Abstract
Most plant studies of green roof taxa have only been conducted for a duration of 1 or 2 years. The problem with this scenario is that it can result in premature conclusions and misleading recommendations because green roofs are dynamic systems. Plants that initially survive may eventually experience reduced coverage or disappear completely due to competition, variability in climate, and other factors. Setting up long-term studies similar to the National Science Foundation (NSF) Long Term Ecological Research (LTER) model would provide the opportunity to follow changes to green roof habitats over time and also examine impacts and ecosystem service outputs on similarly designed roofs across geographic locations. Without consciously considering the effects and changes over time mistakes are not only made, but also repeated. We review several important longitudinal studies and discuss factors that impact long-term plant communities such as substrate composition and fertility, substrate depth, substrate moisture, microclimates, roof slope, orientation, and irradiance levels; as well as initial plant choices, functional diversity and complexity, and maintenance practices. In addition, we discuss the potential of applying the LTER model to green roofs and close with future research needs and questions.
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References
Benvenuti S, Bacci D (2010) Initial agronomic performances of mediterranean xerophytes in simulated dry green roofs. Urban Ecosyst 13:349–363
Berendse F (1998) Effects of dominant plant species on soils during succession in nutrient poor ecosystems. Biogeochemistry 42:73–88
Boivin M, Lamy M, Gosselin A, Dansereau B (2001) Effect of artificial substrate depth on freezing injury of six herbaceous perennials grown in green roof system. Hort Technology 11(3):409–412.
Brenneisen S (2006) Space for urban wildlife: designing green roofs as habitats in Switzerland. Urban Habitats 4:27–36
Butler C, Orians C (2011) Sedum cools soil and can improve neighboring plant performance during water deficit on a green roof. Ecol Eng 37(11):1796–1803
Callahan J (1984) Long-term ecological research. BioScience 34(6):363–367
Cook-Patton S, Bauerle T (2012) Potential benefits of plant diversity on vegetated roofs: a literature review. J Environ Manage 106:85–92
Dewey D, Johnson P, Kjelgren R (2004) Species composition changes in a rooftop grass and wildflower meadow. Native Plants J 5(1):56–65
Dunnett N, Nolan A (2004) The effect of substrate depth and supplementary watering on the growth of nine herbaceous perennials in a semi-extensive green roof. Acta Hort. 643:305–309
Dunnett N, Nagase A, Hallam A (2008) The dynamics of planted and colonizing species on a green roof over six growing seasons 2001–2006: influence of substrate depth. Urban Ecosys 11:373–384
Durhman A, Rowe DB, Rugh C (2006) Effect of watering regimen on chlorophyll fluorescence and growth of selected green roof plant taxa. HortScience 41(7):1623–1628
Durhman A, Rowe DB, Rugh C (2007) Effect of substrate depth on initial growth, coverage, and survival of 25 succulent green roof plant taxa. HortScience 42(3):588–595
Dvorak BD, Volder A (2010) Green roof vegetation for North American ecoregions: a literature review. Landsc Urban Plan 96:197–213
Emilsson T (2008) Vegetation development on extensive vegetated green roof: Influence of substrate composition, establishment method and species mix. Ecol Eng 33:265–277
Emilsson T, Rolf K (2005) Comparison of establishment methods for extensive green roots in southern sweden. Urban for Urban Green 3:103–111
Forschungsgesellschaft Landschaftsentwicklung Landschaftsbau (FLL) (Research Society for Landscape Development and Landscape Design) (2008) Introduction to the FLL: guidelines for the planning, construction and maintenance of green roofing. FLL, Bonn, Germany
Getter K, Rowe DB (2008) Media depth influences Sedum green roof establishment. Urban Ecosys 11:361–372
Getter K, Rowe DB (2009) Substrate depth influences sedum plant community on a green roof. HortScience 44(2):401–407
Getter K, Rowe DB, Andresen JA (2007) Quantifying the effect of slope on extensive green roof stormwater retention. Ecol Eng 31:225–231
Getter K, Rowe DB, Cregg B (2009a) Solar radiation intensity influences extensive green roof plant communities. Urban For Urban Green 8(4):269–281
Getter K, Rowe DB, Robertson G, Cregg B, Andresen J (2009b) Carbon sequestration potential of extensive green roofs. Environ Sci Technol 43(19):7564–7570
Hauser K (2013) An evolving landscape: the living roof at California Academy of Sciences. Pac Hortic 74(4):24–27
Kiers H (2013) Back to nature: an alternative approach to planting green roofs. Pac Hortic 74(4):28–30
Köhler M (2006) Long-term vegetation research on two extensive green roofs in Berlin. Urban Habitiats 4(1):3–26
Köhler M, Poll P (2010) Long-term performance of selected old Berlin greenroofs in comparison to younger extensive greenroofs in Berlin. Ecol Eng 36:722–729
Kratz T, Deegan L, Harmon M, Lauenroth W (2003) Ecological variability in space and time: insights gained from the US LTER program. BioScience 53(1):57–67
Liesecke H (1998) Langzeitentwicklung einer extensiven Dachbegrünung: Untersuchungenzum Substratverhalten und zur Vegetationsentwicklung eines 1985 ausgeführten Objektes (Long-term development of extensive roof vegetation: a study on substrate and vegetation development over 12 years). Stadt-und-Grün 47:428–436
Lundholm J, MacIvor J, MacDougall Z, Ranalli M (2010) Plant species and functional group combinations affect green roof ecosystem functions. PLoS ONE 5(3):11
MacIvor J, Ranalli M, Lundholm J (2011) Performance of dryland and wetland plant species on extensive green roofs. Ann Bot 107:671–679
Monterusso M, Rowe DB, Rugh C (2005) Establishment and persistence of Sedum spp. and native taxa for green roof applications. HortScience 40(2):391–396
Nagase A, Dunnett N (2010) Drought tolerance in different vegetation types for extensive green roofs: effects of watering and diversity. Landsc Urban Plan 97:318–327
Oberndorfer E, Lundholm J, Bass B, Connelly M, Coffman R, Doshi H, Dunnett N, Gaffin S, Köhler M, Lu K, Rowe DB (2007) Green roofs as urban ecosystems: ecological structures, functions, and services. BioScience 57(10):823–833
Rowe DB (2011) Green roofs as a means of pollution abatement. Environ Pollut 159(8–9):2100–2110
Rowe DB, Getter K (2010) Green roofs and roof gardens. In: Aitkenhead-Peterson J, Volder A (eds) Urban ecosystems ecology. Agron. Monogr. 55. American Society of Agronomy. Crop Science Society of America. Soil Science Society of America, Madison, WI, p 391–412
Rowe DB, Monterusso M, Rugh C (2006) Assessment of heat-expanded slate and fertility requirements in green roof substrates. HortTechnology 16(3):471–477
Rowe DB, Getter K, Durhman A (2012) Effect of green roof media depth on Crassulacean plant succession over seven years. Landsc Urban Plan 104(3–4):310–319
Rowe DB, Kolp M, Greer S, Getter K (2014) Comparison of irrigation efficiency and plant health of overhead, drip, and sub-irrigation for extensive green roofs. Ecol Eng 64:306–313
Skabelund L, Blocksome C, Hamehkasi M (2014) Semi-arid green roof research 2009–2014: resilience of native species. Proc. of 12th North American Green Roof Conference: Cities Alive, Nashville, TN
Thuring C, Dunnett N (2014) Vegetation composition of old extensive green roofs (from 1980s Germany). Ecol Process 3:4. doi:10.1186/2192-1709-3-4
Thuring C, Berghage R, Beattie D (2010) Green roof plant responses to different substrate types and depths under various drought conditions. HortTechnology 20(2):395–401
VanWoert N, Rowe DB, Andresen J, Rugh C, Fernandez R, Xiao L (2005a) Green roof stormwater retention: effects of roof surface, slope, and media depth. J Environ Qual 34(3):1036–1044
VanWoert N, Rowe DB, Andresen J, Rugh C, Xiao L (2005b) Watering regime and green roof substrate design affect Sedum plant growth. HortScience 40(3):659–664
Whittinghill L, Rowe DB (2012a) The role of green roof technology in urban agriculture. Renew Agric Food Sys 27(4):314–322
Whittinghill L, Rowe DB (2012b) Vegetable production on extensive green roofs. Proc. of 10th North American Green Roof Conference: Cities Alive, Chicago, IL. 17–20 October, 2012
Whittinghill L, Rowe DB, Cregg B (2013) Evaluation of vegetable production on extensive green roofs. Agroecol Sustain Food Syst 37(4):465–484
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Rowe, B. (2015). Long-term Rooftop Plant Communities. In: Sutton, R. (eds) Green Roof Ecosystems. Ecological Studies, vol 223. Springer, Cham. https://doi.org/10.1007/978-3-319-14983-7_13
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DOI: https://doi.org/10.1007/978-3-319-14983-7_13
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