Uncertainties in climate change projections and regional downscaling in the tropical Andes: implications for water resources management

Buytaert, Wouter; Vuille, Mathias; Dewulf, Art; Urrutia, R.; Karmalkar, Ambarish V.; Célleri, Rolando

doi:10.5194/hess-14-1247-2010

Cited by 191 publications

(134 citation statements)

References 44 publications

(52 reference statements)

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“…As a result, the dry season precipitation bias is reduced in the RCM in these regions (regions 5 and 6; see Table 3). Underestimation of precipitation along the leeward slopes (region 5) and overestimation along the windward slopes (region 6) is also detected in a PRECIS study over South America (Urrutia and Vuille 2009;Buytaert et al 2010) and other RCM studies as well (Caldwell et al 2009;da Rocha et al 2009). …”

Section: Orographic Cloud Formationmentioning

confidence: 87%

Climate change in Central America and Mexico: regional climate model validation and climate change projections

2011

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Central America has high biodiversity, it harbors high-value ecosystems and it's important to provide regional climate change information to assist in adaptation and mitigation work in the region. Here we study climate change projections for Central America and Mexico using a regional climate model. The model evaluation shows its success in simulating spatial and temporal variability of temperature and precipitation and also in capturing regional climate features such as the bimodal annual cycle of precipitation and the Caribbean low-level jet. A variety of climate regimes within the model domain are also better identified in the regional model simulation due to improved resolution of topographic features. Although, the model suffers from large precipitation biases, it shows improvements over the coarse-resolution driving model in simulating precipitation amounts. The model shows a dry bias in the wet season and a wet bias in the dry season suggesting that it's unable to capture the full range of precipitation variability. Projected warming under the A2 scenario is higher in the wet season than that in the dry season with the Yucatan Peninsula experiencing highest warming. A large reduction in precipitation in the wet season is projected for the region, whereas parts of Central America that receive a considerable amount of moisture in the form of orographic precipitation show significant decreases in precipitation in the dry season. Projected climatic changes can have detrimental impacts on biodiversity as they are spatially similar, but far greater in magnitude, than those observed during the El Niño events in recent decades that adversely affected species in the region.

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Section: Orographic Cloud Formationmentioning

confidence: 87%

Climate change in Central America and Mexico: regional climate model validation and climate change projections

2011

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“…First, the use of the delta method to estimate the percentage changes of climate variables compared to a historic baseline entails assumptions about the nature of the changes, including a lack of change in the variability and spatial patters of climate (NORDEN 2010). The lack of meteorological data and high variability of the climate system in the Tropical Andes region complicate the use of more complex downscaling methods (Buytaert et al 2010) and using downscaled information can be no more reliable than the climate model simulation that underlies it; more detail does not automatically imply better information (Taylor et al 2012). Reliance on climate data from KNMI and downscaling from 0.5°grids may also result in incorrect inflows for regions with complex topography where there are sharp changes in rainfall and runoff over short distances.…”

Section: Resultsmentioning

confidence: 99%

“…The magnitude of climate change impacts on hydropower generation is usually assessed by running a baseline calibrated hydrological model driven by various climate projections as input forcing data, followed by an electricity generation model (Hay et al 2002). To assess uncertainty related to climate change, studies use a combination of emission or concentration scenarios to derive a range of probable results but use only data from a limited number of GCMs, often only the mean value of GCM results is used (Buytaert et al 2010). For instance, the studies by CEPAL (2012) and De Lucena et al (2010) assessed vulnerability of hydropower to future climate projections for IPCC's SRES A2 and B2 scenarios 2 and one GCM (HadCM3) for Chile and Brazil, respectively.…”

Section: Introductionmentioning

confidence: 99%

Assessing uncertainty of climate change impacts on long-term hydropower generation using the CMIP5 ensemble—the case of Ecuador

et al. 2017

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This study presents a method to assess the sensitivity of hydropower generation to uncertain water resource availability driven by future climate change. A hydrology-electricity modelling framework was developed and applied to six rivers where 10 hydropower stations operate, which together represent over 85% of Ecuador's installed hydropower capacity. The modelling framework was then forced with bias-corrected output from 40 individual global circulation model experiments from the Coupled Model Intercomparison Project 5 for the Representative Concentration Pathway 4.5 scenario. Impacts of changing climate on hydropower resource were quantified for 2071-2100 relative to a baseline period 1971-2000. Results show a wide annual average inflow range from + 277% to − 85% when individual climate experiments are assessed. The analysis also show that hydropower generation in Ecuador is highly uncertain and sensitive to climate change since variations in inflow to hydropower stations would directly result in changes in the expected hydropower potential. Annual hydroelectric power production in Ecuador is found to vary between − 55 and + 39% of the mean historical output when considering future inflow patterns to hydroelectric reservoirs covering one standard deviation of the CMIP5 RCP4.5 climate ensemble.

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“…Therefore, recent studies tend to use the higher-resolution regional climate models (RCMs) to preserve the physical coherence between atmospheric and land surface variables (Bergstrom et al, 2001;Anderson et al, 2011). As such, when evaluating the impact of climate change on water resources on a watershed scale, the use of RCMs instead of GCMs is preferable since RCMs have proven to provide more reliable results for impact study of climate change on regional water resources than GCM models (Buytaert et al, 2010;Elguindi et al, 2011). However, the raw RCM simulations may be still biased especially in the mountainous regions (Murphy, 1999;Fowler et al, 2007), which makes the use of RCM outputs as direct input for hydrological model challenging.…”

Section: G H Fang Et Al: Hydrologic Impact Study In An Arid Area Imentioning

confidence: 99%

Comparing bias correction methods in downscaling meteorological variables for a hydrologic impact study in an arid area in China

Fang

Jian

Chen

et al. 2015

Hydrol. Earth Syst. Sci.

378

164

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Abstract. Water resources are essential to the ecosystem and social economy in the desert and oasis of the arid Tarim River basin, northwestern China, and expected to be vulnerable to climate change. It has been demonstrated that regional climate models (RCMs) provide more reliable results for a regional impact study of climate change (e.g., on water resources) than general circulation models (GCMs). However, due to their considerable bias it is still necessary to apply bias correction before they are used for water resources research. In this paper, after a sensitivity analysis on input meteorological variables based on the Sobol' method, we compared five precipitation correction methods and three temperature correction methods in downscaling RCM simulations applied over the Kaidu River basin, one of the headwaters of the Tarim River basin. Precipitation correction methods applied include linear scaling (LS), local intensity scaling (LOCI), power transformation (PT), distribution mapping (DM) and quantile mapping (QM), while temperature correction methods are LS, variance scaling (VARI) and DM. The corrected precipitation and temperature were compared to the observed meteorological data, prior to being used as meteorological inputs of a distributed hydrologic model to study their impacts on streamflow. The results show (1) streamflows are sensitive to precipitation, temperature and solar radiation but not to relative humidity and wind speed; (2) raw RCM simulations are heavily biased from observed meteorological data, and its use for streamflow simulations results in large biases from observed streamflow, and all bias correction methods effectively improved these simulations; (3) for precipitation, PT and QM methods performed equally best in correcting the frequency-based indices (e.g., standard deviation, percentile values) while the LOCI method performed best in terms of the time-series-based indices (e.g., Nash-Sutcliffe coefficient, R 2 ); (4) for temperature, all correction methods performed equally well in correcting raw temperature; and (5) for simulated streamflow, precipitation correction methods have more significant influence than temperature correction methods and the performances of streamflow simulations are consistent with those of corrected precipitation; i.e., the PT and QM methods performed equally best in correcting flow duration curve and peak flow while the LOCI method performed best in terms of the time-series-based indices. The case study is for an arid area in China based on a specific RCM and hydrologic model, but the methodology and some results can be applied to other areas and models.

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Uncertainties in climate change projections and regional downscaling in the tropical Andes: implications for water resources management

Cited by 191 publications

References 44 publications

Climate change in Central America and Mexico: regional climate model validation and climate change projections

Climate change in Central America and Mexico: regional climate model validation and climate change projections

Assessing uncertainty of climate change impacts on long-term hydropower generation using the CMIP5 ensemble—the case of Ecuador

Comparing bias correction methods in downscaling meteorological variables for a hydrologic impact study in an arid area in China

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