Performance metrics for climate models

Gleckler, P. J.; Taylor, Karl E.; Doutriaux, Charles

doi:10.1029/2007jd008972

Cited by 1,103 publications

(1,045 citation statements)

References 29 publications

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“…Both stationary and transient MMEM eddy stresses agree well with the observational estimates-better in fact than any single model, as is commonly found [Gleckler et al, 2008;Reichler and Kim, 2008].…”

Section: Multi-model Ensemble-meansupporting

confidence: 74%

Hadley cell bias in climate models linked to extratropical eddy stress

Caballero¹

2008

Geophysical Research Letters

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Recent theoretical and observational work shows that the Reynolds stresses due to large‐scale extratropical eddies play a key role in determining Hadley cell strength. This implies that errors in the representation of extratropical eddies in climate models could force a bias in the tropical circulation. Here, this hypothesis is assessed using output from 17 coupled climate models, focusing on Northern Hemisphere winter. Inter‐model variability in Hadley cell strength, tropical temperature and tropical humidity is found to be significantly correlated with inter‐model differences in stationary eddy stress. Thus, a significant fraction of the tropical climate bias found in current climate models may be forced from the extratropics.

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Section: Multi-model Ensemble-meansupporting

confidence: 74%

Hadley cell bias in climate models linked to extratropical eddy stress

Caballero¹

2008

Geophysical Research Letters

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“…9 using a diagram inspired by the Performance Portrait diagram of Gleckler et al (2008). Figure 9 shows that the two metrics gave similar results in all cases (as a reminder a value of zero corresponds to a perfect match of the two distributions).…”

Section: Anomaly Distributionsmentioning

confidence: 89%

Evaluation of CORDEX-Arctic daily precipitation and temperature-based climate indices over Canadian Arctic land areas

et al. 2017

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“…* CLIMATE CHANGE AND NUTRIENT LOSS 353 these uncertainties. In such instances, the mean of an ensemble of scenarios can provide a strong index to assess the overall outcomes of climate change impact (Gleckler et al 2008). The degree of uncertainty (both due to GHGe projections and physical modelling) is determined by the range of the projection results.…”

Section: Uncertainty Analysismentioning

confidence: 99%

Impacts of climate change on nutrient losses from the Pike River watershed of southern Québec

et al. 2015

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. 2015. Impacts of climate change on nutrient losses from the Pike River watershed of southern Que´bec. Can. J. Soil Sci. 95: 337Á358. The impacts of climate change on water quality in the Pike River watershed, an important contributor of nutrient loads into the northern arm of Lake Champlain, were simulated for the time horizon 2041Á2070. Four water quality scenarios were simulated using a calibrated version of the Soil and Water Assessment Tool (SWAT) customized to Que´bec agroclimatic conditions. Three of the scenarios were generated using climate data simulated with the Fourth-generation Canadian Regional Climate Model (CRCM4). The fourth scenario was generated using the climate simulated with the Arpege Regional Climate Model. Potential mean climate-induced changes in sediment, phosphorus, and nitrogen yield projected by these scenarios were then analyzed for the 2050 horizon. In addition, the impacts of the different sources of climate projection uncertainty were assessed by comparing climate model initial conditions, and climate model physical structure effects on the hydrochemical projections. Only one climate scenario projected a significant increase in mean annual total phosphorus [10 metrics tons (t) yr (1 or 14%] and total nitrogen (260 t yr (1 or 17%) loads. However, when shorter time spans (seasonal and monthly scales) were considered, several significant changes were detected, especially in winter. Sediment and nutrient loadings, in winter, were predicted to become three to four times higher than current levels. These increases were attributed to a greater vulnerability of soils to erosion in winter due to the decrease in the snowpack, early onset of spring snowmelt, a greater number of rainfall events, and snowmelt episodes caused by higher winter and spring temperatures.

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Performance metrics for climate models

Cited by 1,103 publications

References 29 publications

Hadley cell bias in climate models linked to extratropical eddy stress

Hadley cell bias in climate models linked to extratropical eddy stress

Evaluation of CORDEX-Arctic daily precipitation and temperature-based climate indices over Canadian Arctic land areas

Impacts of climate change on nutrient losses from the Pike River watershed of southern Québec

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