An Explanation for the Sensitivity of the Mean State of the Community Atmosphere Model to Horizontal Resolution on Aquaplanets

Herrington, Adam; Reed, Kevin A.

doi:10.1175/jcli-d-16-0069.1

Cited by 23 publications

(51 citation statements)

References 50 publications

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“…It is plausible, however, that a less intuitive relationship between divergence damping and precipitation may emerge in a more realistic configuration, acknowledging that Zhao et al () have reported on a counterintuitive relationship to tropical storm genesis. In our aqua‐planet simulations, the ITCZ, in part, consists of underresolved, deep convective towers simulated by the resolved dynamics, consistent with a prior study of CAM‐HOMME (Herrington & Reed, ). The base of the convective towers often originates within the boundary layer, with convergent flow‐driving resolved upward mass fluxes through the cloud base.…”

Section: Resultssupporting

confidence: 77%

NCAR Release of CAM‐SE in CESM2.0: A Reformulation of the Spectral Element Dynamical Core in Dry‐Mass Vertical Coordinates With Comprehensive Treatment of Condensates and Energy

Lauritzen

Nair

Herrington

et al. 2018

J Adv Model Earth Syst

121

152

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It is the purpose of this paper to provide a comprehensive documentation of the new NCAR (National Center for Atmospheric Research) version of the spectral element (SE) dynamical core as part of the Community Earth System Model (CESM2.0) release. This version differs from previous releases of the SE dynamical core in several ways. Most notably the hybrid sigma vertical coordinate is based on dry air mass, the condensates are dynamically active in the thermodynamic and momentum equations (also referred to as condensate loading), and the continuous equations of motion conserve a more comprehensive total energy that includes condensates. Not related to the vertical coordinate change, the hyperviscosity operators and the vertical remapping algorithms have been modified. The code base has been significantly reduced, sped up, and cleaned up as part of integrating SE as a dynamical core in the CAM (Community Atmosphere Model) repository rather than importing the SE dynamical core from High‐Order Methods Modeling environment as an external code.

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Section: Resultssupporting

confidence: 77%

NCAR Release of CAM‐SE in CESM2.0: A Reformulation of the Spectral Element Dynamical Core in Dry‐Mass Vertical Coordinates With Comprehensive Treatment of Condensates and Energy

Lauritzen

Nair

Herrington

et al. 2018

J Adv Model Earth Syst

121

152

View full text Add to dashboard Cite

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“…The ne30_NE30TP and the RRM_NE30TP simulations have similar total precipitable water, cloud water path, surface evaporation, total precipitation rate, and precipitation efficiency; in contrast, the RRM_NE120TP simulations have clearly higher cloud water path, lower surface evaporation, lower total precipitation rate, and lower precipitation efficiency. The convective precipitation ratio is reduced as the model horizontal resolution increases and the time step decreases in both CAPT and AMIP simulations, which is consistent with previous studies (e.g.,Bacmeister et al, ; Herrington & Reed, ; Tang et al, ). Williamson () argued that if the model time step becomes too short compared with the relaxation time scales in the convection schemes, the extreme precipitation from intense, truncation‐scale storms will increase.…”

Section: Resultsmentioning

confidence: 99%

The Summertime Precipitation Bias in E3SM Atmosphere Model Version 1 over the Central United States

et al. 2019

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This study analyzes the summertime precipitation bias over the Central United States and its relationship to the simulated large‐scale environment and the convection scheme in the Energy Exascale Earth System Model Atmosphere Model version 1. This relationship is mainly examined in a set of short‐term hindcasts initialized with realistic large‐scale conditions for the summer of 2011. Besides the uniform 1° model resolution, we adopt Regionally Refined Meshes to increase the model resolution to 0.25° over the contiguous United States. Additional five‐year Atmospheric Model Intercomparison Project simulations are conducted to confirm that the results from the hindcasts are consistent with the climate runs. We find that the summertime dry precipitation bias over the Great Plains and the wet bias over the Rockies cannot be reduced simultaneously by changing resolution or tuning parameters. As for the diurnal cycle, Energy Exascale Earth System Model Atmosphere Model version 1 captures the general diurnal variation of the large‐scale moisture transport and the large‐scale upward motion over the Central United States. However, the diurnal cycle of precipitation over the Great Plains is out of phase with the diurnal variation of the large‐scale environment because the convective precipitation dominates the total precipitation and its diurnal cycle, and it does not directly respond to the local moisture convergence and the large‐scale upward motion. These results reemphasize the importance of improving the coupling of the convection to the large‐scale environment in reducing the summer precipitation bias over the Central United States in climate models with the resolution of ~0.25°.

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“…One proposal to alleviate this issue is to push climate models to the highest grid‐spacings possible, typically utilizing modern exascale computing systems (Reed & Dongarra, ). This has resulted in a recent surge in research and development addressing multi‐scale modeling (Iorio et al, ; O'Brien et al, ; Tao et al, ), scale‐aware physics (Fan et al, ; Gross et al, ; Herrington & Reed, ; Randall et al, ), and atmospheric models that span hydrostatic and nonhydrostatic scales (Ferguson et al, ; Heinzeller et al, ; Herrington & Reed, ; Park et al, ).…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of Mountain Hydroclimate Simulations in Variable‐Resolution CESM to Microphysics and Horizontal Resolution

Rhoades

Ullrich

Zarzycki

et al. 2018

J Adv Model Earth Syst

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Mountains are natural dams that impede atmospheric moisture transport and water towers that cool, condense, and store precipitation. They are essential in the western United States where precipitation is seasonal, and snowpack is needed to meet water demand. With anthropogenic climate change increasingly threatening mountain snowpack, there is a pressing need to better understand the driving climatological processes. However, the coarse resolution typical of modern global climate models renders them largely insufficient for this task, and signals a need for an advanced strategy. This paper continues the assessment of variable‐resolution in the Community Earth System Model (VR‐CESM) in modeling mountain hydroclimatology to understand the role of grid‐spacing at 55, 28, 14, and 7 km and microphysics, specifically the Morrison and Gettelman (, MG1, https://doi.org/10.1175/2008JCLI2105.1) scheme versus the Gettelman and Morrison (, MG2, https://doi.org/10.1175/JCLI-D-14-00102.1) scheme. Eight VR‐CESM simulations were performed from 1999 to 2015 with the F_AMIP_CAM5 component set, which couples the atmosphere‐land models and prescribes ocean data. Refining horizontal grid‐spacing from 28 to 7 km with the MG1 scheme did not improve the simulated mountain hydroclimatology. Substantial improvements occurred with the use of MG2 at grid‐spacings ≤28 km compared to MG1 as shown with subsequent statistics. Average SWE bias diminished by 9.4X, 4.9X, and 3.5X from 55 to 7 km. The range in minimum (maximum) DJF spatial correlations increased by 0.1–0.2 in both precipitation and SWE. Mountain windward/leeward distributions and elevation profiles improved across hydroclimate variables, however not always with model resolution alone. Disconcertingly, all VR‐CESM simulations exhibited a systemic mountain cold bias that worsened with elevation and will require further examination.

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An Explanation for the Sensitivity of the Mean State of the Community Atmosphere Model to Horizontal Resolution on Aquaplanets

Cited by 23 publications

References 50 publications

NCAR Release of CAM‐SE in CESM2.0: A Reformulation of the Spectral Element Dynamical Core in Dry‐Mass Vertical Coordinates With Comprehensive Treatment of Condensates and Energy

NCAR Release of CAM‐SE in CESM2.0: A Reformulation of the Spectral Element Dynamical Core in Dry‐Mass Vertical Coordinates With Comprehensive Treatment of Condensates and Energy

The Summertime Precipitation Bias in E3SM Atmosphere Model Version 1 over the Central United States

Sensitivity of Mountain Hydroclimate Simulations in Variable‐Resolution CESM to Microphysics and Horizontal Resolution

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