol 50:45–54CrossRefGoogle Scholar
  38. Green M, Alerstam T (2002) The problem of estimating wind drift in migrating birds. J Theor Biol 218:485–496PubMedGoogle Scholar
  39. Green M, Alerstam T, Clausen P, Drent R, Ebbinge BS (2002) Dark-bellied Brent Geese Branta bernicla bernicla, as recorded by satellite telemetry, do not minimize flight distance during spring migration. Ibis 144:106–121CrossRefGoogle Scholar
  40. Green M, Alerstam T, Clausen P (2003) Light-bellied Brent Geese Branta bernicla hrota compensate for wind drift when flying over open sea. In: Green M (ed) Flight strategies in migrating birds: when and how to fly. Department of Ecology, Lund University, Lund, pp 117–130Google Scholar
  41. Green M, Alerstam T, Gudmundsson GA, Hedenström A, Piersma T (2004) Do Arctic waders use adaptive wind drift? J Avian Biol 35:305–315Google Scholar
  42. Gudmundsson GA (1994) Spring migration of the Knot Calidris canutus over southern Scandinavia, as recorded by radar. J Avian Biol 25:15–26CrossRefGoogle Scholar
  43. Gudmundsson GA, Alerstam T, Green M, Hedenström A (2002) Radar Observations of Arctic bird migration at the Northwest passage, Canada. Arctic 55:21–43Google Scholar
  44. Güntürkün O (2000) Sensory physiology: vision. In: Whittow GC (ed) Sturkie’s avian physiology. Academic Press, San Diego, pp 1–14Google Scholar
  45. Gwinner E (1971) Orientierung. In: Schüz E (ed) Grundriss der Vogelzugkunde. Springer, Berlin Heidelberg New York, pp 299–348Google Scholar
  46. Hedenström A, Alerstam T (1992) Climbing performance of migrating birds as a basis for estimating limits for fuel-carrying capacity and muscle work. J Exp Biol 164:19–38Google Scholar
  47. Hedenström A, Alerstam T (1995) Optimal flight speed of birds. Philos Trans R Soc London SerB 348:471–487CrossRefGoogle Scholar
  48. Hedenström A, Alerstam T (1997) Optimum fuel loads in migratory birds: distinguishing between time and energy minimization. J Theor Biol 189:227–234CrossRefPubMedGoogle Scholar
  49. Hedenström A, Alerstam T, Akesson S (2003) Ecology of long-distance movements: migration and orientation performance. Oikos 103:1–445Google Scholar
  50. Hedenström A, Alerstam T, Green M, Gudmundsson GA (2005) Adaptive variation of airspeed in relation to wind, altitude and climb rate by migrating birds in the Arctic. Behav Ecol Sociobiol 52:308–317CrossRefGoogle Scholar
  51. Hilgerloh G (1991) Spring migration of passerine trans-Saharan migrants across the straits of Gibraltar. Ardea 79:57–62Google Scholar
  52. Hüppop O, Hüppop K (2003) North Atlantic Oscillation and timing of spring migration in birds. Proc R Soc London Ser B 270:233–240CrossRefGoogle Scholar
  53. Jenni L, Schaub M (2003) Behavioural and physiological reactions to environmental variation in bird migration: a review. In: Berthold P, Gwinner E, Sonnenschein E (eds) Avian migration. Springer, Berlin Heidelberg New York, pp 155–171Google Scholar
  54. Klaassen M, Biebach H (2000) Flight altitude of trans-Sahara migrants in autumn: a comparison of radar observations with predictions from meteorological conditions and water and energy balance models. J Avian Biol 31:47–55CrossRefGoogle Scholar
  55. Lensink R, van Gasteren H, Hustings F, Buurma LS, van Duin G, Linnartz LG, Vogelzang F, Witkamp C (2002) Vogeltrek over Nederland. Schuyt & Co., HaarlemGoogle Scholar
  56. Liechti F (1992) Flugverhalten nächtlich ziehender Vögel in Abhängigkeit von Wind und Topographie. PhD Thesis, University of Basel, Basel, SwitzerlandGoogle Scholar
  57. Liechti F (1993) Nächtlicher Vogelzug im Herbst über Süddeutschland: Winddrift und Kompensation. J Ornithol 134:373–404CrossRefGoogle Scholar
  58. Liechti F (1995) Modelling optimal heading and airspeed of migrating birds in relation to energy expenditure and wind influence. J Avian Biol 26:330–336CrossRefGoogle Scholar
  59. Liechti F, Bruderer B (1998) The relevance of wind for optimal migration theory. J Avian Biol 29:561–568CrossRefGoogle Scholar
  60. Liechti F, Schaller E (1999) The use of low-level jets by migrating birds. Naturwissenschaften 86:549–551CrossRefPubMedGoogle Scholar
  61. Liechti F, Hedenström A, Alerstam T (1994) Effects of sidewinds on optimal flight speed of birds. J Theor Biol 170:219–225CrossRefGoogle Scholar
  62. Liechti F, Klaassen M, Bruderer B (2000) Predicting migratory flight altitudes by physiological migration models. Auk 117:205–214CrossRefGoogle Scholar
  63. Lindström Å (1991) Maximum fat deposition rates in migrating birds. Ornithol Scand 22:12–19CrossRefGoogle Scholar
  64. Nievergelt F, Liechti F, Bruderer B (1999) Migratory directions of free-flying birds versus orientation in registration cages. J Exp Biol 202:2225–2231PubMedGoogle Scholar
  65. Nisbet ICT, Drury WHJ (1967) Orientation of spring migrants studied by radar. Bird Banding 38:173–186Google Scholar
  66. Pennycuick CJ (1978) Fifteen testable predictions about bird flight. Oikos 30:165–176CrossRefGoogle Scholar
  67. Pennycuick CJ (1989) Bird flight performance: a practical calculation manual. Oxford University Press, OxfordGoogle Scholar
  68. Pennycuick CJ, Einarsson O, Bradbury TAM, Owen M (1996) Migrating Whooper Swans Cygnus cygnus: satellite tracks and flight performance calculations. J Avian Biol 27:118–134CrossRefGoogle Scholar
  69. Pennycuick CJ, Bradbury TAM, Einarsson O, Owen M (1999) Response to weather and light conditions of migrating Whooper Swans Cygnus cygnus and flying height profiles, observed with Argos satellite system. Ibis 141:434–443Google Scholar
  70. Perdeck AC (1958) Two types of orientation in migrating Sturnus vulgaris and Fringilla coelebsas revealed by displacement experiments. Ardea 46:1–37Google Scholar
  71. Piersma T, Lindström Å (2002) Fine-tuned travel planning for hazardous journeys. J Avian Biol 33:3–4CrossRefGoogle Scholar
  72. Piersma T, Klaasen K, Bruggemann HJ, Blomert A, Gueye A, Ntiamoa-Baidu Y, Van Brederode NE (1990) Seasonal timing of the spring departure of waders from the Banc d’Arguin, Mauritania. Ardea 78:123–133Google Scholar
  73. Pyle P, Nur N, Henderson RP, DeSante DF (1993) The effects of weather and lunar cycle on nocturnal migration of landbirds at southeast Farallon Island, California. Condor 95:343–361CrossRefGoogle Scholar
  74. Rabol J, Thorup K (2001) The orientation of migrant birds following displacements by man or wind. A survey based on funnel experiment. In: 4th Int Conf Anim Navigation (RIN 01). Royal Institute of Navigation, pp 23.1–23.10Google Scholar
  75. Richardson WJ (1978) Timing and amount of bird migration in relation to weather: a review. Oikos 30:224–272CrossRefGoogle Scholar
  76. Richardson WJ (1979) Southeastward shorebird migration over Nova Scotia and New Brunswick in autumn: a radar study. Can J Zool 57:107–124CrossRefGoogle Scholar
  77. Richardson WJ (1982) Nocturnal landbird migration over southern Ontario, Canada: orientation vs. wind in autumn. In: Papi F, Wallraff HG (eds) Avian navigation. Springer, Berlin Heidelberg New York, pp 15–27Google Scholar
  78. Richardson WJ (1990a) Timing of bird migration in relation to weather: updated review. In: Gwinner E (ed) Bird migration. Springer, Berlin Heidelberg New York, pp 78–101Google Scholar
  79. Richardson WJ (1990b) Wind and orientation of migrating birds: a review. Experientia 46:416–425CrossRefGoogle Scholar
  80. Richardson WJ (1991) Wind and orientation of migrating birds: a review. In: Berthold P (ed) Orientation in birds. Birkhäuser, Basel, pp 226–249Google Scholar
  81. Salewski V, Bairlein F, Leisler B (2000) Site fidelity of Palearctic passerine migrants in the Northern Guinea savanna zone, West Africa. Vogelwarte 40:298–301Google Scholar
  82. Schaub M, Liechti F, Jenni L (2004) Departure of migrating European robins, Erithacus rubecula, from a stopover site in relation to wind and rain. Anim Behav 67:229–237Google Scholar
  83. Schmidt-Koenig K (1973) Über die Navigation der Vögel. Naturwissenschaften 60:88–94CrossRefGoogle Scholar
  84. Schüz E (1971) Grundriss der Vogelzugkunde. Verlag Paul Parey, Berlin HamburgGoogle Scholar
  85. Spear LB, Ainley DG (1997) Flight speed of seabirds in relation to wind speed and direction. Ibis 139:234–251Google Scholar
  86. Stewart AG (1978) Swans flying at 8,000 m. Br Birds 71:459–460Google Scholar
  87. Thorup K, Alerstam T, Hake M, Kjellén N (2003) Bird orientation: compensation for wind drift in migrating raptors is age dependent. Proc R Soc London Ser B 270:8–11CrossRefGoogle Scholar
  88. Thorup K, Alerstam T, Hake M, Kjellén N (2004) Travelling or stopping of migrating birds in relation to wind: an illustration for the osprey Pandion haliaetus. In: Thorup K (ed) The migratory orientation programme in birds. Zoological Museum, University of Copenhagen, Copenhagen, pp 107–113Google Scholar
  89. Vähätalo AV, Rainio K, Lehikoinen A, Lehikoinen E (2004) Spring arrival of birds depends on the North Atlantic Oscillation. J Avian Biol 35:210–216CrossRefGoogle Scholar
  90. Walch D, Frater H (2004) Wetter und klima. Springer, Berlin Heidelberg New YorkGoogle Scholar
  91. Weber TP, Hedenström A (2000) Optimal stopover decisions under wind influence: the effects of correlated winds. J Theor Biol 205:95–104CrossRefPubMedGoogle Scholar
  92. Weber TP, Houston AI (1997) A general model for time-minimising avian migration. J Theor Biol 185:447–458CrossRefGoogle Scholar
  93. Weber TP, Houston AI, Ens BJ (1994) Optimal departure fat loads and stopover site use in avian migration: an analytical model. Proc R Soc London Ser B 258:29–34CrossRefGoogle Scholar
  94. Weber TP, Alerstam T, Hedenström A (1998a) Stopover decisions under wind influence. J Avian Biol 29:552–560CrossRefGoogle Scholar
  95. Weber TP, Ens BJ, Houston AI (1998b) Optimal avian migration: a dynamic model of fuel stores and site use. Evol Ecol 12:377–401CrossRefGoogle Scholar
  96. Williams TC, Williams JM (1978) An oceanic mass migration of land birds. Sci Am 239:138–145CrossRefGoogle Scholar
  97. Williams TC, Williams JM (1990) Open ocean bird migration. IEE Proc 137:133–137Google Scholar
  98. Williams TC, Williams JM (1999) The migration of land birds over the Pacific Ocean. In: Adam N, Slotow R (eds) Proc Int Ornithol Congr. Birdlife South Africa, Durban, pp 1948–1957Google Scholar
  99. Williamson K (1962) The nature of leading line behaviour. Bird Migration 2:176–186Google Scholar
  100. Wiltschko R, Wiltschko W (2003) Mechanism of orientation and navigation in migratory birds. In: Berthold P, Gwinner E, Sonnenschein E (eds) Avian migration. Springer, Berlin Heidelberg New York, pp 433–456Google Scholar
  101. Zehnder S, Åkesson S, Liechti F, Bruderer B (2001) Nocturnal autumn bird migration at Falsterbo, south Sweden. J Avian Biol 32:239–248CrossRefGoogle Scholar

Copyright information

© Dt. Ornithologen-Gesellschaft e.V. 2006

Authors and Affiliations

  1. 1.Swiss Ornithological InstituteSempachSwitzerland

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