The High-Resolution Rapid Refresh (HRRR): An Hourly Updating Convection-Allowing Forecast Model. Part I: Motivation and System Description

Dowell, David C.; Alexander, Curtis R.; James, Eric; Weygandt, Stephen S.; Benjamin, Stanley G.; Manikin, Geoffrey S.; Blake, Benjamin T.; Brown, John M.; Olson, Joseph B.; Hu, Ming; Smirnova, Tatiana G.; Ladwig, Terra; Kenyon, Jaymes S.; Ahmadov, Ravan; Turner, David D.; Duda, Jeffrey D.; Alcott, Trevor I.

doi:10.1175/waf-d-21-0151.1

Cited by 76 publications

(52 citation statements)

References 107 publications

(74 reference statements)

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“…Additional understanding through emerging technological tools in early NWP (Lavoie, 1972) and maturing operational NWP (Niziol et al, 1995) certainly assisted forecasters in the United States to better anticipate small‐scale convective snowstorms. As numerical guidance has progressed into the current generation of high‐resolution models that allow representation of convections (so‐called Convection Allowing Models or CAMs), greater detail of convective storm behavior can at least be partially represented, which can help forecasters communicate event specifics (Benjamin et al, 2016; Dowell et al, 2022; Olsson et al, 2018). Furthermore, available computational resources are now sufficient to support multiple simulations for a forecast cycle using such a high‐resolution model in an operational environment.…”

Section: Evolution Of Forecast Methodsmentioning

confidence: 99%

“…F I G U R E A Evaporation from Lake Erie and resulting lake-effect snow band, a view from the City Hall of Buffalo, NY, November 18, 2014 (Derek Gee/Buffalo News) representation of convections (so-called Convection Allowing Models or CAMs), greater detail of convective storm behavior can at least be partially represented, which can help forecasters communicate event specifics (Benjamin et al, 2016;Dowell et al, 2022;Olsson et al, 2018). Furthermore, available computational resources are now sufficient to support multiple simulations for a forecast cycle using such a high-resolution model in an operational environment.…”

Section: Evolution Of Forecast Methodsmentioning

confidence: 99%

“…This makes it difficult to accurately represent them in a single modeling framework. In most operational settings, at the time of writing, the highest resolution models are using an approximately 3 km horizontal grid (Benjamin et al, 2016; Dowell et al, 2022). The Warn‐on‐Forecast methods developed by the National Oceanic and Atmospheric Administration (NOAA) even utilize 1 km grid spacing over selected domains and short forecast periods of a few hours.…”

Section: Challenges For Forecastingmentioning

confidence: 99%

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Forecasting lake‐/sea‐effect snowstorms, advancement, and challenges

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Lake-/sea-effect snow forms typically from late fall to winter when a cold air mass moves over the warmer, large water surface. The resulting intense snowfall has many societal impacts on communities living in downwind areas; hence, accurate forecasts of lake-/sea-effect snow are essential for safety and preparedness. Forecasting lake-/sea-effect snow is extremely challenging, but over the past decades the advancement of numerical forecast models and the expansion of observational networks have incrementally improved the forecasting capability. The recent advancement includes numerical forecast models with high spatiotemporal resolutions that allow simulating vigorous snowstorms at the kilometer-scale and the frequent inclusion of radar observations in the model. This combination of more accurate weather prediction models as well as ground-based and remotely sensed observations has aided operational forecasters to make better lake-/sea-effect snow forecasts. A remaining challenge is that many observations of precipitation, surface meteorology, evaporation, and heat supply from the water surface are still limited to being landbased and the information over the water, particularly offshore, remains a gap.This primer overviews the basic mechanisms for lake-/sea-effect snow formation, evolution of forecast techniques, and challenges to be addressed in the future.This article is categorized under: • Science of Water > Water Extremes • Science of Water > Water and Environmental Change • Science of Water > Methods K E Y W O R D S extreme weather, lake-effect snow, numerical model, sea-effect snow, weather forecast

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Section: Evolution Of Forecast Methodsmentioning

confidence: 99%

Section: Evolution Of Forecast Methodsmentioning

confidence: 99%

Section: Challenges For Forecastingmentioning

confidence: 99%

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Forecasting lake‐/sea‐effect snowstorms, advancement, and challenges

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“…Besides the conduction of a comprehensive 18-month long field campaign (Wilczak et al, 2019) and the development of support tools to assist the industry in wind power forecasting, model development efforts were a key component of WFIP2 (Olson et al, 2019b). The basis for the model developments were NOAA's Rapid Refresh (RAP, Benjamin et al (2016)) and High-Resolution Rapid Refresh (HRRR, Dowell et al (2022)) models. In this study, we used three different versions of the HRRR model to evaluate how the model developments impacted the characteristics of a strong and persistent cold pool event in the Columbia River Basin, which occurred within a 10-day period from 10-19 January 2017.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of a cloudy cold-air pool in the Columbia River Basin in different versions of the HRRR model

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Wilczak

Kenyon

et al. 2022

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Abstract. The accurate forecast of persistent orographic cold-air pools in numerical weather prediction models is essential for the optimal integration of wind energy into the electrical grid during these events. Model development efforts during the Second Wind Forecast Improvement Project (WFIP2) aimed to address the challenges also related to this. We evaluated three different versions of NOAA's High-Resolution Rapid Refresh model with two different horizontal grid spacings against in situ and remote sensing observations to investigate how developments in physical parameterizations and numerical methods targeted during WFIP2 impacted the simulation of a persistent cold-air pool in the Columbia River Basin. Differences between the different model versions were in particular visible in the simulated temperature and low-level cloud fields. The model developments led to an enhanced low-level cloud cover in the cold pool, resulting in better agreement with the observations. This removed a diurnal cycle in the near-surface temperature bias at stations throughout the basin by reducing a cold bias during the night and a warm bias during the day. However, low-level clouds did not clear sufficiently during daytime in the newest model version, which led to a warm bias near-the surface during the second night of the reforecasts and leaves room for further model developments. Besides the improvements during the persistent phase of the cold pool, the model developments also led to a better representation of its decay by slowing down its erosion.

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“…Thus, a second major improvement in 2020 with lake representation in the NOAA 3 km HRRR model occurred with the implementation of lagged data coupling with the 3-D hydrodynamic-ice model for the much larger Laurentian Great Lakes as described by Fujisaki-Manome et al (2020). These new improved lake treatments are in the newer HRRR version 4 (HRRRv4) replacing the previous HRRRv3 (differences described in Dowell et al, 2022;hereafter D22).…”

Section: Introductionmentioning

confidence: 99%

Inland lake temperature initialization via coupled cycling with atmospheric data assimilation

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Abstract. Application of lake models coupled within earth-system prediction models, especially for predictions from days to weeks, requires accurate initialization of lake temperatures. Commonly used methods to initialize lake temperatures include interpolation of global sea-surface temperature (SST) analyses to inland lakes, daily satellite-based observations, or model-based reanalyses. However, each of these methods have limitations in capturing the temporal characteristics of lake temperatures (e.g., effects of anomalously warm or cold weather) for all lakes within a geographic region and/or during extended cloudy periods. An alternative lake-initialization method was developed which uses two-way-coupled cycling of a small-lake model within an hourly data assimilation system of a weather prediction model. The lake model simulated lake temperatures were compared with other estimates from satellite and in situ observations and interpolated-SST data for a multi-month period in 2021. The lake cycling initialization, now applied to two operational US NOAA weather models, was found to decrease errors in lake surface temperature from as much as 5–10 K vs. interpolated-SST data to about 1–2 K compared to available in situ and satellite observations.

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The High-Resolution Rapid Refresh (HRRR): An Hourly Updating Convection-Allowing Forecast Model. Part I: Motivation and System Description

Cited by 76 publications

References 107 publications

Forecasting lake‐/sea‐effect snowstorms, advancement, and challenges

Forecasting lake‐/sea‐effect snowstorms, advancement, and challenges

Evaluation of a cloudy cold-air pool in the Columbia River Basin in different versions of the HRRR model

Inland lake temperature initialization via coupled cycling with atmospheric data assimilation

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