Your search keyword '"Linjiong Zhou"' showing total 61 results

1. The Vertical Structure of Tropical Temperature Change in Global Storm‐Resolving Model Simulations of Climate Change

Author

Timothy M. Merlis, Ilai Guendelman, Kai‐Yuan Cheng, Lucas Harris, Yan‐Ting Chen, Christopher S. Bretherton, Maximilien Bolot, Linjiong Zhou, Alex Kaltenbaugh, Spencer K. Clark, and Stephan Fueglistaler

Subjects

Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Global storm‐resolving model (GSRM) simulations (kilometer‐scale horizontal resolution) of the atmosphere can capture the interaction between the scales of deep cumulus convection and the large‐scale dynamics and thermodynamic properties of the atmosphere. Here, we assess the vertical structure of tropical temperature change in Geophysical Fluid Dynamics Laboratory's GSRM X‐SHiELD, perturbed by a uniform sea surface temperature (SST) warming and/or increased CO2 concentration. The simulated warming from an SST increase is weakly amplified relative to the surface through the mid‐troposphere before increasing to a factor of about 2.5 in the upper troposphere. This combination of muted warming in the mid‐troposphere and amplified warming aloft is within the range of CMIP6 models at individual pressure levels but, taken together, is distinctive behavior. The response to CO2 increase with unchanged SST is an approximately vertically uniform warming, comparable to CMIP6 models, and is linearly additive with the SST‐induced warming in X‐SHiELD.

Published

2024

2. Contrasting Response of Mesoscale Convective Systems Occurrence Over Tropical Land and Ocean to Increased Sea Surface Temperature

Author

Wenhao Dong, Ming Zhao, Lucas Harris, Kai‐Yuan Cheng, Linjiong Zhou, and V. Ramaswamy

Subjects

mesoscale convective systems, global storm resolving model, warming climate, convective available potential energy, convective inhibition, precipitation, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Mesoscale convective systems (MCSs) are pivotal in global energy/water cycles and typically produce extreme weather events. Despite their importance, our understanding of their future change remains limited, largely due to inadequate representation in current climate models. Here, using a global storm‐resolving model that accurately simulates MCSs, we conclude contrasting responses to increased SST in their occurrence, that is, notable decreases over land but increases over ocean. This land‐ocean contrast is attributed to the changes in convective available potential energy (CAPE) and convective inhibition (CIN). Over land, notable rises in CIN alongside moderate increases in CAPE effectively suppress (favor) weak to moderate (intense) MCSs, resulting in an overall reduction in MCS occurrences. In contrast, substantial increases in CAPE with minimal changes in CIN over ocean contribute to a significant rise in MCS occurrences. The divergent response in MCS occurrence has profound impacts on both mean and extreme precipitation.

Published

2024

3. Supercells and Tornado‐Like Vortices in an Idealized Global Atmosphere Model

Author

Kai‐Yuan Cheng, Shian‐Jiann Lin, Lucas Harris, and Linjiong Zhou

Subjects

global model, supercell, tornado, thunderstorm, dynamical core, Astronomy, QB1-991, Geology, QE1-996.5

Abstract

Abstract We investigate the representation of individual supercells and intriguing tornado‐like vortices in a simplified, locally refined global atmosphere model. The model, featuring grid stretching, can locally enhance the model resolution and reach cloud‐resolving scales with modest computational resources. Given a conditionally unstable sheared environment, the model can simulate supercells realistically, with a near‐ground vortex and funnel cloud at the center of a rotating updraft reminiscent of a tornado. An analysis of the Eulerian vertical vorticity budget suggests that the updraft core of the supercell tilts horizontal vorticity into the tornado‐like vortex, which is then amplified through vertical stretching by the updraft. Results suggest that the simulated vortex is dynamically similar to observed tornadoes, as well as those simulated in modeling studies at much higher horizontal resolution. Lastly, we discuss the prospects for the study of cross‐scale interactions involving supercells.

Published

2024

4. A flexible tropical cyclone vortex initialization technique for GFDL SHiELD

Author

Kun Gao, Lucas Harris, Mingjing Tong, Linjiong Zhou, Jan-Huey Chen, and Kai-Yuan Cheng

Subjects

hurricanes, tropical cyclones, high-resolution modeling, intensity forecast, initialization, Science

Abstract

Tropical cyclone (TC) intensity forecasting poses challenges due to complex dynamical processes and data inadequacies during model initialization. This paper describes efforts to improve TC intensity prediction in the Geophysical Fluid Dynamics Laboratory (GFDL) System for High-resolution prediction on Earth-to-Local Domains (SHiELD) model by implementing a Vortex Initialization (VI) technique. The GFDL SHiELD model, relying on the Global Forecast System (GFS) analysis for initialization, faces deficiencies in initial TC structure and intensity. The VI method involves adjusting the TC vortex inherited from the GFS analysis and merging it back into the environment at the observed location, enhancing the analyzed representation of storm structure. We made modifications to the VI package implemented in the operational Hurricane Analysis and Forecast System, including handling initial condition data, reducing input domain size, and improving storm intensity enhancement. Experiments using the T-SHiELD configuration demonstrate that using VI significantly improves the representation of initial TC intensity and size, enhancing TC predictions, particularly in storm intensity and outer wind forecasts within the first 48 h.

Published

2024

5. Kilometer-scale global warming simulations and active sensors reveal changes in tropical deep convection

Author

Maximilien Bolot, Lucas M. Harris, Kai-Yuan Cheng, Timothy M. Merlis, Peter N. Blossey, Christopher S. Bretherton, Spencer K. Clark, Alex Kaltenbaugh, Linjiong Zhou, and Stephan Fueglistaler

Subjects

Environmental sciences, GE1-350, Meteorology. Climatology, QC851-999

Abstract

Abstract Changes in tropical deep convection with global warming are a leading source of uncertainty for future climate projections. A comparison of the responses of active sensor measurements of cloud ice to interannual variability and next-generation global storm-resolving model (also known as k-scale models) simulations to global warming shows similar changes for events with the highest column-integrated ice. The changes reveal that the ice loading decreases outside the most active convection but increases at a rate of several percent per Kelvin surface warming in the most active convection. Disentangling thermodynamic and vertical velocity changes shows that the ice signal is strongly modulated by structural changes of the vertical wind field towards an intensification of strong convective updrafts with warming, suggesting that changes in ice loading are strongly influenced by changes in convective velocities, as well as a path toward extracting information about convective velocities from observations.

Published

2023

6. The Precipitation Response to Warming and CO2 Increase: A Comparison of a Global Storm Resolving Model and CMIP6 Models

Author

Ilai Guendelman, Timothy M. Merlis, Kai‐Yuan Cheng, Lucas M. Harris, Christopher S. Bretherton, Maximilien Bolot, Linjiong Zhou, Alex Kaltenbaugh, Spencer K. Clark, and Stephan Fueglistaler

Subjects

cloud resolving models, climate change, precipitation, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Global storm‐resolving models (GSRMs) that can explicitly resolve some of deep convection are now being integrated for climate timescales. GSRMs are able to simulate more realistic precipitation distributions relative to traditional Coupled Model Intercomparison Project 6 (CMIP6) models. In this study, we present results from two‐year‐long integrations of a GSRM developed at Geophysical Fluid Dynamics Laboratory, eXperimental System for High‐resolution prediction on Earth‐to‐Local Domains (X‐SHiELD), for the response of precipitation to sea surface temperature warming and an isolated increase in CO2 and compare it to CMIP6 models. At leading order, X‐SHiELD's response is within the range of the CMIP6 models. However, a close examination of the precipitation distribution response reveals that X‐SHiELD has a different response at lower percentiles and the response of the extreme events are at the lower end of the range of CMIP6 models. A regional decomposition reveals that the difference is most pronounced for midlatitude land, where X‐SHiELD shows a lower increase at intermediate percentiles and drying at lower percentiles.

Published

2024

7. The GFDL Variable‐Resolution Global Chemistry‐Climate Model for Research at the Nexus of US Climate and Air Quality Extremes

Author

Meiyun Lin, Larry W. Horowitz, Ming Zhao, Lucas Harris, Paul Ginoux, John Dunne, Sergey Malyshev, Elena Shevliakova, Hamza Ahsan, Steve Garner, Fabien Paulot, Arman Pouyaei, Steven J. Smith, Yuanyu Xie, Niki Zadeh, and Linjiong Zhou

Subjects

drought, Earth system feedbacks, extremes, air quality‐climate interactions, precipitation, high‐resolution, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract We present a variable‐resolution global chemistry‐climate model (AM4VR) developed at NOAA's Geophysical Fluid Dynamics Laboratory (GFDL) for research at the nexus of US climate and air quality extremes. AM4VR has a horizontal resolution of 13 km over the US, allowing it to resolve urban‐to‐rural chemical regimes, mesoscale convective systems, and land‐surface heterogeneity. With the resolution gradually reducing to 100 km over the Indian Ocean, we achieve multi‐decadal simulations driven by observed sea surface temperatures at 50% of the computational cost for a 25‐km uniform‐resolution grid. In contrast with GFDL's AM4.1 contributing to the sixth Coupled Model Intercomparison Project at 100 km resolution, AM4VR features much improved US climate mean patterns and variability. In particular, AM4VR shows improved representation of: precipitation seasonal‐to‐diurnal cycles and extremes, notably reducing the central US dry‐and‐warm bias; western US snowpack and summer drought, with implications for wildfires; and the North American monsoon, affecting dust storms. AM4VR exhibits excellent representation of winter precipitation, summer drought, and air pollution meteorology in California with complex terrain, enabling skillful prediction of both extreme summer ozone pollution and winter haze events in the Central Valley. AM4VR also provides vast improvements in the process‐level representations of biogenic volatile organic compound emissions, interactive dust emissions from land, and removal of air pollutants by terrestrial ecosystems. We highlight the value of increased model resolution in representing climate–air quality interactions through land‐biosphere feedbacks. AM4VR offers a novel opportunity to study global dimensions to US air quality, especially the role of Earth system feedbacks in a changing climate.

Published

2024

8. A New Framework for Evaluating Model Simulated Inland Tropical Cyclone Wind Fields

Author

Jie Chen, Kun Gao, Lucas Harris, Timothy Marchok, Linjiong Zhou, and Matthew Morin

Subjects

TC inland wind field, hurricane risk, model evaluation, TC landfall, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Though tropical cyclone (TC) models have been routinely evaluated against track and intensity observations, little work has been performed to validate modeled TC wind fields over land. In this paper, we present a simple framework for evaluating simulated low‐level inland winds with in‐situ observations and existing TC structure theory. The Automated Surface Observing Systems, Florida Coastal Monitoring Program, and best track data are used to generate a theory‐predicted wind profile that reasonably represents the observed radial distribution of TC wind speeds. We quantitatively and qualitatively evaluated the modeled inland TC wind fields, and described the model performance with a set of simple indicators. The framework was used to examine the performance of a high‐resolution two‐way nested Geophysical Fluid Dynamics Laboratory model on recent U.S. landfalling TCs. Results demonstrate the capacity of using this framework to assess the modeled TC low‐level wind field in the absence of dense inland observations.

Published

2023

9. Regulating Fine‐Scale Resolved Convection in High‐Resolution Models for Better Hurricane Track Prediction

Author

Kun Gao, Lucas Harris, Morris Bender, Jan‐Huey Chen, Linjiong Zhou, and Thomas Knutson

Subjects

hurricane prediction, high‐resolution, cloud‐resolving, FV3, horizontal advection, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract High‐resolution atmospheric models are powerful tools for hurricane track and intensity predictions. Although using high resolution contributes to better representation of hurricane structure and intensity, its value in the prediction of steering flow and storm tracks is uncertain. Here we present experiments suggesting that biases in the predicted North Atlantic hurricane tracks in a high‐resolution (approximately 3 km grid‐spacing) model originates from the model's explicit simulation of deep convection. Differing behavior of explicit convection leads to changes in the synoptic‐scale pattern and thereby to the steering flow. Our results suggest that optimizing small‐scale convection activity, for example, through the model's horizontal advection scheme, can lead to significantly improved hurricane track prediction (∼10% reduction of mean track error) at lead times beyond 72 hr. This work calls attention to the behavior of explicit convection in high‐resolution models, and its often overlooked role in affecting larger‐scale circulations and hurricane track prediction.

Published

2023

10. Tropical Cyclone Forecasts in the DIMOSIC Project—Medium‐Range Forecast Models With Common Initial Conditions

Author

Jan‐Huey Chen, Linjiong Zhou, Linus Magnusson, Ron McTaggart‐Cowan, and Martin Köhler

Subjects

DIMOSIC project, tropical cyclone forecasts, global model inter‐comparison, Astronomy, QB1-991, Geology, QE1-996.5

Abstract

Abstract The tropical cyclone (TC) forecast skill of the eight global medium‐range forecast models which are participating in the DIfferent Models, Same Initial Conditions project is investigated in this study. Each model was used to generate 10‐day forecasts from the same initial conditions provided by the European Centre for Medium‐Range Weather Forecasts. There are a total of 123 initial dates spanning in one year from June 2018 to June 2019 at 3‐day intervals. The TC track and intensity forecasts are evaluated against the best track data set. TC‐related precipitation and tropical cyclogenesis forecasts are also compared to explore the differences and similarities of TC forecasts across the models. This comparison of TC forecasts allows model developers in different centers to benchmark their model against other models, with the impact of the initial condition quality removed. The verifications reveal that most models show slow‐moving and right‐of‐track biases in their TC track forecasts. Also, a common dry bias in TC‐related precipitation indicates a general deficiency in TC intensity and convection in the models which should be related to insufficient model resolution. These findings provide important references for future model developments.

Published

2023

11. Improving Global Weather Prediction in GFDL SHiELD Through an Upgraded GFDL Cloud Microphysics Scheme

Author

Linjiong Zhou, Lucas Harris, Jan‐Huey Chen, Kun Gao, Huan Guo, Baoqiang Xiang, Mingjing Tong, J. Jacob Huff, and Matthew Morin

Subjects

numerical weather prediction, cloud microphysics, particle size distribution, aerosol and cloud, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract We describe the third version of the Geophysical Fluid Dynamics Laboratory cloud microphysics scheme (GFDL MP v3) implemented in the System for High‐resolution prediction on Earth‐to‐Local Domains (SHiELD). Compared to the GFDL MP v2, the GFDL MP v3 is entirely reorganized, optimized, and modularized into functions. The particle size distribution (PSD) of all hydrometeor categories is redefined to better mimic observations, and the cloud droplet number concentration (CDNC) is calculated from the Modern‐Era Retrospective analysis for Research and Applications, version 2 (MERRA2) aerosol data. In addition, the GFDL MP has been redesigned so all processes use the redefined PSD to ensure overall consistency and easily permit the introduction of new PSDs and microphysical processes. A year's worth of global 13‐km, 10‐day weather forecasts were performed with the new GFDL MP. Compared to the GFDL MP v2, the GFDL MP v3 significantly improves SHiELD's predictions of geopotential height, air temperature, and specific humidity in the Troposphere, as well as the high, middle and total cloud fractions and the liquid water path. The predictions are improved even further by the use of reanalysis aerosol data to calculate CDNC, and also by using the more realistic PSD available in GFDL MP v3. However, the upgrade of the GFDL MP shows little impact on the precipitation prediction. Degradations caused by the new scheme are discussed and provide a guide for future GFDL MP development.

Published

2022

12. On the Resolution‐Dependence of Anvil Cloud Fraction and Precipitation Efficiency in Radiative‐Convective Equilibrium

Author

Nadir Jeevanjee and Linjiong Zhou

Subjects

convection, clouds, precipitation, atmosphere, resolution dependence, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Tropical anvil clouds are an important player in Earth's climate and climate sensitivity, but simulations of anvil clouds are uncertain. Here we identify and investigate one source of uncertainty by demonstrating a marked increase of anvil cloud fraction with resolution in cloud‐resolving simulations of radiative‐convective equilibrium. This increase in cloud fraction can be traced back to the resolution dependence of horizontal mixing between clear and cloudy air. A mixing timescale is diagnosed for each simulation using the cloud fraction theory of Seeley, Jeevanjee, Langhans, and Romps (2019) (https://doi.org/10.1029/2018GL080747) and is found to scale linearly with grid spacing, as expected from a simple scaling law. Thus mixing becomes more efficient with increasing resolution, generating more evaporation in middle and lower tropospheric updrafts. This decreases their precipitation efficiency (PE), thereby increasing their overall mass flux, leading to greater detrainment at the anvil level and hence higher anvil cloud fraction. The decrease in PE also yields a marked increase in relative humidity with resolution.

Published

2022

13. DYAMOND: the DYnamics of the Atmospheric general circulation Modeled On Non-hydrostatic Domains

Author

Bjorn Stevens, Masaki Satoh, Ludovic Auger, Joachim Biercamp, Christopher S. Bretherton, Xi Chen, Peter Düben, Falko Judt, Marat Khairoutdinov, Daniel Klocke, Chihiro Kodama, Luis Kornblueh, Shian-Jiann Lin, Philipp Neumann, William M. Putman, Niklas Röber, Ryosuke Shibuya, Benoit Vanniere, Pier Luigi Vidale, Nils Wedi, and Linjiong Zhou

Subjects

Climate modeling, Model intercomparison project, Tropical convection, Convective parameterization, Geography. Anthropology. Recreation, Geology, QE1-996.5

Abstract

Abstract A review of the experimental protocol and motivation for DYAMOND, the first intercomparison project of global storm-resolving models, is presented. Nine models submitted simulation output for a 40-day (1 August–10 September 2016) intercomparison period. Eight of these employed a tiling of the sphere that was uniformly less than 5 km. By resolving the transient dynamics of convective storms in the tropics, global storm-resolving models remove the need to parameterize tropical deep convection, providing a fundamentally more sound representation of the climate system and a more natural link to commensurately high-resolution data from satellite-borne sensors. The models and some basic characteristics of their output are described in more detail, as is the availability and planned use of this output for future scientific study. Tropically and zonally averaged energy budgets, precipitable water distributions, and precipitation from the model ensemble are evaluated, as is their representation of tropical cyclones and the predictability of column water vapor, the latter being important for tropical weather.

Published

2019

14. Explicit Prediction of Continental Convection in a Skillful Variable‐Resolution Global Model

Author

Lucas M. Harris, Shannon L. Rees, Matthew Morin, Linjiong Zhou, and William F. Stern

Subjects

global modeling, convective‐scale modeling, severe convection, variable‐resolution models, FV3, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract We present a new global‐to‐regional model, cfvGFS, able to explicitly (without parameterization) represent convection over part of the Earth. This model couples the Geophysical Fluid Dynamics Laboratory Finite‐Volume Cubed‐Sphere Dynamical Core (FV3) to the Global Forecast System physics and initial conditions, augmented with a six‐category microphysics and a modified planetary boundary layer scheme. We examine the characteristics of cfvGFS on a 3‐km continental U. S. domain nested within a 13‐km global model. The nested cfvGFS still has good hemispheric skill comparable to or better than the operational Global Forecast System, while supercell thunderstorms, squall lines, and derechos are explicitly represented over the refined region. In particular, cfvGFS has excellent representations of fine‐scale updraft helicity fields, an important proxy for severe weather forecasting. Precipitation biases are found to be smaller than in uniform‐resolution global models and competitive with operational regional models; the 3‐km domain also improves upon the global models in 2‐m temperature and humidity skill. We discuss further development of cfvGFS and the prospects for a unified global‐to‐regional prediction system.

Published

2019

15. Two‐Moment Bulk Cloud Microphysics With Prognostic Precipitation in GFDL's Atmosphere Model AM4.0: Configuration and Performance

Author

Huan Guo, Yi Ming, Songmiao Fan, Linjiong Zhou, Lucas Harris, and Ming Zhao

Subjects

Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract A two‐moment Morrison‐Gettelman bulk cloud microphysics with prognostic precipitation (MG2), together with a mineral dust and temperature‐dependent ice nucleation scheme, have been implemented into the Geophysical Fluid Dynamics Laboratory's Atmosphere Model version 4.0 (AM4.0). We refer to this configuration as AM4‐MG2. This paper describes the configuration of AM4‐MG2, evaluates its performance, and compares it with AM4.0. It is shown that the global simulations with AM4‐MG2 compare favorably with observations and reanalyses. The model skill scores are close to AM4.0. Compared to AM4.0, improvements in AM4‐MG2 include (a) better coastal marine stratocumulus and seasonal cycles, (b) more realistic ice fraction, and (c) dominant accretion over autoconversion. Sensitivity tests indicate that nucleation and sedimentation schemes have significant impacts on cloud liquid and ice water fields, but higher horizontal resolution (about 50 km instead of 100 km) does not.

Published

2021

16. GFDL SHiELD: A Unified System for Weather‐to‐Seasonal Prediction

Author

Lucas Harris, Linjiong Zhou, Shian‐Jiann Lin, Jan‐Huey Chen, Xi Chen, Kun Gao, Matthew Morin, Shannon Rees, Yongqiang Sun, Mingjing Tong, Baoqiang Xiang, Morris Bender, Rusty Benson, Kai‐Yuan Cheng, Spencer Clark, Oliver D. Elbert, Andrew Hazelton, J. Jacob Huff, Alex Kaltenbaugh, Zhi Liang, Timothy Marchok, Hyeyum Hailey Shin, and William Stern

Subjects

Numerical Weather Prediction, Unified Modeling, FV3, Mesoscale Meteorology, Global Modeling, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract We present the System for High‐resolution prediction on Earth‐to‐Local Domains (SHiELD), an atmosphere model developed by the Geophysical Fluid Dynamics Laboratory (GFDL) coupling the nonhydrostatic FV3 Dynamical Core to a physics suite originally taken from the Global Forecast System. SHiELD is designed to demonstrate new capabilities within its components, explore new model applications, and to answer scientific questions through these new functionalities. A variety of configurations are presented, including short‐to‐medium‐range and subseasonal‐to‐seasonal prediction, global‐to‐regional convective‐scale hurricane and contiguous U.S. precipitation forecasts, and global cloud‐resolving modeling. Advances within SHiELD can be seamlessly transitioned into other Unified Forecast System or FV3‐based models, including operational implementations of the Unified Forecast System. Continued development of SHiELD has shown improvement upon existing models. The flagship 13‐km SHiELD demonstrates steadily improved large‐scale prediction skill and precipitation prediction skill. SHiELD and the coarser‐resolution S‐SHiELD demonstrate a superior diurnal cycle compared to existing climate models; the latter also demonstrates 28 days of useful prediction skill for the Madden‐Julian Oscillation. The global‐to‐regional nested configurations T‐SHiELD (tropical Atlantic) and C‐SHiELD (contiguous United States) show significant improvement in hurricane structure from a new tracer advection scheme and promise for medium‐range prediction of convective storms.

Published

2020

17. Tropical Cyclones in Global Storm-Resolving Models

Author

Falko Judt, Daniel Klocke, Rosimar Rios-Berrios, Benoit Vanniere, Florian Ziemen, Ludovic Auger, Joachim Biercamp, Christopher Bretherton, Xi Chen, Peter Duben, Cathy Hohenegger, Marat Khairoutdinov, Chihiro Kodama, Luis Kornblueh, Shian-Jiann Lin, Masuo Nakano, Philipp Neumann, William Putman, Niklas Rober, Malcolm Roberts, Masaki Satoh, Ryosuke Shibuya, Bjorn Stevens, Pier Luigi Vidale, Nils Wedi, and Linjiong Zhou

Subjects

Geosciences (General)

Abstract

Recent progress in computing and model development has initiated the era of global storm-resolving modeling, and with it the potential to transform weather and climate prediction. Within the general theme of vetting this new class of models, the present study evaluates nine global-storm resolving models in their ability to simulate tropical cyclones (TCs). Results indicate that, broadly speaking, the models produce realistic TCs and remove longstanding issues known from global models such as the deficiency in accurately simulating TC intensity. However, TCs are strongly affected by model formulation, and all models suffer from unique biases regarding the number of TCs, intensity, size, and structure. Some models simulated TCs better than others, but no single model was superior in every way. The overall results indicate that global storm-resolving models can open a new chapter in TC prediction, but they need to be improved to unleash their full potential.

Published

2021

18. An Integrated Coupling Framework for Atmospheric Dynamics and Physics

Author

Linjiong Zhou and Lucas Harris

Abstract

Atmospheric resolved-scale air flow (dynamics) and sub-grid parameterizations (physics) are two essential components of a weather or climate model. These two independent components are coupled and advanced using the same time step, either parallel or sequentially split. However, traditionally dynamics and physics are engineered in isolation and developed independently in models. As a result, many parts of the physics run at a physically-inappropriate time frequency or with heat transfers that are inconsistent with the dynamics, leading to errors. In addition, physical parameterizations should contain dynamical and non-dynamical processes. We believe there are compelling reasons that dynamical processes, if resolved, should be taken care of by the dynamical core.Our study proposes a novel integrated dynamics-physics coupling framework (Zhou and Harris, 2022) within the GFDL (Geophysical Fluid Dynamics Laboratory) weather-to-seasonal prediction system SHiELD (System for High-resolution prediction on Earth-to-Local Domains; Harris et al., 2020) that promises to resolve the above issues. We will present our integrated coupling framework and the development of integrated physical parameterization for this framework in detail. The performance of forecast experiments using the modeling system SHiELD with this integrated coupling framework will be highlighted, focusing on large-scale circulation, cloud and precipitation, hurricane, and convective-storm predictions.

Published

2023

19. A Global Survey of Rotating Convective Updrafts in the GFDL X‐SHiELD 2021 Global Storm Resolving Model

Author

Lucas Harris, Linjiong Zhou, Alex David Kaltenbaugh, Spencer Koncius Clark, Kai-Yuan Cheng, and Christopher S. Bretherton

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous)

Published

2023

20. S2S Prediction in GFDL SPEAR: MJO Diversity and Teleconnections

Author

Fanrong Zeng, Ming Zhao, Linjiong Zhou, Guosen Chen, Sarah B. Kapnick, Liwei Jia, Baoqiang Xiang, Bin Wang, Yongqiang Sun, Lucas M. Harris, Jan-Huey Chen, Xiaosong Yang, Kun Gao, J. Jacob Huff, Xiaqiong Zhou, William Cooke, Thomas L. Delworth, Mingjing Tong, Colleen McHugh, Spencer K. Clark, Nathaniel C. Johnson, and Feiyu Lu

Subjects

Atmospheric Science, Climatology, Madden–Julian oscillation, Biology, Spear, Diversity (business), Teleconnection

Abstract

A subseasonal-to-seasonal (S2S) prediction system was recently developed using the GFDL Seamless System for Prediction and Earth System Research (SPEAR) global coupled model. Based on 20-yr hindcast results (2000–19), the boreal wintertime (November–April) Madden–Julian oscillation (MJO) prediction skill is revealed to reach 30 days measured before the anomaly correlation coefficient of the real-time multivariate (RMM) index drops to 0.5. However, when the MJO is partitioned into four distinct propagation patterns, the prediction range extends to 38, 31, and 31 days for the fast-propagating, slow-propagating, and jumping MJO patterns, respectively, but falls to 23 days for the standing MJO. A further improvement of MJO prediction requires attention to the standing MJO given its large gap with its potential predictability (38 days). The slow-propagating MJO detours southward when traversing the Maritime Continent (MC), and confronts the MC prediction barrier in the model, while the fast-propagating MJO moves across the central MC without this prediction barrier. The MJO diversity is modulated by stratospheric quasi-biennial oscillation (QBO): the standing (slow-propagating) MJO coincides with significant westerly (easterly) phases of QBO, partially explaining the contrasting MJO prediction skill between these two QBO phases. The SPEAR model shows its capability, beyond the propagation, in predicting their initiation for different types of MJO along with discrete precursory convection anomalies. The SPEAR model skillfully predicts the observed distinct teleconnections over the North Pacific and North America related to the standing, jumping, and fast-propagating MJO, but not the slow-propagating MJO. These findings highlight the complexities and challenges of incorporating MJO prediction into the operational prediction of meteorological variables.

Published

2022

21. Tropical Cyclone Forecasts in the DIMOSIC Project -- Medium-Range Forecast Models with Common Initial Conditions

Author

Jan-Huey Chen, Linjiong Zhou, Linus Magnusson, Ron McTaggart-Cowan, and Martin Köhler

Abstract

The Tropical cyclone (TC) forecast skill of the eight global medium-range forecast models which are participating in the DIMOSIC (DIfferent Models, Same Initial Conditions) project is investigated in this study. Each model was used to generate 10-day forecasts from the same initial conditions provided by the European Centre for Medium-Range Weather Forecasts. There are a total of 123 initial dates spanning in one year from June 2018 to June 2019 with a 3-day interval. The TC track and intensity forecasts are evaluated against the best track dataset. TC-related precipitation and tropical cyclogenesis forecasts are also compared to explore the differences and similarities of TC forecasts across the models. This comparison of TC forecasts allows model developers in different centers to benchmark their model against other models, with the impact of the initial condition quality removed. The verifications reveal that most models show slow-moving and right-of-track biases in their TC track forecasts. Also, a common dry bias in TC-related precipitation indicates a general deficiency in TC intensity and convection in the models which should be related to insufficient model resolution. These findings provide important references for future model developments.

Published

2022

22. Performance of Two‐Moment Stratiform Microphysics With Prognostic Precipitation in GFDL's CM4.0

Author

Huan Guo, Yi Ming, Songmiao Fan, Andrew T. Wittenberg, Rong Zhang, Ming Zhao, and Linjiong Zhou

Subjects

Global and Planetary Change, General Earth and Planetary Sciences, Environmental Chemistry

Published

2022

23. Integrated Dynamics‐Physics Coupling for Weather to Climate Models: GFDL SHiELD With In‐Line Microphysics

Author

Linjiong Zhou and Lucas Harris

Subjects

Geophysics, General Earth and Planetary Sciences

Published

2022

24. On the Sensitivity of Hurricane Intensity and Structure to Horizontal Tracer Advection Schemes in FV3

Author

Morris A. Bender, Lucas M. Harris, Kun Gao, Linjiong Zhou, and Matthew Morin

Subjects

Atmospheric Science, Advection, TRACER, Environmental science, Sensitivity (control systems), Atmospheric sciences, Hurricane intensity, Physics::Atmospheric and Oceanic Physics

Abstract

We investigate the sensitivity of hurricane intensity and structure to the horizontal tracer advection in the Geophysical Fluid Dynamics Laboratory (GFDL) Finite-Volume Cubed-Sphere Dynamical Core (FV3). We compare two schemes, a monotonic scheme and a less diffusive positive-definite scheme. The positive-definite scheme leads to significant improvement in the intensity prediction relative to the monotonic scheme in a suite of 5-day forecasts that mostly consist of rapidly intensifying hurricanes. Notable storm structural differences are present: the radius of maximum wind (RMW) is smaller and eyewall convection occurs farther inside the RMW when the positive-definite scheme is used. Moreover, we find that the horizontal tracer advection scheme affects the eyewall convection location by affecting the moisture distribution in the inner-core region. This study highlights the importance of dynamical core algorithms in hurricane intensity prediction.

Published

2021

25. Impact of Warmer Sea Surface Temperature on the Global Pattern of Intense Convection: Insights From a Global Storm Resolving Model

Author

Kai‐Yuan Cheng, Lucas Harris, Christopher Bretherton, Timothy M. Merlis, Maximilien Bolot, Linjiong Zhou, Alex Kaltenbaugh, Spencer Clark, and Stephan Fueglistaler

Subjects

Geophysics, General Earth and Planetary Sciences

Published

2022

26. Exploring Convection-Allowing Model Evaluation Strategies for Severe Local Storms Using the Finite-Volume Cubed-Sphere (FV3) Model Core

Author

Jamie K. Wolff, Burkely T. Gallo, Tim Supinie, Yunheng Wang, Chunxi Zhang, Israel L. Jirak, Linjiong Zhou, Adam J. Clark, Ming Xue, Lindsay R. Blank, Lucas M. Harris, Curtis R. Alexander, and Brett Roberts

Subjects

Convection, Core (optical fiber), Atmospheric Science, Finite volume method, Severe weather, Weather forecasting, Storm, Geophysics, computer.software_genre, Cubed sphere, computer, Geology

Abstract

Verification methods for convection-allowing models (CAMs) should consider the finescale spatial and temporal detail provided by CAMs, and including both neighborhood and object-based methods can account for displaced features that may still provide useful information. This work explores both contingency table–based verification techniques and object-based verification techniques as they relate to forecasts of severe convection. Two key fields in severe weather forecasting are investigated: updraft helicity (UH) and simulated composite reflectivity. UH is used to generate severe weather probabilities called surrogate severe fields, which have two tunable parameters: the UH threshold and the smoothing level. Probabilities computed using the UH threshold and smoothing level that give the best area under the receiver operating curve result in very high probabilities, while optimizing the parameters based on the Brier score reliability component results in much lower probabilities. Subjective ratings from participants in the 2018 NOAA Hazardous Weather Testbed Spring Forecasting Experiment (SFE) provide a complementary evaluation source. This work compares the verification methodologies in the context of three CAMs using the Finite-Volume Cubed-Sphere Dynamical Core (FV3), which will be the foundation of the U.S. Unified Forecast System (UFS). Three agencies ran FV3-based CAMs during the five-week 2018 SFE. These FV3-based CAMs are verified alongside a current operational CAM, the High-Resolution Rapid Refresh version 3 (HRRRv3). The HRRR is planned to eventually use the FV3 dynamical core as part of the UFS; as such evaluations relative to current HRRR configurations are imperative to maintaining high forecast quality and informing future implementation decisions.

Published

2021

27. Evaluation of the Outstanding Track Performance of the GFDL SHiELD Global Model During the 2021 Atlantic Hurricane Season

Author

Linjiong Zhou, Morris Bender, Matt Morin, Lucas Harris, Alex Kaltenbaugh, and Jie Chen

Published

2022

28. Multiple Hydrometeors All-Sky Microwave Radiance Assimilation in FV3GFS

Author

Mingjing Tong, Ming Chen, Shian-Jiann Lin, Quanhua Liu, Yanqiu Zhu, Linjiong Zhou, and Emily Liu

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Microphysics, Meteorology, media_common.quotation_subject, 0211 other engineering and technologies, Assimilation (biology), 02 engineering and technology, 01 natural sciences, Sky, Radiance, Environmental science, Microwave, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, media_common

Abstract

Motivated by the use of the GFDL microphysics scheme in the Finite-Volume Cubed-Sphere Dynamical Core Global Forecast System (FV3GFS), the all-sky radiance assimilation framework has been expanded to include precipitating hydrometeors. Adding precipitating hydrometeors allows the assimilation of precipitation-affected radiance in addition to cloudy radiance. In this upgraded all-sky framework, the five hydrometeors, including cloud liquid water, cloud ice, rain, snow, and graupel, are the new control variables, replacing the original cloud water control variable. The Community Radiative Transfer Model (CRTM) was interfaced with the newly added precipitating hydrometeors. Subgrid cloud variability was considered by using the average cloud overlap scheme. Multiple scattering radiative transfer was activated in the upgraded framework. Radiance observations from the Advanced Microwave Sounding Unit-A (AMSU-A) and the Advanced Technology Microwave Sounder (ATMS) over ocean were assimilated in all-sky approach. This new constructed all-sky framework shows neutral to positive impact on overall forecast skill. Improvement was found in 500-hPa geopotential height forecast in both Northern and Southern Hemispheres. Temperature forecast was also improved at 850 hPa in the Southern Hemisphere and the tropics.

Published

2020

29. Two-moment bulk cloud microphysics with prognostic precipitation in the GFDL CM4.0 model: Performance and simulation characteristics

Author

Huan Guo, Yi Ming, Song-Miao Fan, Andrew T. Wittenberg, Rong Zhang, Ming Zhao, and Linjiong Zhou

Published

2022

30. Tropical ice clouds validation in Global Storm Resolving Models using active sensor retrievals

Author

Maximilien Bolot, Stephan Fueglistaler, Lucas Harris, Kai-Yuan Cheng, and Linjiong Zhou

Subjects

Physics::Atmospheric and Oceanic Physics, Physics::Geophysics

Abstract

Tropical ice clouds play an important role in the energy balance of the tropical atmosphere, yet their modeling has been a challenge and feedback from high clouds in climate models is very uncertain. The new generation of Global Storm Resolving Models (GSRM) is capable of resolving convective and mesoscale motions globally, and therefore promises to greatly advance our understanding of tropical clouds. This new generation of model also creates new opportunities for comparison with measurements since their horizontal resolution is comparable to that of active sensor measurements. Here we show the value of metrics evaluating cloud fraction, ice mixing ratio and longwave cloud radiative heating to validate tropical ice clouds simulated by Global Storm Resolving Models using A-Train ice cloud retrieval products. For this purpose, we use the X-SHiELD experimental Cloud Resolving Model, developed at NOAA/GFDL, and observations based on the 2C-ICE and DARDAR products, with the addition of the 2B-FLXHR-LIDAR radiative transfer algorithm for the validation of broadband fluxes. We show that, by aggregating model output and measurements in ice water path – pressure space, biases in the ice distribution can be revealed, whereby the position of the anvils is too low in the model. Such biases point to deficiencies in the microphysics of cloud ice, are likely shared by other models using similar microphysics packages, and have important consequences on thermal emission properties.

Published

2022

31. Weather Prediction in SHiELD: Effect from GFDL Cloud Microphysics Scheme Upgrade

Author

Linjiong Zhou, Lucas Harris, Jan-Huey Chen, Kun Gao, Huan Guo, Baoqiang Xiang, Mingjing Tong, J. Jacob Huff, and Matthew Morin

Published

2022

32. Evaluation of Tropical Cyclone Forecasts in the Next Generation Global Prediction System

Author

Xi Chen, Matthew Morin, Shannon L. Rees, Linjiong Zhou, Shian-Jiann Lin, Morris A. Bender, and Jan-Huey Chen

Subjects

Core (optical fiber), Atmosphere, Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Environmental science, Tropical cyclone, Prediction system, 010502 geochemistry & geophysics, 01 natural sciences, Global model, 0105 earth and related environmental sciences

Abstract

A new global model using the GFDL nonhydrostatic Finite-Volume Cubed-Sphere Dynamical Core (FV3) coupled to physical parameterizations from the National Centers for Environmental Prediction’s Global Forecast System (NCEP/GFS) was built at GFDL, named fvGFS. The modern dynamical core, FV3, has been selected for the National Oceanic and Atmospheric Administration’s Next Generation Global Prediction System (NGGPS) due to its accuracy, adaptability, and computational efficiency, which brings a great opportunity for the unification of weather and climate prediction systems. The performance of tropical cyclone (TC) forecasts in the 13-km fvGFS is evaluated globally based on 363 daily cases of 10-day forecasts in 2015. Track and intensity errors of TCs in fvGFS are compared to those in the operational GFS. The fvGFS outperforms the GFS in TC intensity prediction for all basins. For TC track prediction, the fvGFS forecasts are substantially better over the northern Atlantic basin and the northern Pacific Ocean than the GFS forecasts. An updated version of the fvGFS with the GFDL 6-category cloud microphysics scheme is also investigated based on the same 363 cases. With this upgraded microphysics scheme, fvGFS shows much improvement in TC intensity prediction over the operational GFS. Besides track and intensity forecasts, the performance of TC genesis forecast is also compared between the fvGFS and operational GFS. In addition to evaluating the hit/false alarm ratios, a novel method is developed to investigate the lengths of TC genesis lead times in the forecasts. Both versions of fvGFS show higher hit ratios, lower false alarm ratios, and longer genesis lead times than those of the GFS model in most of the TC basins.

Published

2019

33. CAS FGOALS-f3-L Model Datasets for CMIP6 Historical Atmospheric Model Intercomparison Project Simulation

Author

Xiaocong Wang, Bian He, Qing Bao, Lei Wang, Sicheng He, Xiaoqi Zhang, Linjiong Zhou, Jiandong Li, Yimin Liu, Kangjun Chen, Jinxiao Li, Guokui Nian, Xiaofei Wu, Minghua Zhang, Guoxiong Wu, Wenting Hu, and Jing Yang

Subjects

Atmospheric Science, Coupled model intercomparison project, 010504 meteorology & atmospheric sciences, Meteorology, Atmospheric circulation, Atmospheric Model Intercomparison Project, Madden–Julian oscillation, 010502 geochemistry & geophysics, 01 natural sciences, Benchmark (surveying), Environmental science, Precipitation, Tropical cyclone, Baseline (configuration management), 0105 earth and related environmental sciences

Abstract

The outputs of the Chinese Academy of Sciences (CAS) Flexible Global Ocean-Atmosphere-Land System (FGOALS-f3-L) model for the baseline experiment of the Atmospheric Model Intercomparison Project simulation in the Diagnostic, Evaluation and Characterization of Klima common experiments of phase 6 of the Coupled Model Intercomparison Project (CMIP6) are described in this paper. The CAS FGOALS-f3-L model, experiment settings, and outputs are all given. In total, there are three ensemble experiments over the period 1979–2014, which are performed with different initial states. The model outputs contain a total of 37 variables and include the required three-hourly mean, six-hourly transient, daily and monthly mean datasets. The baseline performances of the model are validated at different time scales. The preliminary evaluation suggests that the CAS FGOALS-f3-L model can capture the basic patterns of atmospheric circulation and precipitation well, including the propagation of the Madden-Julian Oscillation, activities of tropical cyclones, and the characterization of extreme precipitation. These datasets contribute to the benchmark of current model behaviors for the desired continuity of CMIP.

Published

2019

34. Toward Convective-Scale Prediction within the Next Generation Global Prediction System

Author

Lucas M. Harris, Jan-Huey Chen, Xi Chen, Shian-Jiann Lin, Shannon L. Rees, and Linjiong Zhou

Subjects

Convection, Atmospheric Science, Scale (ratio), Meteorology, Geophysical fluid dynamics, Prediction system, Global model, Geology

Abstract

The Geophysical Fluid Dynamics Laboratory (GFDL) has developed a new variable-resolution global model with the ability to represent convective-scale features that serves as a prototype of the Next Generation Global Prediction System (NGGPS). The goal of this prediction system is to maintain the skill in large-scale features while simultaneously improving the prediction skill of convectively driven mesoscale phenomena. This paper demonstrates the new capability of this model in convective-scale prediction relative to the current operational Global Forecast System (GFS). This model uses the stretched-grid functionality of the Finite-Volume Cubed-Sphere Dynamical Core (FV3) to refine the global 13-km uniform-resolution model down to 4-km convection-permitting resolution over the contiguous United States (CONUS), and implements the GFDL single-moment 6-category cloud microphysics to improve the representation of moist processes. Statistics gathered from two years of simulations by the GFS and select configurations of the FV3-based model are carefully examined. The variable-resolution FV3-based model is shown to possess global forecast skill comparable with that of the operational GFS while quantitatively improving skill and better representing the diurnal cycle within the high-resolution area compared to the uniform mesh simulations. Forecasts of the occurrence of extreme precipitation rates over the southern Great Plains are also shown to improve with the variable-resolution model. Case studies are provided of a squall line and a hurricane to demonstrate the effectiveness of the variable-resolution model to simulate convective-scale phenomena.

Published

2019

35. LASG Global AGCM with a Two-moment Cloud Microphysics Scheme: Energy Balance and Cloud Radiative Forcing Characteristics

Author

Lei Wang, Jinxiao Li, Hua Gong, Guokui Nian, Wei-Chyung Wang, Bian He, Qing Bao, Xiaocong Wang, Yimin Liu, Guoxiong Wu, Jiandong Li, and Linjiong Zhou

Subjects

Cloud forcing, Atmospheric Science, 010504 meteorology & atmospheric sciences, Longwave, Cloud physics, Atmospheric model, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Aerosol, Liquid water content, Latent heat, Environmental science, Shortwave, 0105 earth and related environmental sciences

Abstract

Cloud dominates influence factors of atmospheric radiation, while aerosol-cloud interactions are of vital importance in its spatiotemporal distribution. In this study, a two-moment (mass and number) cloud microphysics scheme, which significantly improved the treatment of the coupled processes of aerosols and clouds, was incorporated into version 1.1 of the IAP/LASG global Finite-volume Atmospheric Model (FAMIL1.1). For illustrative purposes, the characteristics of the energy balance and cloud radiative forcing (CRF) in an AMIP-type simulation with prescribed aerosols were compared with those in observational/reanalysis data. Even within the constraints of the prescribed aerosol mass, the model simulated global mean energy balance at the top of the atmosphere (TOA) and at the Earth’s surface, as well as their seasonal variation, are in good agreement with the observational data. The maximum deviation terms lie in the surface downwelling longwave radiation and surface latent heat flux, which are 3.5 W m-2 (1%) and 3 W m-2 (3.5%), individually. The spatial correlations of the annual TOA net radiation flux and the net CRF between simulation and observation were around 0.97 and 0.90, respectively. A major weakness is that FAMIL1.1 predicts more liquid water content and less ice water content over most oceans. Detailed comparisons are presented for a number of regions, with a focus on the Asian monsoon region (AMR). The results indicate that FAMIL1.1 well reproduces the summer-winter contrast for both the geographical distribution of the longwave CRF and shortwave CRF over the AMR. Finally, the model bias and possible solutions, as well as further works to develop FAMIL1.1 are discussed.

Published

2019

36. Explicit Prediction of Continental Convection in a Skillful Variable‐Resolution Global Model

Author

Shannon L. Rees, W. Stern, Linjiong Zhou, Lucas M. Harris, and Matthew Morin

Subjects

severe convection, Convection, Global and Planetary Change, Meteorology, global modeling, Global model, Variable resolution, lcsh:Oceanography, variable‐resolution models, General Earth and Planetary Sciences, Environmental Chemistry, Environmental science, lcsh:GC1-1581, convective‐scale modeling, lcsh:GB3-5030, Global modeling, lcsh:Physical geography, FV3

Abstract

We present a new global‐to‐regional model, cfvGFS, able to explicitly (without parameterization) represent convection over part of the Earth. This model couples the Geophysical Fluid Dynamics Laboratory Finite‐Volume Cubed‐Sphere Dynamical Core (FV3) to the Global Forecast System physics and initial conditions, augmented with a six‐category microphysics and a modified planetary boundary layer scheme. We examine the characteristics of cfvGFS on a 3‐km continental U. S. domain nested within a 13‐km global model. The nested cfvGFS still has good hemispheric skill comparable to or better than the operational Global Forecast System, while supercell thunderstorms, squall lines, and derechos are explicitly represented over the refined region. In particular, cfvGFS has excellent representations of fine‐scale updraft helicity fields, an important proxy for severe weather forecasting. Precipitation biases are found to be smaller than in uniform‐resolution global models and competitive with operational regional models; the 3‐km domain also improves upon the global models in 2‐m temperature and humidity skill. We discuss further development of cfvGFS and the prospects for a unified global‐to‐regional prediction system.

Published

2019

37. Dependence on initial conditions versus model formulations for medium‐range forecast error variations

Author

Xi Chen, Shian-Jiann Lin, Jan-Huey Chen, Linus Magnusson, and Linjiong Zhou

Subjects

Atmospheric Science, Forecast error, Meteorology, Medium range, Forecast skill, Numerical weather prediction, Mathematics

Published

2019

38. Advancements in Hurricane Prediction With NOAA's Next‐Generation Forecast System

Author

Xi Chen, Jan-Huey Chen, Linjiong Zhou, Lucas M. Harris, Linus Magnusson, Shian-Jiann Lin, Matthew Morin, Baoqiang Xiang, Morris A. Bender, and Shannon L. Rees

Subjects

Geophysics, General Earth and Planetary Sciences, Environmental science

Published

2019

39. On the resolution-dependence of cloud fraction, precipitation efficiency, and evaporation in radiative-convective equilibrium

Author

Nadir Jeevanjee and Linjiong Zhou

Subjects

Convection, Cloud fraction, Resolution (electron density), Evaporation, Radiative transfer, Climate sensitivity, Environmental science, Precipitation, Atmospheric sciences, Earth (classical element)

Abstract

Tropical anvil clouds are an important player in Earth's climate and climate sensitivity, but simulations of anvil clouds are uncertain. Here we pinpoint one source of uncertainty by demonstrating ...

Published

2021

40. Tropical Cyclones in Global Storm-Resolving Models

Author

Joachim Biercamp, Xi Chen, Masaki Satoh, Cathy Hohenegger, Nils Wedi, Falko Judt, Chihiro Kodama, Ryosuke Shibuya, Linjiong Zhou, Daniel Klocke, Bjorn Stevens, Peter Düben, Benoit Vanniere, Niklas Röber, Pier Luigi Vidale, Florian Ziemen, Rosimar Rios-Berrios, Philipp Neumann, Ludovic Auger, Christopher S. Bretherton, Luis Kornblueh, William M. Putman, Masuo Nakano, Marat Khairoutdinov, Shian-Jiann Lin, and Malcolm J. Roberts

Subjects

Atmospheric Science, Climatology, Environmental science, Storm, Tropical cyclone

Abstract

Recent progress in computing and model development has initiated the era of global storm-resolving modeling and with it the potential to transform weather and climate prediction. Within the general theme of vetting this new class of models, the present study evaluates nine global-storm resolving models in their ability to simulate tropical cyclones (TCs). Results show that, broadly speaking, the models produce realistic TCs and remove longstanding issues known from global models such as the deficiency to accurately simulate TC intensity. However, TCs are strongly affected by model formulation, and all models suffer from unique biases regarding the number of TCs, intensity, size, and structure. Some models simulated TCs better than others, but no single model was superior in every way. The overall results indicate that global storm-resolving models are able to open a new chapter in TC prediction, but they need to be improved to unleash their full potential.

Published

2021

41. GFDL SHiELD: A Unified System for Weather‐to‐Seasonal Prediction

Author

Kai-Yuan Cheng, Andrew Hazelton, Timothy Marchok, Jan-Huey Chen, Alex Kaltenbaugh, Yongqiang Sun, Hyeyum Hailey Shin, Shannon L. Rees, Linjiong Zhou, Oliver D. Elbert, Kun Gao, Xi Chen, Mingjing Tong, Shian-Jiann Lin, W. Stern, J. Jacob Huff, Lucas M. Harris, Rusty Benson, Baoqiang Xiang, Matthew Morin, Zhi Liang, Spencer K. Clark, and Morris A. Bender

Subjects

Physical geography, 010504 meteorology & atmospheric sciences, Meteorology, Mesoscale meteorology, GC1-1581, Atmospheric model, Oceanography, 010502 geochemistry & geophysics, 01 natural sciences, Shield, Numerical Weather Prediction, Environmental Chemistry, Physics::Atmospheric and Oceanic Physics, FV3, Global Modeling, 0105 earth and related environmental sciences, Mesoscale Meteorology, Global and Planetary Change, Numerical weather prediction, GB3-5030, Unified system, Unified Modeling, Coupling (computer programming), General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics, Global modeling

Abstract

We present the System for High‐resolution prediction on Earth‐to‐Local Domains (SHiELD), an atmosphere model developed by the Geophysical Fluid Dynamics Laboratory (GFDL) coupling the nonhydrostatic FV3 Dynamical Core to a physics suite originally taken from the Global Forecast System. SHiELD is designed to demonstrate new capabilities within its components, explore new model applications, and to answer scientific questions through these new functionalities. A variety of configurations are presented, including short‐to‐medium‐range and subseasonal‐to‐seasonal prediction, global‐to‐regional convective‐scale hurricane and contiguous U.S. precipitation forecasts, and global cloud‐resolving modeling. Advances within SHiELD can be seamlessly transitioned into other Unified Forecast System or FV3‐based models, including operational implementations of the Unified Forecast System. Continued development of SHiELD has shown improvement upon existing models. The flagship 13‐km SHiELD demonstrates steadily improved large‐scale prediction skill and precipitation prediction skill. SHiELD and the coarser‐resolution S‐SHiELD demonstrate a superior diurnal cycle compared to existing climate models; the latter also demonstrates 28 days of useful prediction skill for the Madden‐Julian Oscillation. The global‐to‐regional nested configurations T‐SHiELD (tropical Atlantic) and C‐SHiELD (contiguous United States) show significant improvement in hurricane structure from a new tracer advection scheme and promise for medium‐range prediction of convective storms.

Published

2020

42. Climatology of tracked persistent maxima of 500-hPa geopotential height

Author

Bian He, Raymond Sukhdeo, Yimin Liu, Dingchen Hou, Yuejian Zhu, Hong Guan, Ping Liu, Linjiong Zhou, Wei Li, Q. Zhang, Malaquias Peña, Jon Gottschalck, Wenting Hu, Christopher Melhauser, Minghua Zhang, Xiaqiong Zhou, and Guoxiong Wu

Subjects

Atmospheric Science, Geopotential, 010504 meteorology & atmospheric sciences, Northern Hemisphere, Geopotential height, 010502 geochemistry & geophysics, 01 natural sciences, symbols.namesake, Anticyclone, Western europe, Climatology, symbols, Maxima, Longitude, Lagrangian, Geology, 0105 earth and related environmental sciences

Abstract

Persistent open ridges and blocking highs (maxima) of 500-hPa geopotential height (Z500; PMZ) adjacent in space and time are identified and tracked as one event with a Lagrangian objective approach to derive their climatological statistics with some dynamical reasoning. A PMZ starts with a core that contains a local eddy maximum of Z500 and its neighboring grid points whose eddy values decrease radially to about 20 geopotential meters (GPMs) smaller than the maximum. It connects two consecutive cores that share at least one grid point and are within 10° of longitude of each other using an intensity-weighted location. The PMZ ends at the core without a successor. On each day, the PMZ impacts an area of grid points contiguous to the core and with eddy values decreasing radially to 100 GPMs. The PMZs identified and tracked consist of persistent ridges, omega blockings and blocked anticyclones either connected or as individual events. For example, the PMZ during 2–13 August 2003 corresponds to persistent open ridges that caused the extreme heatwave in Western Europe. Climatological statistics based on the PMZs longer than 3 days generally agree with those of blockings. In the Northern Hemisphere, more PMZs occur in DJF season than in JJA and their duration both exhibit a log-linear distribution. Because more omega-shape blocking highs and open ridges are counted, the PMZs occur more frequently over Northeast Pacific than over Atlantic-Europe during cool seasons. Similar results are obtained using the 200-hPa geopotential height (in place of Z500), indicating the quasi-barotropic nature of the PMZ.

Published

2017

43. DYAMOND: The DYnamics of the Atmospheric general circulation MOdeled on Non-hydrostatic Domains

Author

Masaki Satoh, Marat Khairoutdinov, Shian-Jiann Lin, Falko Judt, Christopher S. Bretherton, Peter Düben, Ludovic Auger, Ryosuke Shibuya, Philipp Neumann, Pier Luigi Vidale, Chihiro Kodama, Joachim Biercamp, Nils Wedi, Luis Kornblueh, Xi Chen, Niklas Röber, Benoit Vanniere, Linjiong Zhou, William M. Putman, Daniel Klocke, and Bjorn Stevens

Subjects

Hydrogeology, 010504 meteorology & atmospheric sciences, Precipitable water, Model intercomparison project, lcsh:QE1-996.5, Tropical convection, lcsh:Geography. Anthropology. Recreation, 010502 geochemistry & geophysics, 01 natural sciences, lcsh:Geology, lcsh:G, 13. Climate action, Climate modeling, Climatology, Convective parameterization, Convective storm detection, General Earth and Planetary Sciences, Environmental science, Climate model, Precipitation, Tropical cyclone, Predictability, Water vapor, 0105 earth and related environmental sciences

Abstract

A review of the experimental protocol and motivation for DYAMOND, the first intercomparison project of global storm-resolving models, is presented. Nine models submitted simulation output for a 40-day (1 August–10 September 2016) intercomparison period. Eight of these employed a tiling of the sphere that was uniformly less than 5 km. By resolving the transient dynamics of convective storms in the tropics, global storm-resolving models remove the need to parameterize tropical deep convection, providing a fundamentally more sound representation of the climate system and a more natural link to commensurately high-resolution data from satellite-borne sensors. The models and some basic characteristics of their output are described in more detail, as is the availability and planned use of this output for future scientific study. Tropically and zonally averaged energy budgets, precipitable water distributions, and precipitation from the model ensemble are evaluated, as is their representation of tropical cyclones and the predictability of column water vapor, the latter being important for tropical weather.

Published

2019

44. On the incident solar radiation in CMIP5 models

Author

Minghua Zhang, Linjiong Zhou, Yimin Liu, and Qing Bao

Subjects

Atmosphere, Coupled model intercomparison project, Geophysics, Meteorology, Oscillation, Diurnal temperature variation, Solar zenith angle, Phase (waves), General Earth and Planetary Sciences, Environmental science, Shortwave radiation, Radiation, Atmospheric sciences

Abstract

Annual incident solar radiation at the top of atmosphere should be independent of longitudes. However, in many Coupled Model Intercomparison Project phase 5 (CMIP5) models, we find that the incident radiation exhibited zonal oscillations, with up to 30 W/m2 of spurious variations. This feature can affect the interpretation of regional climate and diurnal variation of CMIP5 results. This oscillation is also found in the Community Earth System Model. We show that this feature is caused by temporal sampling errors in the calculation of the solar zenith angle. The sampling error can cause zonal oscillations of surface clear-sky net shortwave radiation of about 3 W/m2 when an hourly radiation time step is used and 24 W/m2 when a 3 h radiation time step is used.

Published

2015

45. Exploring Convection-Allowing Model Evaluation Strategies for Severe Local Storms Using the Finite-Volume Cubed-Sphere (FV3) Model Core.

Author

GALLO, BURKELY T., WOLFF, JAMIE K., CLARK, ADAM J., JIRAK, ISRAEL, BLANK, LINDSAY R., ROBERTS, BRETT, YUNHENG WANG, CHUNXI ZHANG, MING XUE, SUPINIE, TIM, HARRIS, LUCAS, LINJIONG ZHOU, and ALEXANDER, CURTIS

Abstract

Verification methods for convection-allowing models (CAMs) should consider the finescale spatial and temporal detail provided by CAMs, and including both neighborhood and object-based methods can account for displaced features that may still provide useful information. This work explores both contingency table-based verification techniques and object- based verification techniques as they relate to forecasts of severe convection. Two key fields in severe weather forecasting are investigated: updraft helicity (UH) and simulated composite reflectivity. UH is used to generate severe weather probabilities called surrogate severe fields, which have two tunable parameters: the UH threshold and the smoothing level. Probabilities computed using the UH threshold and smoothing level that give the best area under the receiver operating curve result in very high probabilities, while optimizing the parameters based on the Brier score reliability component results in much lower probabilities. Subjective ratings from participants in the 2018 NOAA Hazardous Weather Testbed Spring Forecasting Experiment (SFE) provide a complementary evaluation source. This work compares the verification methodologies in the context of three CAMs using the Finite-Volume Cubed-Sphere Dynamical Core (FV3), which will be the foundation of the U.S. Unified Forecast System (UFS). Three agencies ran FV3-based CAMs during the five-week 2018 SFE. These FV3-based CAMs are verified alongside a current operational CAM, the High-Resolution Rapid Refresh version 3 (HRRRv3). The HRRR is planned to eventually use the FV3 dynamical core as part of the UFS; as such evaluations relative to current HRRR configurations are imperative to maintaining high forecast quality and informing future implementation decisions. SIGNIFICANCE STATEMENT: The United States is currently working toward unifying its numerical modeling efforts around a single dynamical core, or set of equations that serves as the model framework. We compared three models built around this new dynamical core to the current operational model, focusing on forecasts of severe convection. We also explored different verification techniques, to look at model performance from many angles. A major point discussed in this work is that subjective choices (i.e., techniques, thresholds, fields, etc. used) still play a role in objective verification. While we found that the experimental models are not yet depicting severe weather as well as the operational model according to traditional verification techniques and metrics, there may be improvements captured by newer verification techniques. [ABSTRACT FROM AUTHOR]

Published

2021

46. Global energy and water balance: Characteristics from Finite-volume Atmospheric Model of the IAP/LASG (FAMIL1)

Author

Wei-Chyung Wang, Yimin Liu, Linjiong Zhou, Bian He, Guoxiong Wu, Qing Bao, Haiyang Yu, Xiaocong Wang, and Jiandong Li

Subjects

Global and Planetary Change, Water balance, Coupled model intercomparison project, Climatology, Radiative transfer, Energy balance, General Earth and Planetary Sciences, Environmental Chemistry, Environmental science, Context (language use), Atmospheric model, Sensible heat, Marine stratocumulus

Abstract

This paper documents version 1 of the Finite-volume Atmospheric Model of the IAP/LASG (FAMIL1), which has a flexible horizontal resolution up to a quarter of 1°. The model, currently running on the “Tianhe 1A” supercomputer, is the atmospheric component of the third-generation Flexible Global Ocean-Atmosphere-Land climate System model (FGOALS3) which will participate in the Coupled Model Intercomparison Project Phase 6 (CMIP6). In addition to describing the dynamical core and physical parameterizations of FAMIL1, this paper describes the simulated characteristics of energy and water balances and compares them with observational/reanalysis data. The comparisons indicate that the model simulates well the seasonal and geographical distributions of radiative fluxes at the top of the atmosphere and at the surface, as well as the surface latent and sensible heat fluxes. A major weakness in the energy balance is identified in the regions where extensive and persistent marine stratocumulus is present. Analysis of the global water balance also indicates realistic seasonal and geographical distributions with the global annual mean of evaporation minus precipitation being approximately 10−5 mm d−1. We also examine the connections between the global energy and water balance and discuss the possible link between the two within the context of the findings from the reanalysis data. Finally, the model biases as well as possible solutions are discussed.

Published

2015

47. The Flexible Global Ocean-Atmosphere-Land system model, Spectral Version 2: FGOALS-s2

Author

Yimin Liu, Bian He, Guoxiong Wu, Xiaocong Wang, Hailong Liu, Jie He, Qing Bao, Wei Zhao, Bin Wang, Fangli Qiao, Jun Wang, Pengfei Lin, Pengfei Wang, Zhenya Song, Bo Wu, Yangchun Li, Jiandong Li, Tianjun Zhou, Lijuan Li, Yongqiang Yu, Tongwen Wu, Zaizhi Wang, Weipeng Zheng, Linjiong Zhou, Haiyang Yu, and Yongfu Xu

Subjects

Atmospheric Science, Coupled model intercomparison project, Global temperature, Atmospheric circulation, Climatology, Environmental science, Climate change, Climate model, Precipitation, Transient climate simulation, Atmospheric sciences, Teleconnection

Abstract

The Flexible Global Ocean-Atmosphere-Land System model, Spectral Version 2 (FGOALS-s2) was used to simulate realistic climates and to study anthropogenic influences on climate change. Specifically, the FGOALS-s2 was integrated with Coupled Model Intercomparison Project Phase 5 (CMIP5) to conduct coordinated experiments that will provide valuable scientific information to climate research communities. The performances of FGOALS-s2 were assessed in simulating major climate phenomena, and documented both the strengths and weaknesses of the model. The results indicate that FGOALS-s2 successfully overcomes climate drift, and realistically models global and regional climate characteristics, including SST, precipitation, and atmospheric circulation. In particular, the model accurately captures annual and semi-annual SST cycles in the equatorial Pacific Ocean, and the main characteristic features of the Asian summer monsoon, which include a low-level southwestern jet and five monsoon rainfall centers. The simulated climate variability was further examined in terms of teleconnections, leading modes of global SST (namely, ENSO), Pacific Decadal Oscillations (PDO), and changes in 19th–20th century climate. The analysis demonstrates that FGOALS-s2 realistically simulates extra-tropical teleconnection patterns of large-scale climate, and irregular ENSO periods. The model gives fairly reasonable reconstructions of spatial patterns of PDO and global monsoon changes in the 20th century. However, because the indirect effects of aerosols are not included in the model, the simulated global temperature change during the period 1850–2005 is greater than the observed warming, by 0.6°C. Some other shortcomings of the model are also noted.

Published

2013

48. Revisiting Asian monsoon formation and change associated with Tibetan Plateau forcing: II. Change

Author

Linjiong Zhou, Guoxiong Wu, Buwen Dong, Jieli Hong, Yimin Liu, Anmin Duan, and Qing Bao

Subjects

Atmospheric Science, geography, Plateau, geography.geographical_feature_category, Global warming, Sensible heat, Atmospheric sciences, Sverdrup balance, Anticyclone, Climatology, Environmental science, East Asian Monsoon, East Asia, Precipitation

Abstract

Data analysis based on station observations reveals that many meteorological variables averaged over the Tibetan Plateau (TP) are closely correlated, and their trends during the past decades are well correlated with the rainfall trend of the Asian summer monsoon. However, such correlation does not necessarily imply causality. Further diagnosis confirms the existence of a weakening trend in TP thermal forcing, characterized by weakened surface sensible heat flux in spring and summer during the past decades. This weakening trend is associated with decreasing summer precipitation over northern South Asia and North China and increasing precipitation over northwestern China, South China, and Korea. An atmospheric general circulation model, the HadAM3, is employed to elucidate the causality between the weakening TP forcing and the change in the Asian summer monsoon rainfall. Results demonstrate that a weakening in surface sensible heating over the TP results in reduced summer precipitation in the plateau region and a reduction in the associated latent heat release in summer. These changes in turn result in the weakening of the near-surface cyclonic circulation surrounding the plateau and the subtropical anticyclone over the subtropical western North Pacific, similar to the results obtained from the idealized TP experiment in Part I of this study. The southerly that normally dominates East Asia, ranging from the South China Sea to North China, weakens, resulting in a weaker equilibrated Sverdrup balance between positive vorticity generation and latent heat release. Consequently, the convergence of water vapor transport is confined to South China, forming a unique anomaly pattern in monsoon rainfall, the so-called “south wet and north dry.” Because the weakening trend in TP thermal forcing is associated with global warming, the present results provide an effective means for assessing projections of regional climate over Asia in the context of global warming.

Published

2012

49. FGOALS-s2 Brief

Author

Pengfei Lin, Jiandong Li, Tianju Zhou, Yongqiang Yu, Xiaocong Wang, Bian He, Jun Wang, Qing Bao, Guoxiong Wu, Haiyang Yu, Linjiong Zhou, and Yimin Liu

Subjects

Coupled model intercomparison project, geography, geography.geographical_feature_category, Global climate, Climatology, Sea ice, Environmental science, Climate change, System model

Abstract

This chapter describes the framework of the global climate system model known as FGOALS-s2. FGOALS-s2 consists of the following components: SAMIL2 (atmosphere), LICOM2 (ocean), CSIM5 (sea ice), and CLM3 (land). These components are coupled together with the flux coupler from NCAR. FGOALS-s2 has been used to conduct the experiments for analysis studies in support of the fifth assessment report of the Intergovernmental Panel on Climate Change (IPCC AR5) and phase 5 of the Coupled Model Intercomparison Project (CMIP5). Here, the 500-year preindustrial control run was adopted to briefly investigate the stability of FGOALS-s2.

Published

2013

50. High-Resolution FAMIL

Author

Haiyang Yu, Linjiong Zhou, and Qing Bao

Subjects

General Circulation Model, Scalability, Environmental science, High resolution, Atmospheric model, Supercomputer, Computational science

Abstract

This chapter describes the model speed and model in/out (I/O) efficiency of the high-resolution atmospheric general circulation model the Finite-volume Atmospheric Model of IAP/LASG (FAMIL), investigated at the National Supercomputer Center in Tianjin, China, on its Tianhe-1A supercomputer platform. A series of three-model-day simulations were conducted with the standard Aqua-Planet Experiment (APE) project, designed within FAMIL, to obtain time stamps for the calculation of model speed, simulation cost, and model I/O efficiency. The results of the simulation demonstrate that FAMIL has remarkable scalability below 3,456 and 6,144 cores; the lowest simulation costs were found to be 1,536 and 3,456 cores for 12.5 and 6.25 km resolutions, respectively. Furthermore, FAMIL has excellent I/O scalability and efficiencies of more than 80 and 99 % on 6 and 1,536 I/Os, respectively.

Published

2013