Autumn Migration Of The Thrush Nightingale (Luscinia Luscinia) In Northern Hungary

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Abstract

Kováts D. 2012. Autumn migration of the Thrush Nightingale (Luscinia luscinia) in northernHungary. Ring 34: 23-36.

The autumn migration of the Thrush Nightingale was studied in Szalonna in northern Hungary in 1989-2010. Birds were mist-netted, ringed, aged, measured, weighed and fat scored. In total, 193 Thrush Nightingales were ringed during 22 years. Relations between arrival time and biometrical measurements were determined. Within the study period (6 August - 26 September) the migration curve was bimodal showing maximum on 22 August and 27 August. Immature birds arrived significantly earlier with lower body mass and shorter wing length and had more pointed wings in the first half of their passage. The distribution of fat score classes did not differ significantly between the early and late periods of the most intensive migration, although the mean of the deposited fat was the lowest during the peak of migration. Fat reserve distribution was bimodal in autumn suggesting that Thrush Nightingales probably start their journey from different breeding ranges (populations) or follow still undiscovered migration strategies of sex/age groups. The low proportion of recaptures proved that the area was not used as a stopover site or premigratory fattening area. Within 22 years of study, the median date of autumn migration of Thrush Nightingales shifted 7.9 days earlier, probably due to current climate change.

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  • Alerstam T. 1990. Bird migration. Cambridge Univ. Press Cambridge.

  • Alerstam T. Hedenström A. 1998. The development of bird migration theory. J. Avian Biol. 29: 343-369.

  • Alerstam T. Högstedt G. 1982. Bird migration and reproduction in relation to habitats for survivaland breeding. Ornis Scand. 13 1: 25-37.

  • Baker R.R. 1978. The evolutionary ecology of animal migration. Hodder and Stoughton London.

  • Berthold P. 1975. Migration control and metabolic physiology. In: Farner D.S. King J.R. (Eds). Avian Biology. vol. 5 Acad. Press New York: pp. 77-128.

  • Berthold P. 1990. Patterns of avian migration in light of current global ‘greenhouse’ effects: a centralEuropean perspective. Acta Cong. Int. Ornithol. 20: 780-786.

  • Berthold P. 1993. Bird migration. A general survey. Oxford Univ. Press Oxford.

  • Berthold P. 1996. Control of Bird Migration. Chapman and Hall London.

  • Blem P.R. 1980. The energetics of migration. In: Gauthreux S.A. (Ed.). Animal migration orientationand navigation. Acad. Press New York.

  • Both C. Artemyev A.V. Blaauw B. Cowie R.J. Dekhuijzen A.J. Eeva T. Enmar A. Gustafsson L. Ivankina E.V. Jarvinen A. Metcalfe N.B. Nyholm N.E.I. Potti J. Ravussin P.A. Sanz J.J. Silverin B. Slater F.M. Sokolov L.V. Török J. Winkel W. Wright J. Zang H. Visser M.E. 2004. Large-scale geographical variation confirms that climate change causes bird to lay earlier. Proc. R. Soc. Lond. B 271: 1657-1662. DOI: 10.1098/rspb.2004.2770 Both C. Visser M.E. 2001. Adjustment to climate change is constrained by arrival date in a longdistancemigrant bird. Nature 411: 296-298. DOI: 10.1038/35077063

  • Bradley N.L. Leopold A.C. Ross J. Huffaker W. 1999. Phenological changes reflect climatechange in Wisconsin. Proc. Natl. Acad. Sci. USA 96: 9701-9704.

  • Burfield I. Van Bommel F. 2004. Birds in Europe: population estimated trends and conservationstatus. BirdLife Int. Cambridge UK.

  • Busse P. 1990. Key to sexing and ageing of European passerines. Not. Orn. 31 5: 1-364.

  • Busse P. Kania W. 1970. Operation Baltic. Polish Section. Methods. Acta orn. 12: 231-267.

  • Butler C.J. 2003. The disproportionate effect of global warming on the arrival dates of short distancemigratory birds in North America. Ibis 145 3: 485-495. DOI: 10.1046/j.1474-919X. 2003.00193.x

  • Coppack T. Both C. 2002. Predicting life-cycle adaptation of migratory birds to global climatechange. Ardea 90 3: 369-377.

  • Cotton P. 2003. Avian migration phenology and global climate change. Proc. Natl. Acad. Sci. USA 100 21: 12219-12222. DOI: 10.1073/pnas.1930548100

  • Cramp S. (Ed). 1992. Handbook of the birds of Europe the Middle East and North Africa. Thebirds of the Western Palearctic. vol. 6. Oxford Univ. Press Oxford.

  • Crick H.Q.P. 2004. The impact of climate change on birds. Ibis 146 Suppl.: 48-56. DOI: 10.1111/j.1474-919X.2004.00327.x

  • Crick H.Q.P. Dudley C. Glue D.E. Thomson D.L. 1997. UK birds are laying eggs earlier. Nature 388: 526.

  • Crick H.Q.P. Sparks T.H. 2006. Changes in the phenology of breeding and migration in relation toglobal climate change. Acta Zool. Sin. 52 Suppl.: 154-157.

  • Csörgõ T. Harnos A. Kovács Sz. Nagy K. 2009. Study of the impacts of climate change usinglong-term bird ringing data. Természetvédelmi Közlemények 15: 1-12.

  • Csörgõ T. Lövei G. 1986. [Weight growing of the Thrush Nightingale (Luscinia luscinia) beforeautumn migration.] Proceedings of the 2thScientific Meeting of the Hungarian Ornithological Society Szeged: pp. 143-149. (In Hungarian).

  • Csörgõ T. Lövei G. 1990. [Wing shape of a Chiffchaff (Phylloscopus collybita) population breedingin Hungary]. Proceedings of the 2thScientific Meeting of the Hungarian Ornithological Society Szeged: pp. 155-158. (In Hungarian).

  • Csörgõ T. Lövei G. 1995. Autumn migration and recurrence of the Thrush Nightingale Luscinialuscinia at a stopover site in Central Hungary. Ardeola 42 1: 57-68.

  • Dowsett-Lemaire F. Dowsett R.J. 1987. European Reed and Marsh Warblers in Africa: migrationpatterns moult and habitat. Ostrich 58 2: 65-85. DOI: 10.1080/00306525.1987.9634145

  • Forchhammer M.C. Post E. Stenseth N.C. 2002. North Atlantic Oscillation timing of long-andshort-distance migration. J. Anim. Ecol. 71 6: 1002-1014. DOI: 10.1046/j.1365-2656.2002. 00664.x

  • Gaston A.J. 1974. Adaption in the genus Phylloscopus. Ibis 116 4: 432-450. DOI: 10.1111/j.1474-919X.1974.tb07644.x

  • Gauthreaux S.A. 1996. Bird migration: methodologies and major research trajectories(1945-1995). Condor 98: 442-453.

  • Gienapp R. Leimu R. Merilä J. 2007. Responses to climate change in avian migration time - microevolutionversus phenotypic plasticity. Clim. Res. 35: 25-35. DOI: 10.3354/cr00712

  • Gordo O. Brotons L. Ferrer X. Comas P. 2005. Do changes in climate patterns in wintering areasaffect the timing of the spring arrival of trans-Saharan migrant birds? Glob. Change Biol. 11 1: 12-21. DOI: 10.1111/j.1365-2486.2004.00875.x

  • Hedenström A. Barta Z. Helm B. Houston A.I. McNemara J.M. Jonzen N. 2007. Migrationspeed and scheduling of annual events by migrating birds in relation to climate change. Clim. Res. 35: 79-91. DOI: 10.3354/cr00715

  • Hogg P. Dare P.J. Rintoul J.V. 1984. Palearctic migrants in the Central Sudan. Ibis 126 3: 307-331. DOI: 10.1111/j.1474-919X.1984.tb00253.x

  • Holynsky R. 1965. Methods for the analysis of the wing shape of birds. Not. Orn. 6: 21-25.

  • IPCC (International Panel of Climate Change) 2001. Climate Change 2001: The scientific basis. Third assessment Report of Working Group I. In: Albritton D.L. Meira Filho L.G. (Eds). Cambridge Univ. Press Cambridge.

  • Jenni L. Kéry M. 2003. Timing of autumn bird migration under climate change: advances inlong-distance migrants delays in short-distance migrants. Proc. R. Soc. Lond. Ser. B 270 1523: 1467-1471. DOI: 10.1098/rspb.2003.2394

  • Keith S. Urban E.K. Fry C.M. 1992. The Birds of Africa. vol. 4. London: pp. 408-409.

  • Klein H. Berthold P. Querner U. 1982. Der zur europaischer Garten-Monchsgrasmucker (Sylviaborin and S. atricapilla). Vogelwarte 27: 73-134.

  • Lack P.C. 1983. The movements of Palearctic landbird migrants in Tsavo East National ParkKenya. J. Anim. Ecol. 52: 513-524.

  • Lehikoinen E. Sparks T.H. Zalakevicius M. 2004. Arrival and departure dates. Adv. Ecol. Res. 35: 1-31.

  • Leisler B. Winkler H. 1985. Ecomorphology. Curr. Ornithol. 2: 155-186.

  • Lövei G. 1983. Wing shape variations of Chiffchaffs on autumn migration in Hungary. Ring. & Migr. 4 4: 231-236. DOI: 10.1080/03078698.1983.9673811

  • Lundberg A. Edholm M. 1982. Earlier and later arrivals of migrants in central Sweden. Brit. Birds 75: 583-585.

  • Miholcsa T. Csörgõ T. 2007. The effects of climate change on the autumn migration of Segde Warblerand Reed Warbler. 8th Behavioral Ecology Meeting Cluj Napoca.

  • Miholcsa T. Tóth A. Csörgõ T. 2008. Change of the timing of autumn migration in Acrocephalusand Locustella genus. Acta Zool. Acad. Sci. Hung. 55 2: 175-185.

  • Moreau R.E. 1972. The Palearctic-African bird migration system. Acad. Press New York.

  • Péron G. Henry P-Y. Provost P. Dehorter O. Julliard R. 2007. Climate changes and post-nuptialmigration strategy by two reedbed passerines. Clim. Res. 35: 147-157. DOI: 10.3354/cr00721

  • Pulido F. Berthold P. Moth G. Querner U. 2001. Heritability of the timing of autumn migrationin a natural bird population. Proc. Soc. Roy. London. 268 1470: 885-993. DOI: 10.1098/rspb.2001.1602

  • Schaub M Pradel R Jenni L Lebreton J.D. 2001. Migrating birds stop over longer than usuallythought: An improved capture-recapture analysis. Ecology. 82 3: 852-859.

  • Schmidt E. 1982. Data on the autumn migration of the Thrush Nightingale (Luscinia luscinia) inHungary. Madártani Tájékoztató 6: 171-172.

  • Scisłowska M. Busse P. 2005. Fat reserves and body mass in some passerines migrating inthrough the southern Baltic coast. Ring 27 1: 3-31. DOI: 10.2478/v10050-008-0014-1

  • Seather B-E. Sutherland W.J. Engen S. 2004. Climate influences on avian population dynamics. In: Moller A. Fiedler W. Berthold P. (Eds). Birds and climate change. Elsevier Ltd. Amsterdam: pp. 185-210.

  • Shirihai H. 1996. The Birds of Israel. Acad. Press London.

  • Sokolov L.V. Markovets M.Y. Morozov Y.G. 1999. Long term dynamics of the mean date ofautumn migration in passerines on the Courish Spit of the Baltic Sea. Avian Ecol. Behav. 2: 1-18.

  • Sorjonen J. 1980. Selection of breeding habitat by the thrush nightingale Luscinia luscinia and itsposition in bird communities. Ornis Scand. 11 2: 125-134.

  • Svensson L. 1992. Identification Guide to European Passerines. Naturhistoriska Riksmuséet Stockholm.

  • Szentendrey G. Lövei G. Kállay Gy. 1979. [Measuring methods in the bird ringing camps of ActioHungarica.] Állattani Közlemények 66: 161-166. (In Hungarian).

  • Tellería J. Pérez-Tris J. Carbonell R. 2001. Seasonal changes in abundance and flight-relatedmorphology reveal different migration patterns in iberian forest passerines. Ardeola 48 1: 24-46

  • Thomas C.D. Lennon J.J. 1999. Birds extend their range northwards. Nature 399: 213. DOI: 10.1038/20335

  • Thorup K. Rabøl J. 2001. The orientation system and migration pattern of long-distance migrants:conflict between model predictions and observed patterns. J. Avian Biol. 32 2: 111-119. DOI: 10.1034/j.1600-048X.2001.320203.x

  • Tøttrup A.P. Thorup K. Rahbek C. 2006. Changes in timing of autumn migration in North Europeansongbird populations. Ardea 94 3: 527-536.

  • Williamson K. 1975. Birds and climate change. Bird Study 22: 143-164.

  • Yom-Tov Y. Yom-Tov S. Wright J. Du Feu T. Du Feu R. 2006. Recent changes in body weight andwing length among some British passerine birds. Oikos 112: 91-101.

  • Zalakevicius M. Bartkevicienem G. Raudonikis L. Januaitis J. 2006. Spring arrival response toclimate change in birds: a case study from eastern Europe. J. Field Ornithol. 147 2: 326-343. DOI: 10.1007/s10336-005-0016-6

  • Zalakevicius M. Zalakeviciute R. 2001. Global climate change impact on birds: a review of researchin Lithuania. Folia Zool. 50: 1-17.

  • Zink G. 1975. Der Zug europaeischer Singvögel. Vogelwarte Radolfzell.

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