Hydrological Impact of a High-Density Reservoir Network in Semiarid Northeastern Brazil
Publication: Journal of Hydrologic Engineering
Volume 17, Issue 1
Abstract
Dense reservoir networks, with thousand of small dams, can be increasingly found throughout the world, especially in water-scarce environments, such as the Brazilian northeastern region. Although the effect of individual small dams might be negligible, their joint effect has proved to be relevant on water and sediment connectivity. Literature, however, is scarce concerning the effect of such networks on water availability and/or sustainability of mesoscale or large-scale basins. This research intended both to assess the effect of the dense reservoir network of the semiarid Upper Jaguaribe Basin (UJB; , in Brazil) for a 45-year period (1961–2005) and to investigate a network arrangement that maximized its hydrologic sustainability. Imagery of the years 1970 and 2002 was analyzed to assess temporal evolution of the network. The Water Availability in Semiarid Environments (WASA) model, which proved valid for the Upper Jaguaribe Basin, was used to assess its sustainability for almost 100 different arrangements. The optimization process was performed using the Simplex-MSX algorithm. Results showed that the hydrologic sustainability of the basin increased throughout the analysis period. Nonetheless, since the late 1990s, the system showed clear signs of saturation. The optimization process identified that the best network arrangement should have residence time of approximately 3 years, with volumetric density of , and the importance of the reservoir size continuity to obtain effective hydrologic performance.
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Acknowledgments
The authors would like to acknowledge the financial support of the DISPAB Project by the Brazilian Studies and Projects Financing Agency FINEP. The authors are also grateful to the Brazilian National Department of Droughts—DNOCS for the support given to the first author, and to CNPq for research support granted to the second author (process 303010/2008-8).
References
Aragão Araújo, J. A. (1990). Dams in the northeast of Brazil, 2nd Ed., DNOCS—Brazilian National Dept. of Droughts, Fortaleza, Brazil.
ASCE. (1998). “Sustainability criteria for water resource systems.” Working Group of UNESCO/IHP IV Project M-4.3, Reston, VA.
Attari, J., and Mojahedi, S. A. (2009). “Water sustainability index: Application of CWSI for Ahwaz County.” Proc., World Environmental and Water Resources Congress 2009: Great Rivers, S. Starrett, ed., ASCE, Reston, VA, 1–7, .
Bolaane, B. (2000). “Towards sustainable management of scarce water resources in Botswana.” Water Int., 25(2), 246–252.
Bronstert, A. et al. (2007). Investigating erosion and sediment transport from headwaters to catchments to reduce reservoir siltation in drylands, IAHS, Wallingford, UK, 317, 119–122.
Callow, J. N., and Smettem, K. R. J. (2009). “The effect of farm dams and constructed banks on hydrologic connectivity and runoff estimation in agricultural landscapes.” Environ. Model. Software, 24(8), 959–968.
Campos, J. N. B. (1987). “A procedure for reservoir sizing in intermittent rivers under high evaporation rate.” Ph.D. dissertation, Colorado State Univ., Fort Collins, CO.
de Araújo, J. C. et al. (2004). “Water scarcity under scenarios for global climate change and regional development in semiarid Northeastern Brazil.” Water Int., 29(2), 209–220.
de Araújo, J. C., and Gonzalez Piedra, J. I. (2009). “Comparative hydrology: Analysis of a semiarid and a humid tropical watershed.” Hydrol. Processes, 23(8), 1169–1178.
de Araújo, J. C., Güntner, A., and Bronstert, A. (2006). “Loss of reservoir volume by sediment deposition and its impact on water availability in semiarid Brazil.” Hydrol. Sci. J., 51(1), 157–170.
de Araújo, J. C., Molinas, P. A., Joca, E. L. L., Bemfeito, C. J. S., and Belo, P. S. C. (2005). “Costs related with water availability and distribution by several sources in Ceará.” Revista Econômica do Nordeste, 36, 81–307 (in Portuguese).
de Vente, J., Poesen, J., and Verstraeten, G. (2005). “The application of semi-quantitative methods and reservoir sedimentation rates for the prediction of basin sediment yield in Spain.” J. Hydrol. (Amsterdam, Neth.), 305(1–4), 63–68.
Figueiredo, M. C. B. et al. (2007). “Assessment of environmental vulnerability of reservoirs concerning eutrophication.” Engenharia Sanitária e Ambiental, 12(4), 399–409 (in Portuguese).
Francke, T., Güntner, A., Bronstert, A., Mamede, G. L., and Müller, E. N. (2008). “Automated catena-based discretization of landscapes for the derivation of hydrological modelling units.” Int. J. Geogr. Inf. Sci. 22(2), 111–132.
Gaiser, T., Krol, M., Frischkorn, H., and de Araújo, J. C., eds. (2003). Global change and regional impacts, Springer-Verlag, Berlin.
Güntner, A., and Bronstert, A. (2004). “Representation of landscape variability and lateral redistribution processes for large-scale hydrological modelling in semi-arid areas.” J. Hydrol. (Amsterdam, Neth.), 297(1–4), 136–161.
Güntner, A., Krol, M., de Araújo, J. C., and Bronstert, A. (2004). “Simple water balance modelling of surface reservoir systems in a large data-scarce semiarid region.” Hydrol. Sci. J., 49(5), 901–918.
Hashimoto, T., Stedinger, J. R., and Loucks, D. P. (1982). “Reliability, resilience and vulnerability criteria for water resource system performance evaluation.” Water Resour. Res., 18(1), 14–20.
Krol, M. S., Jaeger, A., Bronstert, A., and Güntner, A. (2006). “Integrated modelling of climate, water, soil, agricultural and socio-economic processes: A general introduction of the methodology and some exemplary results from the semi-arid Northeast of Brazil.” J. Hydrol. (Amsterdam, Neth.), 328(3–4), 417–431.
Li, H., Zhang, Y., Chiew, F. H. S., and Xu, S. (2009). “Predicting runoff in ungauged catchments by using Xinanjiang model with MODIS leaf area index.” J. Hydrol. (Amsterdam, Neth.), 370(1–4), 155–162.
Li, X.-G., and Wei, X. (2008). “An improved genetic algorithm-simulated annealing hybrid algorithm for the optimization of multiple reservoirs.” Water Resour. Manage., 22(8), 1031–1049, .
Lima Neto, I. E., Wiegand, M. C., and de Araújo, J. C. (2011). “Sediment redistribution due to a dense reservoir network in a large semi-arid Brazilian basin.” Hydrol. Sci. J., 56, 319–333.
Lowe, L., Nathan, R., and Morden, R. (2005). “Assessing the impact of farm dams on streamflows, Part II: Regional characterisation.” Aust. J. Water Resour., 9(1), 13–26.
Malveira, V. T. C. (2009). “Small reservoirs and hydrological sustainability in large semiarid basins: Case study of the Orós dam.” Doctorate dissertation, Federal Univ. of Ceará, Fortaleza, Brazil (in Portuguese).
Mamede, G. L. (2008). “Reservoir sedimentation in dryland catchments: Modelling and management.” Doctorate dissertation, Univ. of Potsdam, Potsdam, Germany.
Mamede, G. L., de Lyra, D. L., and de Sousa, D. C. B. (2010). “Impact of climate variability on water availability in reservoirs of the northeast of Brazil: The case of the Santa Cruz do Apodi dam basin.” Proc., 8th National Meeting of Sediment Engineering, World Association for Sedimentation and Erosion Research, Beijing (in Portuguese).
McMahon, T. A., Adeloye, A. J., and Zhou, S. (2006). “Understanding performance measures of reservoirs.” J. Hydrol. (Amsterdam, Neth.), 324(1–4), 359–382.
Medeiros, P. H. A. (2009). “Hydro-sedimentological processes and connectivity in a semiarid basin.” Doctorate dissertation, Federal University of Ceará, Fortaleza, Brazil (in Portuguese).
Medeiros, P. H. A., Güntner, A., Francke, T., Mamede, G. L., and Araújo, J. C. (2010). “Modelling spatio-temporal patterns of sediment yield and connectivity in a semi-arid catchment with the WASA-SED model.” Hydrol. Sci. J., 55(4), 636–648.
Minear, J. T., and Kondolf, G. M. (2009). “Estimating reservoir sedimentation rates at large spatial and temporal scales: A case study of California.” Water Resour. Res., 45(W12502), 1–8, .
Molle, F., and Cadier, E. (1992). Manual of small dams, SUDENE/ORSTON, Recife, Brazil (in Portuguese).
Morris, G. L., Annandale, G., and Hotchkiss, R. (2008). “Reservoir sedimentation.” Sedimentation engineering: processes, measurements, modeling, and practice, M. H. García, ed., ASCE Manual of Practice 110, ASCE, Reston, VA., 579–609.
Mueller, E. N., Güntner, A., Francke, T., and Mamede, G. (2008). “Modelling water availability, sediment export and reservoir sedimentation in drylands with the WASA-SED model.” Geoscientific Model Dev. Discuss., 1(1), 285–314.
Nash, J. E., and Sutcliffe, J. V. (1970). “River flow forecasting through conceptual models part I—A discussion of principles.” J. Hydrol. (Amsterdam, Neth.), 10(3), 282–290.
Nathan, R., Jordan, P., and Morden, R. (2005). “Assessing the impact of farm dams on streamflows, Part I: Development of simulation tools.” Aust. J. Water Resour., 9(1), 1–12.
Nelder, J. A., and Mead, R. (1965). “A simplex method for function minimization.” Comput. J. (UK), 7(4), 308–313.
Nicklow, J. W., and Mays, L. W. (2000). “Optimization of multiple reservoir networks for sedimentation control.” J. Hydraul. Eng., 126(4), 232–242.
Pinheiro, F. D. (2004). Private and cooperation dams in Ceará, DNOCS—Brazilian National Dept. of Droughts, Fortaleza, Brazil.
Pisaniello, J. D., Zhifang, W., and McKay, J. M. (2006). “Small dams safety issues—engineering/policy models and community responses from Australia.” Water Policy, 8, 81–95.
Rãdoane, M., and Rãdoane, N. (2005). “Dams, sediment sources and reservoir silting in Romania.” Geomorphology, 71(1–2), 112–125.
Salameh, E. (2000). “Redefining the water poverty index.” Water Int., 25(3), 469–473.
Shih, D. S., and Yeh, G. T. (2011). “Identified model parameterization, calibration and validation of the physically distributed hydrological model, WASH123D.” J. Hydrol. Eng., 16(2), 126–136.
Silliman, S. E., Hamlin, C., Crane, P. E., and Boukan, M. (2008). “International collaborations and incorporating the social sciences in research in hydrology and hydrologic engineering.” J. Hydrol. Eng., 13(1), 13–19.
Singh, V. P. (1995). Computer models of watershed hydrology, Water Resources Publications, Littleton, CO.
Sorooshian, S., and Gupta, V. K. (1995). “Model calibration.” Computer models of watershed hydrology, V. P. Singh, ed., Water Resources Publication, Highlands Ranch, CO, 23–68.
Teegavarapu, R. S. V., and Simonovic, S. P. (2002). “Optimal operation of reservoir systems using simulated annealing.” Water Resour. Manage., 16(5), 401–428.
van Oel, P. R., Krol, M., Hoekstra, A. Y., and de Araújo, J. C. (2008). “The impact of upstream water abstractions on reservoir yield: The case of the Orós Reservoir in Brazil.” Hydrol. Sci. J., 53(4), 857–867.
Verstraeten, G., Poesen, J., de Vente, J., and Koninckx, X. (2003). “Sediment yield variability in Spain: A quantitative and semiqualitative analysis using reservoir sedimentation rates.” Geomorphology, 50(4), 327–348.
Voerkelius, S. et al. (2003). “Investigations on water management and water quality in Picos/PI and Tauá/CE.” Global change and regional impacts, T. Gaiser, M. S. Krol, H. Frischkorn and J. C. de Araújo, eds., Springer-Verlag, Berlin, 173–184.
Yoshitani, J., Chen, Z. Q., Kavvas, M. L., and Fukami, K. (2009). “Atmospheric model-based streamflow forecasting at small, mountainous watersheds by a distributed hydrologic model: Application to a watershed in Japan.” J. Hydrol. Eng., 14(10), 1107–1118.
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Published In
Journal of Hydrologic Engineering
Volume 17 • Issue 1 • January 2012
Pages: 109 - 117
Copyright
© 2012 American Society of Civil Engineers.
History
Received: Jul 22, 2010
Accepted: Mar 31, 2011
Published online: Apr 2, 2011
Published in print: Jan 1, 2012
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