Abstract
Urbanisation is among the most severe drivers of the recent biodiversity crisis. It has been shown that stormwater ponds have a high value for the conservation of dragon- and damselflies in urban areas. However, information on the relevance of different types of stormwater ponds is lacking so far. The aim of this study was to compare the Odonata assemblages of three types of urban stormwater ponds (n per type = 10): (i) ponds only containing temporary water bodies (TEMP), (ii) ponds with temporary and small perennial water bodies (TEMP/PERE) and (iii) ponds with one large perennial water body (PERE). We observed distinct differences in environmental conditions and Odonata assemblages among the three types of stormwater ponds. In particular, vegetation structure and the partly interrelated microclimate differed considerably between TEMP on the one hand, and TEMP/PERE and PERE on the other hand. Odonate species richness and exuviae density of threatened species differed, too. Due to their early successional stages with low cover of riparian woodland and shallow water bodies, TEMP were characterised by a warmer microclimate than TEMP/PERE and PERE. Odonate species richness and exuviae density of threatened species were highest in TEMP and lowest in PERE. Moreover, indicator species were only identified for TEMP. Our study showed that stormwater ponds with a temporary hydroperiod play an important role for the conservation of odonates in urban areas. This is especially the case for specialised threatened species, such as Libellula depressa and Ischnura pumilio.
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References
Balmford A, Green RE, Jenkins M (2003) Measuring the changing state of nature. Trends Ecol Evol 18:326–330
Barnosky AD, Matzke N, Tomiya S, Wogan GOU, Swartz B, Quental TB, Marshall C, McGuire JL, Lindsey EL, Maguire KC, Mersey B, Ferrer EA (2011) Has the Earth’s sixth mass extinction already arrived? Nature 471:51–57
Beninde J, Veith M, Hochkirch A (2015) Biodiversity in cities need space: a meta-analysis of factors determining intra-urban biodiversity variation. Ecol Lett 18:581–592
Bezirksregierung Köln (2018) Digitale Orthophotos (DOP). http://www.wms.nrw.de. Accessed 15 November 2018
Birx-Raybuck DA, Price SJ, Dorcas ME (2010) Pond age and riparian zone proximity influence anuran occupancy of urban retention ponds. Urban Ecosyst 13:181–190
Booth DB, Jackson RJ (1997) Urbanization of aquatic systems: degradation, thresholds, stormwater detection and the limits of mitigation. J Am Water Resour Assoc 33:1077–1090
Brand AB, Snodgrass JW (2010) Value of artificial habitats for amphibian reproduction in altered landscapes. Conserv Biol 24:295–301. https://doi.org/10.1111/j.1523-1739.2009.01301.x
Bried JT, D’Amico FD, Samways MJ (2012) A critique of the dragonfly delusion hypothesis: why sampling exuviae does not avoid bias. Insect Conserv Divers 5:398–402
Brochard C, Groenendijk D, van der Ploeg E, Termaat T (2012) Fotogids Larvenhuidjes van Libellen. KNNV Uitgeverij, Zeist
City of Münster (2017) Münster—data and facts. http://www.muenster.de. Accessed 17 May 2018
Clausnitzer V, Kalkman VJ, Ram M, Collen B, Baillie JEM, Bedjanič M, Darwall WRT, Dijkstra K-DB, Dow R, Hawking J, Karube H, Malikova E, Paulson D, Schütte K, Suhling F, Villanueva RJ, von Ellenrieder N, Wilson K (2009) Odonata enter the biodiversity crisis debate: the first global assessment of an insect group. Biol Conserv 142:1864–1869
Collinson NH, Biggs J, Corfield A, Hodson MJ, Walker D, Whitfield M, Williams PJ (1995) Temporary and permanent ponds: an assessment of the effects of drying out on the conservation value of aquatic macroinvertebrate communities. Biol Conserv 74:125–133
Corbet PS (2004) Dragonflies. Behaviour and ecology of Odonata. Brill, New York
D’Amico F, Darblade S, Avigno S, Blanc-Manel S, Ormerod SJ (2004) Odonates as indicators of shallow lake restoration by liming: comparing adult and larval responses. Restor Ecol 12:439–446
De Vos JM, Joppa LN, Gittleman JL, Stephens PR, Pimm SL (2014) Estimating the normal background rate of species extinction. Conserv Biol 29:452–462
Dijkstra K-DB, Lewington R (2006) Field guide to the dragonflies of Britain and Europe. British Wildlife Publishing, Dorset
Diniz-Filho JA, Bini LM, Hawkins BA (2003) Spatial autocorrelation and red herrings in geographical ecology. Glob Ecol Biogeol 12:53–64
Donnelly R, Marzluff JM (2006) Relative importance of habitat quantity, structure, and spatial pattern to birds in urbanizing environments. Urban Ecosyst 9:99–117
Dufrêne M, Legendre P (1997) Species assemblages and indicator species: the need for a flexible asymmetrical approach. Ecol Monogr 67:345–366
DWD (Deutscher Wetterdienst) (2018) Langjährige Mittelwerte. http://www.dwd.de. Accessed 17 May 2018
Ehrenfeld JB (2000) Evaluating wetlands within an urban context. Ecol Eng 15:253–265
Eichel S, Fartmann T (2008) Management of calcareous grasslands for Nickerl’s fritillary (Melitaea aurelia) has to consider habitat requirements of the immature stages, isolation, and patch area. J Insect Conserv 12:677–688. https://doi.org/10.1007/s10841-007-9110-9
Fahrig L (2003) Effects of habitat fragmentation on biodiversity. Annu Rev Ecol Syst 34:487–515
Foote AL, Hornung CLR (2005) Odonates as biological indicators of grazing effects on Canadian prairie wetlands. Ecol Entomol 30:273–283
Gallagher MT, Snodgrass JW, Ownby DR, Brand AB, Casey RE, Lev S (2011) Watershed-scale analysis of pollutant distributions in stormwater management ponds. Urban Ecosyst 14:469–484
Gledhill DG, James P, Davies DH (2008) Pond diversity as a determinant of aquatic species richness in an urban landscape. Landsc Ecol 23:1219–1230
Goertzen D, Suhling F (2013) Promoting dragonfly diversity in cities: major determinants and implications for urban pond design. J Insect Conserv 17:399–409
Grimm NB, Faeth SH, Golubiewski NE, Redman CL, Wu J, Bai X, Briggs J (2008) Global change and the ecology of cities. Science 319:756–760
Hamer AJ, Smith PJ, McDonnell MJ (2012) The importance of habitat design and aquatic connectivity in amphibian use of urban stormwater retention ponds. Urban Ecosyst 15:451–471
Hassall C (2014) The ecology and biodiversity of urban ponds. WIREs Water 1:187–206
Hassall C, Anderson S (2015) Stormwater ponds can contain comparable biodiversity to unmanaged wetlands in urban areas. Hydrobiologia 745:137–149
Herrmann J (2012) Chemical and biological benefits in a stormwater wetland in Kalmar, SE Sweden. Limnologica 42:299–309
Hill MJ, Biggs J, Thornhill I, Briers RA, Gledhill DG, White JC, Wood PJ, Hassall C (2017) Urban ponds as an aquatic biodiversity resource in modified landscapes. Glob Chang Biol 23:986–999. https://doi.org/10.1111/gcb.13401
Holtmann L, Philipp K, Becke C, Fartmann T (2017) Effects of habitat and landscape quality on amphibian assemblages of urban stormwater ponds. Urban Ecosyst 20:1249–1259. https://doi.org/10.1007/s11252-017-0677-y
Holtmann L, Juchem M, Brüggeshemke J, Möhlmeyer A, Fartmann T (2018) Stormwater ponds promote dragonfly (Odonata) species richness and density in urban areas. Ecol Eng 118:1–11. https://doi.org/10.1016/j.ecoleng.2017.12.028
Jeanmougin M, Leprieur F, Loïs G, Clergeau P (2014) Fine-scale urbanisation affects Odonata species diversity in ponds of a megacity (Paris, France). Acta Oecol 59:26–34
Kadoya T, Suda S, Washitani I (2004) Dragonfly species richness on man-made ponds: effects of pond size and pond age on newly established assemblages. Ecol Res 19:461–467
Kuhn K, Burbach K (1998) Libellen in Bayern. Eugen Ulmer, Stuttgart
Lambin EF, Turner BL, Geist HJ, Agbola SB, Angelsen A, Bruce JW, Coomes OT, Dirzo R, Fischer G, Folke C, George PS, Homewood K, Imbernon J, Leemans R, Li X, Moran EF, Mortimore M, Ramakrishnan PS, Richards JF, Skånes H, Steffen W, Stone GD, Svedin U, Veldkamp TA, Vogel C, Xu J (2001) The causes of land-use and land-cover change: moving beyond the myths. Glob Environ Change 11:261–269
LANUV NRW (Landesamt für Natur, Umwelt und Verbraucherschutz in Nordrhein-Westfalen) (2010) Rote Liste und Artenverzeichnis der Libellen—Odonata—in Nordrhein-Westfalen. http://www.lanuv.de. Accessed 17 May 2018
Le Viol I, Mocq J, Julliard R, Kerbiriou C (2009) The contribution of motorway stormwater retention ponds to the biodiversity of aquatic macroinvertebrates. Biol Conserv 142:3163–3171
Le Viol I, Chiron F, Julliard R, Kerbiriou C (2012) More amphibians than expected in highway stormwater ponds. Ecol Eng 47:146–154
Legendre P, Legendre L (2012) Numerical ecology. Elsevier, Amsterdam
Lohr M (2007) Libellen in europäischen Flusslandschaften. Dissertation, University of Münster
McCallum ML (2015) Vertebrate biodiversity losses point to a sixth mass extinction. Biodivers Conserv 24:2497–2519. https://doi.org/10.1007/s10531-015-0940-6
McKinney ML (2006) Urbanization as a major cause of biotic homogenization. Biol Conserv 127:247–260
Oertli B, Joye DA, Castella E, Juge R, Cambin D, Lachavanne J-B (2002) Does size matter? The relationship between pond area and biodiversity. Biol Conserv 104:59–70
Ott J (2008) Die Kleine Pechlibelle—Ischnura pumilio (Charpentier, 1925) (Odonata: Coenagrionidae) in der Pfalz: ein Profiteur von Regenrückhaltebecken, Naturschutzgewässern und der Klimaänderung. Mainz Nat Arch 46:233–261
Paul MJ, Meyer JL (2001) Streams in the urban landscape. Annu Rev Ecol Syst 32:333–365
Piersanti S, Rebora M, Salerno G, Gaino E (2007) Behaviour of the larval dragonfly Libellula depressa (Odonata Libellulidae) in drying pools. Ethol Ecol Evol 19:127–136
Poniatowski D, Fartmann T (2010) What determines the distribution of a flightless bush-cricket (Metrioptera brachyptera) in a fragmented landscape? J Insect Conserv 14:637–645. https://doi.org/10.1007/s10841-010-9293-3
Quinn GP, Keough MJ (2002) Experimental design and data analysis for biologists. Cambridge University Press, Cambridge
R Development Core Team (2018) R: a language and environment for statistical computing. http://www.r-project.org. Accessed 17 May 2018
Raebel EM, Merckx T, Riordan P, Macdonald DW, Thompson DJ (2010) The dragonfly delusion: why is it essential to sample exuviae to avoid biased surveys. J Insect Conserv 14:523–533
Sahlén G, Ekestubbe K (2001) Identification of dragonflies (Odonata) as indicators of general species richness in boreal forest lakes. Biodivers Conserv 10:673–690
Sala OE, Chapin FS, Armesto JJ, Berlow E, Bloomfield J, Dirzo R, Huber-Sanwald E, Huenneke LF, Jackson RB, Kinzig A, Leemans R, Lodge DM, Mooney HA, Oesterheld M, Poff NL, Sykes MT, Walker BH, Walker M, Wall DH (2000) Global biodiversity scenarios for the year 2100. Science 287:1770–1774
Samways MJ (2008) Dragonflies as focal organisms in contemporary conservation biology. In: Córdoba-Aguilar A (ed) Dragonflies and damselflies. Model organisms for ecological and evolutionary research. Oxford University Press, New York, pp 97–108
Scher O, Thièry A (2005) Odonata, Amphibia and environmental characteristics in motorway stormwater retention ponds (Southern France). Hydrobiologia 551:237–251
Snep RPH, Opdam PFM, Baveco JM, WallisDeVries MF, Timmermans W, Kwak RGM, Kuypers V (2006) How peri-urban areas can strengthen animal populations within cities: a modeling approach. Biol Conserv 127:345–355
Steele MK, Heffernan JB (2014) Morphological characteristics of urban water bodies: mechanisms of change and implications for ecosystem function. Ecol Appl 24:1070–1084
Sternberg K, Buchwald R (eds) (1999) Die Libellen Baden-Württembergs. Band 1: Allgemeiner Teil. Kleinlibellen (Zygoptera). Eugen Ulmer, Stuttgart (Hohenheim)
Tonne F (1954) Besser bauen mit Besonnungs- und Tageslicht-Planung. Hofmann, Schorndorf/Stuttgart
United Nations (2010) World urbanization prospects: the 2009 revision. United Nations, New York
Villareal EL, Semadeni-Davies A, Bengtsson L (2004) Inner city stormwater control using a combination of best management practices. Ecol Eng 22:279–298
Wildermuth H, Martens A (2014) Taschenatlas der Libellen Europas. Alle Arten von den Azoren bis zum Ural im Porträt. Quelle & Meyer, Wiebelsheim
Williams DD (1996) Environmental constraints in temporary fresh waters and their consequences for the insect fauna. J N Am Benthol Soc 15:634–650
Williams DD (1997) Temporary ponds and their invertebrate communities. Aqua Conserv Mar Fresh Ecosyst 7:105–117
Willigalla C, Fartmann T (2009) Die Libellenfauna der Regenrückhaltebecken der Stadt Mainz (Odonata). Libellula 28:117–137
Willigalla C, Fartmann T (2012) Patterns in the diversity of dragonflies (Odonata) in cities across Central Europe. Eur J Entomol 109:235–245. https://doi.org/10.14411/eje.2012.031
Willigalla C, Menke N, Kronshage A (2003) Naturschutzbedeutung von Regenrückhaltebecken. Dargestellt am Beispiel der Libellen in Münster/Westfalen. Naturschutz Landschaftsplanung 35:83–89
Wood PJ, Greenwood MT, Agnew MD (2003) Pond biodiversity and habitat loss in the UK. Area 35:206–216
Acknowledgements
J. Möhring (Civil Engineering Office Münster) and M. Genius (Nature Conservation Agency Münster) gave permissions for the investigation. A. Möhlmeyer conducted chemical analyses of water samples.
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The study was funded by a Ph.D. scholarship from the Deutsche Bundesstiftung Umwelt (DBU).
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Holtmann, L., Brüggeshemke, J., Juchem, M. et al. Odonate assemblages of urban stormwater ponds: the conservation value depends on pond type. J Insect Conserv 23, 123–132 (2019). https://doi.org/10.1007/s10841-018-00121-x
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DOI: https://doi.org/10.1007/s10841-018-00121-x