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1. Investigating the "Too Bright" Issue Pertaining to Non‐PBL Clouds Over the South Pacific Trade‐Wind Region in CMIP6 Global Climate Models.

Author

Li, J.‐L. F., Xu, Kuan‐Man, Jiang, Jonathan H., Lee, Wei‐Liang, Yu, Jia‐Yuh, Chern, Jiun‐dar, Cesana, Gregory V., Wu, Longtao, and Stephens, Graeme

Subjects
ATMOSPHERIC boundary layer, CLIMATE change models, INTERTROPICAL convergence zone, ATMOSPHERIC models, TRADE winds
Abstract

This paper examines the "too bright" issue pertaining to non‐planetary boundary layer (PBL) clouds over the South Pacific trade‐wind region and its potential link to the falling ice radiative effects (FIREs). We run sensitivity experiments with CESM2‐CAM6 (CESM2) global climate model with FIREs on (SON) and off (NOS). The model exhibits more in‐cloud liquid water content (CLWC) and droplet above the PBL in NOS, leading to larger shortwave (SW) reflectivity at the top of the atmosphere than in SON over the trade wind regions. CMIP6 models are divided into three subsets: separately calculates the radiative effects of cloud ice and falling ice (SON2), combined (SON1) and without falling ice (NOS). SON2 models exhibit improved CLWC and SW reflectivity similar to CESM2‐SON, while NOS and SON1 models are akin to CESM2‐NOS owing to weaker surface wind stress and warmer ocean surface, caused by the lack of FIREs over the convective zones. Plain Language Summary: This paper examines why some clouds simulated by global climate models (GCMs) tend to reflect too much sunlight back into space (i.e., appear too bright) in the South Pacific trade‐wind region. It explores whether this is linked to the effects of falling ice (FIREs) over the convective zones of the Pacific Intertropical Convergence Zone (ITCZ). Using the CESM2‐CAM6 GCM, we conducted experiments with FIREs turned on (CESM2‐SON) and off (CESM2‐NOS), primarily occurring in the ITCZ. The results showed that when FIREs are turned off, the model predicts more liquid water and cloud droplets above the planetary boundary layer, causing these clouds to reflect more sunlight over the trade‐wind regions. Additionally, we analyzed different climate models from the Coupled Model Intercomparison Project (CMIP6), categorizing them into three groups: those that separately account for the radiative effects of cloud ice and falling ice (SON2), as in CESM2‐SON; those that combine these effects (SON1); and those without falling ice (NOS). The SON2 models showed a better vertical spatial distribution of liquid water content and sunlight reflectivity over the trade‐wind region, while the NOS and SON1 models performed similarly to CESM2‐NOS. Key Points: Cloud properties in CESM2 with falling ice radiative effects (FIREs) (SON) are compared to without FIREs (NOS) over the trade‐wind regionCESM2 NOS exhibits more liquid water content above the planetary boundary layer (PBL) with more SW reflectivity at top of the atmosphere (TOA) over the trade‐wind region compared to CESM2 SONSimilar improvements are found in CESM2‐SON‐type subset of CMIP6 models, linked to stronger surface wind stress and cooler ocean surface [ABSTRACT FROM AUTHOR]

Published
2024
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3. Systematic Validation of Ensemble Cloud‐Process Simulations using Polarimetric Radar Observations and Simulator over the NASA Wallops Flight Facility

Author

Matsui, Toshi, primary, Wolff, David B., additional, Lang, Stephen, additional, Mohr, Karen, additional, Zhang, Minghua, additional, Xie, Shaocheng, additional, Tang, Shuaiqi, additional, Saleeby, Stephen M., additional, Posselt, Derek J., additional, Braun, Scott A., additional, Chern, Jiun‐Dar, additional, Dolan, Brenda, additional, Pippitt, Jason L., additional, and Loftus, Adrian M., additional

Published
2023
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5. Systematic Validation of Ensemble Cloud-Process Simulations Using Polarimetric Radar Observations and Simulator Over the NASA Wallops Flight Facility

Author

Matsui, Toshi, Matsui, Toshi, Wolff, David B., Lang, Stephen, Mohr, Karen, Zhang, Minghua, Xie, Shaocheng, Tang, Shuaiqi, Saleeby, Stephen M., Posselt, Derek J., Braun, Scott A., Chern, Jiun-Dar, Dolan, Brenda, Pippitt, Jason L., Loftus, Adrian M., Matsui, Toshi, Matsui, Toshi, Wolff, David B., Lang, Stephen, Mohr, Karen, Zhang, Minghua, Xie, Shaocheng, Tang, Shuaiqi, Saleeby, Stephen M., Posselt, Derek J., Braun, Scott A., Chern, Jiun-Dar, Dolan, Brenda, Pippitt, Jason L., and Loftus, Adrian M.

Abstract

The BiLateral Operational Storm-Scale Observation and Modeling (BLOSSOM) project was initiated to establish a long-term supersite to improve understanding of cloud physical states and processes as well as to support satellite and climate model programs over the Wallops Flight Facility site via a bilateral approach of storm-scale observations and process modeling. This study highlights a noble systematic validation framework of the BLOSSOM ensemble cloud-process simulations through mixed-phase, light-rain, and deep-convective precipitation cases. The framework consists of creating a domain-shifted ensemble of large-scale forcing data sets, and configuring and performing cloud-process simulations with three different bulk microphysics schemes. Validation uses NASA S-band dual-POLarimetric radar observations in the form of statistical composites and skill scores via a polarimetric radar simulator and newly developed CfRad Data tool (CfRAD). While the simulations capture the overall structures of the reflectivity composites, polarimetric signals are still poorly simulated, mainly due to a lack of representation of ice microphysics diversity in shapes, orientation distributions, and their complex mixtures. Despite the limitation, this new ensemble-based validation framework demonstrates that (a) no particular forcing or microphysics scheme outperforms the rest and (b) the skill scores of coarse- and fine-resolution ensemble simulations with different domain-shifted forcing and microphysics schemes are highly correlated with each other with no clear improvement. On the other hand, this suggests that coarse-resolution ensemble simulations are relevant for selecting the best meteorological forcing and microphysics scheme before conducting computationally demanding large eddy simulations in support of aircraft and satellite instrument development as well as cloud-precipitation-convection parameterizations.

Published
2023

6. Evaluating Precipitation Features and Rainfall Characteristics in a Multi-scale Modeling Framework

Author

Chern, Jiun-Dar, Tao, Wei-Kuo, Lang, Stephen E, Li, Xiaowen, and Matsui, Toshihisa

Subjects
Meteorology And Climatology
Abstract

Cloud and precipitation systems over the tropics and subtropics are simulated with a multi-scale modeling framework (MMF) and compared against the TRMM radar precipitation features (RPFs) product. A methodology, in close analogy to the TRMM RPFs, is developed to analyze simulated cloud precipitating structures from the embedded two-dimensional cloud-resolving models (CRMs) within an MMF. Despite the two-dimensionality of the CRMs, the simulated RPFs population distribution, and horizontal and vertical structure are in good agreement with TRMM observations. However, some deficits are also found in the model simulations. The model tends to overestimate mean convective precipitation rates for RPFs with a size less than 100 km, contributing to the excessive precipitation biases in the warm pool and western Pacific, western and northern India Ocean, and eastern Pacific commonly found in most MMFs. For large features with a size greater than 150 km, both convective and stratiform rain rates are underestimated. The distribution of maximum radar echo top heights as a function of RPF size is well simulated except the model tends to underestimate the occurrence frequency of maximum heights greater than 15 km. The maximum echo top heights for convective cells embedded within large RPFs with a size greater than 150 km are also underestimated. The cyclic lateral boundary with a limited model domain generates artificial occurrences for RPFs with a size close to the model domain size, producing a significant contribution to the total rainfall due to their sizes. This cyclic lateral boundary effect can be easily identified and quantified in both probability and cumulative distribution functions of RPFs. The geophysical distribution of the population of the largest RPFs in the control experiment shows they are mainly located in the Subtropics but also partially contribute to the common MMF biases of excessive precipitation in the Tropics. Sensitivity experiments using CRMs with different domain sizes and different grid spacings show larger domains (higher resolution) tend to shift the RPFs distribution to large (small) sizes. The cyclic lateral boundary biases increase as CRM domain size decreases. The impacts of model horizontal and vertical resolution on simulated convective systems are also investigated.

Published
2019

11. Performance of the Goddard Multiscale Modeling Framework with Goddard Ice Microphysical Schemes

Author

Chern, Jiun-Dar, Tao, Wei-Kuo, Lang, Stephen E, Matsui, Toshihisa, Li, J.-L, Mohr, Karen I, Skofronick-Jackson, Gail M, and Peters-Lidard, Christa D

Subjects
Meteorology And Climatology
Abstract

The multiscale modeling framework (MMF), which replaces traditional cloud parameterizations with cloud-resolving models (CRMs) within a host atmospheric general circulation model (GCM), has become a new approach for climate modeling. The embedded CRMs make it possible to apply CRM-based cloud microphysics directly within a GCM. However, most such schemes have never been tested in a global environment for long-term climate simulation. The benefits of using an MMF to evaluate rigorously and improve microphysics schemes are here demonstrated. Four one-moment microphysical schemes are implemented into the Goddard MMF and their results validated against three CloudSat/CALIPSO cloud ice products and other satellite data. The new four-class (cloud ice, snow, graupel, and frozen drops/hail) ice scheme produces a better overall spatial distribution of cloud ice amount, total cloud fractions, net radiation, and total cloud radiative forcing than earlier three-class ice schemes, with biases within the observational uncertainties. Sensitivity experiments are conducted to examine the impact of recently upgraded microphysical processes on global hydrometeor distributions. Five processes dominate the global distributions of cloud ice and snow amount in long-term simulations: (1) allowing for ice supersaturation in the saturation adjustment, (2) three additional correction terms in the depositional growth of cloud ice to snow, (3) accounting for cloud ice fall speeds, (4) limiting cloud ice particle size, and (5) new size-mapping schemes for snow and graupel. Despite the cloud microphysics improvements, systematic errors associated with subgrid processes, cyclic lateral boundaries in the embedded CRMs, and momentum transport remain and will require future improvement.

Published
2016
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13. Benefits of a 4th Ice Class in the Simulated Radar Reflectivities of Convective Systems Using a Bulk Microphysics Scheme

Author

Lang, Stephen E, Tao, Wei-Kuo, Chern, Jiun-Dar, Wu, Di, and Li, Xiaowen

Subjects
Meteorology And Climatology
Abstract

Numerous cloud microphysical schemes designed for cloud and mesoscale models are currently in use, ranging from simple bulk to multi-moment, multi-class to explicit bin schemes. This study details the benefits of adding a 4th ice class (hail) to an already improved 3-class ice bulk microphysics scheme developed for the Goddard Cumulus Ensemble model based on Rutledge and Hobbs (1983,1984). Besides the addition and modification of several hail processes from Lin et al. (1983), further modifications were made to the 3-ice processes, including allowing greater ice super saturation and mitigating spurious evaporationsublimation in the saturation adjustment scheme, allowing graupelhail to become snow via vapor growth and hail to become graupel via riming, and the inclusion of a rain evaporation correction and vapor diffusivity factor. The improved 3-ice snowgraupel size-mapping schemes were adjusted to be more stable at higher mixing rations and to increase the aggregation effect for snow. A snow density mapping was also added. The new scheme was applied to an intense continental squall line and a weaker, loosely-organized continental case using three different hail intercepts. Peak simulated reflectivities agree well with radar for both the intense and weaker case and were better than earlier 3-ice versions when using a moderate and large intercept for hail, respectively. Simulated reflectivity distributions versus height were also improved versus radar in both cases compared to earlier 3-ice versions. The bin-based rain evaporation correction affected the squall line case more but did not change the overall agreement in reflectivity distributions.

Published
2015

14. Evaluating Observation Influence on Regional Water Budgets in Reanalyses

Author

Bosilovich, Michael G, Chern, Jiun-Dar, Mocko, David, Robertson, Franklin R, and daSilva, Arlindo M

Subjects
Earth Resources And Remote Sensing
Abstract

The assimilation of observations in reanalyses incurs the potential for the physical terms of budgets to be balanced by a term relating the fit of the observations relative to a forecast first guess analysis. This may indicate a limitation in the physical processes of the background model, or perhaps inconsistencies in the observing system and its assimilation. In the MERRA reanalysis, an area of long term moisture flux divergence over land has been identified over the Central United States. Here, we evaluate the water vapor budget in this region, taking advantage of two unique features of the MERRA diagnostic output; 1) a closed water budget that includes the analysis increment and 2) a gridded diagnostic output data set of the assimilated observations and their innovations (e.g. forecast departures). In the Central United States, an anomaly occurs where the analysis adds water to the region, while precipitation decreases and moisture flux divergence increases. This is related more to a change in the observing system than to a deficiency in the model physical processes. MERRAs Gridded Innovations and Observations (GIO) data narrow the observations that influence this feature to the ATOVS and Aqua satellites during the 06Z and 18Z analysis cycles. Observing system experiments further narrow the instruments that affect the anomalous feature to AMSUA (mainly window channels) and AIRS. This effort also shows the complexities of the observing system, and the reactions of the regional water budgets in reanalyses to the assimilated observations.

Published
2014

16. Purdue Atmospheric Models and Applications

Author

Sun, Wen-Yih, primary, Hsu, Wu-Ron, additional, Chern, Jiun-Dar, additional, Chen, Shu-Hua, additional, Wu, Ching-Chi, additional, Yang, Kate Jr-Shiuan, additional, Yeh, Kaosan, additional, Bosilovich, Michael G., additional, Haines, Patrick A, additional, Min, Ki-Hong, additional, Oh, Tae-Jin, additional, MacCall, B. T., additional, Yildirim, Ahmet, additional, Chang, Yi-Lin, additional, Chang, Chiao-Zen, additional, and Yu, Yi-Chiang, additional

Published
2008
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18. Impacts of Aerosol Direct Effects on the South Asian Climate: Assessment of Radiative Feedback Processes Using Model Simulations and Satellite/Surface Measurements

Author

Wang, Sheng-Hsiang, Gautam, Ritesh, Lau, William K. M, Tsay, Si-Chee, Sun, Wen-Yih, Kim, Kyu-Myong, Chern, Jiun-Dar, Hsu, Christina, and Lin, Neng-Huei

Subjects
Meteorology And Climatology
Abstract

Current assessment of aerosol radiative effect is hindered by our incomplete knowledge of aerosol optical properties, especially absorption, and our current inability to quantify physical and microphysical processes. In this research, we investigate direct aerosol radiative effect over heavy aerosol loading areas (e.g., Indo-Gangetic Plains, South/East Asia) and its feedbacks on the South Asian climate during the pre-monsoon season (March-June) using the Purdue Regional Climate Model (PRCM) with prescribed aerosol data derived by the NASA Goddard Earth Observing System Model (GEOS-5). Our modeling domain covers South and East Asia (60-140E and 0-50N) with spatial resolutions of 45 km in horizontal and 28 layers in vertical. The model is integrated from 15 February to 30 June 2008 continuously without nudging (i.e., only forced by initial/boundary conditions). Two numerical experiments are conducted with and without the aerosol-radiation effects. Both simulations are successful in reproducing the synoptic patterns on seasonal-to-interannual time scales and capturing a pre-monsoon feature of the northward rainfall propagation over Indian region in early June which shown in Tropical Rainfall Measuring Mission (TRMM) observation. Preliminary result suggests aerosol-radiation interactions mainly alter surface-atmosphere energetics and further result in an adjustment of the vertical temperature distribution in lower atmosphere (below 700 hPa). The modifications of temperature and associated rainfall and circulation feedbacks on the regional climate will be discussed in the presentation.

Published
2011

19. Improvements in the Scalability of the NASA Goddard Multiscale Modeling Framework for Hurricane Climate Studies

Author

Shen, Bo-Wen, Tao, Wei-Kuo, and Chern, Jiun-Dar

Subjects
Meteorology And Climatology
Abstract

Improving our understanding of hurricane inter-annual variability and the impact of climate change (e.g., doubling CO2 and/or global warming) on hurricanes brings both scientific and computational challenges to researchers. As hurricane dynamics involves multiscale interactions among synoptic-scale flows, mesoscale vortices, and small-scale cloud motions, an ideal numerical model suitable for hurricane studies should demonstrate its capabilities in simulating these interactions. The newly-developed multiscale modeling framework (MMF, Tao et al., 2007) and the substantial computing power by the NASA Columbia supercomputer show promise in pursuing the related studies, as the MMF inherits the advantages of two NASA state-of-the-art modeling components: the GEOS4/fvGCM and 2D GCEs. This article focuses on the computational issues and proposes a revised methodology to improve the MMF's performance and scalability. It is shown that this prototype implementation enables 12-fold performance improvements with 364 CPUs, thereby making it more feasible to study hurricane climate.

Published
2007

20. Simulation of Water Sources and Precipitation Recycling for the MacKenzie, Mississippi and Amazon River Basins

Author

Bosilovich, Michael G and Chern, Jiun-Dar

Subjects
Meteorology And Climatology
Abstract

An atmospheric general circulation model simulation for 1948-1997 of the water budgets for the MacKenzie, Mississippi and Amazon River basins is presented. In addition to the water budget, we include passive tracers to identify the geographic sources of water for the basins, and the analysis focuses on the mechanisms contributing to precipitation recycling in each basin. While each basin s precipitation recycling has a strong dependency on evaporation during the mean annual cycle, the interannual variability of the recycling shows important relationships with the atmospheric circulation. The MacKenzie River basin has only a weak interannual dependency on evaporation, where the variations in zonal moisture transport from the Pacific Ocean can affect the basin water cycle. On the other hand, the Mississippi River basin has strong interannual dependencies on evaporation. While the precipitation recycling weakens with increased low level jet intensity, the evaporation variations exert stronger influence in providing water vapor for convective precipitation at the convective cloud base. High precipitation recycling is also found to be partly connected to warm SSTs in the tropical Pacific Ocean. The Amazon River basin evaporation exhibits small interannual variations, so that the interannual variations of precipitation recycling are related to atmospheric moisture transport from the tropical south Atlantic Ocean. Increasing SSTs over the 50-year period are causing increased easterly transport across the basin. As moisture transport increases, the Amazon precipitation recycling decreases (without real time varying vegetation changes). In addition, precipitation recycling from a bulk diagnostic method is compared to the passive tracer method used in the analysis. While the mean values are different, the interannual variations are comparable between each method. The methods also exhibit similar relationships to the terms of the basin scale water budgets.

Published
2005

21. Numerical experiments of vortices in the wakes of large idealized mountains

Author

Sun Wen-Yih and Chern Jiun-Dar

Subjects
Vortex-motion -- Research, Atmospheric circulation -- Research, Wakes (Fluid dynamics) -- Research, Atmospheric turbulence -- Research, Mountains -- Environmental aspects, Earth sciences, Science and technology
Abstract

The Purdue Mesoscale Model (PMM) is applied to study the flow past large idealized mountains under a low Froude number. Results show that for Reynolds numbers in the range of 4 < Re < 1000, as long as the flow is symmetric to the central line of a symmetric mountain, two vortices remain stably attached to the mountain. For Re is less than or equal to 100, the size of the attached vortices after 120 hours of integration increases linearly with the increase of Re, but the size decreases slightly with Re for Re > 100. Results also show that small perturbations in the oncoming wind, the inclination of the oncoming wind and major axis of the mountain, the mountain shape, and the Coriolis force all can contribute to atmospheric vortex shedding. The Reynolds number is not a good indicator of whether a vortex will stay or break away from the mountain in the atmosphere. When the earth's rotation is included, the simulated pressure field and wind increase considerably on the left-hand side (facing downstream) of the mountain, which is quite different from that of an irrotational flow, although the pattern of vortex shedding is similar. It is also found that the Reynolds number and Beta effect can change the propagating speed but not the period of vortex shedding. On the other hand, the shape and size of the mountain and asymmetry of the oncoming wind can strongly influence the character of vortex shedding.

Published
1994

22. Implementation of Coupled Skin Temperature Analysis and Bias Correction in a Global Atmospheric Data Assimilation System

Author

Radakovich, Jon, Bosilovich, M, Chern, Jiun-dar, and daSilva, Arlindo

Subjects
Earth Resources And Remote Sensing
Abstract

The NASA/NCAR Finite Volume GCM (fvGCM) with the NCAR CLM (Community Land Model) version 2.0 was integrated into the NASA/GMAO Finite Volume Data Assimilation System (fvDAS). A new method was developed for coupled skin temperature assimilation and bias correction where the analysis increment and bias correction term is passed into the CLM2 and considered a forcing term in the solution to the energy balance. For our purposes, the fvDAS CLM2 was run at 1 deg. x 1.25 deg. horizontal resolution with 55 vertical levels. We assimilate the ISCCP-DX (30 km resolution) surface temperature product. The atmospheric analysis was performed 6-hourly, while the skin temperature analysis was performed 3-hourly. The bias correction term, which was updated at the analysis times, was added to the skin temperature tendency equation at every timestep. In this presentation, we focus on the validation of the surface energy budget at the in situ reference sites for the Coordinated Enhanced Observation Period (CEOP). We will concentrate on sites that include independent skin temperature measurements and complete energy budget observations for the month of July 2001. In addition, MODIS skin temperature will be used for validation. Several assimilations were conducted and preliminary results will be presented.

Published
2004

23. On the Land-Ocean Contrast of Tropical Convection and Microphysics Statistics Derived from TRMM Satellite Signals and Global Storm-Resolving Models

Author

Chern, Jiun-Dar, Tao, Wei-Kuo, Lang, Stephen, Matsui, Toshi, Satoh, Masaki, Hashino, Tempei, and Kubota, Takuji

Subjects
Convection, Atmospheric Science, 010504 meteorology & atmospheric sciences, NICAM, Geographic location / entity, Storm environments, Atmospheric model, Precipitation, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Article, Circulation/Dynamics, IPWG-7, Statistics, Mesoscale processes, 0105 earth and related environmental sciences, Microphysics, Atmospheric models, Tropics, Storm, Continental forcing, Atm/Ocean Structure/Phenomena, Climatology, Convective clouds, Environmental science, Satellite
Abstract

A 14-yr climatology of Tropical Rainfall Measuring Mission (TRMM) collocated multisensor signal statistics reveals a distinct land-ocean contrast as well as geographical variability of precipitation type, intensity, and microphysics. Microphysics information inferred from the TRMM Precipitation Radar and Microwave Imager show a large land-ocean contrast for the deep category, suggesting continental convective vigor. Over land, TRMM shows higher echo-top heights and larger maximum echoes, suggesting taller storms and more intense precipitation, as well as larger microwave scattering, suggesting the presence of more/larger frozen convective hydrometeors. This strong land-ocean contrast in deep convection is invariant over seasonal and multiyear time scales. Consequently, relatively short-term simulations from two global storm-resolving models can be evaluated in terms of their land-ocean statistics using the TRMM Triple-Sensor Three-Step Evaluation Framework via a satellite simulator. The models evaluated are the NASA Multiscale Modeling Framework (MMF) and the Nonhydrostatic Icosahedral Cloud Atmospheric Model (NICAM). While both simulations can represent convective land-ocean contrasts in warm precipitation to some extent, near-surface conditions over land are relatively moister in NICAM than MMF, which appears to be the key driver in the divergent warm precipitation results between the two models. Both the MMF and NICAM produced similar frequencies of large CAPE between land and ocean. The dry MMF boundary layer enhanced microwave scattering signals over land, but only NICAM had an enhanced deep convection frequency over land. Neither model could reproduce a realistic land-ocean contrast in deep convective precipitation microphysics. A realistic contrast between land and ocean remains an issue in global storm-resolving modeling., 形態: カラー図版あり, Physical characteristics: Original contains color illustrations, 資料番号: PA1610019000

Published
2016

28. A view of Hurricane Katrina with early 21st century technology

Author

Lin, Xin, Li, Jui-Lin F., Suarez, Max J., Tompkins, Adrian M., Waliser, Duane E., Rienecker, Michele M., Backmeister, Julio, Jiang, Jonathan H., Wu, Huey-T., Tassone, Caterina M., Chern, Jiun-Dar, Chen, Baode, Su, Hui, Lin, Xin, Li, Jui-Lin F., Suarez, Max J., Tompkins, Adrian M., Waliser, Duane E., Rienecker, Michele M., Backmeister, Julio, Jiang, Jonathan H., Wu, Huey-T., Tassone, Caterina M., Chern, Jiun-Dar, Chen, Baode, and Su, Hui

Published
2006

31. A view of Hurricane Katrina with early 21st century technology

Author

Lin, Xin, primary, Li, Jui‐Lin E., additional, Suarez, Max J., additional, Tompkins, Adrian M., additional, Waliser, Duane E., additional, Rienecker, Michele M., additional, Bacmeister, Julio, additional, Jiang, Jonathan H., additional, Wu, Huey‐Tzu, additional, Tassone, Caterina M., additional, Chern, Jiun‐Dar, additional, Chen, Baode, additional, and Su, Hui, additional

Published
2006
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