Evaluating the utility of dynamical downscaling in agricultural impacts projections

Glotter, Michael; Elliott, Joshua; McInerney, David; Best, Neil; Foster, Ian; Moyer, E. J.

doi:10.1073/pnas.1314787111

Cited by 76 publications

(57 citation statements)

References 51 publications

(44 reference statements)

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“…Any climate change assessment where the GCM outputs are used as input will inherit the biases in the subsequent outputs. Studies on climate change impacts on land surface hydrology and agriculture report that models forced with outputs directly from the GCMs or even regional climate models nested within GCMs result in unacceptably biased simulations, and therefore, the GCM (or regional model) outputs ought to be bias corrected [ Glotter et al , ; Salathé et al , ; Sulis et al , ; Wood et al , ]. Since the model outputs cannot be used directly, we apply bias correction that corrects all moments of the climate fields' statistical distribution at monthly scale.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of historical and future simulations of precipitation and temperature in central Africa from CMIP5 climate models

et al. 2016

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Global and regional climate change assessments rely heavily on the general circulation model (GCM) outputs such as provided by the Coupled Model Intercomparison Project phase 5 (CMIP5). Here we evaluate the ability of 25 CMIP5 GCMs to simulate historical precipitation and temperature over central Africa and assess their future projections in the context of historical performance and intermodel and future emission scenario uncertainties. We then apply a statistical bias correction technique to the monthly climate fields and develop monthly downscaled fields for the period of 1948–2099. The bias‐corrected and downscaled data set is constructed by combining a suite of global observation and reanalysis‐based data sets, with the monthly GCM outputs for the 20th century, and 21st century projections for the medium mitigation (representative concentration pathway (RCP)45) and high emission (RCP85) scenarios. Overall, the CMIP5 models simulate temperature better than precipitation, but substantial spatial heterogeneity exists. Many models show limited skill in simulating the seasonality, spatial patterns, and magnitude of precipitation. Temperature projections by the end of the 21st century (2070–2099) show a robust warming between 2 and 4°C across models, whereas precipitation projections vary across models in the sign and magnitude of change (−9% to 27%). Projected increase in precipitation for a subset of models (single model ensemble (SME)) identified based on performance metrics and causal mechanisms are slightly higher compared to the full multimodel ensemble (MME) mean; however, temperature projections are similar between the two ensemble means. For the near‐term (2021–2050), neither the historical performance nor choice of models is related to the precipitation projections, indicating that natural variability dominated any signal. With fewer models, the “blind” MME approach will have larger uncertainties in future precipitation projections compared to projections by the SME models. We propose the latter a better approach in regions that lack quality climate observations. Our analyses also show that the choice of model and emission scenario dominate the uncertainty in precipitation projections, whereas the emission scenario dominates the temperature projections. Although our analyses are done for central Africa, the final Bias‐Corrected Spatially Downscaled data set is available for global land areas. The framework for climate change assessment and the data will be useful for a variety of climate assessment, impact, and adaptation studies.

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Section: Discussionmentioning

confidence: 99%

Evaluation of historical and future simulations of precipitation and temperature in central Africa from CMIP5 climate models

et al. 2016

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“…Despite these limitations, the WorldClim dataset is the best-developed dataset available for Nepal [20,42,43,53,54]. Moreover, a study by Glotter et al [55] showed that, once a correction is applied, the results of general circulation models and regional climate models are indistinguishable in all four scenarios. This suggests that, when developing impact assessments, the benefits that are generated by dynamically downscaling raw, general-circulation models may not be sufficient to justify the computational demand.…”

Section: Limitations Of the Date Setmentioning

confidence: 99%

Climate Changes and Their Impact on Agricultural Market Systems: Examples from Nepal

Barrueto

Merz²,

Clot³

et al. 2017

Sustainability

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Abstract:Global climate models foresee changes in temperature and precipitation regimes that shift regional climate zones and influence the viability of agricultural market systems. Understanding the influence of climate change on the different sub-sectors and functions of a market system is crucial to increasing the systems' climate resilience and to ensuring the long-term viability of the sectors. Our research applies a new approach to climate change analysis to better understand the influence of climate change on each step of an agricultural market system-on its core (processing units, storage facilities and sales) and support functions (sapling supply, research, insurance and agricultural policy). We use spatial climate analyses to investigate current and projected changes in climate for different regions in Nepal. We then analyse the risks and vulnerabilities of the sub-sectors banana, charcoal, coffee, macadamia, orange, vegetables and walnut. Our results show that temperatures and precipitation levels will change differently depending on the climatic regions, and that climate change elicits different responses from the market functions both between and within each of the different sub-sectors. We conclude that climate-related interventions in market systems must account for each different market function's specific response and exposure to climate change, in order to select adaptation measures that ensure long-term climate resilience.

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“…These results can highlight the potential need for conservation strategies in water-limited regions. Other researchers have used RCM output to drive crop simulations in central Asia (Bobojonov and Aw-Hassan 2014) and the Midwestern U.S. (Glotter et al 2014) to examine the agronomic response to changes in regional climate. An integrated modeling continuum.…”

Section: Definition and Scopementioning

confidence: 99%

Transition Pathways to Sustainable Agricultural Water Management: A Review of Integrated Modeling Approaches

Haacker

Sharda

Cano

et al. 2019

J American Water Resour Assoc

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Agricultural water management (AWM) is an interdisciplinary concern, cutting across traditional domains such as agronomy, climatology, geology, economics, and sociology. Each of these disciplines has developed numerous process‐based and empirical models for AWM. However, models that simulate all major hydrologic, water quality, and crop growth processes in agricultural systems are still lacking. As computers become more powerful, more researchers are choosing to integrate existing models to account for these major processes rather than building new cross‐disciplinary models. Model integration carries the hope that, as in a real system, the sum of the model will be greater than the parts. However, models based upon simplified and unrealistic assumptions of physical or empirical processes can generate misleading results which are not useful for informing policy. In this article, we use literature and case studies from the High Plains Aquifer and Southeastern United States regions to elucidate the challenges and opportunities associated with integrated modeling for AWM and recommend conditions in which to use integrated models. Additionally, we examine the potential contributions of integrated modeling to AWM — the actual practice of conserving water while maximizing productivity. Editor's note: This paper is part of the featured series on Optimizing Ogallala Aquifer Water Use to Sustain Food Systems. See the February 2019 issue for the introduction and background to the series.

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Evaluating the utility of dynamical downscaling in agricultural impacts projections

Cited by 76 publications

References 51 publications

Evaluation of historical and future simulations of precipitation and temperature in central Africa from CMIP5 climate models

Evaluation of historical and future simulations of precipitation and temperature in central Africa from CMIP5 climate models

Climate Changes and Their Impact on Agricultural Market Systems: Examples from Nepal

Transition Pathways to Sustainable Agricultural Water Management: A Review of Integrated Modeling Approaches

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