Kilometer-Scale Climate Models: Prospects and Challenges

Schär, Christoph; Fuhrer, Oliver; Arteaga, Andrea; Ban, Nikolina; Charpilloz, Christophe; Girolamo, Salvatore Di; Hentgen, Laureline; Hoefler, Torsten; Lapillonne, Xavier; Leutwyler, David; Osterried, Katherine; Panosetti, Davide; Rüdisühli, Stefan; Schlemmer, Linda; Schulthess, T. C.; Sprenger, Michael; Ubbiali, Stefano; Wernli, Heini

doi:10.1175/bams-d-18-0167.1

Cited by 157 publications

(149 citation statements)

References 84 publications

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“…Minobe et al, 2008;Shaffrey et al, 2009;Roberts et al, 2016). Synoptic-scale dynamics are better resolved in GCMs with increasing resolution, which improves the representation of midlatitude eddy-driven jet variability, extratropical cyclones, and associated extreme precipitation (Catto et al, 2010;Haarsma et al, 2013;Schiemann et al, 2018;Baker et al, 2019), as well as blocking events (Matsueda and Palmer, 2011;Berckmans et al, 2013). The intensity of tropical cyclones in GCMs also increases with resolution, and their inter-annual variability is better captured (e.g.…”

Section: High-resolution Gcmsmentioning

confidence: 99%

European daily precipitation according to EURO-CORDEX regional climate models (RCMs) and high-resolution global climate models (GCMs) from the High-Resolution Model Intercomparison Project (HighResMIP)

et al. 2020

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Abstract. In this study, we evaluate a set of high-resolution (25–50 km horizontal grid spacing) global climate models (GCMs) from the High-Resolution Model Intercomparison Project (HighResMIP), developed as part of the EU-funded PRIMAVERA (Process-based climate simulation: Advances in high resolution modelling and European climate risk assessment) project, and from the EURO-CORDEX (Coordinated Regional Climate Downscaling Experiment) regional climate models (RCMs) (12–50 km horizontal grid spacing) over a European domain. It is the first time that an assessment of regional climate information using ensembles of both GCMs and RCMs at similar horizontal resolutions has been possible. The focus of the evaluation is on the distribution of daily precipitation at a 50 km scale under current climate conditions. Both the GCM and RCM ensembles are evaluated against high-quality gridded observations in terms of spatial resolution and station density. We show that both ensembles outperform GCMs from the 5th Coupled Model Intercomparison Project (CMIP5), which cannot capture the regional-scale precipitation distribution properly because of their coarse resolutions. PRIMAVERA GCMs generally simulate precipitation distributions within the range of EURO-CORDEX RCMs. Both ensembles perform better in summer and autumn in most European regions but tend to overestimate precipitation in winter and spring. PRIMAVERA shows improvements in the latter by reducing moderate-precipitation rate biases over central and western Europe. The spatial distribution of mean precipitation is also improved in PRIMAVERA. Finally, heavy precipitation simulated by PRIMAVERA agrees better with observations in most regions and seasons, while CORDEX overestimates precipitation extremes. However, uncertainty exists in the observations due to a potential undercatch error, especially during heavy-precipitation events. The analyses also confirm previous findings that, although the spatial representation of precipitation is improved, the effect of increasing resolution from 50 to 12 km horizontal grid spacing in EURO-CORDEX daily precipitation distributions is, in comparison, small in most regions and seasons outside mountainous regions and coastal regions. Our results show that both high-resolution GCMs and CORDEX RCMs provide adequate information to end users at a 50 km scale.

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Section: High-resolution Gcmsmentioning

confidence: 99%

European daily precipitation according to EURO-CORDEX regional climate models (RCMs) and high-resolution global climate models (GCMs) from the High-Resolution Model Intercomparison Project (HighResMIP)

et al. 2020

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“…Such a coarse resolution is usually not capable of capturing orographic precipitation in complex terrain [1][2][3] . Although global circulation and weather models such as WRF-ARF 4 , or ICON 5,6 , for example, can be run at high horizontal resolutions close to 1 km, they are still heavily constrained by computational limits 7 . Currently, global kilometre-scale models only achieve a simulation throughput of 0.043 SYPD (simulated years per day) 8 , which amounts to an 25 x shortfall compared to what would be computationally efficient simulations of 1 SYPD 7,9 .…”

Section: Background and Summarymentioning

confidence: 99%

“…Although global circulation and weather models such as WRF-ARF 4 , or ICON 5,6 , for example, can be run at high horizontal resolutions close to 1 km, they are still heavily constrained by computational limits 7 . Currently, global kilometre-scale models only achieve a simulation throughput of 0.043 SYPD (simulated years per day) 8 , which amounts to an 25 x shortfall compared to what would be computationally efficient simulations of 1 SYPD 7,9 . Even with the largest supercomputers and state-of-the-art climate models, as well as large financial investments, such a shortfall can currently only be reduced by a factor of 20 (ref.…”

Section: Background and Summarymentioning

confidence: 99%

High-resolution monthly precipitation and temperature time series from 2006 to 2100

et al. 2020

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the CHELSA algorithm 17 , which provides a more accurate representation of temperature and precipitation in highly complex terrain. Data based on the CHELSA algorithm 17 have already been used to infer e.g. ecological niches 24 , soil nutrients 25,26 , or to assess climate change impacts of forests 27 , insect pests 28 , and biodiversity 29. Mean monthly maximum daily temperatures and mean monthly minimum daily temperatures have been downscaled using the delta change method based on the high-spatial-resolution data taken from CHELSA V.1.2. Monthly precipitation sums have been downscaled by applying the CHELSA algorithm directly on bias corrected GCM data. The CHELSA algorithm allows for representing the effects from changing wind patterns and boundary layer conditions in the process of downscaling, and therefore allows for a better estimation of the km-scale changes in precipitation patterns under future climate projections. Methods Selection of global circulation models (GCMs). Projected future climate variables were taken from four global circulation models (GCMs) driven by two scenarios of representative concentration pathways (RCPs) in a factorial manner. The four selected models originate from the CMIP5 collection of model runs used in IPCC's 5th Assessment Report 30 (IPCC 2013). GCMs are, however, often based on similar code which consequently results in similar output 31,32. We therefore chose models that show a low amount of interdependence to allow for a good representation of uncertainty among available climate projections. Model selection was performed to reduce model interdependence in ensembles (see ref. 32).

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“…Fronts are characterized by strong horizontal contrasts in low-level temperature and humidity, which makes equivalent potential temperature θ e at 850 hPa a suitable field for front detection (specifically, the modulus |∇θ e | of the θ e gradient). Schemm et al (2018) discuss this choice in detail and provide a historical context. Following the general approach proposed by Hewson (1998), the front identification method developed by Jenkner et al (2010) is based on applying the thermal front parameter (TFP; Renard and Clarke, 1965) to θ e and using the cross-frontal wind component to distinguish between cold, warm, and quasistationary fronts.…”

Section: Frontsmentioning

confidence: 99%

“…While such methods are in principle objective, choosing specific approaches and configurations involves many ultimately subjective choices. Lacking a universally accepted definition of fronts, it is not inherently clear how to identify them, and consequently, many different approaches exist, as discussed in detail by Schemm et al (2018) and Thomas and Schultz (2019). Another subjective choice is involved when attributing precipitation to a front within a certain distance, which might also depend on the resolution of the available datasets.…”

Section: Introductionmentioning

confidence: 99%

Attribution of precipitation to cyclones and fronts over Europe in a kilometer-scale regional climate simulation

Rüdisühli

Sprenger

Leutwyler

et al. 2020

Weather Clim. Dynam.

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Abstract. This study presents a detailed analysis of the climatological distribution of precipitation in relation to cyclones and fronts over Europe for the 9-year period 2000–2008. The analysis uses hourly output of a COSMO (Consortium for Small-scale Modeling) model simulation with 2.2 km grid spacing and resolved deep convection. Cyclones and fronts are identified as two-dimensional features in 850 hPa geopotential, equivalent potential temperature, and wind fields and subsequently tracked over time based on feature overlap and size. Thermal heat lows and local thermal fronts are removed based on track properties. This dataset then serves to define seven mutually exclusive precipitation components: cyclonic (near cyclone center), cold-frontal, warm-frontal, collocated (e.g., occlusion area), far-frontal, high-pressure (e.g., summer convection), and residual. The approach is illustrated with two case studies with contrasting precipitation characteristics. The climatological analysis for the 9-year period shows that frontal precipitation peaks in winter and fall over the eastern North Atlantic and the Alps (> 70 % in winter), where cold frontal precipitation is also crucial year-round; cyclonic precipitation is largest over the North Atlantic (especially in summer with > 40 %) and in the northern Mediterranean (widespread > 40 %); high-pressure precipitation occurs almost exclusively over land and primarily in summer (widespread 30 %–60 %, locally >80 %); and the residual contributions uniformly amount to about 20 % in all seasons. Considering heavy precipitation events (defined based on the local 99.9th all-hour percentile) reveals that high-pressure precipitation dominates in summer over the continent (50 %–70 %, locally >80 %); cold fronts produce much more heavy precipitation than warm fronts; and cyclones contribute substantially (50 %–70 %), especially in the Mediterranean in fall through spring and in northern Europe in summer.

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Kilometer-Scale Climate Models: Prospects and Challenges

Cited by 157 publications

References 84 publications

European daily precipitation according to EURO-CORDEX regional climate models (RCMs) and high-resolution global climate models (GCMs) from the High-Resolution Model Intercomparison Project (HighResMIP)

European daily precipitation according to EURO-CORDEX regional climate models (RCMs) and high-resolution global climate models (GCMs) from the High-Resolution Model Intercomparison Project (HighResMIP)

High-resolution monthly precipitation and temperature time series from 2006 to 2100

Attribution of precipitation to cyclones and fronts over Europe in a kilometer-scale regional climate simulation

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