The CWRF is developed as a climate extension of the Weather Research and Forecasting model (WRF) by incorporating numerous improvements in the representation of physical processes and integration of external (top, surface, lateral) forcings that are crucial to climate scales, including interactions between land, atmosphere, and ocean; convection and microphysics; and cloud, aerosol, and radiation; and system consistency throughout all process modules. This extension inherits all WRF functionalities for numerical weather prediction while enhancing the capability for climate modeling. As such, CWRF can be applied seamlessly to weather forecast and climate prediction. The CWRF is built with a comprehensive ensemble of alternative parameterization schemes for each of the key physical processes, including surface (land, ocean), planetary boundary layer, cumulus (deep, shallow), microphysics, cloud, aerosol, and radiation, and their interactions. This facilitates the use of an optimized physics ensemble approach to improve weather or climate prediction along with a reliable uncertainty estimate. The CWRF also emphasizes the societal service capability to provide impactrelevant information by coupling with detailed models of terrestrial hydrology, coastal ocean, crop growth, air quality, and a recently expanded interactive water quality and ecosystem model.

This study provides a general CWRF description and basic skill evaluation based on a continuous integration for the period 1979– 2009 as compared with that of WRF, using a 30-km grid spacing over a domain that includes the contiguous United States plus southern Canada and northern Mexico. In addition to advantages of greater application capability, CWRF improves performance in radiation and terrestrial hydrology over WRF and other regional models. Precipitation simulation, however, remains a challenge for all of the tested models.

An extension of the WRF, incorporating a comprehensive ensemble of alternative physics representations, facilitates seamless applications for regional weather forecasting and climate prediction.

RCMs (see the appendix for expanded acronyms) have been widely applied and well recognized as an essential tool to address scientific issues concerning climate variability, changes, and impacts at regional–local scales (Giorgi and Mearns 1999; Giorgi et al. 2001; Leung et al. 2003; Wang et al. 2004; Giorgi 2006; Fowler et al. 2007; Christensen et al. 2007; Bader et al. 2008; Liang et al. 2008a,b). Numerous RCMs have been developed that demonstrate useful downscaling skill, and yet many model deficiencies remain to be resolved. The most commonly used RCMs have been based on various versions of the Pennsylvania State University/NCAR Mesoscale Model (Anthes et al. 1987; Grell et al. 1994; Dudhia et al. 2005); this model family has now been superseded by the WRF (Skamarock et al. 2008). Accordingly, we have undertaken a lengthy effort to develop a version of WRF (CWRF) specifically improved for climate time-scale applications. The most crucial improvements targeted interactions between land, atmosphere, and ocean; convection and microphysics; and cloud, aerosol, and radiation, as well as system consistency throughout all process modules (Liang et al. 2002, 2004c, 2005b,d,a,c, 2006b; Xu et al. 2005; Choi 2006; Choi et al. 2007; Choi and Liang 2010; Yuan and Liang 2011a).

The WRF was designed originally for short-range NWP but not expressly for long-term climate simulation. There has been some success using WRF for regional climate downscaling with a continuous model integration of longer than a season (Liang et al. 2002; Leung and Qian 2009; Evans and McCabe 2010; and all the following references cited in this paragraph). Such direct applications, however, also have encountered numerous problems. These include 1) degradation of summer daily rainfall variations over China by downscaling (Wang and Yang 2008); 2) strong overprediction (underprediction) of winter precipitation intensity (frequency), and large warm biases in summer surface temperature along with low estimates of soil moisture over California (Caldwell et al. 2009); 3) notable warm biases in surface daily minimum temperature in winter and autumn, and low correlations between modeled and observed daily precipitation over the U.S. Pacific Northwest (Zhang et al. 2009); 4) precipitation overestimation over West Africa (Druyan et al. 2009; Vigaud et al. 2011); and 5) excessive rainfall at off-equatorial latitudes and a deficit near the equator (Tulich et al. 2011). To remedy unsatisfactory predictive skill scores, Lo et al. (2008) suggested more frequent reinitialization or stronger 3D observational nudging; Heikkilä et al. (2011) sought after domainwise spectral nudging to maintain the large-scale feature; Bukovsky and Karoly (2009) recommended careful scrutiny of model consistencies; and Chin et al. (2010), Mukhopadhyay et al. (2010), Awan et al. (2011), Crétat et al. (2012), and Flaounas et al. (2011) emphasized model sensitivities to different physics schemes. Even using a daily initialization, Hines et al. (2011) found that WRF still produces warm temperature biases in winter and summer and a marked summer cloud cover deficit with excessive incident shortwave radiation over the western Arctic. None of these studies focused on the systematic development of improved physics representations that are suitable for climate prediction at certain resolutions. This is the key goal of the CWRF development.

The CWRF has been built on three main principles. First, CWRF is an extension of WRF, inheriting all WRF functionalities for NWP while enhancing its capability to predict climate. As such, CWRF can be applied to both weather forecasting and climate prediction (e.g., Zeng et al. 2008a,b; Liu et al. 2008). This unification offers an opportunity to develop, test, and verify new physical parameterizations of unresolved processes, identify their systematic errors, and eventually improve them over a wide range of phenomena, from weather to climate scales. Incorporation of the WRF data assimilation system enables CWRF to produce short-range weather forecasts from realistic initial conditions. High-frequency NWP analyses and unassimilated observations can be used to identify and correct parameterization deficiencies, resulting in improvements initially manifested in short-range weather forecasts and then persisted in climate simulations (Phillips et al. 2004). In contrast, some systematic climate biases that develop slowly probably cannot be identified and removed by the NWP-based approach (Liang et al. 2005c; Bukovsky and Karoly 2009). Clearly, CWRF provides a unique tool to develop improved schemes for realistic and seamless prediction of weather and climate, which were declared as both necessary and possible at the recent World Modelling Summit for Climate Prediction (Shukla et al. 2009).

Second, CWRF provides a multimodel ensemble prediction capability by incorporating a comprehensive list of alternative parameterization schemes for each of the key physical processes, including surface (land, ocean), PBL, cumulus (deep, shallow), microphysics, cloud, aerosol, and radiation. The CWRF currently contains over 1024 configurations representing these processes and their interactions, which we believe is the largest among existing weather/climate modeling systems. Different schemes were designed with different conceptual underpinnings and tunable parameters that are not universal and are also quite uncertain (Arakawa 2004). No single scheme performs uniformly well under all conditions, and each has predictive ability highly dependent on weather or climate regimes (Tselioudis and Jakob 2002; Liang et al. 2004a,b; Mapes et al. 2004; Jankov et al. 2005; Gallus and Bresch 2006; Zhu and Liang 2007) and application scales (Kiehl and Williamson 1991; Dudek et al. 1996; Giorgi and Marinucci 1996; Jung and Arakawa 2004; Hack et al. 2006). Thus, consensus weather and climate predictions based on an ensemble of multiple physics configurations of a model or multiple models have recently been highlighted for their superior skills over those using a single configuration or model (Krishnamurti et al. 2000; Palmer et al. 2004; Gleckler et al. 2008; Kirtman and Min 2009). Such superiority is realized because distinct regions are identified where each model or scheme complementarily captures certain but not all observed signals. Our recent research suggests that better prediction, especially for precipitation, is achievable through intelligent optimization of the model physics ensemble (Liang et al. 2007; Zeng et al. 2008a; Liu et al. 2009). The CWRF physics ensemble, when optimized against observations, will result in improved weather or climate prediction at regional– local scales.

Third, CWRF emphasizes a societal service capability to provide credible information for climate impacts and risk analyses. The CWRF development has included an effort to incorporate modules designed to address certain specific needs of stakeholders for quantitative information on natural resource changes at regional–local scales. In this regard, we have built additional component models that are capable of predicting terrestrial hydrology (Choi 2006; Choi et al. 2007; Choi and Liang 2010; Yuan and Liang 2011a), upper-ocean processes (Ling et al. 2011), air quality (Huang et al. 2007; Wang et al. 2010), UV radiation (Xu et al. 2006), and crop growth (Xu et al. 2005; Liang et al. 2012a,b). The last two modules and others (e.g., water quality, ecosystem) have been evaluated in standalone mode and are being coupled with CWRF. The optimal use of such output by decision makers requires not only accurate predictions of key surface quantities (temperature, precipitation, soil moisture, streamflow, runoff, water table, crop yields, pollutants, UV levels, etc.), including their means and extremes, but also reliable estimates of corresponding uncertainties, especially in projecting future climate change. The CWRF physics ensemble offers a pragmatic approach to achieve that goal. Weighting individual members by their skill in resolving past observations can provide strong constraints on the ensemble prediction of future outcomes (Murphy et al. 2004; Palmer et al. 2008), although how to apply the constraints is still a matter of debate (Scaife et al. 2009; Palmer et al. 2009).

The CWRF improvements have been accomplished through iterative, extensive model refinements, sensitivity experiments, and rigorous evaluations over the past 8 yr. As a result, CWRF has demonstrated greater application capability than the original WRF and overall better performance in simulating the U.S. regional climate than the existing CMM5 (Liang et al. 2001, 2004b,Liang et al. 2007; Zhu and Liang 2005, 2007). This justifies its initial release for community use. A series of papers being prepared will document details of the CWRF formulations as well as weather forecast and climate prediction skill. The present study provides a general model description and a basic evaluation of model skill using a continuous CWRF integration for the period 1979–2009 as compared with those of CMM5 and WRF. All models were run on an identical U.S. computational domain of 30-km grid spacing (Liang et al. 2004b) and driven by the same global R-2 (Kanamitsu et al. 2002), one of the best available proxies for observations. These integrations are also compared with a similar run, named WRFG, which uses the earlier WRF version 2 over an extended domain and relatively coarse 50-km grid spacing (Leung et al. 2011) as a part of the NARCCAP effort (Mearns et al. 2012). These comparisons depict the critical dependence of the RCM climate downscaling skill on the model configurations for physics, resolution, and domain.

BRIEF MODEL DESCRIPTION.

Figure 1 illustrates the current CWRF physics options and executing structure. There are seven major drivers, each of which controls multiple alternative schemes for the physical processes of cloud, aerosol, radiation, surface, PBL, cumulus, and microphysics, in the sequential order of computation. The first three drivers (cloud, aerosol, radiation) form the CAR ensemble modeling system that incorporates over 1018 different ways to simulate interactions among cloud, aerosol, and radiation, developed from seven packages available in the leading global and regional models around the world. This replaces the original WRF single radiation driver that consists of the CAM1 and AER packages, along with the now-obsolete MISC schemes. The surface driver manages all schemes handling surface and subsurface processes over land and oceans, as well as surface–atmosphere flux exchanges. In particular, CWRF adds the advanced CSSP and CROP for terrestrial hydrology and crop growth over land, and SOM and UOM for mixed-layer and upper-ocean effects. The two urban schemes are separated from Noah and now work with all land surface schemes. All seven surface layer schemes, originally tied to specific options, are now interchangeable for all surface and PBL schemes. The PBL driver hosts seven WRF plus two new (CAM, UW) PBL schemes, all of which are integrated with the ORO, accounting for orographic turbulence stress and gravity wave drag. The cumulus driver provides the hub for seven WRF plus six new (GR, ZML, CSU, GFDL, MIT, ECP) deep cumulus schemes, all of which can be coupled with a shallow convection scheme (UW). A consistent switch is added to control whether shallow convection is activated internally in eight deep cumulus schemes or done externally by the UW scheme. The microphysics driver incorporates the 11 microphysics schemes of WRF.

Fig. 1.

The schematic of the current CWRF physics options and executing sequence from the top-down. The CAR ensemble system and all modules or schemes outlined in yellow are additions specifically developed for CWRF, while others are inherited from WRF .

Fig. 1.

The schematic of the current CWRF physics options and executing sequence from the top-down. The CAR ensemble system and all modules or schemes outlined in yellow are additions specifically developed for CWRF, while others are inherited from WRF .

Of central importance, we strove to make all alternative schemes in CWRF fully coupled across all drivers with plug-and-play interfaces. Even without counting the grand CAR ensemble, CWRF currently contains over 106 configurations for the surface, PBL, cumulus, and microphysics processes and their interactions. To achieve this, substantial efforts were made to scrutinize all individual schemes for consistency and incorporate suitable algorithms for missing variables to enable the coupling for the overall system. Particular care has been taken to ensure continuous model integration that can be restarted at any interval while resulting in bit-bybit numerical agreement. This is not trivial, especially if time-step intervals differ among executing individual physics drivers. A seamless averaging procedure is implemented to replace prognostic cumulative variables by their averages between two consecutive steps of the driver at work during the integration. This is especially effective for precipitation fields (convective/resolved rainfall/snowfall) that are used for different purposes in the cumulus, microphysics, surface, cloud, and aerosol drivers. Other diagnostic cumulative variables, such as surface water and energy budget fields, can be set to zero at any restart checkpoint to reduce truncation errors. As such, CWRF can be run reliably for a long-term climate simulation with frequent restarts as needed and with varying time steps for all seven physics drivers. In contrast, WRF2 with several tested configurations has been reported to result in numerical instability or serious drift that prohibits its use for continuous climate-scale simulations.

The CWRF has improved WRF with major advances in the integration of external (top, surface, lateral) forcing conditions and in the representation of physical processes that are essential to climate modeling. These improvements have been implemented mostly as “plug-compatible physics,” and thus will not cause any problem with parallelism and supercomputing optimization in general. All the new schemes in CWRF are summarized in the supplementary material (http://dx.doi.org/10.1175/BAMS-D-11-00180.2), while those of the original WRF are referenced in Skamarock et al. (2008) and Wang et al. (2012).

MODEL EXPERIMENT DESIGN AND EVALUATION DATA.

The CWRF computational domain for this study (Fig. 2) is centered at 37.5°N, 95.5°W, covers the entire continental United States with 30-km grid spacing, and represents regional climate variations that result from interactions with the planetary circulation (as forced by LBCs) and North American surface processes, including orography, soil, vegetation, and coastal oceans. The buffer zones are located across 14 grids along four edges of the domain, where varying LBCs are specified through a dynamic relaxation technique (Liang et al. 2001). This domain design has produced skillful simulations of U.S. precipitation, surface temperature, and soil moisture (Liang et al. 2004a,b, 2005c, 2006a,b, 2007; Zhu and Liang 2005, 2007). Also displayed in Fig. 2 are the land cover and ocean depth distributions, lakes, major rivers, and main streams as well as the Corn/Soybean and Cotton Belts. These fields are a small subset of the comprehensive SBCs used by CWRF (Liang et al. 2005b,d, 2012a).

Fig. 2.

The CWRF computational domain for this study. The hatched edge areas are the buffer zones, where LBCs are specified. Overlaid are the geographic distributions of land cover (USGS 24 categories) and ocean depth (m), lakes, major rivers, and main streams as well as the outlines of the Corn/Soybean and Cotton Belts.

Fig. 2.

The CWRF computational domain for this study. The hatched edge areas are the buffer zones, where LBCs are specified. Overlaid are the geographic distributions of land cover (USGS 24 categories) and ocean depth (m), lakes, major rivers, and main streams as well as the outlines of the Corn/Soybean and Cotton Belts.

Table 1 summarizes the key model configuration differences of the CWRF simulation from those of WRF, WRFG, and CMM5 to be compared. All simulations are driven by the R-2 LBCs, while the integration length varies. This study compares the model performance in the common period, from 1 January 1982 to 31 December 2004. The WRF and CMM5 runs are done over an identical domain with the same horizontal grid as CWRF, whereas the WRFG run is made over a larger domain (North America) with a coarser g r id (50 km). The buffer zone, where the LBCs are dynamically relaxed with linear– exponential nudging coefficients, has a comparable width among the runs. The CMM5 uses a lower vertical resolution than others. Important differences exist in the physics configuration. In particular, CWRF incorporates several newly developed and more advanced schemes, including those for radiation, surface (land and ocean), and cumulus (deep and shallow) processes. Note that the PBL schemes (CAM, YSU, MRF) are similar in both physical formulation and skill performance (via offline test), while the CAM radiation, Noah surface, GSFC GCE microphysics, and G3 cumulus are the updated CCM2, OSU, GSFC, and GD (rooted from GR) versions, respectively. As such, this collection of simulations represents a comparison of the physics schemes that are most relevant among the RCMs with available long integrations of the same kind.

Table 1.

Key model configuration differences between the CWRF, WRF, WRFG, and CMM5 simulations in comparison.

Key model configuration differences between the CWRF, WRF, WRFG, and CMM5 simulations in comparison.
Key model configuration differences between the CWRF, WRF, WRFG, and CMM5 simulations in comparison.

Given that RCM downscaling skill is sensitive to large-scale forcing errors (e.g., Liang et al. 2001), an additional CWRF integration during 1989–2010 driven by the LBCs from the recently available ERI (Uppala et al. 2008) is conducted and compared with the control run to explain certain systematic model departures from observations (see below).

For model evaluation, daily total precipitation and daily mean (average of maximum and minimum) surface air temperature (at the screen height of 1.25–2 m above the ground) data are based on measurements from 7,235 National Weather Service cooperative stations across the United States. They are mapped onto the CWRF grid following the objective analysis of Liang et al. (2004b) with the topographic adjustment of Daly et al. (2008). The station density is generally high and compatible with the CWRF 30-km grid except for mountainous regions in the Rockies. Over Canada and Mexico, precipitation and temperature data are based on the NOAA/CPC 0.5° daily analysis (Chen et al. 2008) and the CRU TS3.0 0.5° monthly mean analysis (www.cru.uea.ac.uk/cru/data/hrg/), respectively, both from station measurements and with no topographic adjustment. Data for surface downwelling shortwave radiation flux are taken from the ISCCP satellite 280-km monthly mean product available from July 1983 onward. These global analysis data are mapped onto the CWRF 30-km grid using bilinear spatial interpolation to supplement corresponding values beyond the U.S. land area.

CWRF PERFORMANCE ON SEASONAL VARIATION.

Figure 3 compares the geographic distributions of 1982–2004 averaged seasonal mean precipitation as observed and simulated by CWRF, WRF, WRFG, and CMM5. Observed precipitation amounts are relatively high along the West Coast (except during summer) and east of about 100°W and relatively low in the western intermountain area and just east of the Rocky Mountains. All RCMs accurately simulate the dry zone transition that arises from precipitation shadowing by the mountain ranges. West of that zone, two distinct precipitation regimes occur: a cold-season maximum in the Northwest and a warm-season maximum in the Southwest. East of that zone, there exist two major precipitation regimes with a rather even seasonal distribution in the Midwest and the Gulf states. These four regimes are governed by distinct physical processes, for which the RCMs' skills vary significantly and thus are summarized as follows. To facilitate the interpretation of the results, Fig. 4 illustrates the annual cycles of model precipitation biases (departures from observations) along with observations as averaged over the four key regions representative of the four systems.

Fig. 3.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) mean precipitation (mm day−1) averaged during 1982–2004 as OBS and simulated by R-2, CMM5, WRFG, WRF, and CWRF. Also shown is the CWRF/ERI result averaged during 1990–2008, where observations have minor differences from the OBS.

Fig. 3.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) mean precipitation (mm day−1) averaged during 1982–2004 as OBS and simulated by R-2, CMM5, WRFG, WRF, and CWRF. Also shown is the CWRF/ERI result averaged during 1990–2008, where observations have minor differences from the OBS.

Fig. 4.

The 1982–2004 mean annual cycles of precipitation biases (mm day−1, scale on left) simulated by the R-2, CMM5, WRFG, WRF, and CWRF along with observations (mm day−1, scale on right) as averaged over the four key regions. Also shown are the CWRF/ERI biases averaged during 1990–2008.

Fig. 4.

The 1982–2004 mean annual cycles of precipitation biases (mm day−1, scale on left) simulated by the R-2, CMM5, WRFG, WRF, and CWRF along with observations (mm day−1, scale on right) as averaged over the four key regions. Also shown are the CWRF/ERI biases averaged during 1990–2008.

Over the Northwest, all RCMs capture the observed precipitation mesoscale patterns and their seasonal variations rather well. Precipitation is a maximum over the west slopes of all major mountain ranges, peaks in winter, decreases in spring and autumn, and diminishes in summer. Cold-season (September–May) precipitation over the Cascade Range is overestimated by CWRF and WRF but is realistically simulated by WRFG and CMM5. Precipitation there is dominated by large-scale forcing associated with orographic uplift within the eastward-moving Pacific storm systems. Hence, the contribution from the subgrid convective process is small, and the model precipitation is affected little by all choices of cumulus parameterization schemes. Sensitivity experiments show that the regional precipitation overestimation is systematic for all microphysics schemes available in CWRF or WRF. The reduced bias from WRF to WRFG likely results from the coarser resolution, which leads to weaker orographic lift and thus less precipitation. By this explanation, we speculate that CMM5 may produce weaker lift than CWRF due to, for example, stronger numerical damping. It is not clear what causes the overestimation increase from WRF to CWRF. In contrast, the CWRF/ERI integration mostly eliminates the overestimation, producing precipitation seasonal variations very close to observations in both phase and magnitude (Figs. 3 and 4). Therefore, the existence of large-scale forcing errors is probably the major cause for CWRF and WRF overestimation of the orographic precipitation when driven by the R-2 LBCs.

Over the Southwest, the summer rainfall maximum is caused by the NAM. The CMM5 basically fails to simulate the NAM rainfall pattern due to various factors discussed in Liang et al. (2004b). The WRF and WRFG results are improved somewhat, but there is still a general underestimation. Simulation of the NAM remains a challenging issue for both RCMs and GCMs (Liang et al. 2008a,b). Conversely, CWRF (also CWRF/ERI) generally captures the observed NAM rainfall characteristics, including the mean geographic distribution (Fig. 3), annual cycle (Fig. 4), and daily evolution (not shown). Note that the observational analysis makes no topographic adjustment over the NAM region and hence likely underestimates the actual peak rainfall amounts along the mountain ranges. Given this success, CWRF provides an excellent tool for future sensitivity studies to better understand the physical processes that govern NAM rainfall variability. For example, a sensitivity experiment for year 1993 indicates that the CWRF's successful simulation of the NAM rainfall variation is mainly attributed to its use of the ECP cumulus parameterization, with relatively small dependence on other driver schemes. In contrast, G3 (in WRF), GD (in WRFG), GR (in CMM5), BMJ, MIT, TDK, SAS, and NSAS all produce large summer deficit, while NKF and ZML yield large summer overestimation.

Over the Midwest, abundant precipitation is a critical element for the most productive agriculture in the world. The WRFG systematically underestimates the regional precipitation from July to December. It is a common difficulty for other RCMs (Takle et al. 1999; Mearns et al. 2012) to make an accurate simulation over this region, where rainfall results from multiscale circulations involving extratropical cyclones and the accompanying upper-level westerly jet but also regional phenomena, such mesoscale convective complexes and the nocturnal low-level southerly jet. In contrast, as with CMM5 (Liang et al. 2004b), CWRF reasonably well reproduces the regional precipitation distribution. The CWRF generates the most realistic precipitation in autumn through early winter, but there is some underestimation during summer and overestimation during spring. The WRF shares a similar performance with CWRF except for smaller excess in spring but a larger deficit from summer to autumn. Note that, in terms of absolute biases averaged over the year, WRF is slightly better than CWRF, comparing 0.49 to 0.61 mm day−1. It is beyond the scope of this study to determine the causes for the seasonal contrast between the two models.

For the Gulf states, the rainfall results are mainly from convective processes associated with tropical disturbances (easterly waves, tropical cyclones) in the warm season and with extratropical cyclones associated with the southward advance of the upper-level jet stream in the cold season. The WRFG largely underestimates rainfall throughout the year, especially in summer through winter. Similar problems were identified in other RCMs (see Liang et al. 2004b). The CMM5 and WRF improve the result somewhat but still produce large deficits except in April, July, and August. In contrast, CWRF captures the general characteristics of the rainfall geographic distribution and seasonal variation, but it overestimates the amount by 10%–15%. [On average over the year, CWRF absolute biases are very close to WRF, comparing 0.63 with 0.62 mm day−1.] In particular, CWRF simulates excessive rainfall over the southern Great Plains in spring and along the Gulf coast throughout the year. Sensitivity experiments show that these overestimations are mainly due to the CWRF use of the moisture convergence closure in the current ECP cumulus scheme, and that it can be reduced by refining the closure algorithm, for example, using the cloud work function tendency or imposing a certain perturbation to decrease the convective base mass flux.

Note that R-2 incorporates no direct precipitation measurements, such that its precipitation is a product generated by the global assimilation model in balance with the constraint of observed atmospheric circulation fields. Thus, the R-2 precipitation result provides a reference for the RCM downscaling skill enhancement due to its refined spatial resolution and improved physics representation. Clearly, R-2 cannot resolve the mesoscale orographic precipitation patterns west of the Rockies during winter, spring, and autumn, with large underestimations on the west slopes of all major mountain ranges and overestimations on the east slope of the Cascade Range. R-2 produces excessive summer rainfall over Mexico as well as the Gulf and eastern states but large dry winter biases over the Gulf states and Cascade Range. For all these regional features, the CWRF downscaling has significant skill enhancement over the driving R-2.

Figures 5 and 6 compare the corresponding biases (simulations minus observations) between the RCMs for surface air temperature and downwelling shortwave radiation flux, respectively. Four major conclusions can be drawn from the comparison. First, systematic warm biases exist across the Great Plains. This is evident even in WRF, which produces cold biases virtually everywhere else. CWRF experiments indicate that such warm biases are sensitive to the surface albedo parameterization and the vegetation distribution developed from the earlier MODIS and AVHRR products, respectively (Liang et al. 2005a,d). A revised albedo parameterization with a new vegetation distribution, both from the updated MODIS data, substantially reduces the biases, with general improvement over most of the domain. Second, cold biases occur over Mexico, especially for WRFG and WRF. They are coincident with the peak ranges of the Sierra Madres. Given the lack of direct measurements at high elevations over steep mountainous regions, the uncertainties in the CRU analysis without orographic adjustments are likely large. The CMM5 has small cold biases but is accompanied with large rainfall deficits. In contrast, CWRF temperature and rainfall biases are both relatively small and within the observational uncertainties. Third, shortwave radiation is substantially overestimated over most land areas by CMM5, WRFG, and WRF, especially in spring and summer with excesses of 30–60 W m−2. The CWRF, however, produces a much more realistic simulation, mostly within ±20 W m−2. Fourth, inconsistencies exist in biases among variables. For example, WRF has excessive shortwave radiation, counter to its notable cold biases. WRFG and CMM5 have similar radiation overestimations but smaller temperature biases; these model deficiencies seem disconnected. In contrast, the CWRF result is quite realistic for both radiation and temperature, where their biases are consistent with the intuitive physics expectation.

Fig. 5.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) mean surface air temperature (°C) biases (departures from observations) averaged during 1982–2004 as simulated by CMM5, WRFG, WRF, and CWRF. Also shown is the CWRF/ERI biases averaged during 1990–2008.

Fig. 5.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) mean surface air temperature (°C) biases (departures from observations) averaged during 1982–2004 as simulated by CMM5, WRFG, WRF, and CWRF. Also shown is the CWRF/ERI biases averaged during 1990–2008.

Fig. 6.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) mean surface downwelling shortwave radiation flux (W m−2) biases (departures from observations) averaged during 1984–2004 as simulated by CMM5, WRFG, WRF, and CWRF .

Fig. 6.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) mean surface downwelling shortwave radiation flux (W m−2) biases (departures from observations) averaged during 1984–2004 as simulated by CMM5, WRFG, WRF, and CWRF .

The CWRF incorporates aerosol radiative effects. The direct effect is calculated from MISR monthly climatological mean data of the angstrom exponent, total aerosol optical depth and single scattering albedo, along with the MODIS asymmetry factor. These data are linearly interpolated in both time and space for instantaneous radiation calculation at model grids. The indirect effect is based on Martin et al. (1994) through modification on cloud effective radius, whereas the impact on precipitation is deactivated. The lack of the aerosol effects in the other RCMs explains less than one-quarter of their differences from CWRF shown in Fig. 6. A sensitivity experiment for year 1993 indicates that the aerosol effects reduce surface shortwave radiation flux by 5–20 W m−2 in CWRF, with peaks during spring in response to maximum loadings. This reduction is more uniformly distributed in space and much smaller in magnitude than the CWRF differences from other RCMs. The more realistic CWRF simulation of radiation results mainly from a better cloud prediction, along with the improved surface albedo parameterization.

Note that the driving LBCs' uncertainties have profound effects on the RCM downscaling skill. The ERI large-scale forcings enable CWRF to reproduce the precipitation and temperature patterns more realistically than those driven by the R-2 LBCs. The improvements are most obvious for precipitation over the Cascade Range during winter and spring (as discussed earlier), the Southeast in spring, and the Southern Great Plains in autumn, as well for temperature with general bias reductions especially in summer and autumn. The large sensitivity to driving conditions cautions that any serious fine-tuning of the RCM physics schemes must be made in conjunction with a rigorous assessment of the LBCs' uncertainties. Nonetheless, the GSFC radiation, CSSP surface, and ECP cumulus schemes, newly developed in CWRF, have certain advantages over their counterparts, producing overall smaller climate biases and better temporal correspondences. Their consistent integration is the key reason for the notable improvement in the downscaling skill of CWRF over the typical WRF physics configuration and also the well-established CMM5 (Liang et al. 2004b).

CWRF PERFORMANCE ON INTERANNUAL VARIATION.

Figure 7 compares seasonal spatial frequency distributions of pointwise correlation coefficients and rms errors of precipitation, surface air temperature, and downwelling shortwave radiation flux variations during 1982–2004 between observations and simulations by CWRF, WRF, WRFG, and CMM5. The statistics are based on monthly means for all land grids over the entire inner domain (excluding the buffer zones). As a general rule, the peak frequency occurring more to the right (left) indicates that the respective model simulation has more grids of higher correlations (smaller rms errors) with observations and hence is more realistic overall. The correlations measure the temporal correspondences, while the rms errors depict the magnitude differences between modeled and observed interannual variations. Clearly, WRFG's performance is the worst by both statistics in all seasons for all the three variables. This results partially from its use of a coarser horizontal resolution and a larger computational domain. For precipitation and temperature, the CWRF and WRF skills are comparable and slightly better than those of CMM5. By contrast, for radiation, CWRF exibits notable improvement to the others throughout the year, particularly as measured by rms errors.

Fig. 7.

Spatial frequency distributions of (top) correlations and (bottom) rms errors between simulated (CMM5, WRFG, WRF, CWRF) and observed monthly mean variations of PR (mm day−1), surface air temperature (T2M, K), and surface downwelling shortwave radiation flux (W m−2) in the four seasons (DJF, MAM, JJA, SON) during 1982–2004 (1984–2004 for radiation).

Fig. 7.

Spatial frequency distributions of (top) correlations and (bottom) rms errors between simulated (CMM5, WRFG, WRF, CWRF) and observed monthly mean variations of PR (mm day−1), surface air temperature (T2M, K), and surface downwelling shortwave radiation flux (W m−2) in the four seasons (DJF, MAM, JJA, SON) during 1982–2004 (1984–2004 for radiation).

Figure 8 compares, with observations, the CWRF and WRF-simulated annual cycles and the interannual variations of precipitation and soil moisture in the top 0.1-, 1-, and 2-m soil layers averaged over Illinois during 1984–2008. Clearly, the CWRF result is more realistic than that of WRF. For both annual cycle and interannual variation, correlation coefficients with observations are systematically higher as simulated by CWRF than by WRF. The enhancement is especially large for soil moisture, with correlation increases of 0.07–0.13. For the annual cycle, WRF overestimates the amplitude, increasingly so toward deeper soil and doubled in the top 2 m; but, its soil moisture is much drier than observations from summer to autumn (worst) to winter, and is associated with precipitation deficits. In contrast, the CWRF result is comparable to observations, with some overestimation in spring that is accompanied by precipitation excesses. For the interannual variation, CWRF tracks observations very well, with correlations of 0.74–0.78, whereas WRF overestimates the variability along with systematic drier conditions. The standard deviation ratio (simulated to observed) for the top 1-m soil moisture is 1.52 for WRF and 0.91 for CWRF, respectively, and for the top 2-m it is 1.88 and 1.23, respectively. Thus, CWRF generates not only more realistic phase (higher correlations) but also better amplitude (deviation ratios closer to 1) of the soil moisture seasonal–interannual variations throughout the root zone than WRF. This contrast mainly arises from the advanced representation of the terrestrial hydrology in CWRF using the CSSP surface scheme as compared to the WRF use of the Noah scheme. As demonstrated by Yuan and Liang (2011a) and the more recent comparison of offline integrations driven by observational reanalysis data, the CSSP has clear advantages in modeling the U.S. terrestrial hydrology (soil moisture, runoff) over its root models and the Noah scheme.

Fig. 8.

Monthly mean precipitation (mm day−1) and soil moisture (mm) for the top 0.1-, 1-, and 2-m soil layers averaged over Illinois as observed and simulated by the CWRF and WRF. Shown are (left) interannual variations, (right) annual cycles, and CC of simulations (WRF then CWRF) with observations.

Fig. 8.

Monthly mean precipitation (mm day−1) and soil moisture (mm) for the top 0.1-, 1-, and 2-m soil layers averaged over Illinois as observed and simulated by the CWRF and WRF. Shown are (left) interannual variations, (right) annual cycles, and CC of simulations (WRF then CWRF) with observations.

Figure 9 compares, with observations, the CWRF and WRF geographic distributions of interannual correlation coefficients of monthly mean anomalies (with the annual cycle removed) between surface air temperature and downwelling shortwave radiation during 1984–2004. Assuming monthly independence, correlation magnitudes greater than 0.248 are statistically significant at the 95% level. Observed surface temperature and radiation are positively correlated along the Great Plains throughout the year, most significantly during summer, when it extends to almost the entire domain except the southwestern United States. Positive (albeit weaker) correlations are also observed in spring and autumn over broad regions, including the western United States. For these regions, surface temperature changes largely in response to solar radiation forcing. Negative correlations are observed in winter over the northwestern and central-northeastern United States and adjacent Canadian regions, and in autumn over the southeastern United States. These negative relationships likely result from the snow–albedo feedback (warmer temperatures causing more snowfall, reflecting more radiation) in northern latitudes and from the convection–cloud feedback (warmer temperatures causing more convective cloud, reflecting more radiation) in low latitudes. The CWRF realistically captures these observed patterns but overestimates the strength of winter negative and summer positive correlations. The WRF simulation is overall less realistic, where it overestimates negative correlations over more extensive regions in both winter and autumn, and even during spring, when they are absent in both observations and the CWRF simulation.

Fig. 9.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) averaged interannual correlation coefficients of monthly mean anomalies (with the annual cycle removed) during 1984–2004 between surface air temperature (T2M) and SWD OBS and simulated by CWRF and WRF, as well as those simulated between PR and SM 200.

Fig. 9.

The geographic distributions of seasonal (DJF, MAM, JJA, SON) averaged interannual correlation coefficients of monthly mean anomalies (with the annual cycle removed) during 1984–2004 between surface air temperature (T2M) and SWD OBS and simulated by CWRF and WRF, as well as those simulated between PR and SM 200.

Figure 9 also compares CWRF- and WRF-simulated correlations between precipitation and the top 2-m soil moisture anomalies during 1984–2004. Both models produce mainly positive correlations, that is, more precipitation is associated with wetter soil moisture. Significant correlations are generated by CWRF in winter, spring, summer, and autumn over 61%, 78%, 94%, and 87% of land grids, respectively, compared to 46%, 60%, 72%, and 61% of land grids, respectively, by WRF. In particular, CWRF simulates large correlations in spring and summer over Mexico and the Great Plains, where strong land– atmosphere coupling has been identified (Koster et al. 2004). The WRF, however, generates rather weak correlations. Such relationships, having important consequences on regional hydrology and climate prediction, require verification with future available observations for soil moisture distributions.

CWRF PHYSICS ENSEMBLE PREDICTION—A CAPABILITY TEST.

The CWRF incorporates a massive suite of alternative numerical schemes for microphysics, convection, cloud, aerosol, radiation, surface, turbulence, and transport processes, all of which are fully coupled with nonlinear interactions. The CWRF downscaling can significantly reduce the biases of the driving global reanalyses (e.g., Figs. 3 and 4) or climate models (e.g., Yuan and Liang 2011b). The skill enhancement, however, is sensitive to model physics configurations, and no single combination of the available schemes can adequately simulate all key aspects of the observed climate system. Various physics schemes work better in different regions with distinct climate regimes. Consensus predictions based on an ensemble of multiple physics configurations may offer significant skill enhancement (Liang et al. 2007; Zeng et al. 2008a; Liu et al. 2009). A preliminary test demonstrating the capability of the CWRF physics ensemble to improve precipitation prediction at regional–local scales was conducted.

The test uses a limited subset of the CWRF full ensemble, focusing on the control configuration (same as used in the 1979–2009 simulation presented in the previous sections) and all major alternative schemes across each physics driver, altered one at a time; a total of 26 configurations were modeled. Table S1 lists, for each driver, these alternative schemes and their key references (see supplementary material for exact citations). Each simulation is driven by the R-2 LBCs and integrated from 1 November 1992 to 31 December 1993, with the initial two months used as a model spinup. During the 1993 summer, record flooding occurred in the Mississippi River basin. This extreme event has been associated with physical mechanisms at both the planetary and regional–local scales (e.g., Kunkel et al. 1994) and thus is an ideal case for evaluation of the RCMs' performance (Liang et al. 2001).

Figure 10 illustrates the spatial frequency distributions of pointwise correlation coefficients and rms errors of daily mean rainfall variations between observations and simulations by CWRF for the 26 physics configurations. The statistics are shown in five color groups, each containing the tested schemes of a specific physics driver. Shown also are the ensemble results as the averages of all runs with either equal or optimal weights. The latter is computed based on the local minimization of rms errors in an entire season, and the skill score depicts the upper limit of daily rainfall predictability that can be achieved from the best optimization of the ensemble. Clearly, the equal-weight ensemble average of alternative physics configurations substantially increases the predictive skill over all individual schemes, with more frequent occurrences of higher correlation coefficients and smaller rms errors. The skill enhancement is most pronounced in summer, followed by autumn and spring, but rather weak in winter.

Fig. 10.

Spatial frequency distributions of (left) correlations and (right) rms errors between CWRF and OBS daily mean rainfall variations in the four seasons (DJF, MAM, JJA, SON) of 1993 for all the model physics configurations listed in Table S1. Each line depicts a specific configuration in groups of the five key physical processes (color). The ENS is the average of all runs with AVE or OPT weights, shown as a black solid or dashed line, respectively.

Fig. 10.

Spatial frequency distributions of (left) correlations and (right) rms errors between CWRF and OBS daily mean rainfall variations in the four seasons (DJF, MAM, JJA, SON) of 1993 for all the model physics configurations listed in Table S1. Each line depicts a specific configuration in groups of the five key physical processes (color). The ENS is the average of all runs with AVE or OPT weights, shown as a black solid or dashed line, respectively.

The CWRF overall performance is very similar among all the individual configurations except for those using CSU, GFDL, MIT and ZML cumulus schemes. These schemes happen to be widely used in the latest global GCMs. They underestimate total precipitation and have poorer daily correspondence with observations, leading to systematically larger rms errors and lower correlations than the ECP, BMJ and NKF schemes typically used in mesoscale RCMs. In contrast, their removal actually reduces the ensemble average skill. Hence, these schemes contain certain regional signals that are complementary to others.

The ensemble average using the localized optimal weights has predictive skill significantly higher than that using the equal weight as well as the individuals throughout the entire year. Thus, there exists substantial room to further enhance that skill through intelligent optimization. This optimized physics ensemble downscaling approach provides a promising pathway for skill enhancement of predicting weather and climate, especially precipitation, at regional–local scales (Zeng et al. 2008a; Yuan and Liang 2011b; Yuan et al. 2012). We intend to explore various posterior optimization methods, including Liang et al. (2007), Kug et al. (2008), and Lee et al. (2011), to maximize the ensemble predictive skill. These methods are posterior because they are based on postsimulation composite analyses of multiple model outputs rather than improving a specific model physics configuration or a particular parameterization. Given that an individual scheme's performance is regime dependent, a better result is achievable through dynamic optimization of an overall predictive system. A good example of this concept is the ECP cumulus scheme modified from Grell and Dévényi (2002) that utilizes a suite of alternative closure assumptions. In principle, this approach applies an ensemble of cumulus parameterizations at every time step and at each grid point, and then feeds back the average of all solutions to the predictive system. The current ECP implements the moisture convergence plus cloud work function closures with an equal weight over land and the cloud work function closure only over ocean, and then feeds back the ensemble result to interact with the other processes of CWRF. Such a dynamic approach can be expanded to construct an optimized CWRF predictive system that consists of an ensemble of multiple alternative schemes for each physics driver with appropriate regime-specific weights. These weights can be derived from retrospective predictions made with individual schemes and functional relationships established with static (geographic distribution, such as land vs ocean) or dynamic (spatiotemporal distribution, such as model-resolvable variables) quantities. The derivation will involve forecast error analysis and inverse modeling to minimize the model-toobservation differences. In this regard, advanced data assimilation techniques, such as LETKF (Hunt et al. 2007), will play a critical role.

SUMMARY AND DISCUSSION.

The goal of the CWRF development has been to achieve a regional modeling system that can be applied seamlessly to weather forecast and climate prediction as well as to climate impacts assessment at regional–local scales. The CWRF has been built on three main principles, emphasizing 1) an extension of WRF to capitalize on the broad community efforts for all weather forecast functionalities while enhancing credible climate prediction capabilities; 2) a capability to use a grand ensemble of alternative schemes for key physical processes and their interactions to improve predictive skills through optimization against observations while providing robust uncertainty estimates; and 3) a service capability to provide impact-relevant information, including terrestrial hydrology, coastal ocean, crop growth, ecosystem, air quality, and water quality. The resulting CWRF is the state-of-the-science model that incorporates a comprehensive collection of interactive physics configurations fully exchangeable and capable of ensemble prediction and system optimization for general applications at a wide range of temporal and spatial scales.

The CWRF performance was evaluated over land areas of the contiguous United States plus southern Canada and northern Mexico using a continuous integration driven by R-2 during 1979–2009 and compared with those of CMM5 (Liang et al. 2004b) and the original WRF, and also a similar run of WRFG based on the earlier WRF version 2 over an extended domain of relatively coarse grid spacing (Leung et al. 2011). The CWRF's control physics configuration, not available in WRF, consists of the GSFC radiation, CSSP-land-plus-UOM-ocean surface, CAM-eddy-plus-ORO-orography PBL, ECP-deep-plus-UW-shallow cumulus, and GSFC GCE microphysics schemes. Compared to the other RCMs, CWRF more realistically reproduces the principal characteristics of the observed geographic distributions, seasonal–interannual variations, and coupled relationships among key variables, including surface air temperature, surface downwelling shortwave radiation flux, and Illinois soil moisture. However, accurate simulation of precipitation in all seasons and regions remains a challenge for all of the tested models. Further studies will evaluate other aspects of the model performance, including precipitation diurnal cycle, frequency distribution and extreme events, surface wind, terrestrial hydrology, energy partitioning, as well as responses to external (natural or anthropogenic) forcing and contrasts between land and ocean.

A preliminary test demonstrated the capability of a physics ensemble approach to improve precipitation prediction at regional–local scales. It involved a total of 26 selected key physics configurations, each with a simulation for year 1993, when the record summer flood occurred over the U.S. Midwest. These configurations represent a small subset (from a system of 1024 choices), focusing on only the control configuration and major alternative schemes, altered one at a time, across each physics driver of radiation, surface, PBL, cumulus, and microphysics processes. The ensemble average of these configurations using an equal weight substantially increases the predictive skill of daily rainfall variations over all individuals. The skill enhancement, with increased occurrence of higher correlation coefficients and smaller rms errors, is most pronounced during summer, followed by autumn and spring, but rather weak in winter. There exists, however, substantial room to further enhance that skill through intelligent optimization of the ensemble, especially for precipitation.

The advances in both physics formulations and predictive skills documented above justify the initial release of CWRF for community use (http://cwrf.umd.edu). We plan to update CWRF following future new WRF releases with identical model version numbers. Because of the lack of funding for model development and user support, these updates are expected to be less frequent than those for WRF. It is hoped that CWRF, with a comprehensive but expandable ensemble of alternative physics schemes, will facilitate fundamental progress on quantitative understanding and probabilistic prediction of climate variability and change at regional–local scales. A critical need for cost-effective modeling is to define a viable subset of the ensemble with a computationally feasible and manageable size that best captures the full range of observed climate processes. An initial but substantial reduction in the choices of CWRF configurations for consideration can be made through basic knowledge of the prevailing physical processes that dominate regional climate variations over the domain of interest. Further reduction can be obtained via CWRF sensitivity experiments for certain weather or climate systems typical of the region. Intelligent optimization against observations can then be sought to create the optimized physics ensemble that incorporates statistical or dynamic weights to account for the relative contributions of individual members depending on climate regimes. This will improve the fidelity of climate change predictions and their utility for impacts assessment and strategic planning. The developed ensemble of alternative physics schemes in CWRF can be applied to other regional as well as global climate models at similar mesoscale resolutions. Its general application, however, requires accurate specification of the most comprehensive surface boundary conditions, some of which are not readily available. This requirement arises from the necessary coupling with the advanced CSSP that significantly improves the simulation of terrestrial hydrology processes. The actual performance of the ensemble and its individual members also will inevitably depend on model resolution. These issues, both scientific and technical, will be the focus of future studies.

Acknowledgments

We acknowledge the WRF developers for the integrated effort making this model available as the excellent base from which CWRF has been developed; the PRISM group at Oregon State University for precipitation data with topographic correction; Ruby Leung for the WRFG simulation; and Arthur Samel, Gary Lackmann (editor), and two anonymous reviewers for their constructive comments and suggestions for improving the manuscript. This research was supported by the state of Illinois through the CAQIMS modeling program, the NOAA Education Partnership Program (EPP) subaward COM Howard 631017 and Climate Prediction Program for the Americas (CPPA) Grants NA08OAR4310575 and NA08OAR4310875, the EPA Science to Achieve Results (STAR) Grants RD-83337302 and RD-83418902, the DOE Office of Biological and Environmental Research (BER) Grant DE-SC0001683, the Colorado State University UV-B Monitoring and Research Program subaward USDACSREES- 2009-34263-19774 (G-1449-1), the NASA Grant NNX08AL94G, the National Science Foundation (NSF) Grants ATM 06–28687 and DMS 07–24752, the China National Basic Research Program Grant 2010CB951603, and the Shanghai Science and Technology Support Program Grant 10DZ0581600. The model simulations were conducted at the DOE/NERSC, NOAA/ESRL, and UIUC/NCSA supercomputing facilities. The views expressed are those of the authors and do not necessarily reflect those of the sponsoring agencies.

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APPENDIX: ABBREVIATIONS AND ACRONYMS

     
  • 3D

    Three dimensional

  •  
  • ACM

    Asymmetric convective model

  •  
  • AER

    Atmospheric and Environmental Research

  •  
  • AMIP

    Atmospheric Model Intercomparison Project

  •  
  • AvCL

    Averaged cloud properties for radiation calculation

  •  
  • AVE

    Ensemble result by average

  •  
  • AVHRR

    Advanced Very High Resolution Radiometer

  •  
  • BEP

    Building Environment Parameterization (multilevel urban model)

  •  
  • BL

    CWRF PBL physics driver

  •  
  • BMJ

    Betts–Miller–Janjić cumulus parameterization

  •  
  • BouLac

    Bougeault–Lacarrère PBL scheme

  •  
  • CAM NCAR

    Community Atmosphere Model

  •  
  • CAR CWRF

    cloud–aerosol–radiation ensemble modeling system

  •  
  • CAWCR

    Centre for Australian Weather and Climate Research

  •  
  • CC

    Correlation coefficients

  •  
  • CCCMA

    Canadian Centre for Climate Modelling and Analysis

  •  
  • CCM2

    NCAR Community Climate Model, version 2

  •  
  • CMM5

    Climate extension of the fifth-generation PSU–NCAR Mesoscale Model version 5

  •  
  • Const DIF

    Constant diffusion scheme

  •  
  • CPC

    NOAA Climate Prediction Center

  •  
  • CROP

    Dynamic crop growth modeling system

  •  
  • CSSP

    Conjunctive Surface–Subsurface Process Model

  •  
  • CSU

    Colorado State University

  •  
  • CRU

    Climate Research Unit

  •  
  • CU

    CWRF cumulus physics driver

  •  
  • CWRF

    Climate extension of the WRF

  •  
  • DJF

    December–February

  •  
  • DOE

    U.S. Department of Energy

  •  
  • DST/DSSAT

    Decision Support System for Agrotechnology Transfer (crop models)

  •  
  • ECMWF

    European Centre for Medium-Range Weather Forecasts

  •  
  • ECP

    Ensemble cumulus parameterization modified from G3

  •  
  • ENS

    Ensemble result

  •  
  • ERI

    Global Interim ECMWF Re-Analysis

  •  
  • FLG

    Fu–Liou–Gu radiation transfer scheme

  •  
  • G3

    Grell 3D ensemble cumulus parameterization

  •  
  • GCE

    Goddard Cumulus Ensemble parameterization

  •  
  • GCM

    General Circulation Model

  •  
  • GD

    Grell–Dévényi ensemble cumulus parameterization

  •  
  • GFDL

    Geophysical Fluid Dynamics Laboratory

  •  
  • GFS

    NOAA Global Forecast System

  •  
  • GR

    Grell cumulus parameterization

  •  
  • GSFC

    NASA Goddard Space Flight Center

  •  
  • GSY

    Gossypium cotton growth model

  •  
  • HIR

    High-resolution PBL scheme

  •  
  • ISCCP

    International Satellite Cloud Climatology Project

  •  
  • JJA

    June–August

  •  
  • Kessler

    Kessler microphysics scheme

  •  
  • L2.5 TKE

    2.5-order TKE diffusion scheme

  •  
  • L2 3D DEF

    2-order 3D deformation and stability diffusion scheme

  •  
  • LBCs

    Lateral boundary conditions

  •  
  • LETKF

    Local ensemble transform Kalman filter

  •  
  • Lin

    Lin et al. microphysics scheme

  •  
  • LW

    Longwave

  •  
  • MAM

    March–May

  •  
  • MISC

    Miscellaneous (obsolete) radiation schemes

  •  
  • MISR

    Multiangle Imaging SpectroRadiometer

  •  
  • MIT

    Massachusetts Institute of Technology

  •  
  • MODIS

    Moderate Resolution Imaging Spectroradiometer

  •  
  • Morrison

    Morrison et al. two-moment microphysics scheme

  •  
  • MP

    CWRF microphysics driver

  •  
  • MRF

    Medium-Range Forecast Model

  •  
  • MYJ

    Mellor–Yamada–Janjić PBL scheme

  •  
  • MYNN

    Mellor–Yamada PBL scheme modified by Nakanishi–Niino

  •  
  • NAM

    North American monsoon

  •  
  • NARCCAP

    North American Regional Climate Change Assessment Program

  •  
  • NASA

    National Aeronautics and Space Administration

  •  
  • NCAR

    National Center for Atmospheric Research

  •  
  • NCEP

    National Centers for Environmental Prediction

  •  
  • NKF

    New Kain–Fritsch cumulus parameterization

  •  
  • NOAA

    National Oceanic and Atmospheric Administration

  •  
  • Noah

    NCAR–NCEP unified land surface model

  •  
  • NSAS

    New Simplified Arakawa-Schubert scheme

  •  
  • NWP

    Numerical weather prediction

  •  
  • OBS

    Observed

  •  
  • OCN

    SfcExt for ocean characteristics

  •  
  • OPT

    Ensemble result by optimization

  •  
  • ORO

    Module for orographic turbulence stress and gravity wave drag

  •  
  • OSU

    Oregon State University

  •  
  • PBL

    Planetary boundary layer

  •  
  • PR

    Precipitation

  •  
  • PSU

    Pennsylvania State University

  •  
  • PX

    Pleim-Xiu land surface scheme

  •  
  • QNSE

    Quasi-normal scale elimination PBL scheme

  •  
  • R-2

    NCEP–DOE AMIP-II Reanalysis

  •  
  • RA

    CWRF radiation physics driver

  •  
  • RadExt

    CWRF module for external radiative conditions (solar constant, atmospheric gas volume mixing ratios, aerosol distributions)

  •  
  • RCM

    Regional climate model

  •  
  • RMS/rms

    Root-mean-square

  •  
  • RUC

    Rapid Update Cycle

  •  
  • SAS

    Simplified Arakawa–Schubert scheme

  •  
  • SBCs

    Surface boundary conditions

  •  
  • SF

    CWRF surface physics driver

  •  
  • SfcExt

    CWRF module for external surface and subsurface conditions

  •  
  • Slab

    5-layer thermal diffusion model

  •  
  • SM200

    Top 2-m soil moisture

  •  
  • SOM

    Simple ocean model

  •  
  • SON

    September–November

  •  
  • SST

    SfcExt for sea surface temperature

  •  
  • SW

    Shortwave

  •  
  • SWD

    Downwelling shortwave

  •  
  • T2M

    2-m temperature

  •  
  • Tao

    Tao et al. microphysics scheme

  •  
  • TDK

    Tiedtke cumulus scheme

  •  
  • TEMF

    Total energy–mass flux boundary layer scheme (Angevine et al. 2001)

  •  
  • Thompson

    Thompson et al. microphysics scheme

  •  
  • TKE

    Turbulent kinetic energy

  •  
  • TS

    Time series

  •  
  • UCM

    Single layer urban canopy model

  •  
  • UOM

    Multilevel upper-ocean model

  •  
  • U.S.

    United States

  •  
  • USGS

    U.S. Geological Survey

  •  
  • UV

    Ultraviolet radiation

  •  
  • UW

    University of Washington

  •  
  • VEG

    SfcExt for vegetation characteristics

  •  
  • WDM6

    WRF Double-Moment 6-class microphysics scheme

  •  
  • WSM5

    WRF Single-Moment 5-class microphysics scheme

  •  
  • WSM6

    WRF Single-Moment 6-class microphysics scheme

  •  
  • WRF

    Weather Research and Forecasting model

  •  
  • WRFG

    WRF version 2 with the GD cumulus scheme

  •  
  • WSM3

    WRF Single-Moment 3-class scheme

  •  
  • YSU

    Yonsei University

  •  
  • Zhao

    Eta microphysics scheme

  •  
  • ZML

    Zhang–McFarlane–Liang cumulus scheme

Footnotes

*CURRENT AFFILIATION: National Renewable Energy Laboratory, Golden, Colorado

A supplement to this article is available online (DOI: 10.1175/BAMS-D-11-00180.2)

1

For the purpose of conciseness, this paper uses many abbreviations and acronyms. All the physics schemes actually used in this study with their respective references are listed in the supplementary material or otherwise listed in the appendix of this paper. Note also that several schemes, including AER and FLG radiation and UW and ZML cumulus, have been added to the latest WRF release. They are, however, implemented differently with numerous variations in CWRF.

2

Note that the WRF can be configured to many versions using different combinations of physics schemes. The reported WRF configurations are limited. The statement was drawn from our own experience with the WRF runs and through review of several journal manuscripts of others.

Supplemental Material