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Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE

Australian magpies exhibit increased tolerance of aircraft noise on an airport, and are more responsive to take-off than to landing noises

G. D. Linley A C , K. Kostoglou B , R. Jit A and M. A. Weston B
+ Author Affiliations
- Author Affiliations

A Avisure, McDonald House, 37 Connor St, McDonald House, Level 4, Burleigh Heads, Qld 4220, Australia.

B Deakin University, Centre for Integrative Ecology, School of Life and Environmental Sciences, Faculty of Science, Engineering and the Built Environment, Melbourne Campus, 221 Burwood Hwy, Burwood, Vic. 3125, Australia.

C Corresponding author. Email: glinley@avisure.com

Wildlife Research 45(3) 282-286 https://doi.org/10.1071/WR18039
Submitted: 27 October 2017  Accepted: 5 April 2018   Published: 25 May 2018

Abstract

Context: On airports, birds often exhibit escape behaviour in response to aircraft. Avian escape behaviours can enable birds to effectively avoid collisions with aircraft, although some are maladaptive and may increase the risk of collision (e.g. erratic flying). Habituation and habituation-like processes among birds potentially mediate the likelihood of aircraft-bird collisions. Moreover, because managers exploit avian escape behaviour to reduce bird–aircraft collision risks, habituation may decrease the efficiency of bird-hazard management.

Aims: Our aim was to better understand avian behavioural responses to approaching aircraft, which may inform bird-hazard management.

Methods: We examined the response of Australian magpie, Cracticus tibicen, a species commonly involved in collisions with aircraft, to the noise associated with take-off and landing in three areas: airside, on airport but not airside, and off airport.

Key results: Magpies responded to aircraft noise in a nuanced way. Take-off produced more responses, and more intense responses, than did landing; both resulted in more frequent, and more intense, responses than did a ‘silent’ control. Responses were least likely, and response latencies were longer, airside, followed by on airport but not airside, and off airport. Intensity of responses was similar across these areas.

Conclusions: Magpies on the airside were least responsive, and this might influence their strike risk.

Implications: Given that most wildlife collisions occur during take-off and landing and at low altitudes, and that take-off has greatest overall strike risk, the lack of responsiveness of airside-inhabiting magpies may contribute to collision risk.


References

Allan, J. R., and Orosz, A. P. (2001). The costs of birdstrikes to commercial aviation. In ‘Proceedings of the 2001 Bird Strike Committee – USA/Canada. Third Joint Annual Meeting’, Calgary, AB. p. 2. (Transport Canada: Ottawa, Ontario)

Arévalo, J. E., and Newhard, K. (2011). Traffic noise affects forest bird species in a protected tropical forest. Revista de Biología Tropical 59, 969–980.

Australian Transport Safety Bureau (2017). Australian Aviation Wildlife Strike Statistics: 2006–2015. (Australian Transport Safety Bureau: Canberra.)

Awbrey, F. T., and Hunsaker, D. (1997). Effects of fixed‐wing military aircraft noise on California gnatcatcher reproduction. The Journal of the Acoustical Society of America 102, 3177.
Effects of fixed‐wing military aircraft noise on California gnatcatcher reproduction.Crossref | GoogleScholarGoogle Scholar |

Baxter, A. T., and Robinson, A. P. (2007). Monitoring and influencing feral Canada goose (Branta canadensis) behaviour to reduce birdstrike risks to aircraft. International Journal of Pest Management 53, 341–346.
Monitoring and influencing feral Canada goose (Branta canadensis) behaviour to reduce birdstrike risks to aircraft.Crossref | GoogleScholarGoogle Scholar |

Bermúdez-Cuamatzin, E., Ríos-Chelén, A. A., Gil, D., and Garcia, C. M. (2010). Experimental evidence for real-time song frequency shift in response to urban noise in a passerine bird. Biology Letters 7, 36–38.
Experimental evidence for real-time song frequency shift in response to urban noise in a passerine bird.Crossref | GoogleScholarGoogle Scholar |

Bernhardt, G. E., Blackwell, B. F., DeVault, T. L., and Kutschbach-Brohl, L. (2010). Fatal injuries to birds from collisions with aircraft reveal anti-predator behaviours. The Ibis 152, 830–834.
Fatal injuries to birds from collisions with aircraft reveal anti-predator behaviours.Crossref | GoogleScholarGoogle Scholar |

Blumstein, D. T. (2006). Developing an evolutionary ecology of fear: how life history and natural history traits affect disturbance tolerance in birds. Animal Behaviour 71, 389–399.
Developing an evolutionary ecology of fear: how life history and natural history traits affect disturbance tolerance in birds.Crossref | GoogleScholarGoogle Scholar |

Blumstein, D. T. (2016). Habituation and sensitization: new thoughts about old ideas. Animal Behaviour 120, 255–262.
Habituation and sensitization: new thoughts about old ideas.Crossref | GoogleScholarGoogle Scholar |

Brown, A. (1990). Measuring the effect of aircraft noise on sea birds. Environment International 16, 587–592.
Measuring the effect of aircraft noise on sea birds.Crossref | GoogleScholarGoogle Scholar |

Brumm, H. (2004). The impact of environmental noise on song amplitude in a territorial bird. Journal of Animal Ecology 73, 434–440.
The impact of environmental noise on song amplitude in a territorial bird.Crossref | GoogleScholarGoogle Scholar |

Burger, J. (1981). Behavioural responses of herring gulls (Larus argentatus) to aircraft noise. Environmental Pollution. Series A. Ecological and Biological 24, 177–184.
Behavioural responses of herring gulls (Larus argentatus) to aircraft noise.Crossref | GoogleScholarGoogle Scholar |

Burger, J. (1983). Jet aircraft noise and bird strikes: why more birds are being hit. Environmental Pollution. Series A. Ecological and Biological 30, 143–152.
Jet aircraft noise and bird strikes: why more birds are being hit.Crossref | GoogleScholarGoogle Scholar |

Burger, J. (1985). Factors affecting bird strikes on aircraft at a coastal airport. Biological Conservation 33, 1–28.
Factors affecting bird strikes on aircraft at a coastal airport.Crossref | GoogleScholarGoogle Scholar |

Conomy, J. T., Collazo, J. A., Dubovsky, J. A., and Fleming, W. J. (1998a). Dabbling duck behavior and aircraft activity in coastal North Carolina. The Journal of Wildlife Management 62, 1127–1134.
Dabbling duck behavior and aircraft activity in coastal North Carolina.Crossref | GoogleScholarGoogle Scholar |

Conomy, J. T., Dubovsky, J. A., Collazo, J. A., and Fleming, W. J. (1998b). Do black ducks and wood ducks habituate to aircraft disturbance? The Journal of Wildlife Management 62, 1135–1142.
Do black ducks and wood ducks habituate to aircraft disturbance?Crossref | GoogleScholarGoogle Scholar |

Cooper, W. E., and Blumstein, D. T. (2015). ‘Escaping from Predators: an Integrative View of Escape Decisions.’ (Cambridge University Press: UK.)

Delaney, D. K., Grubb, T. G., Beier, P., Pater, L. L., and Reiser, M. H. (1999). Effects of helicopter noise on Mexican spotted owls. The Journal of Wildlife Management 63, 60–76.
Effects of helicopter noise on Mexican spotted owls.Crossref | GoogleScholarGoogle Scholar |

DeVault, T. L., Blackwell, B. F., Seamans, T. W., Lima, S. L., and Fernández-Juricic, E. (2015). Speed kills: ineffective avian escape responses to oncoming vehicles. Proceedings of the Royal Society B 282, 20142188.
Speed kills: ineffective avian escape responses to oncoming vehicles.Crossref | GoogleScholarGoogle Scholar |

DeVault, T., Seamans, T., Blackwell, B. F., Lima, S., Martinez, M., and Fernández‐Juricic, E. (2017). Can experience reduce collisions between birds and vehicles? Journal of Zoology 301, 17–22.
Can experience reduce collisions between birds and vehicles?Crossref | GoogleScholarGoogle Scholar |

Dolbeer, R. A. (1998). Evaluation of shooting and falconry to reduce bird strikes with aircraft at John F. Kennedy International Airport. Wildlife Society Bulletin 21, 442–450.

Dolbeer, R. A. (2013). The history of wildlife strikes and management at airports. In ‘Wildlife in Airport Environments: Preventing Animal–Aircraft Collisions through Science-based Management’. (Ed. T. L. DeVault, B.F. Belant, J.L) pp. 1–6. (The John Hopkins University Press in association with The Wildlife Society: Baltimore, MD.)

Dolbeer, R. A., Belant, J. L., and Sillings, J. L. (1993). Shooting gulls reduces strikes with aircraft at John F. Kennedy International Airport. Wildlife Society Bulletin 21, 442–450.

Dolbeer, R., Wright, S., Weller, J., Anderson, A., and Begier, M. (2015). Wildlife Strikes to Civil Aircraft in the United States: 1990–2014. Serial Report No. 21. (US Department of Transportation: Washington, DC.)

Dunnet, G. M. (1977). Observations on the effects of low-flying aircraft at seabird colonies on the coast of Aberdeenshire, Scotland. Biological Conservation 12, 55–63.
Observations on the effects of low-flying aircraft at seabird colonies on the coast of Aberdeenshire, Scotland.Crossref | GoogleScholarGoogle Scholar |

Ellis, D. H., Ellis, C. H., and Mindell, D. P. (1991). Raptor responses to low-level jet aircraft and sonic booms. Environmental Pollution 74, 53–83.
Raptor responses to low-level jet aircraft and sonic booms.Crossref | GoogleScholarGoogle Scholar |

Gil, D., Honarmand, M., Pascual, J., Pérez-Mena, E., and Garcia, C. M. (2015). Birds living near airports advance their dawn chorus and reduce overlap with aircraft noise. Behavioral Ecology 26, 435–443.
Birds living near airports advance their dawn chorus and reduce overlap with aircraft noise.Crossref | GoogleScholarGoogle Scholar |

Goudie, R. I., and Jones, I. L. (2004). Dose-response relationships of harlequin duck behaviour to noise from low-level military jet over-flights in central Labrador. Environmental Conservation 31, 289–298.
Dose-response relationships of harlequin duck behaviour to noise from low-level military jet over-flights in central Labrador.Crossref | GoogleScholarGoogle Scholar |

Harms, C. A., Fleming, W. J., and Stoskopf, M. K. (1997). A technique for dorsal subcutaneous implantation of heart rate biotelemetry transmitters in black ducks: application in an aircraft noise response study. The Condor 99, 231–237.
A technique for dorsal subcutaneous implantation of heart rate biotelemetry transmitters in black ducks: application in an aircraft noise response study.Crossref | GoogleScholarGoogle Scholar |

Legagneux, P., and Ducatez, S. (2013). European birds adjust their flight initiation distance to road speed limits. Biology Letters 9, 20130417.
European birds adjust their flight initiation distance to road speed limits.Crossref | GoogleScholarGoogle Scholar |

Lima, S. L., Blackwell, B. F., DeVault, T. L., and Fernández‐Juricic, E. (2015). Animal reactions to oncoming vehicles: a conceptual review. Biological Reviews of the Cambridge Philosophical Society 90, 60–76.
Animal reactions to oncoming vehicles: a conceptual review.Crossref | GoogleScholarGoogle Scholar |

Lowry, H., Lill, A., and Wong, B. B. M. (2011). Tolerance of auditory disturbance by an avian urban adapter, the noisy miner. Ethology 117, 490–497.
Tolerance of auditory disturbance by an avian urban adapter, the noisy miner.Crossref | GoogleScholarGoogle Scholar |

McKee, J., Shaw, P., Dekker, A., and Patrick, K. (2016). Approaches to wildlife management in aviation. In ‘Problematic Wildlife. A Cross-disciplinary Approach’. (Ed. F. M. Angelici.) pp. 465–488. (Springer International Publishing: Cham, Switzerland)

McLeod, E. M., Guay, P.-J., Taysom, A. J., Robinson, R. W., and Weston, M. A. (2013). Buses, cars, bicycles and walkers: the influence of the type of human transport on the flight responses of waterbirds. PLoS One 8, e82008.
Buses, cars, bicycles and walkers: the influence of the type of human transport on the flight responses of waterbirds.Crossref | GoogleScholarGoogle Scholar |

Mumme, R. L., Schoech, S. J., Woolfenden, G. E., and Fitzpatrick, J. W. (2000). Life and death in the fast lane: demographic consequences of road mortality in the Florida scrub-jay. Conservation Biology 14, 501–512.
Life and death in the fast lane: demographic consequences of road mortality in the Florida scrub-jay.Crossref | GoogleScholarGoogle Scholar |

Patrick, K., and Shaw, P. (2012). Bird strike hazard management programs at airports: what works? In ‘Proceedings of the 5th Symposium of Flight Safety’, 28–30 August, São José dos Campos/SP, Brazil. pp. 28–30. (Department of Science and Aerospatiale Technology)

Quinn, J. L., Whittingham, M. J., Butler, S. J., and Cresswell, W. (2006). Noise, predation risk compensation and vigilance in the chaffinch (Fringilla coelebs). Journal of Avian Biology 37, 601–608.
Noise, predation risk compensation and vigilance in the chaffinch (Fringilla coelebs).Crossref | GoogleScholarGoogle Scholar |

Thomson, B. (2007). A cost effective grassland management strategy to reduce the number of bird strikes at the Brisbane airport. PhD thesis, Queensland University of Technology.

van Dongen, W. F. D., Robinson, R. W., Weston, M. A., Mulder, R. A., and Guay, P.-J. (2015). Variation at the DRD4 locus is associated with wariness and local site selection in urban black swans. BMC Evolutionary Biology 15, 253.
Variation at the DRD4 locus is associated with wariness and local site selection in urban black swans.Crossref | GoogleScholarGoogle Scholar |

Ward, D. H., and Stehn, R. A. (1990). Response of Brant and Other Geese to Aircraft Disturbances at Izembek Lagoon, Alaska. Final report to Minerals Management Service, Intra-agency agreement 14-12-0001-30332. 193pp. (Alaska Fish and Wildlife Research Center: Anchorage, AK, United States.)

Warne, R. M., and Jones, D. N. (2003). Evidence of target specificity in attacks by Australian magpies on humans. Wildlife Research 30, 265–267.
Evidence of target specificity in attacks by Australian magpies on humans.Crossref | GoogleScholarGoogle Scholar |

Weston, M. A., McLeod, E. M., Blumstein, D. T., and Guay, P. J. (2012). A review of flight-initiation distances and their application to managing disturbance to Australian birds. Emu - Austral Ornithology 112, 269–286.