Impacts from hydropower production on biodiversity in an LCA framework—review and recommendations

WATER USE IN LCA

Abstract

Purpose

Expanding renewable energy production is widely accepted as a promising strategy in climate change mitigation. However, even renewable energy production has some environmental impacts, some of which are not (yet) covered in life cycle impact assessment (LCIA). We aim to identify the most important cause-effect pathways related to hydropower production on biodiversity, as one of the most common renewable energy sources, and to provide recommendations for future characterization factor (CF) development.

Methods

We start with a comprehensive review of cause-effect chains related to hydropower production for both aquatic and terrestrial biodiversity. Next, we explore contemporary coverage of impacts on biodiversity from hydropower production in LCA. Further, we select cause-effect pathways displaying some degree of consistency with existing LCA frameworks for method development recommendations. For this, we compare and contrast different hydrologic models and discuss how existing LCIA methodologies might be modified or combined to improve the assessment of biodiversity impacts from hydropower production.

Results and discussion

Hydropower impacts were categorized into three overarching impact pathways: (1) freshwater habitat alteration, (2) water quality degradation, and (3) land use change. Impacts included within these pathways are flow alteration, geomorphological alteration to habitats, changes in water quality, habitat fragmentation, and land use transformation. For the majority of these impacts, no operational methodology exists currently. Furthermore, the seasonal nature of river dynamics requires a level of temporal resolution currently beyond LCIA modeling capabilities. State-of-the-art LCIA methods covering biodiversity impacts exist for land use and impacts from consumptive water use that can potentially be adapted to cases involving hydropower production, while other impact pathways need novel development.

Conclusions

In the short term, coverage of biodiversity impacts from hydropower could be significantly improved by adding a time step representing seasonal ecological water demands to existing LCIA methods. In the long term, LCIA should focus on ecological response curves based on multiple hydrologic indices to capture the spatiotemporal aspects of river flow, by using models based on the “ecological limits to hydrologic alteration” (ELOHA) approach. This approach is based on hydrologic alteration-ecological response curves, including site-specific environmental impact data. Though data-intensive, ELOHA represents the potential to build a global impact assessment framework covering multiple ecological indicators from local impacts. Further, we recommend LCIA methods based on degree of regulation for geomorphologic alteration and a fragmentation index based on dam density for “freshwater habitat alteration,” which our review identified as significant unquantified threats to aquatic biodiversity.

Keywords

Biodiversity Ecosystem quality Freshwater use Hydropower Life cycle impact assessment Review 

Notes

Acknowledgements

This work was funded by the Research Council of Norway through the EcoManage project (project number 215934) and the SURE project (project number 244109). The authors would like to thank Ottar Michelsen of NTNU and the EcoManage project leaders for support and guidance during the course of this publication, especially Atle Harby and Håkon Sundt.

References

  1. Alho CJ (2011) Environmental effects of hydropower reservoirs on wild mammals and freshwater turtles in Amazonia: a review. Oecologia Australis 15:593–604CrossRefGoogle Scholar
  2. Anderson EP, Freeman MC, Pringle CM (2006) Ecological consequences of hydropower development in Central America: impacts of small dams and water diversion on neo-tropical stream fish assemblages. River Res Appl 22:397–411CrossRefGoogle Scholar
  3. Angilletta MJ, Ashley Steel E, Bartz KK, Kingsolver JG, Scheuerell MD, Beckman BR, Crozier LG (2008) Big dams and salmon evolution: changes in thermal regimes and their potential evolutionary consequences. Evol Appl 1:286–299CrossRefGoogle Scholar
  4. Arthington AH, Naiman RJ, McClain ME, Nilsson C (2010) Preserving the biodiversity and ecological services of rivers: new challenges and research opportunities. Freshwat Biol 55:1–16CrossRefGoogle Scholar
  5. Bakken TH, Sundt H, Ruud A, Harby A (2012) Development of small versus large hydropower in Norway-comparison of environmental impacts. In: Tranell G (ed) Technoport 2012—Sharing Possibilities and 2nd Renewable Energy Research Conference, 20th edn. Energy Procedia, Amsterdam, pp 185–199Google Scholar
  6. Bayart J-B, Bulle C, Deschenes L, Margni M, Pfister S, Vince F, Koehler A (2010) A framework for assessing off-stream freshwater use in LCA. Int J Life Cycle Assess 15:439–453CrossRefGoogle Scholar
  7. Bednarek AT, Hart DD (2005) Modifying dam operations to restore rivers: ecological responses to Tennessee River dam mitigation. Ecol Appl 15:997–1008CrossRefGoogle Scholar
  8. Berga L et al (2006) Dams and reservoirs, docieties and environment in the 21st century. Taylor & Francis, LondonGoogle Scholar
  9. Berger M, Finkbeiner M (2010) Water footprinting: how to address water use in life cycle assessment? Sustainability 2(4):919–944Google Scholar
  10. Bernacsek GM (1984) Guidelines for dam design and operation to optimize fish production in impounded river basins (based on a review of the ecological effects of large dams in Africa). CIFA Tech Pap 11:1–98Google Scholar
  11. Biemans H, Haddeland I, Kabat P, Ludwig F, Hutjes RWA, Heinke J, von Bloh W, Gerten D (2011) Impact of reservoirs on river discharge and irrigation water supply during the 20th century. Water Resour Res 47:W03509, doi:10.1029/2009WR008929
  12. Boulay A-M, Bulle C, Bayart J-B, Deschenes L, Margni M (2011) Regional characterization of freshwater use in LCA: modeling direct impacts on human health. Environ Sci Technol 45:8948–8957CrossRefGoogle Scholar
  13. Bradford MJ (1997) An experimental study of stranding of juvenile salmonids on gravel bars and in sidechannels during rapid flow decreases. Regul Rivers: Res Manage 13:395–401CrossRefGoogle Scholar
  14. Bradford MJ, Taylor GC, Allan JA, Higgins PS (1995) An experimental study of the stranding of juvenile coho salmon and rainbow trout during rapid flow decreases under winter conditions. N Am J Fish Manage 15:473–479CrossRefGoogle Scholar
  15. Brown A, Muller S, Dobrotkova Z (2011) Renewable Energy Prospects and Technology: IEAGoogle Scholar
  16. Budy P, Thiede GP, Bouwes N, Petrosky C, Schaller H (2002) Evidence linking delayed mortality of Snake River salmon to their earlier hydrosystem experience. N Am J Fish Manage 22:35–51CrossRefGoogle Scholar
  17. Bunn SE, Arthington AH (2002) Basic principles and ecological consequences of altered flow regimes for aquatic biodiversity. Environ Manage 30:492–507CrossRefGoogle Scholar
  18. Burke M, Jorde K, Buffington JM (2009) Application of a hierarchical framework for assessing environmental impacts of dam operation: changes in streamflow, bed mobility and recruitment of riparian trees in a western North American river. J Environ Manag 90:S224–S236CrossRefGoogle Scholar
  19. Cadwallader PL (1978) Some causes of the decline in range and abundance of native fish in the Murray Darling system Australia. Proceedings of the Royal Society of Victoria 90(1/2):211–224Google Scholar
  20. Caissie D (2006) The thermal regime of rivers: a review. Freshwat Biol 51:1389–1406CrossRefGoogle Scholar
  21. Chaudhary A, Verones F, de Baan L, Hellweg S (2015) Quantifying land use impacts on biodiversity: combining species–area models and vulnerability indicators. Environ Sci Technol 49:9987–9995CrossRefGoogle Scholar
  22. Clarkson RW, Childs MR, Schaefer S (2000) Temperature effects of hypolimnial-release dams on early life stages of Colorado River basin big-river fishes. Copeia 2000:402–412CrossRefGoogle Scholar
  23. Connor EJ, Pflug DE (2004) Changes in the distribution and density of pink, chum, and Chinook salmon spawning in the upper Skagit River in response to flow management measures. N Am J Fish Manage 24:835–852CrossRefGoogle Scholar
  24. Curran M et al (2011) Toward meaningful end points of biodiversity in life cycle assessment. Environ Sci Technol 45:70–79CrossRefGoogle Scholar
  25. Cushman RM (1985) Review of ecological effects of rapidly varying flows downstream from hydroelectric facilities. N Am J Fish Manage 5:330–339CrossRefGoogle Scholar
  26. De Baan L, Mutel CL, Curran M, Hellweg S, Koellner T (2013) Land use in life cycle assessment: global characterization factors based on regional and global potential species extinction. Environ Sci Technol 47:9281–9290CrossRefGoogle Scholar
  27. DePhilip M, Moberg T (2010) Ecosystem flow recommendations for the Susquehanna River basin. The Nature Conservancy, Harrisburg, PennsylvaniaGoogle Scholar
  28. Döll P, Zhang J (2010) Impact of climate change on freshwater ecosystems: a global-scale analysis of ecologically relevant river flow alterations. Hydrol Earth Syst Sci 14(5):783–799Google Scholar
  29. Dudgeon D (2000) Large-scale hydrological changes in tropical Asia: prospects for riverine biodiversity. the construction of large dams will have an impact on the biodiversity of tropical Asian rivers and their associated wetlands. Bioscience 50:793–806CrossRefGoogle Scholar
  30. Dudgeon D, Arthington AH, Gessner MO, Kawabata Z, Knowler DJ, Lévêque C, Naiman RJ, Prieur-Richard AH, Soto D, Stiassny ML, Sullivan CA (2006) Freshwater biodiversity: importance, threats, status and conservation challenges. Biol Rev 81:163–182CrossRefGoogle Scholar
  31. Dynesius M, Nilsson C (1994) Fragmentation and flow regulation of river systems in the northern 3rd of the world. Science 266:753–762CrossRefGoogle Scholar
  32. Egré D, Milewski JC (2002) The diversity of hydropower projects. Energy Policy 30:1225–1230CrossRefGoogle Scholar
  33. Finer M, Jenkins CN (2012) Proliferation of hydroelectric dams in the Andean Amazon and implications for Andes-Amazon connectivity. Plos one 7:e35126CrossRefGoogle Scholar
  34. Finger D, Schmid M, Wuest A (2006) Effects of upstream hydropower operation on riverine particle transport and turbidity in downstream lakes. Water Resour Res 42Google Scholar
  35. Finkbeiner M, Ackermann R, Bach V, Berger M, Brankatschk G, Chang YJ, Grinberg M, Lehmann A, Martínez-Blanco J, Minkov N, Neugebaur S, Scheumann R, Schneider L, Wolf K (2014) Challenges in life cycle assessment: an overview of current gaps and research needs. In: Klöpffer W (ed) Background and future prospects in life cycle assessment. LCA compendium—the complete world of life cycle assessment. Springer Netherlands, Berlin, pp 207–258CrossRefGoogle Scholar
  36. Fischer J, Lindenmayer D (2000) An assessment of the published results of animal relocations. Biol Conserv 96:1–11CrossRefGoogle Scholar
  37. Flury, K, Frischknecht (2012) Life cycle inventories of hydroelectric power generation. ESU-Services Ltd.Google Scholar
  38. Friedl G, Wuest A (2002) Disrupting biogeochemical cycles—consequences of damming. Aquat Sci 64:55–65CrossRefGoogle Scholar
  39. Gagnon L, Belanger C, Uchiyama Y (2002) Life-cycle assessment of electricity generation options: the status of research in year 2001. Energy Policy 30:1267–1278CrossRefGoogle Scholar
  40. Garcia A, Jorde K, Habit E, Caamano D, Parra O (2011) Downstream environmental effects of dam operations: changes in habitat quality for native fish species. River Res Appl 27:312–327CrossRefGoogle Scholar
  41. Gehrke PC, Brown P, Schiller CB, Moffatt DB, Bruce AM (1995) River regulation and fish communities in the Murray-Darling river system, Australia. Regulated Rivers-Research & Management 11:363–375CrossRefGoogle Scholar
  42. George CJ (1972) The role of the Aswan High Dam in changing the fisheries of the southeastern Mediterranean. The Careless Technology. Ecology and International Development, New York, pp 159–178Google Scholar
  43. Gippel CJ, Blackham D (2002) Review of environmental impacts of flow regulation and other water resource developments in the River Murray and Lower Darling River system. Final Report by Fluvial Systems Pty Ltd, Stockton, to Murray-Darling Basin Commission, Canberra, ACTGoogle Scholar
  44. Gore JA, Petts GE (1989) Alternatives in regulated river management. CRC Press, Inc., Boca Raton, Florida, USA, p 343Google Scholar
  45. Habit E, Belk MC, Parra O (2007) Response of the riverine fish community to the construction and operation of a diversion hydropower plant in central Chile. Aquatic Conservation-Marine and Freshwater Ecosystems 17:37–49CrossRefGoogle Scholar
  46. Haddeland I, Skaugen T, Lettenmaier DP (2006) Anthropogenic impacts on continental surface water fluxes. Geophys Res Lett 33:L08406CrossRefGoogle Scholar
  47. Haeseker SL, McCann JA, Tuomikoski J, Chockley B (2012) Assessing freshwater and marine environmental influences on life-stage-specific survival rates of Snake River spring–summer Chinook salmon and steelhead. Trans Am Fish Soc 141:121–138CrossRefGoogle Scholar
  48. Hanafiah MM, Xenopoulos MA, Pfister S, Leuven RSEW, Huijbregts MAJ (2011) Characterization factors for water consumption and greenhouse gas emissions based on freshwater fish species extinction. Environ Sci Technol 45:5272–5278CrossRefGoogle Scholar
  49. Harnish RA, Sharma R, McMichael GA, Langshaw RB, Pearsons TN (2014) Effect of hydroelectric dam operations on the freshwater productivity of a Columbia River fall Chinook salmon population. Can J Fish Aquat Sci 71:602–615CrossRefGoogle Scholar
  50. Haxton TJ, Findlay CS (2008) Meta-analysis of the impacts of water management on aquatic communities. Can J Fish Aquat Sci 65:437–447CrossRefGoogle Scholar
  51. Hefny K (1982) Land-use and (water) management problems in the Nile (river) delta, (Egypt). Nature and Resour 18(2):22–27Google Scholar
  52. Hertwich EG (2013) Addressing biogenic greenhouse gas emissions from hydropower in LCA. Environ Sci Technol 47:9604–9611CrossRefGoogle Scholar
  53. Hoback WW, Barnhart MC (1996) Lethal limits and sublethal effects of hypoxia on the amphipod Gammarus pseudolimnaeus. J N Am Benthol Soc 15:117–126CrossRefGoogle Scholar
  54. Hugueny B, Oberdorff T, Tedesco PA (2010) Community ecology of river fishes: a large-scale perspective. In: American Fisheries Society Symposium, 2010. pp 29-62.Google Scholar
  55. Humborg C, Ittekkot V, Cociasu A, Bv B (1997) Effect of Danube River dam on Black Sea biogeochemistry and ecosystem structure. Nature 386:385–388CrossRefGoogle Scholar
  56. ICOLD (International Commission on Large Dams) (2014) Register of Dams: General Synthesis.Google Scholar
  57. IEA (International Energy Agency) (2000) Hydropower and the environment: present context and guidelines for future action. IEA (International Energy Agency), Paris, FranceGoogle Scholar
  58. IEA (International Energy Agency) (2010) Energy technology perspectives: scenarios and strategies to 2050. IEA (International Energy Agency), Paris, FranceGoogle Scholar
  59. IHA (International Hydropower Association) (2003) The Role of Hydropower in Sustainable Development. 140 pp.Google Scholar
  60. IPCC (International Panel on Climate Change) (2011) IPCC special report on renewable energy sources and climate change mitigation. In: Edenhofer O, Pichs-Madruga R, Sokona Y, Seyboth K, Matschoss P, Kadner S, Zwickel T, Eickemeier P, Hansen G, Schlömer S, von Stechow C (eds) Prepared by Working Group III of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, p 1075Google Scholar
  61. ISO (International Standardization Organisation) (2006) Environmental management, life cycle assessment, principles and framework. International Standard ISO 14044; International Organisation for Standardization, Geneva, SwitzerlandGoogle Scholar
  62. Ittekkot V, Humborg C, Schäfer P (2000) Hydrological alterations and marine biogeochemistry: a silicate issue?: silicate retention in reservoirs behind dams affects ecosystem structure in coastal seas. Bioscience 50:776–782CrossRefGoogle Scholar
  63. Iwasaki Y, Ryo M, Sui P, Yoshimura C (2012) Evaluating the relationship between basin-scale fish species richness and ecologically relevant flow characteristics in rivers worldwide. Freshwat Biol 57:2173–2180CrossRefGoogle Scholar
  64. Jansson R, Nilsson C, Renöfält B (2000) Fragmentation of riparian floras in rivers with multiple dams. Ecology 81:899–903CrossRefGoogle Scholar
  65. Jelks HL et al (2008) Conservation status of imperiled North American freshwater and diadromous fishes. Fisheries 33:372–407CrossRefGoogle Scholar
  66. Johnsen BO, Arnekleiv JV, Asplin L, Barlaup BT, Næsje TF, Rosseland BO, Saltveit SJ, Tvede A (2010) Hydropower development—ecological Effects. In: Atlantic Salmon Ecology. Wiley-Blackwell, Oxford, pp 351–385CrossRefGoogle Scholar
  67. Jowett IG, Biggs BJ (2006) Flow regime requirements and the biological effectiveness of habitat‐based minimum flow assessments for six rivers. JRBM 4:179–189Google Scholar
  68. Junk WJ, Bayley PB, Sparks RE (1989) The flood pulse concept in river-floodplain systems. Can Spec Publ Fish Aquat Sci 106:110–127Google Scholar
  69. Kibler KM, Tullos DD (2013) Cumulative biophysical impact of small and large hydropower development in Nu River, China. Water Resour Res 49:3104–3118CrossRefGoogle Scholar
  70. King AJ (2005) Fish and the Barmah-Millewa Forest: history, status and management challenges. Proceedings of the Royal Society of Victoria 117(1):117–125Google Scholar
  71. King AJ, Tonkin Z, Mahoney J (2009) Environmental flow enhances native fish spawning and recruitment in the Murray River, Australia. River Res Appl 25:1205–1218CrossRefGoogle Scholar
  72. King AJ, Ward KA, O’Connor P, Green D, Tonkin Z, Mahoney J (2010) Adaptive management of an environmental watering event to enhance native fish spawning and recruitment. Freshwat Biol 55:17–31CrossRefGoogle Scholar
  73. Koehler A (2008) Water use in LCA: managing the planet’s freshwater resources. Int J LCA 13:451–455CrossRefGoogle Scholar
  74. Koellner T, De Baan L, Beck T, Brandão M, Civi B, Margni M, Milà i Canals L, Saad R, de Souza DM, Müller-Wenk R (2013) UNEP-SETAC guideline on global land use impact assessment on biodiversity and ecosystem services in LCA. Int J Life Cycle Assess 18:1188–1202CrossRefGoogle Scholar
  75. Kondolf GM (2013) Managing bedload sediment in regulated rivers: examples from California, U.S.A. In: Natural and anthropogenic Influences in fluvial geomorphology. American Geophysical Union, Washington, D. C, pp 165–176Google Scholar
  76. Kondolf GM, Gao Y, Annandale GW, Morris GL, Jiang E, Zhang J, Cao Y, Carling P, Fu K, Guo Q, Hotchkiss R, Peteuil C, Sumi T, Wang HW, Wang Z, Wei Z, Wu B, Wu C, Yang CT (2014) Sustainable sediment management in reservoirs and regulated rivers: experiences from five continents. Earths Future 2:256–280CrossRefGoogle Scholar
  77. Konrad CP, Olden JD, Lytle DA, Melis TS, Schmidt JC, Bray EN, Freeman MC, Gido KP, Hemphill NP, Kennard MJ, McMullen LE, Mims MC, Pyron M, Robinson CT, Williams JG (2011) Large-scale flow experiments for managing river systems. Bioscience 61:948–959CrossRefGoogle Scholar
  78. Kounina A, Margni M, Bayar JB, Boulay AM, Berger M, Bulle C, Frischknecht R, Koehler A, Milà i Canals L, Motoshita M, Núñez M, Peters G, Pfister S, Ridoutt B, van Zelm R, Verones F, Humbert S (2013) Review of methods addressing freshwater use in life cycle inventory and impact assessment. Int J Life Cycle Assess 18:707–721CrossRefGoogle Scholar
  79. Kumar A, Schei T, Ahenkorah A, Caceres Rodriguez R, Devernay J-M, Freitas M, Hall D, Killingtveit A, Liu Z (2011) Hydropower. In: Edenhofer O, Pichs-Madruga R, Sokona Y et al (eds) IPCC special report on renewable energy sources and climate change mitigation. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USAGoogle Scholar
  80. Kyläkorpi K, Rydgren B, Ellegård A, Miliander S, Grusell E (2005) The Biotope method 2005: a method to assess the impact of land use on biodiversity. Vattenfall, SwedenGoogle Scholar
  81. Lehner B, Liermann CR, Revenga C, Vörösmarty C, Fekete B, Crouzet P, Döll P, Endejan M, Frenken K, Magome J, Nilsson C, Robertson JC, Rödel R, Sindorf N, Wisser D (2011) High-resolution mapping of the world’s reservoirs and dams for sustainable river-flow management. Front Ecol Environ 9:494–502CrossRefGoogle Scholar
  82. Liquete C, Canals M, Arnau P, Urgeles R, Durrieu de Madron X (2004) The impact of humans on strata formation along Mediterranean margins. Oceanography 17:42–51CrossRefGoogle Scholar
  83. Loubet P, Roux P, Nunez M, Belaud G, Bellon-Maurel V (2013) Assessing water deprivation at the sub-river basin scale in LCA integrating downstream cascade effects. Environ Sci Technol 47:14242–14249CrossRefGoogle Scholar
  84. Lundqvist H, Rivinoja P, Leonardsson K, McKinnell S (2008) Upstream passage problems for wild Atlantic salmon (Salmo salar L.) in a regulated river and its effect on the population. Hydrobiologia 602:111–127CrossRefGoogle Scholar
  85. Maendly R, Humbert S (2009) Empirical characterization model and factors assessing aquatic biodiversity damages of hydropower water use. In. J Life Cycle Assess 2009 (submitted)Google Scholar
  86. Maia de Souza D, Teixeira RFM, Ostermann OP (2015) Assessing biodiversity loss due to land use with life cycle assessment: are we there yet? Global Change Biol 21:32–47CrossRefGoogle Scholar
  87. McAllister DE, Craig JF, Davidson N, Delany S, Seddon M (2001) Biodiversity impacts of large dams. Background paper 1 IUCN / UNEP / WCDGoogle Scholar
  88. McManamay RA, Samu N, Kao SC, Bevelhimer MS, Hetrick SC (2015) A multi-scale spatial approach to address environmental effects of small hydropower development. Environ Manage 55:217–243CrossRefGoogle Scholar
  89. Milà i Canals L, Chenoweth J, Chapagain A, Orr S, Antón A, Clift R (2009) Assessing freshwater use impacts in LCA: part I—inventory modelling and characterisation factors for the main impact pathways. Int J Life Cycle Assess 14:28–42CrossRefGoogle Scholar
  90. Millenium Ecosystem Assessment (MA) (2005) Ecosystems and human well-being: biodiversity synthesis. Millenium Ecosystem Assessment (MA), Washington, DCGoogle Scholar
  91. Milliman JD, Meade RH (1983) World-wide delivery of river sediment to the oceans. J Geol 91:1–21CrossRefGoogle Scholar
  92. Mims MC, Olden JD (2012) Life history theory predicts fish assemblage response to hydrologic regimes. Ecology 93:35–45CrossRefGoogle Scholar
  93. Moog O (1993) Quantification of daily peak hydropower effects on aquatic fauna and management to minimize environmental impacts. Regul Rivers: Res Manage 8:5–14CrossRefGoogle Scholar
  94. Moreau V, Bage G, Marcotte D, Samson R (2012) Statistical estimation of missing data in life cycle inventory: an application to hydroelectric power plants. J Clean Prod 37:335–341CrossRefGoogle Scholar
  95. Motoshita M, Itsubo N, Inaba A (2011) Development of impact factors on damage to health by infectious diseases caused by domestic water scarcity. Int J Life Cycle Assess 16:65–73CrossRefGoogle Scholar
  96. Næsje TF, Fiske P, Forseth T, Thorstad EB, Ugedal O, Finstad AG, Hvidsten NA, Jensen AJ, Saksgård L (2005) Biologiske undersøkelser i Altaelva. Faglig oppsummering og kommentarer til forslag om varig manøvreringsreglement. NINA-rapport 80:1–99, in Norwegian Google Scholar
  97. Nagrodski A, Raby GD, Hasler CT, Taylor MK, Cooke SJ (2012) Fish stranding in freshwater systems: sources, consequences, and mitigation. J Environ Manage 103:133–141CrossRefGoogle Scholar
  98. Nilsson C, Svedmark M (2002) Basic principles and ecological consequences of changing water regimes: riparian plant communities. Environ Manage 30:468–480CrossRefGoogle Scholar
  99. Nilsson C, Reidy CA, Dynesius M, Revenga C (2005) Fragmentation and flow regulation of the world’s large river systems. Science 308:405–408CrossRefGoogle Scholar
  100. Nilsson C, Brown RL, Jansson R, Merritt DM (2010) The role of hydrochory in structuring riparian and wetland vegetation. Biol Rev 85:837–858Google Scholar
  101. Noonan MJ, Grant JW, Jackson CD (2012) A quantitative assessment of fish passage efficiency. Fish Fish 13:450–464CrossRefGoogle Scholar
  102. Novak J, Loar J, Cada G (2003) Evaluation of mitigation effectiveness at hydropower projects: fish passage, draft report. Division of Hydropower Administration and Compliance Office of Energy Projects Federal Energy Regulatory Commission. Technical report. 64pGoogle Scholar
  103. Oberdorff T, Guégan JF, Hugueny B (1995) Global scale patterns of fish species richness in rivers. Ecography 18:345–352CrossRefGoogle Scholar
  104. Olden JD, Naiman RJ (2010) Incorporating thermal regimes into environmental flows assessments: modifying dam operations to restore freshwater ecosystem integrity. Freshwat Biol 55:86–107CrossRefGoogle Scholar
  105. Olden JD, Poff N (2003) Redundancy and the choice of hydrologic indices for characterizing streamflow regimes. River Res Appl 19:101–121CrossRefGoogle Scholar
  106. Owens J (2001) Water resources in life‐cycle impact assessment: considerations in choosing category indicators. J Ind Ecol 5:37–54CrossRefGoogle Scholar
  107. Pandit MK, Grumbine RE (2012) Potential effects of ongoing and proposed hydropower development on terrestrial biological diversity in the Indian Himalaya. Conserv Biol 26:1061–1071CrossRefGoogle Scholar
  108. Peters GM, Wiedemann SG, Rowley HV, Tucker RW (2010) Accounting for water use in Australian red meat production. Int J Life Cycle Assess 15:311–320CrossRefGoogle Scholar
  109. Pfister S, Bayer P (2014) Monthly water stress: spatially and temporally explicit consumptive water footprint of global crop production. J Clean Prod 73:52–62CrossRefGoogle Scholar
  110. Pfister S, Koehler A, Hellweg S (2009) Assessing the environmental impacts of freshwater consumption in LCA. Environ Sci Technol 43:4098–4104CrossRefGoogle Scholar
  111. Phelan J, Jones P, Mathews K (2015) Montana prairie wetlands and intermittent/ephemeral streams: hydrologic needs assessment for healthy watersheds. Report prepared for the US Environmental Protection Agency, Healthy Watersheds Program by RTI International, Research Triangle Park, North CarolinaGoogle Scholar
  112. Poff NL, Zimmerman JK (2010) Ecological responses to altered flow regimes: a literature review to inform the science and management of environmental flows. Freshwat Biol 55:194–205CrossRefGoogle Scholar
  113. Poff NL, Allan D, Bain MB, Karr JR, Prestegaard KL, Richter BD, Sparks RE, Stromberg JC (1997) The natural flow regime. Bioscience 47:769–784CrossRefGoogle Scholar
  114. Poff NL, Angermeier P, Cooper S, Lake PS, Fausch K, Winemiller K, Mertes LK, Oswood M, Reynolds J, Rahel FJ (2001) Fish diversity in streams and rivers. In: Global biodiversity in a changing environment. Springer, New York, pp 315–349CrossRefGoogle Scholar
  115. Poff NL, Olden JD, Merritt DM, Pepin DM (2007) Homogenization of regional river dynamics by dams and global biodiversity implications. Proc Natl Acad Sci U S A 104:5732–5737CrossRefGoogle Scholar
  116. Poff NL, Richter BD, Arthington AH, Bunn SE, Naiman RJ, Kendy E, Acreman M, Apse C, Bledsoe BP, Freeman MC, Henriksen J, Jacobson RB, Kennen JG, Merritt DM, O’Keeffe JH, Olden JD, Rogers K, Tharme RE, Warner A (2010) The ecological limits of hydrologic alteration (ELOHA): a new framework for developing regional environmental flow standards. Freshwat Biol 55:147–170CrossRefGoogle Scholar
  117. Postel SL, Daily GC, Ehrlich PR (1996) Human appropriation of renewable fresh water. Science-AAAS-Weekly Paper Edition 271:785–787Google Scholar
  118. Pringle CM (2001) Hydrologic connectivity and the management of biological reserves: a global perspective. Ecol Appl 11:981–998CrossRefGoogle Scholar
  119. Pringle CM, Freeman MC, Freeman BJ (2000) Regional effects of hydrologic alterations on riverine macrobiota in the new world: tropical-temperate comparisons. Bioscience 50:807–823CrossRefGoogle Scholar
  120. Raadal HL, Gagnon L, Modahl IS, Hanssen OJ (2011) Life cycle greenhouse gas (GHG) emissions from the generation of wind and hydropower. Renew Sustainable Energy Rev 15:3417–3422CrossRefGoogle Scholar
  121. Raadal HL, Modahl IS, Bakken TH (2012) Energy indicators for electricity production. Comparing technologies and the nature of the indicators energy payback ratio (EPR), net energy ratio (NER) and cumulative energy demand (CED), Ostfold Research, OR 9Google Scholar
  122. Renöfält B, Jansson R, Nilsson C (2010) Effects of hydropower generation and opportunities for environmental flow management in Swedish riverine ecosystems. Freshwat Biol 55:49–67CrossRefGoogle Scholar
  123. Ricciardi A, Rasmussen JB (1999) Extinction rates of North American freshwater fauna. Conserv Biol 13:1220–1222CrossRefGoogle Scholar
  124. Richter B, Baumgartner J, Wigington R, Braun D (1997) How much water does a river need? Freshwat Biol 37:231–249CrossRefGoogle Scholar
  125. Richter BD, Baumgartner JV, Braun DP, Powell J (1998) A spatial assessment of hydrologic alteration within a river network. Regul Rivers: Res Manage 14:329–340CrossRefGoogle Scholar
  126. Rioux S, Savard J-PL, Gerick AA (2013) Avian mortalities due to transmission line collisions: a review of current estimates and field methods with an emphasis on applications to the Canadian electric network. ACE 8:7Google Scholar
  127. Robinson CT, Uehlinger U (2008) Experimental floods cause ecosystem regime shift in a regulated river. Ecol Appl 18:511–526CrossRefGoogle Scholar
  128. Robson AC, Cowx IG, Harvey JP (2011) Impact of run-of-river hydro-schemes upon fish populations. Scotland and Northern Ireland Forum for Environmental Research (SNIFFER), Edinburgh, Scotland, UKGoogle Scholar
  129. Rood SB, Gourley CR, Ammon EM, Heki LG, Klotz JR, Morrison ML, Mosley D, Scoppettone GG, Swanson S, Wagner PL (2003) Flows for floodplain forests: a successful riparian restoration. Bioscience 53:647–656CrossRefGoogle Scholar
  130. Rose BP, Mesa MG (2013) Effects of summer drawdown on the fishes and larval chironomids in Beulah Reservoir, Oregon. Northwest Sci 87:207–218CrossRefGoogle Scholar
  131. Rosenberg DM, Berkes F, Bodaly R, Hecky R, Kelly C, Rudd JW (1997) Large-scale impacts of hydroelectric development. Environ Rev 5:27–54CrossRefGoogle Scholar
  132. Rosenberg DM, McCully P, Pringle CM (2000) Global-scale environmental effects of hydrological alterations: introduction. Bioscience 50:746–751CrossRefGoogle Scholar
  133. Rosenzweig ML (1995) Species diversity in space and time. Cambridge University Press, CambridgeCrossRefGoogle Scholar
  134. Sabaton C, Souchon Y, Capra H, Gouraud V, Lascaux JM, Tissot L (2008) Long-term brown trout populations responses to flow manipulation. River Res Appl 24:476–505CrossRefGoogle Scholar
  135. Saltveit S, Halleraker J, Arnekleiv J, Harby A (2001) Field experiments on stranding in juvenile Atlantic salmon (Salmo salar) and brown trout (Salmo trutta) during rapid flow decreases caused by hydropeaking. Regul Rivers: Res Manage 17:609–622CrossRefGoogle Scholar
  136. Santucci VJ Jr, Gephard SR, Pescitelli SM (2005) Effects of multiple low-head dams on fish, macroinvertebrates, habitat, and water quality in the Fox River, Illinois. N Am J Fish Manage 25:975–992CrossRefGoogle Scholar
  137. Sathaye J, Lucon O, Rahman A, Christensen J, Denton F, Fujino J, Heath G, Kadner S, Mirza M, Rudnick H, Schlaepfer A, Shmakin A (2011) Renewable energy in the context of sustainable development. In: Edenhofer O et al (eds) IPCC special report on renewable energy sources and climate change mitigation. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USAGoogle Scholar
  138. Scruton DA, Pennell C, Ollerhead L, Alfredsen K, Stickler M, Harby A, Robertson M, Clarke KD, LeDrew LJ (2008) A synopsis of ‘hydropeaking’ studies on the response of juvenile Atlantic salmon to experimental flow alteration. Hydrobiologia 609:263–275CrossRefGoogle Scholar
  139. Sloan S, Jenkins CN, Joppa LN, Gaveau DLA, Laurance WF (2014) Remaining natural vegetation in the global biodiversity hotspots. Biol Conserv 177:12–24CrossRefGoogle Scholar
  140. Stanford JA, Ward J, Liss WJ, Frissell CA, Williams RN, Lichatowich JA, Coutant CC (1996) A general protocol for restoration of regulated rivers. US Department of Energy Publications, 43 pGoogle Scholar
  141. Stevens LE, Shannon JP, Blinn DW (1997) Colorado River benthic ecology in Grand Canyon, Arizona, USA: dam, tributary and geomorphological influences. Regul Rivers: Res Manage 13:129–149CrossRefGoogle Scholar
  142. Stucker JH, Buhl DA, Sherfy MH (2013) Consequences of Least Tern (Sternula antillarum) microhabitat nest-site selection on natural and mechanically constructed sandbars in the Missouri River. Auk 130:753–763CrossRefGoogle Scholar
  143. Sutela T, Mutenia A, Salonen E (2002) Relationship between annual variation in reservoir conditions and year-class strength of peled (Coregonus peled) and whitefish (C-lavaretus). Hydrobiologia 485:213–221CrossRefGoogle Scholar
  144. Syvitski JP, Vörösmarty CJ, Kettner AJ, Green P (2005) Impact of humans on the flux of terrestrial sediment to the global coastal ocean. Science 308:376–380CrossRefGoogle Scholar
  145. Tendall DM, Hellweg S, Pfister S, Huijbregts MA, Gr G (2014) Impacts of river water consumption on aquatic biodiversity in life cycle assessment—a proposed method, and a case study for Europe. Environ Sci Technol 48:3236–3244CrossRefGoogle Scholar
  146. Teodoru C., Bastien J, Bonneville MC, del Giorgio PA, Demarty M, Garneau M, Hélie JF, Pelletier L, Prairie YT, Roulet NT, Strachan IB, Tremblay A (2012) The net carbon footprint of a newly created boreal hydroelectric reservoir. Global Biogeochemical Cycles 26, doi: 10.1029/2011GB004187
  147. Tharme RE (2003) A global perspective on environmental flow assessment: emerging trends in the development and application of environmental flow methodologies for rivers. River Res Appl 19:397–441CrossRefGoogle Scholar
  148. Thomaz SM, Pagioro TA, Bini LM, Murphy KJ (2006) Effect of reservoir drawdown on biomass of three species of aquatic macrophytes in a large sub-tropical reservoir (Itaipu, Brazil). Hydrobiologia 570:53–59CrossRefGoogle Scholar
  149. Tockner K, Stanford JA (2002) Riverine flood plains: present state and future trends. Environ Conserv 29:308–330CrossRefGoogle Scholar
  150. Tolotti M, Boscaini A, Salmaso N (2010) Comparative analysis of phytoplankton patterns in two modified lakes with contrasting hydrological features. Aquat Sci 72:213–226CrossRefGoogle Scholar
  151. Truffer B, Bratrich C, Markard J, Peter A, Wuest A, Wehrli B (2003) Green Hydropower: the contribution of aquatic science research to the promotion of sustainable electricity. Aquat Sci 65:99–110Google Scholar
  152. Turconi R, Boldrin A, Astrup T (2013) Life cycle assessment (LCA) of electricity generation technologies: overview, comparability and limitations. Renew Sustainable Energy Rev 28:555–565CrossRefGoogle Scholar
  153. Turek JG, Goodger TE, Bigford TE, Nichols JS (1987) Influence of freshwater inflows on estuarine productivity, National Oceanic and Atmospheric Administration, National Marine Fisheries Service. Northeast Fisheries Center, Woods Hole, MAGoogle Scholar
  154. Ugedal O, Næsje TF, Thorstad EB, Forseth T, Saksgård LM, Heggberget TG (2008) Twenty years of hydropower regulation in the River Alta: long-term changes in abundance of juvenile and adult Atlantic salmon. Hydrobiologia 609:9–23CrossRefGoogle Scholar
  155. UNEP (United Nations Environmental Programme) (2000) Planning and management of lakes and reservoirs: an integrated approach to eutrophication. UNEP International Environmental Technology Centre, Osaka, JapanGoogle Scholar
  156. Van Beek L, Bierkens MF (2009) The global hydrological model PCR-GLOBWB: conceptualization, parameterization and verification. Utrecht University, NetherlandsGoogle Scholar
  157. Van Beek L, Wada Y, Bierkens MF (2011) Global monthly water stress: 1. Water balance and water availability. Water Resour Res 47, doi: 10.1029/2010WR009792 DOI:10.1029/2010WR009792#_blank#Link to external resource: 10.1029/2010WR009792
  158. Verones F, Pfister S, Hellweg S (2013a) Quantifying area changes of internationally important wetlands due to water consumption in LCA. Environ Sci Technol 47:9799–9807CrossRefGoogle Scholar
  159. Verones F, Saner D, Pfister S, Baisero D, Rondinini C, Hellweg S (2013b) Effects of consumptive water use on biodiversity in wetlands of international importance. Environ Sci Technol 47:12248–12257CrossRefGoogle Scholar
  160. Vistnes I, Nellemann C, Jordhøy P, Strand O (2004) Effects of infrastructure on migration and range use of wild reindeer. J Wildl Manage 68:101–108CrossRefGoogle Scholar
  161. Vörösmarty CJ, Meybeck M, Fekete B, Sharma K, Green P, Syvitski JP (2003) Anthropogenic sediment retention: major global impact from registered river impoundments. Global Planet Change 39:169–190CrossRefGoogle Scholar
  162. Vörösmarty CJ, McIntyre P, Gessner MO, Dudgeon D, Prusevich A, Green P, Glidden S, Bunn SE, Sullivan CA, Liermann CR (2010) Global threats to human water security and river biodiversity. Nature 467:555–561CrossRefGoogle Scholar
  163. Wada Y, Van Beek L, Viviroli D, Dürr HH, Weingartner R, Bierkens MF (2011) Global monthly water stress: 2. Water demand and severity of water stress. Water Resour Res. 47, doi: 10.1029/2010WR009791 DOI:10.1029/2010WR009791#_blank#Link to external resource: 10.1029/2010WR009791
  164. Ward JV (1989) The 4-dimensional nature of lotic ecosystems. J N Am Benthol Soc 8:2–8CrossRefGoogle Scholar
  165. Ward JV, Stanford JA (1995) The serial discontinuity concept—extending the model to floodplain rivers. Regul Rivers: Res Manage 10:159–168CrossRefGoogle Scholar
  166. Ward J, Tockner K, Schiemer F (1999) Biodiversity of floodplain river ecosystems: ecotones and connectivity. Regul Rivers: Res Manage 15:125–139CrossRefGoogle Scholar
  167. Warner AT, Bach LB, Hickey JT (2014) Restoring environmental flows through adaptive reservoir management: planning, science, and implementation through the Sustainable Rivers Project. Hydrol Sci J 59:770–785CrossRefGoogle Scholar
  168. WCD (World Commission on Dams (2000) Dams and development: A new framework for decision-making: The report of the world commission on dams. EarthscanGoogle Scholar
  169. Welcomme RL (1985) River fisheries. Food and Agriculture Organization of the United Nations, RomeGoogle Scholar
  170. Wolf CM, Griffith B, Reed C, Temple SA (1996) Avian and mammalian translocations: update and reanalysis of 1987 survey data. Conserv Biol 10:1142–1154CrossRefGoogle Scholar
  171. Xenopoulos MA, Lodge DM (2006) Going with the flow: using species-discharge relationships to forecast losses in fish biodiversity. Ecology 87:1907–1914CrossRefGoogle Scholar
  172. Xenopoulos MA, Lodge DM, Alcamo J, Märker M, Schulze K, Van Vuuren DP (2005) Scenarios of freshwater fish extinctions from climate change and water withdrawal. Global Change Biol 11:1557–1564CrossRefGoogle Scholar
  173. Yoshikawa S, Yanagawa A, Iwasaki Y, Sui P, Koirala S, Hirano K, Khajuria A, Mahendran R, Hirabayashi Y, Yoshimura C, Kanae S (2014) Illustrating a new global-scale approach to estimating potential reduction in fish species richness due to flow alteration. Hydrol Earth Syst Sci 18:621–630CrossRefGoogle Scholar
  174. Zhai H, Cui B, Hu B, Zhang K (2010) Prediction of river ecological integrity after cascade hydropower dam construction on the mainstream of rivers in Longitudinal Range-Gorge Region (LRGR), China. Ecol Eng 36:361–372CrossRefGoogle Scholar
  175. Zhao Q, Liu S, Dong S (2010) Effect of dam construction on spatial–temporal change of land use: a case study of Manwan, Lancang River, Yunnan, China. Proc Environ Sci 2:852–858CrossRefGoogle Scholar
  176. Zhao QH, Liu SL, Deng L, Dong SK, Yang ZF, Liu Q (2013) Determining the influencing distance of dam construction and reservoir impoundment on land use: a case study of Manwan Dam, Lancang River. Ecol Eng 53:235–242CrossRefGoogle Scholar
  177. Ziv G, Baran E, Nam S, Rodríguez-Iturbe I, Levin SA (2012) Trading-off fish biodiversity, food security, and hydropower in the Mekong River Basin. Proc Natl Acad Sci U S A 109:5609–5614CrossRefGoogle Scholar

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© Springer-Verlag Berlin Heidelberg 2016

Authors and Affiliations

  1. 1.Industrial Ecology Programme, Department of Energy and Process Engineering, NTNUTrondheimNorway

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