Scale space methods for climate model analysis

Marvel, Kate; Ivanova, D.; Taylor, Karl E.

doi:10.1002/jgrd.50433

Cited by 7 publications

(9 citation statements)

References 46 publications

(60 reference statements)

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“…In this paper, we focus on boreal winter (December-February; hereafter DJF). We begin by smoothing observed DJF seasonal precipitation climatologies so that spatial structure on scales less than 5°is removed (18). Fig.…”

Section: Thermodynamic and Dynamic Indicatorsmentioning

confidence: 99%

Identifying external influences on global precipitation

Marvel

Bonfils

2013

Proc. Natl. Acad. Sci. U.S.A.

223

175

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Changes in global (ocean and land) precipitation are among the most important and least well-understood consequences of climate change. Increasing greenhouse gas concentrations are thought to affect the zonal-mean distribution of precipitation through two basic mechanisms. First, increasing temperatures will lead to an intensification of the hydrological cycle ("thermodynamic" changes). Second, changes in atmospheric circulation patterns will lead to poleward displacement of the storm tracks and subtropical dry zones and to a widening of the tropical belt ("dynamic" changes). We demonstrate that both these changes are occurring simultaneously in global precipitation, that this behavior cannot be explained by internal variability alone, and that external influences are responsible for the observed precipitation changes. Whereas existing model experiments are not of sufficient length to differentiate between natural and anthropogenic forcing terms at the 95% confidence level, we present evidence that the observed trends result from human activities.climate modeling | multimodel database | climate change detection W ater is the single most important natural resource, and many societal and natural impacts of climate change will depend on the response of the hydrological cycle to anthropogenic warming. Several large-scale changes in precipitation, inferred from theoretical understanding, observations, and climate model predictions, are expected in a warming world (1). To first order, anthropogenic forcings are expected to influence the hydrological cycle through two basic mechanisms. "Thermodynamic" changes follow from the Clausius-Clapeyron relation, which dictates that saturation-specific humidity increases roughly exponentially with temperature, and from the vertical warming profile (2, 3). In the absence of other changes, this increase in tropospheric water vapor will make wet regions wetter and dry regions drier. Tropospheric water vapor is indeed increasing in response to human activities (4), and there is evidence that this increase has contributed to the moistening of wet regions and drying of dry regions (5-7). Existing large-scale studies (7-9) are constrained over land, and thus neglect the 77% of precipitation that falls over oceans. Thermodynamic changes are expected to be even stronger over ocean, because evaporation is limited over dry land regions, and trends in ocean salinity may indicate an intensification of the global hydrological cycle (10). However, no study has yet detected a signal of climate change in global (land and ocean) precipitation."Dynamic" changes result from shifts in atmospheric circulation, which in turn affect the horizontal and vertical transport of water vapor. Numerous observational and model-based studies have detected circulation shifts using various metrics (ref. 11 and references therein). Models indicate that increasing greenhouse gases, in the absence of other external forcing terms, result in a poleward expansion of the tropical Hadley cell and subtropical dry zones (12...

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Section: Thermodynamic and Dynamic Indicatorsmentioning

confidence: 99%

Identifying external influences on global precipitation

Marvel

Bonfils

2013

Proc. Natl. Acad. Sci. U.S.A.

223

175

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“…Consequently, they generally better reproduce observed climatology, such as mean and extreme precipitation, for almost all regions and seasons but especially in heterogeneous regions such as the mountains (Prein et al , ). Moreover, the large‐scale dynamics of the climate systems are partially determined by nonlinear processes, whose characteristic scales might be unresolved at coarse resolutions (Marvel et al , ) but captured at higher resolution. With these improvements, high resolution RCMs are expected to simulate local and regional weather phenomena more accurately (Marvel et al , ) leading to improved simulation of the distribution of events at finer temporal scales, e.g.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of the added value of a high‐resolution regional climate model simulation of the South Asian summer monsoon climatology

Karmacharya

Jones

Moufouma-Okia

et al. 2016

Intl Journal of Climatology

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The South Asian summer monsoon (SASM) is a continental scale weather phenomenon, which fluctuates at a range of temporal and spatial scales. Although majority of global climate models are broadly able to simulate the large scale characteristics of the SASM, they generally have major deficiencies such as constraints in reproducing observed mean precipitation. It is generally anticipated that higher resolution regional climate models (RCMs) would be able to simulate an improved mean state owing to their capacity to better simulate fine temporal and spatial scale features and variability. Here, we analyse SASM simulations using a contemporary Hadley Centre RCM, forced by ERA‐Interim reanalysis and observed sea surface temperature, at medium (0.44°) and high (0.11°) horizontal resolutions. Evaluation of the results show that, compared to the medium resolution RCM, the high resolution RCM is able to better resolve the interaction of the low level monsoon flow with the Himalayan orography leading to added value in simulating many aspects of SASM precipitation such as the seasonal mean, relative frequency distribution of daily precipitation, and various metrics of precipitation extremes. In contrast to many previous studies, maximum added value is note along the Indo‐Gangetic plain rather than over the complex Himalayas, and the added values of up to 5 mm day−1 and 50 days are noted for mean precipitation and number of wet days, respectively over the region. Similarly, added values of up to 15 and 3 mm day−1 are noted for 95th percentile of daily precipitation and simple daily intensity index, respectively over central India and the Himalayan range. These results suggest that higher resolution RCMs have the potential to add more value when downscaling global climate model climate change projections.

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“…We note that, because the {z A i } are uniform across each region, there will be discontinuities at the region boundaries, which could pose problems, particularly for spectral dynamical cores. Further research will need to be undertaken to reveal how this can best be handled; one possibility could be scale space smoothing methods (Marvel et al, 2013).…”

Section: Climate Model Simulationsmentioning

confidence: 99%

Technical note: Simultaneous fully dynamic characterization of multiple input–output relationships in climate models

et al. 2017

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Abstract. We introduce system identification techniques to climate science wherein multiple dynamic input-output relationships can be simultaneously characterized in a single simulation. This method, involving multiple small perturbations (in space and time) of an input field while monitoring output fields to quantify responses, allows for identification of different timescales of climate response to forcing without substantially pushing the climate far away from a steady state. We use this technique to determine the steady-state responses of low cloud fraction and latent heat flux to heating perturbations over 22 regions spanning Earth's oceans. We show that the response characteristics are similar to those of step-change simulations, but in this new method the responses for 22 regions can be characterized simultaneously. Furthermore, we can estimate the timescale over which the steady-state response emerges. The proposed methodology could be useful for a wide variety of purposes in climate science, including characterization of teleconnections and uncertainty quantification to identify the effects of climate model tuning parameters.

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Scale space methods for climate model analysis

Cited by 7 publications

References 46 publications

Identifying external influences on global precipitation

Identifying external influences on global precipitation

Evaluation of the added value of a high‐resolution regional climate model simulation of the South Asian summer monsoon climatology

Technical note: Simultaneous fully dynamic characterization of multiple input–output relationships in climate models

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