Foraging strategies determine the effect of traffic noise on bats

• Autorzy: Bonsen G. , Law B. , Ramp D.
• Języki publikacji: EN

Abstrakty

EN

Anthropogenic noise is a concern in many ecological systems. One important source of noise pollution is traffic noise as it can dominate the soundscape in urban and peri-urban environments. Taxa that rely on acoustics for behavioural strategies are likely to be especially susceptible to noise, as noise can inhibit the perception of informational sounds. Bats use echolocation to hunt prey while foraging and are therefore prime candidates for adverse effects. Captive studies have shown that foraging efficiency can be significantly reduced in noisy environments for some bat species, and that these species actively avoid noisy areas. However, it remains unclear how this selective sensitivity manifests in urban environments. Given that mode of flying and use of echolocation is entwined with foraging strategies, we hypothesised that different foraging guilds (i.e. fast flyers versus slow flyers) may show different levels of sensitivity to noisy roads. We used transects running perpendicular to a major traffic route in Sydney, Australia, to record bat activity and traffic noise levels. Noise amplitude levels across each frequency band dropped by over 50% in the first 50 m, with high frequency components ( > 10 kHz) being especially soft at this distance. Furthermore, all traffic noise above 5 kHz was lost within the first 150 m from the road. Fast flying bats flew close to the road, despite the traffic noise. In contrast, slow flying species appeared to fly more often away from the road. However, few calls of slow flyers were recorded, probably reflecting their difficulty in detecting them using acoustic surveys as well as their earlier decline in these peri-urban environments.

• Wydawca: -
• Czasopismo: Acta Chiropterologica
• Rocznik: 2015
• Tom: 17
• Numer: 2
• Opis fizyczny: p.347-357,fig.,ref.

Twórcy

autor

Bonsen G.

• Centre for Compassionate Conservation, School of Life Sciences, University of Technology, Broadway NSW 2007, Sydney, Australia

autor

Law B.

• Forest Science Unit, NSW Primary Industries, Locked Bag 5123, Parramatta, NSW 2124, Australia

autor

Ramp D.

• Centre for Compassionate Conservation, School of Life Sciences, University of Technology, Broadway NSW 2007, Sydney, Australia

Bibliografia

• 1. I. M. Abbott , F. Butler , and S. Harrison . 2012. When flyways meet highways — the relative permeability of different motorway crossing sites to functionally diverse bat species. Landscape and Urban Planning, 106: 293–302. Google Scholar
• 2. M. D. Adams , B. S. Law , and K. O. French . 2005. Effect of lights on activity levels of forest bats: increasing the efficiency of surveys and species identification. Wildlife Research, 32: 173–182. Google Scholar
• 3. M. D. Adams , B. S. Law , and M. S. Gibson . 2010. Reliable automation of bat call identification for eastern New South Wales, Australia, using classification trees and AnaScheme software. Acta Chiropterologica, 12: 231–245. Google Scholar
• 4. R. Avila-Flores , and M. B. Fenton . 2005. Use of spatial features by foraging insectivorous bats in a large urban landscape. Journal of Mammalogy, 86: 1193–1204. Google Scholar
• 5. J. R. Barber , K. R. Crooks , and K. M. Fristrup . 2009. The costs of chronic noise exposure for terrestrial organisms. Trends in Ecology & Evolution 25: 180–189. Google Scholar
• 6. R. Basham , B. Law , and P. Banks . 2011. Microbats in a ‘leafy’ urban landscape: are they persisting, and what factors influence their presence? Austral Ecology, 36: 663–678. Google Scholar
• 7. A. Berthinussen , and J. Altringham . 2011. The effect of a major road on bat activity and diversity. Journal of Applied Ecology, 49: 82–89. Google Scholar
• 8. D. Botteldooren , B. De Coensel , and T. Demuer . 2006. The temporal structure of urban soundscapes. Journal of Sound and Vibration, 292: 105–123. Google Scholar
• 9. A. A. Y. Chan , P. Giraldo-Perez , S. Smith , and D. T. Blumstein . 2010. Anthropogenic noise affects risk assessment and attention: the distracted prey hypothesis. Biology Letters, 6: 458–461. Google Scholar
• 10. S. Churchill 2008. Australian bats, 2nd edition. Allen & Unwin, Crows Nest, NSW, Australia, 254 pp. Google Scholar
• 11. L. Collins , R. A. Bradsctock , E. M. Tasker , and R. J. Whelan . 2012. Can gullies preserve complex forest structure in frequently burnt landscapes? Biological Conservation, 153: 177–186. Google Scholar
• 12. J. E. Duchamp , and R. K. Swihard . 2008. Shifts in bat community structure related to evolved traits and features of hu man-altered landscapes. Landscape Ecology, 23: 849–860. Google Scholar
• 13. J. E. Duchamp , D. W. Sparks , and J. O. Whitaker Jr. 2004. For aging-habitat selection by bats at an urban-rural interface: comparison between a successful and a less successful species. Canadian Journal of Zoology, 82: 1157–1164. Google Scholar
• 14. J. L. Erickson , and S. D. West . 2003. Associations of bats with local structure and landscape features of forested stands in western Oregon and Washington. Biological Conser vation, 109: 95–102. Google Scholar
• 15. J. D. A. Grant 1991. Prey location by two Australian longeared bats, Nyctophilus gouldi and N. geoffroyi. Australian Journal of Zoology, 39: 45–56. Google Scholar
• 16. W. Halfwerk , L. J. M. Holleman , C. K. M. Lessells , and H. Slabbekoorn . 2011. Negative impact of traffic noise on avian reproductive success. Journal of Applied Ecology, 48: 210–219. Google Scholar
• 17. D. J. Hosken , W. J. Bailey , J. E. O'Shea , and J. D. Roberts . 1994. Localisation of insect calls by the bat Nyctophilus geoffroyi (Chiroptera: Vespertilionidae ): a laboratory study. Australian Journal of Zoology, 42: 177–184. Google Scholar
• 18. C. L. Hourigan , C. Johnson , and S. K. A. Robson . 2006. The structure of a micro-bat community in relation to gradients of environmental variation in a tropical urban area. Urban Ecosystems, 9: 67–82. Google Scholar
• 19. C. L. Hourigan , C. P. Catterall , D. Jones , and M. Rhodes . 2010. The diversity of insectivorous bat assemblages among habitats within a subtropical urban landscape. Austral Ecology, 35: 849–857. Google Scholar
• 20. J. Kaku , M. Hiroe , S. Kuwano , and S. Namba . 2004. Sleep disturbance by traffic noise: an experimental study in subjects' own houses using a portable CD player. Journal of Sound and Vibration, 277: 459–464. Google Scholar
• 21. G. Kerth , and M. Melber . 2009. Species-specific barrier effects of a motorway on the habitat use of two threatened forest-living bat species. Biological Conservation, 142: 270–279. Google Scholar
• 22. B. S. Law , J. Anderson , and M. Chidel . 1998. A bat survey in State Forests on the south-west slopes region of New South Wales with suggestions of improvements for future surveys. Australian Zoologist, 30: 467–479. Google Scholar
• 23. B. S. Law , J. Anderson , and M. Chidel . 1999. Bat communities in a fragmented forest landscape on the south-west slopes of New South Wales, Australia. Biological Conservation, 88: 333–345. Google Scholar
• 24. B. S. Law , M. Chidel , and P. Tap . 2011. Bat activity in ephemeral stream-beds in the Pilliga forests: clarifying the importance of flyways and buffer widths in open forest and woodland. Pp. 308–321, in The biology and conservation of Australian bats (B. Law , P. Eby , D. Lunney , and L. Lumsden , eds.). Royal Zoological Society of NSW, Mosman, NSW, Australia, 498 pp. Google Scholar
• 25. P. E. Lentini , P. Gibbson , J. Fischer , B. Law , J. Hanspach , and T. G. Martin . 2012. Bats in a farming landscape benefit from linear remnants and unimproved pastures. PLoS ONE, 7: e48201. Google Scholar
• 26. G. Lesiński , A. Sikora , and A. Olszewski . 2011. Bat casualties on a road crossing a mosaic landscape. European Journal of Wildlife Research, 57: 217–223. Google Scholar
• 27. A. Lloyd , B. Law , and R. Goldingay . 2006. Bat activity on riparian zones and upper slopes in Australian timber production forests and the effectiveness of riparian buffers. Biological Conservation, 129: 207–220. Google Scholar
• 28. G. M. Morgan , T. E. Wilcoxen , M. A. Rensel , and S. J. Schoech . 2012. Are roads and traffic sources of physiological stress for the Florida scrub-jay? Wildlife Research, 39: 301–310. Google Scholar
• 29. K. M. Parris , M. Velik-Lord , and J. M. A. North . 2009. Frogs call at a higher pitch in traffic noise. Ecology and Society, 14(1): 25. Available at http://www.ecologyandsociety.org/vol14/iss1/art25/. Google Scholar
• 30. M. Pennay , B. Law , and L. Reinhold . 2004. Bat calls of New South Wales: region based guide to the echolocation calls of microchiropteran bats. NSW Department of Environment and Conservation, Hurstville, NSW, Australia, 87 pp. Google Scholar
• 31. PITTWATER COUNCIL. 1997. Urban bushland inventory and action plan, South Ward Reserves. Volume 2. Pittwater Council Natural Resources Unit, Warriewood, NSW, Australia, 101 pp. Google Scholar
• 32. R CORE TEAM. 2012. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. Available at http://www.R-project.org/. Google Scholar
• 33. M. Raimbault , and D. Dubois . 2005. Urban soundscapes: Ex peri ences and knowledge. Cities, 22: 339–350. Google Scholar
• 34. M. Rhodes , and C. P. Catterall . 2008. Spatial foraging behavior and use of an urban landscape by a fast-flying bat, the molossid Tadarida australis. Journal of Mammalogy, 89: 34–42. Google Scholar
• 35. ROADS and MARITIME SERVICES. 2012. Average daily traffic volume. Roads and Maritime Services, NSW Government. Available online at: http://www.rms.nsw.gov.au/documents/about/corporatepublications/statistics/nsw-traffic-volumes-2012.pdf. Google Scholar
• 36. J. Rydell , L. A. Miller , and M. E. Jensen . 1999. Ecolochation constraints of Daubenton's bat foraging over water. Functional Ecology, 13: 247–255. Google Scholar
• 37. A. Schaub , J. Ostwald , and B. M. Siemers . 2008. Foraging bats avoid noise. Journal of Experimental Biology, 211: 3174–3180. Google Scholar
• 38. B. M. Siemers , and A. Schaub . 2011. Hunting at the high-way: traffic noise reduces foraging efficiency in acoustic predators. Proceedings of the Royal Society, 278B: 1646–1652. Google Scholar
• 39. J. R. Speakman , P. I. Webb , and P. A. Racey . 1991. Effects of disturbance on the energy expenditure of hibernating bats. Journal of Applied Ecology, 28: 1087–1104. Google Scholar
• 40. E. L. Stone , G. Jones , and S. Harris . 2009. Street lighting disturbs commuting bats. Current Biology, 19: 1123–1127. Google Scholar
• 41. A. Surlykke , and E. K. V. Kalko . 2008. Echolocating bats cry out loud to detect their prey. PLoS ONE, 3: e2036. Google Scholar
• 42. J. M. Szewczak , and E. B. Arnett . 2008. Field test results of a potential acoustic deterrent to reduce bat mortality from wind turbines. An investigative report submitted to the Bats and Wind Energy Co-operative. Bat Con ser vation International, Austin, TX, USA. Available at http://www.batsandwind.org/pdf/2007DeterrentPondStudyFinal.pdf. Google Scholar
• 43. C. G. Threlfall , B. Law , and P. B. Banks . 2012. Sensitivity of insectivorous bats to urbanization: implications for suburban conservation planning. Biological Conservation, 146: 41–52. Google Scholar
• 44. C. G. Threlfall , B. Law , and P. B. Banks . 2013. The urban matrix and artificial light restricts the nightly ranging behaviour of Gould's long-eared bat (Nyctophilus gouldi). Austral Ecology, 38: 921–930. Google Scholar
• 45. C. Threlfall , B. Law , T. Penman , and P. B. Banks . 2011. Ecological processes in urban landscapes: mechanisms influencing the distribution and activity of insectivorous bats. Ecography, 34: 814–826. Google Scholar
• 46. D. M. Watson 2011. A productivity-based explanation for wood land bird declines: poorer soils yield less food. Emu, 111: 10–18. Google Scholar

Identyfikatory

DOI

10.3161/15081109ACC2015.17.2.010