Your search keyword '"Basara, Jeffrey"' showing total 43 results

1. Farming and the Risk of Flash Droughts.

Author

Basara, Jeffrey and Christian, Jordan

Subjects

*DROUGHTS, *FARM risks, *GREENHOUSE gases, *RAINFALL, *ATMOSPHERIC models, *GLOBAL warming

Published

2023

2. Quantifying Precipitation Efficiency and Drivers of Excessive Precipitation in Post-Landfall Hurricane Harvey.

Author

Brauer, Noah S., Basara, Jeffrey B., Homeyer, Cameron R., McFarquhar, Greg M., and Kirstetter, Pierre E.

Subjects

*HURRICANE Harvey, 2017, *SCIENTIFIC literature, *METEOROLOGICAL precipitation, *TROPICAL cyclones, *RAINFALL, *THUNDERSTORMS

Abstract

Hurricane Harvey produced unprecedented widespread rainfall amounts over 1000 mm in portions of southeast Texas, including Houston, from 26 to 31 August 2017. The highly efficient and prolonged warm rain processes associated with Harvey played a key role in the catastrophic flooding that occurred throughout the region. Precipitation efficiency (PE) is widely referred to in the scientific literature when discussing excessive precipitation events that lead to catastrophic flash flooding, but has yet to be explored or quantified in tropical cyclones coincident with polarimetric radar observations. With the introduction of dual-polarization radar to the NEXRAD WSR-88D network, polarimetric radar variables such as ZH, ZDR, and KDP can be used to gain insight into the precipitation processes that contribute to enhanced PE. It was found that 6-h mean values of ZH between 35 and 45 dBZ, ZDR between 1 and 1.5 dB, and KDP greater than 1° km−1 were collocated with the regions of PE greater than 100% between 27 and 29 August. Additionally, supercell thunderstorms embedded in the outer bands of Harvey were identified via 3–6 km Multi-Radar Multi-Senor (MRMS) rotation tracks and were collocated with swaths of enhanced positive ZH, ZDR, and KDP. A polarimetric rainfall relationship estimates that 1-h mean rainfall rates in these supercells were as high as 85 mm h−1 and made a significant contribution to the excessive precipitation event that occurred over the region. [ABSTRACT FROM AUTHOR]

Published

2020

3. Role of Sea Surface Temperatures in Forcing Circulation Anomalies Driving U.S. Great Plains Pluvial Years.

Author

Flanagan, Paul X., Basara, Jeffrey B., Furtado, Jason C., Martin, Elinor R., and Xiao, Xiangming

Subjects

*OCEAN temperature, *SURFACE forces, *PRECIPITATION anomalies, *PRECIPITATION variability, *WATER supply, *PLAINS

Abstract

In the U.S. Great Plains (GP), diagnosing precipitation variability is key in developing an understanding of the present and future availability of water in the region. Building on previous work investigating U.S. GP pluvial years, this study uses ERA twentieth century (ERA-20C) reanalysis data to investigate key circulation anomalies driving GP precipitation anomalies during a subset of GP pluvial years (called in this paper Pattern pluvial years). With previous research showing links between tropical Pacific sea surface temperature (SST) anomalies and GP climate variability, this study diagnoses the key circulation anomalies through an analysis of SSTs and their influence on the atmosphere. Results show that during Pattern southern Great Plains (SGP) pluvial years, central tropical Pacific SST anomalies are coincident with key atmospheric anomalies across the Pacific basin and North America. During northern Great Plains (NGP) Pattern pluvial years, no specific pattern of oceanic anomalies emerges that forces the circulation anomaly feature inherent in specific NGP pluvial years. Utilizing the results for SGP pluvial years, a conceptual model is developed detailing the identified pathway for the occurrence of circulation patterns that are favorable for pluvial years over the SGP. Overall, results from this study show the importance of the identified SGP atmospheric anomaly signal and the potential for predictability of such events. [ABSTRACT FROM AUTHOR]

Published

2019

4. A Modified Framework for Quantifying Land–Atmosphere Covariability during Hydrometeorological and Soil Wetness Extremes in Oklahoma.

Author

Wakefield, Ryann A., Basara, Jeffrey B., Furtado, Jason C., Illston, Bradley G., Ferguson, Craig. R., and Klein, Petra M.

Subjects

*HUMIDITY, *EXTREME environments, *SOIL moisture, *DROUGHT forecasting, *LAND-atmosphere interactions, *CLIMATOLOGY

Abstract

Global "hot spots" for land–atmosphere coupling have been identified through various modeling studies—both local and global in scope. One hot spot that is common to many of these analyses is the U.S. southern Great Plains (SGP). In this study, we perform a mesoscale analysis, enabled by the Oklahoma Mesonet, that bridges the spatial and temporal gaps between preceding local and global analyses of coupling. We focus primarily on east–west variations in seasonal coupling in the context of interannual variability over the period spanning 2000–15. Using North American Regional Reanalysis (NARR)-derived standardized anomalies of convective triggering potential (CTP) and the low-level humidity index (HI), we investigate changes in the covariance of soil moisture and the atmospheric low-level thermodynamic profile during seasonal hydrometeorological extremes. Daily CTP and HI z scores, dependent upon climatology at individual NARR grid points, were computed and compared to in situ soil moisture observations at the nearest mesonet station to provide nearly collocated annual composites over dry and wet soils. Extreme dry and wet year CTP and HI z-score distributions are shown to deviate significantly from climatology and therefore may constitute atmospheric precursors to extreme events. The most extreme rainfall years differ from climatology but also from one another, indicating variability in the strength of land–atmosphere coupling during these years. Overall, the covariance between soil moisture and CTP/HI is much greater during drought years, and coupling appears more consistent. For example, propagation of drought during 2011 occurred under antecedent CTP and HI conditions that were identified by this study as being conducive to positive dry feedbacks demonstrating potential utility of this framework in forecasting regional drought propagation. [ABSTRACT FROM AUTHOR]

Published

2019

5. A Methodology for Flash Drought Identification: Application of Flash Drought Frequency across the United States.

Author

Christian, Jordan I., Basara, Jeffrey B., Otkin, Jason A., Hunt, Eric D., Wakefield, Ryann A., Flanagan, Paul X., and Xiao, Xiangming

Subjects

*DROUGHT management, *DROUGHTS, *ARID regions, *U.S. states, *SCIENTIFIC community, *CLIMATOLOGY

Abstract

With the increasing use of the term "flash drought" within the scientific community, Otkin et al. provide a general definition that identifies flash droughts based on their unusually rapid rate of intensification. This study presents an objective percentile-based methodology that builds upon that work by identifying flash droughts using standardized evaporative stress ratio (SESR) values and changes in SESR over some period of time. Four criteria are specified to identify flash droughts: two that emphasize the vegetative impacts of flash drought and two that focus on the rapid rate of intensification. The methodology was applied to the North American Regional Reanalysis (NARR) to develop a 38-yr flash drought climatology (1979–2016) across the United States. It was found that SESR derived from NARR data compared well with the satellite-based evaporative stress index for four previously identified flash drought events. Furthermore, four additional flash drought cases were compared with the U.S. Drought Monitor (USDM), and SESR rapidly declined 1–2 weeks before a response was evident with the USDM. From the climatological analysis, a hot spot of flash drought occurrence was revealed over the Great Plains, the Corn Belt, and the western Great Lakes region. Relatively few flash drought events occurred over mountainous and arid regions. Flash droughts were categorized based on their rate of intensification, and it was found that the most intense flash droughts occurred over the central Great Plains, Corn Belt, and western Great Lakes region. [ABSTRACT FROM AUTHOR]

Published

2019

6. Primary Atmospheric Drivers of Pluvial Years in the United States Great Plains.

Author

Flanagan, Paul X., Basara, Jeffrey B., Furtado, Jason C., and Xiao, Xiangming

Subjects

*METEOROLOGICAL precipitation, *OCEAN temperature, *EVAPOTRANSPIRATION, *RAINFALL periodicity

Abstract

Precipitation variability has increased in recent decades across the Great Plains (GP) of the United States. Drought and its associated drivers have been studied in the GP region; however, periods of excessive precipitation (pluvials) at seasonal to interannual scales have received less attention. This study narrows this knowledge gap with the overall goal of understanding GP precipitation variability during pluvial periods. Through composites of relevant atmospheric variables from the ECMWF twentieth-century reanalysis (ERA-20C), key differences between southern Great Plains (SGP) and northern Great Plains (NGP) pluvial periods are highlighted. The SGP pluvial pattern shows an area of negative height anomalies over the southwestern United States with wind anomalies consistent with frequent synoptic wave passages along a southward-shifted North Pacific jet. TheNGPpattern during pluvial periods, by contrast, depicts anomalously low heights in the northwestern United States and an anomalously extended Pacific jet. Analysis of daily heavy precipitation events reveals the key drivers for these pluvial events, namely, an east-west height gradient and associated stronger poleward moisture fluxes. Therefore, the results show that pluvial years over the GP are likely driven by synoptic-scale processes rather than by anomalous seasonal precipitation driven by longer time-scale features. Overall, the results present a possible pathway to predicting the occurrence of pluvial years over the GP and understanding the causes of GP precipitation variability, potentially mitigating the threats of water scarcity and excesses for the public and agricultural sectors. [ABSTRACT FROM AUTHOR]

Published

2018

7. The Effect of the Dry Line and Convective Initiation on Drought Evolution over Oklahoma during the 2011 Drought.

Author

Flanagan, Paul X., Basara, Jeffrey B., Illston, Bradley G., and Otkin, Jason A.

Subjects

*DROUGHTS, *METEOROLOGICAL research, *MATHEMATICAL models of forecasting, *SIMULATION methods & models, *SOIL moisture

Abstract

Observations from the Oklahoma Mesonet and high resolution Weather Research and Forecasting model simulations were used to evaluate the effect that the dry line and large-scale atmospheric patterns had on drought evolution during 2011. Mesonet observations showed that a “dry” and “wet” pattern developed across Oklahoma due to anomalous atmospheric patterns. The location of the dry line varied due to this “dry” and “wet” pattern, with the average dry line location around 1.5° longitude further to the east than climatology. Model simulations were used to further quantify the impact of variable surface conditions on dry line evolution and convective initiation (CI) during April and May 2011. Specifically, soil moisture conditions were altered to depict “wet” and “dry” conditions across the domain by replacing the soil moisture values by each soil category’s porosity or wilting point value. Overall, the strength of the dry line boundary, its position, and subsequent CI were dependent on the modification of soil moisture. The simulations demonstrated that modifying soil moisture impacted the nature of the dry line and showed that soil moisture conditions during the first half of the warm season modified the dry line pattern and influenced the evolution and perpetuation of drought over Oklahoma. [ABSTRACT FROM AUTHOR]

Published

2017

8. Usage of Existing Meteorological Data Networks for Parameterized Road Ice Formation Modeling.

Author

Toms, Benjamin A., Basara, Jeffrey B., and Hong, Yang

Subjects

*IMAGING systems in meteorology, *ATMOSPHERIC circulation, *GEOPHYSICAL prediction, *ATMOSPHERIC sciences, *EARTH sciences, *WEATHER forecasting

Abstract

A road ice prediction model was developed on the basis of existing data networks with an objective of providing a computationally efficient method of road ice forecasting. Icing risk was separated into three distinct road ice formation mechanisms: hoarfrost, freezing fog, and frozen precipitation. Hoarfrost parameterizations were mostly gathered as presented in previous literature, with modifications incorporated to account for diffusional ice crystal growth-rate complexity. Freezing-fog parameterizations were based on previous fog typological analyses under the assumption that fog formation mechanisms are similar in above- and subfreezing temperatures. Frozen-precipitation parameterizations were primarily unique to the developed model but were also partially based on previous research. Diagnostic analyses use a synthesis of Automated Surface Observing System (ASOS), Automated Weather Observing System (AWOS), and Oklahoma Mesonet data. Prognostic analyses utilize the National Digital Forecast Database (NDFD), a 2.5-km gridded database of forecast meteorological variables output from National Weather Service Weather Forecast Offices. A frequency analysis was performed using the diagnostic parameterizations to determine general road icing risk across the state of Oklahoma. The frequency analyses aligned well with expected temporal maxima and confirmed the viability of the developed parameterizations. Further, a fog typological analysis showed the implemented freezing-fog-formation parameterizations to capture 89% of fog events. These results suggest that the developed model, identified as the Road-Ice Model (RIM), may be implemented as a robust option for analyzing the potential for road ice development based on the background meteorological environment. [ABSTRACT FROM AUTHOR]

Published

2017

9. Insights into Atmospheric Contributors to Urban Flash Flooding across the United States Using an Analysis of Rawinsonde Data and Associated Calculated Parameters.

Author

Schroeder, Amanda, Basara, Jeffrey, Shepherd, J. Marshall, and Nelson, Steven

Subjects

*FLOODS, *RAWINSONDES, *CLIMATE research, *WEATHER forecasting, *HAZARD mitigation

Abstract

Flooding is routinely one of the most deadly weather-related hazards in the United States, which highlights the need for more hydrometeorological research related to forecasting these hazardous events. Building upon previous literature, a synergistic study analyzes hydrometeorological aspects of major urban flood events in the United States from 1977 through 2014 caused by locally heavy precipitation. Primary datasets include upper-air soundings and climatological precipitable water (PW) distributions. A major finding of this work is that major urban flood events are associated with extremely anomalous PW values, many of which exceeded the 99th percentile of the associated climatological dataset and all of which were greater than 150% of the climatological mean values. However, of the 40 cases examined in this study, only 15 had PW values that exceeded 50.4 mm (2 in.), illustrating the importance of including the location-specific PW climatology in a PW analysis relevant to the potential for flash floods. Additionally, these events revealed that, despite geographic location and time of year, most had a warm cloud depth of at least 6 km, which is defined here as the layer between the lifting condensation level and the height of the −10°C level. A 'composite' flood sounding was also calculated and revealed a characteristically tropical structure, despite cases related to tropical cyclones being excluded from the study. [ABSTRACT FROM AUTHOR]

Published

2016

10. The WxChallenge: Forecasting Competition, Educational Tool, and Agent of Cultural Change.

Author

Illston, Bradley G., Basara, Jeffrey B., Weiss, Christopher, and Voss, Mike

Subjects

*FORECASTING, *RESEARCH, *COLLEGE students, *GRADUATE students, *SOCIAL change, *HIGHER education research, *CONTESTS

Abstract

The WxChallenge, a project developed at the University of Oklahoma, brings a state-of-the-art, fun, and exciting forecast contest to participants at colleges and universities across North America. The challenge is to forecast the maximum and minimum temperatures, precipitation, and maximum wind speeds for select locations across the United States over a 24-h prediction period. The WxChallenge is open to all undergraduate and graduate students, as well as higher-education faculty, staff, and alumni. Through the use of World Wide Web interfaces accessible by personal computers, tablet computer, and smartphones, the WxChallenge provides a state-of-the-art portal to aid participants in submitting forecasts and alleviate many of the administrative issues (e.g., tracking and scoring) faced by local managers and professors. Since its inception in 2006, 110 universities have participated in the contest and it has been utilized as part of the curricula for 140 classroom courses at various institutions. The inherently challenging nature of the WxChallenge has encouraged its adoption as an educational tool. As its popularity has grown, professors have seen the utility of the Wx-Challenge as a teaching aid and it has become an instructional resource of many meteorological classes at institutions for higher learning. In addition to evidence of educational impacts, the competition has already begun to leave a cultural and social mark on the meteorological learning experience. [ABSTRACT FROM AUTHOR]

Published

2013

11. Mesoscale observations of an extended heat burst and associated wind storm in Central Oklahoma.

Author

Basara, Jeffrey B. and Rowell, Mason D.

Subjects

*WINDSTORMS, *WIND speed, *LOWS (Meteorology), *ATMOSPHERIC pressure, *AIR masses

Abstract

On 13 May 2009, 13 surface-based observing stations within central and western Oklahoma recorded maximum wind speeds in excess of 22.5 m s−1, along with gusts exceeding 28 m s−1 in isolated locations, during a localized wind storm that lasted in excess for over an hour. These wind speeds were associated with an enhanced mesoscale pressure gradient that developed during the late evening of 12 May 2009 and early morning hours of 13 May 2009, which then slowly propagated from west to east. Ultimately, the event produced localized wind damage in northern portions of Oklahoma City. Analysis of the synoptic and mesoscale conditions present at each stage of the event revealed that specific parameters associated with heat bursts occurred during the event, but with the inclusion of varying mesoscale and microscale influences. As such, a close examination of the mesoscale pressure field indicated that a dynamically variable mesoscale convective system (MCS) produced a mesohigh/mesolow couplet that ultimately created the strong pressure gradient. The result was a prolonged period (in excess of 1 h) of enhanced wind speed values across a swath approximately 300 km in length and 50 km in width that were not directly associated with the anomalously warmer and drier conditions that occurred due to the heat burst. Copyright © 2011 Royal Meteorological Society [ABSTRACT FROM AUTHOR]

Published

2012

12. The Oklahoma City Micronet.

Author

Basara, Jeffrey B., Illston, Bradley G., Fiebrich, Christopher A., Browder, Phillip D., Morgan, Cynthia R., McCombs, Alexandria, Bostic, Jared P., McPherson, Renee A., Schroeder, Amanda J., and Crawford, Kenneth C.

Subjects

*METROPOLITAN areas, *LAND use, *ATMOSPHERE, *METEOROLOGICAL equipment

Abstract

The Oklahoma City Micronet (OKCNET) is an operational surface observing network designed to improve atmospheric monitoring across the Oklahoma City, Oklahoma, metropolitan area. The 40 station network consists of 4 Oklahoma Mesonet stations and 36 micronet stations mounted on traffic signals at an average station spacing of approximately 3 km. Using several technical innovations as well as existing infrastructure in Oklahoma City, data are collected and quality assured in near real-time at an interval of 1 min for the traffic signal sites and 5 min for the Mesonet sites. Because OKCNET also spans a land use gradient from rural to urban, the spatial and temporal densities of OKCNET observations have shed new insights on atmospheric processes (e.g. the urban heat island, severe thunderstorm evolution) across the Oklahoma City metropolitan area. Copyright © 2010 Royal Meteorological Society [ABSTRACT FROM AUTHOR]

Published

2011

13. The Impact of the Urban Heat Island during an Intense Heat Wave in Oklahoma City.

Author

Basara, Jeffrey B., Basara, Heather G., Illston, Bradley G., and Crawford, Kenneth C.

Subjects

*URBAN heat islands, *HEAT waves (Meteorology), *HUMIDITY, *HEAT conduction, *THERMODYNAMICS, *CLIMATOLOGY, *MANAGEMENT science

Abstract

During late July and early August 2008, an intense heat wave occurred in Oklahoma City. To quantify the impact of the urban heat island (UHI) in Oklahoma City on observed and apparent temperature conditions during the heat wave event, this study used observations from 46 locations in and around Oklahoma City. The methodology utilized composite values of atmospheric conditions for three primary categories defined by population and general land use: rural, suburban, and urban. The results of the analyses demonstrated that a consistent UHI existed during the study period whereby the composite temperature values within the urban core were approximately 0.5°?C warmer during the day than the rural areas and over 2°?C warmer at night. Further, when the warmer temperatures were combined with ambient humidity conditions, the composite values consistently revealed even warmer heat-related variables within the urban environment as compared with the rural zone. [ABSTRACT FROM AUTHOR]

Published

2010

14. A Geographic Information Systems–Based Analysis of Supercells across Oklahoma from 1994 to 2003.

Author

Hocker, James E. and Basara, Jeffrey B.

Subjects

*THUNDERSTORMS, *ACOUSTIC phenomena in nature, *GEOGRAPHIC information systems, *RAINSTORMS, *RAINFALL, *NATURAL disasters, *WEATHER

Abstract

Oklahoma is a region that is well known for its high frequency of severe thunderstorms, which vary in activity, mode, and coverage. In particular, this region experiences a significant number of highly organized supercell thunderstorms that pose hazards such as high winds, large hail, and tornadoes. This demonstration study focuses on the development and analysis of a 10-yr sample of supercell storms resulting from organized severe weather events in Oklahoma. Geographic information systems (GIS) were used as the primary tool to develop and analyze the 10-yr supercell dataset. The use of GIS technologies within the field of meteorology has increased dramatically in recent years and will likely continue as additional atmospheric science data formats become available in popular GIS software packages such as the Environmental Systems Research Institute’s ArcGIS series. For this specific study, GIS served as a critical component for developing individual georeferenced storm features and analyzing the life span and characteristics of 943 supercell thunderstorms. The results of a series of spatial storm frequency, initiation, termination, and direction analyses are presented. Results revealed that for the period spanning 1994–2003 supercell storms resulting from organized severe weather events were most frequent across several regions, including east-central Oklahoma, southwest Oklahoma, and west-central through northeast Oklahoma, with an overall mean track from the southwest to northeast. Supercell tracks were predominantly southwesterly during the first 5 months of the year, northwesterly from June through September, and once again southwesterly from October through the end of the year. A final set of analyses and examples illustrate the utility of storm feature–based climatologies. [ABSTRACT FROM AUTHOR]

Published

2008

15. Mesoscale Monitoring of Soil Moisture across a Statewide Network.

Author

Illston, Bradley G., Basara, Jeffrey B., Fisher, Daniel K., Elliott, Ronald, Fiebrich, Christopher A., Crawford, Kenneth C., Humes, Karen, and Hunt, Eric

Subjects

*GROUNDWATER, *SOIL moisture, *SOIL physics, *IRRIGATED soils, *SOIL infiltration, *HUMIDITY, *COOLING towers & climate, *ATMOSPHERE, *INDUSTRIAL management

Abstract

Soil moisture is an important component in many hydrologic and land–atmosphere interactions. Understanding the spatial and temporal nature of soil moisture on the mesoscale is vital to determine the influence that land surface processes have on the atmosphere. Recognizing the need for improved in situ soil moisture measurements, the Oklahoma Mesonet, an automated network of 116 remote meteorological stations across Oklahoma, installed Campbell Scientific 229-L devices to measure soil moisture conditions. Herein, background information on the soil moisture measurements, the technical design of the soil moisture network embedded within the Oklahoma Mesonet, and the quality assurance (QA) techniques applied to the observations are provided. This project also demonstrated the importance of operational QA regarding the data collected, whereby the percentage of observations that passed the QA procedures increased significantly once daily QA was applied. [ABSTRACT FROM AUTHOR]

Published

2008

16. Significant Inversions and Rapid In Situ Cooling at a Well-Sited Oklahoma Mesonet Station.

Author

Hunt, Eric D., Basara, Jeffrey B., and Morgan, Cynthia R.

Subjects

*METEOROLOGICAL stations, *INVERSIONS (Geology), *FIELD research, *COOLING, *LANDSCAPE assessment, *GEOPHYSICAL observatories, *WIND speed, *ATMOSPHERIC temperature

Abstract

The El Reno Oklahoma Mesonet (ELRE) site is one of a few Oklahoma Mesonet sites that has measured inversions of 10°C or greater between 1.5 and 9 m. Historical analyses revealed that strong inversions at ELRE have occurred because of rapid cooling near the surface shortly after sunset when conditions are calm, clear, and dry. In addition, ELRE is a very well sited station and is located on very slightly sloped terrain with no obstructions nearby. Four Portable Automated Research Micrometeorological Stations (PARMS) were deployed along a transect orthogonal to ELRE for 3 months in the spring of 2005 to quantify the micrometeorological processes that caused rapid cooling and subsequent strong inversions to form. One-minute data collected from the PARMS and ELRE during the study verified the variability and duration of strong inversion events. Analyses from the field study also revealed that significant horizontal and vertical differences in air temperature and wind speed existed during periods of differential wind speeds between the PARMS and ELRE. [ABSTRACT FROM AUTHOR]

Published

2007

17. The Impact of Land–Atmosphere Interactions on the Benson, Minnesota, Tornado of 11 June 2001.

Author

Cheresnick, Daniel R. and Basara, Jeffrey B.

Subjects

*ATMOSPHERE, *MOISTURE, *EVAPORATION (Meteorology), *TRANSPIRATION (Physics), *WEATHER, *METEOROLOGY

Abstract

Investigates how land–atmosphere interactions played an important role in modifying the local environment. Synoptic conditions; Role of evaporation and transpiration; Impact of moisture in the low-level atmosphere; Potential for severe weather.

Published

2005

18. Improved Installation Procedures for Deep-Layer Soil Moisture Measurements.

Author

Basara, Jeffrey B. and Crawford, Todd M.

Subjects

*SOIL moisture measurement instruments, *SOIL matric potential

Abstract

The Oklahoma Mesonet, an automated network of 115 meteorological observing stations, includes soil moisture monitoring devices at 60 locations. The Campbell Scientific model 229-L matric potential (water potential) sensor was chosen for operational use based on its capability to perform as a fully automated soil water measuring device. Extensive laboratory calibrations were performed on each sensor to ensure the quality of the matric potential measurements. Examination of the data from the Norman site during July 1997 revealed significant inconsistencies between near-surface (5 and 25 cm) measurements of soil moisture and deep-layer (60 and 75 cm) measurements of soil moisture. In particular, a heavy precipitation event was followed by only a small increase in near-surface soil water potential values, while a much larger increase occurred in the deep-layer values. It is theorized that an installation flaw is the cause for these inconsistencies. A solution is proposed in the hope that future efforts to measure soil moisture will not be hindered by similar problems. [ABSTRACT FROM AUTHOR]

Published

2000

19. Synoptic Characteristics of 14-Day Extreme Precipitation Events across the United States.

Author

JENNRICH, GREGORY C., FURTADO, JASON C., BASARA, JEFFREY B., and MARTIN, ELINOR R.

Subjects

*ZONAL winds, *JET streams, *MODES of variability (Climatology), *GEOPOTENTIAL height, *FORECASTING

Abstract

Although significant improvements have been made to the prediction and understanding of extreme precipitation events in recent decades, there is still much to learn about these impactful events on the subseasonal time scale. This study focuses on identifying synoptic patterns and precursors ahead of an extreme precipitation event over the contiguous United States (CONUS). First, we provide a robust definition for 14-day ‘‘extreme precipitation events’’ and partition the CONUS into six different geographic regions to compare and contrast the synoptic patterns associated with events in those regions. Then, several atmospheric variables from ERA-Interim (e.g., geopotential height and zonal winds) are composited to understand the evolution of the atmospheric state before and during a 14-day extreme precipitation event. Common synoptic signals seen during events include significant zonally oriented trough–ridge patterns, an energized subtropical jet stream, and enhanced moisture transport into the affected area. Also, atmospheric-river activity increases in the specific region during these events. Modes of climate variability and lagged composites are then investigated for their potential use in lead-time prediction. Key findings include synoptic-scale anomalies in the North Pacific Ocean and regional connections to modes such as the Pacific–North American pattern and the North Pacific Oscillation. Taken together, our results represent a significant step forward in understanding the evolution of 14-day extreme precipitation events for potential damage and casualty mitigation. [ABSTRACT FROM AUTHOR]

Published

2020

20. Diagnosing Moisture Sources for Flash Floods in the United States. Part II: Terrestrial and Oceanic Sources of Moisture.

Author

Erlingis, Jessica M., Gourley, Jonathan J., and Basara, Jeffrey B.

Subjects

*MOISTURE, *SOIL moisture, *OCEAN temperature, *BOUNDARY layer (Aerodynamics), *FLOODS, *SURFACE interactions, *LATENT heat

Abstract

Backward trajectories were derived from North American Regional Reanalysis data for 19 253 flash flood reports published by the National Weather Service to determine the along-path contribution of the land surface to the moisture budget for flash flood events in the conterminous United States. The impact of land surface interactions was evaluated seasonally and for six regions: the West Coast, Arizona, the Front Range, Flash Flood Alley, the Missouri Valley, and the Appalachians. Parcels were released from locations that were impacted by flash floods and traced backward in time for 120 h. The boundary layer height was used to determine whether moisture increases occurred within the boundary layer or above it. Moisture increases occurring within the boundary layer were attributed to evapotranspiration from the land surface, and surface properties were recorded from an offline run of the Noah land surface model. In general, moisture increases attributed to the land surface were associated with anomalously high surface latent heat fluxes and anomalously low sensible heat fluxes (resulting in a positive anomaly of evaporative fraction) as well as positive anomalies in top-layer soil moisture. Over the ocean, uptakes were associated with positive anomalies in sea surface temperatures, the magnitude of which varies both regionally and seasonally. Major oceanic surface-based source regions of moisture for flash floods in the United States include the Gulf of Mexico and the Gulf of California, while boundary layer moisture increases in the southern plains are attributable in part to interactions between the land surface and the atmosphere. [ABSTRACT FROM AUTHOR]

Published

2019

21. Diagnosing Moisture Sources for Flash Floods in the United States. Part I: Kinematic Trajectories.

Author

Erlingis, Jessica M., Gourley, Jonathan J., and Basara, Jeffrey B.

Subjects

*ATMOSPHERIC boundary layer, *METEOROLOGICAL services, *MOUNTAINS, *FLOODS

Abstract

This study uses backward trajectories derived from North American Regional Reanalysis data for 19 253 flash flood reports during the period 2007–13 published by the National Weather Service to assess the origins of air parcels for flash floods in the conterminous United States. The preferred flow paths for parcels were evaluated seasonally and for six regions of interest: the West Coast, Arizona, the Front Range of the Rocky Mountains, Flash Flood Alley in south-central Texas, the Missouri Valley, and the Appalachians. Parcels were released from vertical columns in the atmosphere at times and locations where there were reported flash floods; these were traced backward in time for 5 days. The temporal and seasonal cycles of flood events in these regions are also explored. The results show the importance of trajectories residing for long periods over oceanic regions such as the Gulf of Mexico and the Caribbean Sea. The flow is generally unidirectional with height in the lower layers of the atmosphere. The trajectory paths from oceanic genesis regions to inland hotspots and their orientation with height provide clues that can assist in the diagnosis of impending flash floods. Part II of this manuscript details the land–atmosphere interactions along the trajectory paths. [ABSTRACT FROM AUTHOR]

Published

2019

22. Sensitivity of Predictions of the Urban Surface Energy Balance and Heat Island to Variations of Urban Canopy Parameters in Simulations with the WRF Model.

Author

NEMUNAITIS-BERRY, KODI L., KLEIN, PETRA M., BASARA, JEFFREY B., and FEDOROVICH, EVGENI

Subjects

*URBAN heat islands, *SURFACE energy, *ATMOSPHERIC models, *SKIN temperature, *CIRCADIAN rhythms, *TEMPERATURE, *HEAT flux

Abstract

As NWP and climate models continue to evolve toward finer grid spacing, efforts have been undertaken to better represent urban effects. For this study, the single-layer urban canopy model (SLUCM) of the High-Resolution Land Data Assimilation System (HRLDAS) and WRF Model was used to investigate the sensitivity of near-surface air temperatures and energy fluxes to SLUCM parameters in uncoupled (land) and coupled (land-atmosphere) predictions. Output from HRLDAS and WRF was compared with observations from the Oklahoma Mesonet and Joint Urban 2003 experiment. Variations in roof albedo (0.04-0.4) produced 40-135 W m22 changes in net radiation and sensible heat fluxes. Sensible and ground heat fluxes varied by 40-100 W m22 with changes in roof thermal conductivity (0.05-1.4). The urban fraction was found to be the only SLUCM parameter to significantly impact latent heat fluxes. Near-surface air temperatures, particularly during the daytime, did not show significant variations with SLUCM parameters (remaining within the 0.5-K range). Differences in urban air temperatures due to the change in boundary layer scheme were greater than the temperature changes due to SLUCM parameter variations. The sensitivity of near-surface air temperatures to SLUCM parameters depended on the method used to calculate the skin temperature of the impervious surface. For all simulations, predicted 2-m urban air temperatures were consistently higher than observations, with deviations approaching 8K during the day and below 3K at night. These large errors affected the model's skill in reproducing the diurnal cycle of UHI intensity. [ABSTRACT FROM AUTHOR]

Published

2017

23. Assessing agricultural drought in summer over Oklahoma Mesonet sites using the water-related vegetation index from MODIS.

Author

Bajgain, Rajen, Xiao, Xiangming, Basara, Jeffrey, Wagle, Pradeep, Zhou, Yuting, Zhang, Yao, and Mahan, Hayden

Subjects

*DROUGHTS, *EFFECT of drought on plants, *DROUGHT management, *WATER temperature, *DROUGHT forecasting

Abstract

Agricultural drought, a common phenomenon in most parts of the world, is one of the most challenging natural hazards to monitor effectively. Land surface water index (LSWI), calculated as a normalized ratio between near infrared (NIR) and short-wave infrared (SWIR), is sensitive to vegetation and soil water content. This study examined the potential of a LSWI-based, drought-monitoring algorithm to assess summer drought over 113 Oklahoma Mesonet stations comprising various land cover and soil types in Oklahoma. Drought duration in a year was determined by the number of days with LSWI <0 (DNLSWI) during summer months (June-August). Summer rainfall anomalies and LSWI anomalies followed a similar seasonal dynamics and showed strong correlations ( r = 0.62-0.73) during drought years (2001, 2006, 2011, and 2012). The DNLSWI tracked the east-west gradient of summer rainfall in Oklahoma. Drought intensity increased with increasing duration of DNLSWI, and the intensity increased rapidly when DNLSWI was more than 48 days. The comparison between LSWI and the US Drought Monitor (USDM) showed a strong linear negative relationship; i.e., higher drought intensity tends to have lower LSWI values and vice versa. However, the agreement between LSWI-based algorithm and USDM indicators varied substantially from 32 % ( D class, moderate drought) to 77 % (0 and D class, no drought) for different drought intensity classes and varied from ∼30 % (western Oklahoma) to >80 % (eastern Oklahoma) across regions. Our results illustrated that drought intensity thresholds can be established by counting DNLSWI (in days) and used as a simple complementary tool in several drought applications for semi-arid and semi-humid regions of Oklahoma. However, larger discrepancies between USDM and the LSWI-based algorithm in arid regions of western Oklahoma suggest the requirement of further adjustment in the algorithm for its application in arid regions. [ABSTRACT FROM AUTHOR]

Published

2017

24. Drought and Pluvial Dipole Events within the Great Plains of the United States.

Author

Christian, Jordan, Christian, Katarina, and Basara, Jeffrey B.

Subjects

*DROUGHTS, *METEOROLOGICAL precipitation, *METEOROLOGICAL research, *CLIMATE research, *STANDARD deviations

Abstract

The purpose of this study was to quantify dipole events (a drought year followed by a pluvial year) for various spatial scales including the nine Oklahoma climate divisions and the author-defined regions of the U.S. Southern Great Plains (SGP), High Plains (HP), and Northern Great Plains (NGP). Analyses revealed that, on average, over twice as many standard deviation (STDEV) dipoles existed in the latter half of the dataset (1955-2013) relative to the first half (1896-1954), suggesting that dramatic increases in precipitation from one year to the next within the Oklahoma climate divisions are increasing with time. For the larger regions within the Great Plains of the United States, the percent chance of a significant pluvial year following a significant drought year was approximately 25% of the time for the SGP and NGP and approximately 16% of the time for the HP. The STDEV dipole analyses further revealed that the frequency of dipoles was consistent between the first and second half of the dataset for the NGP and HP but was increasing with time in the SGP. The temporal periods of anomalous precipitation during relative pluvial years within the STDEV dipole events were unique for each region whereby October occurred most frequently (70%) within the SGP, September occurred most frequently (60%) within the HP, and May occurred most frequently (62%) within the NGP. [ABSTRACT FROM AUTHOR]

Published

2015

25. Improving a Biogeochemical Model to Simulate Microbial‐Mediated Carbon Dynamics in Agricultural Ecosystems.

Author

Deng, Jia, Frolking, Steve, Bajgain, Rajen, Cornell, Carolyn R., Wagle, Pradeep, Xiao, Xiangming, Zhou, Jizhong, Basara, Jeffrey, Steiner, Jean, and Li, Changsheng

Subjects

*ECOSYSTEM dynamics, *ECOLOGICAL disturbances, *MICROBIAL physiology, *SOIL microbiology, *ENZYME kinetics, *CARBON cycle, *SOIL dynamics

Abstract

Soil microbes drive decomposition of soil organic matter (SOM) and regulate soil carbon (C) dynamics. Process‐based models have been developed to quantify changes in soil organic carbon (SOC) and carbon dioxide (CO2) fluxes in agricultural ecosystems. However, microbial processes related to SOM decomposition have not been, or are inadequately, represented in these models, limiting predictions of SOC responses to changes in microbial activities. In this study, we developed a microbial‐mediated decomposition model based on a widely used biogeochemical model, DeNitrification‐DeComposition (DNDC), to simulate C dynamics in agricultural ecosystems. The model simulates organic matter decomposition, soil respiration, and SOC formation by simulating microbial and enzyme dynamics and their controls on decomposition, and considering impacts of climate, soil, crop, and farming management practices (FMPs) on C dynamics. When evaluated against field observations of net ecosystem CO2 exchange (NEE) and SOC change in two winter wheat systems, the model successfully captured both NEE and SOC changes under different FMPs. Inclusion of microbial processes improved the model's performance in simulating peak CO2 fluxes induced by residue return, primarily by capturing priming effects of residue inputs. We also investigated impacts of microbial physiology, SOM, and FMPs on soil C dynamics. Our results demonstrated that residue or manure input drove microbial activity and predominantly regulated the CO2 fluxes, and manure amendment largely regulated long‐term SOC change. The microbial physiology had considerable impacts on the microbial activities and soil C dynamics, emphasizing the necessity of considering microbial physiology and activities when assessing soil C dynamics in agricultural ecosystems. Plain Language Summary: Soil microbes drive decomposition of soil organic matter (SOM) and regulate soil carbon (C) dynamics. Process‐based models are useful tools for quantifying changes in soil organic carbon (SOC) and carbon dioxide (CO2) fluxes in agricultural ecosystems. However, microbial processes related to SOM decomposition have not been, or are inadequately, represented in these models, limiting predictions of SOC responses to changes in microbial activities. We developed a microbial‐mediated decomposition model based on a widely used biogeochemical model, DeNitrification‐DeComposition (DNDC), to simulate C dynamics in agricultural ecosystems. The model simulates organic matter decomposition, soil respiration, and SOC formation by simulating microbial dynamics and controls on decomposition, and considering impacts of climate, soil, crop, and farming management practices (FMPs) on C dynamics. We also investigated impacts of microbial physiology, SOM, and FMPs on soil C dynamics. Our results demonstrated that residue or manure input drove microbial activity and predominantly regulated CO2 fluxes, and manure amendment largely regulated long‐term SOC change. The microbial physiology had considerable impacts on microbial activities and soil C dynamics, emphasizing the necessity of considering microbial physiology and activities when assessing soil C dynamics in agricultural ecosystems. These results provide insights in simulating microbial‐mediated soil C dynamics in agricultural ecosystems. Key Points: A biogeochemical model was improved to simulate microbe‐driven soil organic matter (SOM) decomposition and carbon dynamics in agricultural ecosystemsThe model simulates carbon dynamics by simulating both microbial controls and impacts of soil, crop, and farming management practicesCarbon input drives microbial activity and exerts large impacts on carbon dynamics while microbes play a central role in decomposing SOM [ABSTRACT FROM AUTHOR]

Published

2021

26. Tornadic Supercell Environments Analyzed Using Surface and Reanalysis Data: A Spatiotemporal Relational Data-Mining Approach.

Author

Gagne, David John, McGovern, Amy, Basara, Jeffrey B., and Brown, Rodger A.

Subjects

*THUNDERSTORMS, *DATA mining, *WIND shear, *ACOUSTIC phenomena in nature, *SPATIOTEMPORAL processes, *ALGORITHMS

Abstract

Oklahoma Mesonet surface data and North American Regional Reanalysis data were integrated with the tracks of over 900 tornadic and nontornadic supercell thunderstorms in Oklahoma from 1994 to 2003 to observe the evolution of near-storm environments with data currently available to operational forecasters. These data are used to train a complex data-mining algorithm that can analyze the variability of meteorological data in both space and time and produce a probabilistic prediction of tornadogenesis given variables describing the near-storm environment. The algorithm was assessed for utility in four ways. First, its probability forecasts were scored. The algorithm did produce some useful skill in discriminating between tornadic and nontornadic supercells as well as in producing reliable probabilities. Second, its selection of relevant attributes was assessed for physical significance. Surface thermodynamic parameters, instability, and bulk wind shear were among the most significant attributes. Third, the algorithm's skill was compared with the skill of single variables commonly used for tornado prediction. The algorithm did noticeably outperform all of the single variables, including composite parameters. Fourth, the situational variations of the predictions from the algorithm were shown in case studies. They revealed instances both in which the algorithm excelled and in which the algorithm was limited. [ABSTRACT FROM AUTHOR]

Published

2012

27. From Standard Weather Stations to Virtual Micro-Meteorological Towers in Ungauged Sites: Modeling Tool for Surface Energy Fluxes, Evapotranspiration, Soil Temperature, and Soil Moisture Estimations.

Author

Celis, Jorge A., Moreno, Hernan A., Basara, Jeffrey B., McPherson, Renee A., Cosh, Michael, Ochsner, Tyson, Xiao, Xiangming, and Biggs, Trent W.

Subjects

*SOIL temperature, *FLUX (Energy), *METEOROLOGICAL stations, *SURFACE energy, *EVAPOTRANSPIRATION, *GRASSLAND soils, *SOIL moisture

Abstract

One of the benefits of training a process-based, land surface model is the capacity to use it in ungauged sites as a complement to standard weather stations for predicting energy fluxes, evapotranspiration, and surface and root-zone soil temperature and moisture. In this study, dynamic (i.e., time-evolving) vegetation parameters were derived from remotely sensed Moderate Resolution Imaging Spectroradiometer (MODIS) imagery and coupled with a physics-based land surface model (tin-based Real-time Integrated Basin Simulator (tRIBS)) at four eddy covariance (EC) sites in south-central U.S. to test the predictability of micro-meteorological, soil-related, and energy flux-related variables. One cropland and one grassland EC site in northern Oklahoma, USA, were used to tune the model with respect to energy fluxes, soil temperature, and moisture. Calibrated model parameters, mostly related to the soil, were then transferred to two other EC sites in Oklahoma with similar soil and vegetation types. New dynamic vegetation parameter time series were updated according to MODIS imagery at each site. Overall, the tRIBS model captured both seasonal and diurnal cycles of the energy partitioning and soil temperatures across all four stations, as indicated by the model assessment metrics, although large uncertainties appeared in the prediction of ground heat flux, surface, and root-zone soil moisture at some stations. The transferability of previously calibrated model parameters and the use of MODIS to derive dynamic vegetation parameters enabled rapid yet reasonable predictions. The model was proven to be a convenient complement to standard weather stations particularly for sites where eddy covariance or similar equipment is not available. [ABSTRACT FROM AUTHOR]

Published

2021

28. Polarimetric Signatures in Landfalling Tropical Cyclones.

Author

Homeyer, Cameron R., Fierro, Alexandre O., Schenkel, Benjamin A., Didlake Jr., Anthony C., McFarquhar, Greg M., Hu, Jiaxi, Ryzhkov, Alexander V., Basara, Jeffrey B., Murphy, Amanda M., and Zawislak, Jonathan

Subjects

*TROPICAL cyclones, *WIND shear, *RADAR, *ATMOSPHERIC temperature, *HURRICANES, *ALTITUDES

Abstract

Polarimetric radar observations from the NEXRAD WSR-88D operational radar network in the contiguous United States, routinely available since 2013, are used to reveal three prominent microphysical signatures in landfalling tropical cyclones: 1) hydrometeor size sorting within the eyewall convection, 2) vertical displacement of the melting layer within the inner core, and 3) dendritic growth layers within stratiform regions of the inner core. Size sorting signatures within eyewall convection are observed with greater frequency and prominence in more intense hurricanes, and are observed predominantly within the deep-layer environmental wind shear vector-relative quadrants that harbor the greatest frequency of deep convection (i.e., downshear and left-of-shear). Melting-layer displacements are shown that exceed 1 km in altitude compared to melting-layer altitudes in outer rainbands and are complemented by analyses of archived dropsonde data. Dendritic growth and attendant snow aggregation signatures in the inner core are found to occur more often when echo-top altitudes are low (≤10 km MSL), nearer the −15°C isotherm commonly associated with dendritic growth. These signatures, uniquely observed by polarimetric radar, provide greater insight into the physical structure and thermodynamic characteristics of tropical cyclones, which are important for improving rainfall estimation and the representation of tropical cyclones in numerical models. [ABSTRACT FROM AUTHOR]

Published

2021

29. Flash Droughts: A Review and Assessment of the Challenges Imposed by Rapid-Onset Droughts in the United States.

Author

Otkin, Jason A., Svoboda, Mark, Hunt, Eric D., Ford, Trent W., Anderson, Martha C., Hain, Christopher, and Basara, Jeffrey B.

Subjects

*METEOROLOGICAL observations, *DROUGHT forecasting, *DROUGHTS, *ATMOSPHERIC models, *EVAPOTRANSPIRATION

Abstract

Given the increasing use of the term “flash drought” by the media and scientific community, it is prudent to develop a consistent definition that can be used to identify these events and to understand their salient characteristics. It is generally accepted that flash droughts occur more often during the summer owing to increased evaporative demand; however, two distinct approaches have been used to identify them. The first approach focuses on their rate of intensification, whereas the second approach implicitly focuses on their duration. These conflicting notions for what constitutes a flash drought (i.e., unusually fast intensification vs short duration) introduce ambiguity that affects our ability to detect their onset, monitor their development, and understand the mechanisms that control their evolution. Here, we propose that the definition for “flash drought” should explicitly focus on its rate of intensification rather than its duration, with droughts that develop much more rapidly than normal identified as flash droughts. There are two primary reasons for favoring the intensification approach over the duration approach. First, longevity and impact are fundamental characteristics of drought. Thus, short-term events lasting only a few days and having minimal impacts are inconsistent with the general understanding of drought and therefore should not be considered flash droughts. Second, by focusing on their rapid rate of intensification, the proposed “flash drought” definition highlights the unique challenges faced by vulnerable stakeholders who have less time to prepare for its adverse effects. [ABSTRACT FROM AUTHOR]

Published

2018

30. Solar Energy Prediction: An International Contest to Initiate Interdisciplinary Research on Compelling Meteorological Problems.

Author

McGovern, Amy, Gagne, David John, Basara, Jeffrey, Hamill, Thomas M., and Margolin, David

Subjects

*CONTESTS, *SOLAR energy, *ENVIRONMENTAL sciences, *ARTIFICIAL intelligence, *WEBSITES

Abstract

The article discusses the changes made to the format of the international contest sponsored by the AMS Committee on Artificial Intelligence and Its Applications to Environmental Science for 2013-2014 to determine which approach produces the best total daily solar energy forecast. These changes include the use of the year prior to the contest to gather a more complex dataset for predictions, the hosting of the contest Website on Kaggle and the extension of the contest's time window.

Published

2015

31. Atmospheric Contributors to Heavy Rainfall Events in the Arkansas-Red River Basin.

Author

McCorkle, Taylor A., Williams, Skylar S., Pfeiffer, Timothy A., and Basara, Jeffrey B.

Subjects

*METEOROLOGICAL precipitation, *WATERSHEDS, *RAINFALL, *CLIMATOLOGY, *THERMODYNAMICS

Abstract

This study analyzed the top 1% 24-hour rainfall events from 1994 to 2013 at eight climatological sites that represent the east to west precipitation gradient across the Arkansas-Red River Basin in North America. A total of 131 cases were identified and subsequently classified on the synoptic-scale, mesoscale, and local-scale to compile a climatological analysis of these extreme, heavy rainfall events based on atmospheric forcings. For each location, the prominent midtropospheric pattern, mesoscale feature, and predetermined thermodynamic variables were used to classify each 1% rainfall event. Individual events were then compared with other cases throughout the basin. The most profound results were that the magnitudes of the thermodynamic variables such as convective available potential energy and precipitable water values were poor predictors of the amount of rainfall produced in these extreme events. Further, the mesoscale forcings had more of an impact during the warm season and for the westernmost locations, whereas synoptic forcings were extremely prevalent during the cold season at the easternmost locations in the basin. The implications of this research are aimed at improving the forecasting of heavy precipitation at individual weather forecasts offices within the basin through the identified patterns at various scales. [ABSTRACT FROM AUTHOR]

Published

2016

32. Facilitating the Use of Drought Early Warning Information through Interactions with Agricultural Stakeholders.

Author

OTKIN, JASON A., SHAFER, MARK, SVOBODA, MARK, WARDLOW, BRIAN, ANDERSON, MARTHA C., HAIN, CHRISTOPHER, and BASARA, JEFFREY

Subjects

*DROUGHTS, *EVAPORATION (Meteorology), *GLOBAL temperature change research, *CLIMATE research, *METEOROLOGICAL research

Abstract

The article discusses the highlights of focus group meetings with stakeholders on the use of drought early warning information to mitigate drought risk. Topics covered include the effective dissemination of drought early warning information, the characteristics and impacts of flash droughts, and the evolution of the Evaporative Stress Index (ESI), ESI change anomalies, Rapid Change Index (RCI) and drought intensification probabilistic forecasts.

Published

2015

33. A Semiphysical Microwave Surface Emission Model for Soil Moisture Retrieval.

Author

Shen, Xinyi, Hong, Yang, Qin, Qiming, Basara, Jeffrey B., Mao, Kebiao, and Wang, D.

Subjects

*MICROWAVES, *SOIL moisture, *REMOTE sensing, *ROUGH surfaces, *EMISSIVITY

Abstract

This study proposes a microwave surface emission model for soil moisture retrieval using radiometer data based on today's most widely used physical model, i.e., advanced integral equation model (AIEM). Soil roughness and moisture effects are easily yet accurately decoupled in the proposed model. In the field case study, the total least squares method, instead of the least squares (LS) method, is applied for the first time in soil moisture retrieval to solve the error in variable linear equation set to further reduce the estimation error. Validated by the Soil Moisture Experiment 2003 campaign data in Oklahoma, the root mean square error (RMSE) and R^2 of volumetric soil moisture varies from 1.5% to 4.2% and 0.92 to 0.43 at L/C/X bands and 40/55° incidence angles. Compared with previous studies, the proposed model has several new features: 1) it is location independent since the model is derived through reproducing the behavior of the AIEM; 2) its high fidelity to AIEM significantly improves the accuracy, whereas its linearity makes it easy to invert; and 3) the soil moisture retrieval based on the proposed model requires no prior knowledge of soil roughness in the scenario of the demonstrated case study. The L-band/V-polarization radiometer data yield the best retrieval result with an RMSE of 1.5% and R^2 of 0.92, whereas increasing frequency increases the error because the sensitivity of emissivity to ground soil moisture decreases, and the valid roughness region, i.e., khRMS < 3, of the AIEM narrows. [ABSTRACT FROM PUBLISHER]

Published

2015

34. Examining Rapid Onset Drought Development Using the Thermal Infrared-Based Evaporative Stress Index.

Author

OTKIN, JASON A., ANDERSON, MARTHA C., HAIN, CHRISTOPHER, MLADENOVA, ILIANA E., BASARA, JEFFREY B., and SVOBODA, MARK

Subjects

*DROUGHTS, *REMOTE sensing, *NATURAL disaster warning systems, *EVAPOTRANSPIRATION, *METEOROLOGY, *ATMOSPHERIC temperature, *COMPARATIVE studies

Abstract

Reliable indicators of rapid drought onset can help to improve the effectiveness of drought early warning systems. In this study, the evaporative stress index (ESI), which uses remotely sensed thermal infrared imagery to estimate évapotranspiration (ET), is compared to drought classifications in the U.S. Drought Monitor (USDM) and standard precipitation-based drought indicators for several cases of rapid drought development that have occurred across the United States in recent years. Analysis of meteorological time series from the North American Regional Reanalysis indicates that these events are typically characterized by warm air temperature and low cloud cover anomalies, often with high winds and dewpoint depressions that serve to hasten evaporative depletion of soil moisture reserves. Stan-dardized change anomalies depicting the rate at which various multiweek ESI composites changed over different time intervals are computed to more easily identify areas experiencing rapid changes in ET. Overall, the results demonstrate that ESI change anomalies can provide early warning of incipient drought impacts on agricultural systems, as indicated in crop condition reports collected by the National Agricultural Statistics Service. In each case examined, large negative change anomalies indicative of rapidly drying conditions were either coincident with the introduction of drought in the USDM or lead the USDM drought depiction by several weeks, depending on which ESI composite and time-differencing interval was used. Incorporation of the ESI as a data layer used in the construction of the USDM may improve timely depictions of moisture conditions and vegetation stress associated with flash drought events. [ABSTRACT FROM AUTHOR]

Published

2013

35. Climate change affecting temperature and aridity zones: a case study in Eastern Inner Mongolia, China from 1960-2008.

Author

Dong, Jinwei, Liu, Jiyuan, Zhang, Geli, Basara, Jeffrey, Greene, Scott, and Xiao, Xiangming

Subjects

*CLIMATE change, *ECOLOGICAL heterogeneity, *REGRESSION analysis, *CROPPING systems

Abstract

Recent climate change is substantially affecting the spatial pattern of geographical zones, and the temporal and spatial inconsistency of climatic warming and drying patterns contributes to the complexity of the shifting of temperature and aridity zones. Eastern Inner Mongolia, China, located in the interface region of different biomes and ecogeographic zones, has experienced dramatic drying and warming over the past several decades. In this study, the annual accumulated temperature above 10 °C (AAT10) and the aridity index, two key indicators in geographical regionalization, are used to assess warming and drying processes and track the movements of temperature and aridity zones from 1960 to 2008. The results show a significant warming at the regional level from 1960 to 2008 with an AAT10 increase rate of 7.89 °C·d/year ( p < 0.001) in Eastern Inner Mongolia, while the drying trend was not significant during this period. Spatial heterogeneity of warming and drying distributions was also evident. Analysis of warming and drying via piecewise regression revealed two separate, specific trends between the first 31 years (1960-1990) and the subsequent 18 years (1991-2008). Generally, mild warming and very slight wetting occurred prior to 1990, while after 1991 both warming and drying were significant and enhanced. Continuous warming drove a northward shift of temperature zones from the 1960s to 2000s, while aridity zones displayed enhanced temporal and spatial variability. Climate change effects on temperature and aridity zones imply that the patterns of cropping systems, macro-ecosystems, and human land use modes are potentially undergoing migration and modification due to climate change. [ABSTRACT FROM AUTHOR]

Published

2013

36. Using ENVISAT ASAR Global Mode Data for Surface Soil Moisture Retrieval Over Oklahoma, USA.

Author

Pathe, Carsten, Wagner, Wolfgang, Sabel, Daniel, Doubkova, Marcela, and Basara, Jeffrey B.

Subjects

*SYNTHETIC aperture radar, *IMAGING systems, *REMOTE sensing, *ARTIFICIAL satellites, *SOIL moisture measurement, *HYDROLOGY

Abstract

The advanced synthetic aperture radar (ASAR) on-board of the satellite ENVISAT can be operated in global monitoring (GM) mode. ASAR GM mode has delivered the first global multiyear C-band backscatter data set in HH polarization at a spatial resolution of 1 km. This paper investigates if ASAR GM can be used for retrieving soil moisture using a change detection approach over large regions. A method previously developed for the European Remote Sensing (ERS) scatterometer is adapted for use with ASAR GM and tested over Oklahoma, USA. The ASAR-GM-derived relative soil moisture index is compared to 50-km ERS soil moisture data and pointlike in situ measurements from the Oklahoma MESONET. Even though the scale gap from ASAR GM to the in situ measurements is less pronounced than in the case of the ERS scatterometer, the correlation for ASAR against the in situ measurements is, in general, somewhat weaker than for the ERS scatterometer. The analysis suggests that this is mainly due to the much higher noise level of ASAR GM compared to the ERS scatterometer. Therefore, some spatial averaging to 3-10 km is recommended to reduce the noise of the ASAR GM soil moisture images. Nevertheless, the study demonstrates that ASAR GM allows resolving spatial details in the soil moisture patterns not observable in the ERS scatterometer measurements while still retaining the basic capability of the ERS scatterometer to capture temporal trends over large areas. [ABSTRACT FROM AUTHOR]

Published

2009

37. Evaluation of Satellite Estimates of Land Surface Temperature from GOES over the United States.

Author

Pinker, Rachel T., Sun, Donglian, Hung, Meng-Pai, Li, Chuan, and Basara, Jeffrey B.

Subjects

*ALGORITHMS, *TEMPERATURE measurements, *ATMOSPHERIC radiation, *SATELLITE meteorology, *METEOROLOGICAL satellites

Abstract

A comprehensive evaluation of split-window and triple-window algorithms to estimate land surface temperature (LST) from Geostationary Operational Environmental Satellites (GOES) that were previously described by Sun and Pinker is presented. The evaluation of the split-window algorithm is done against ground observations and against independently developed algorithms. The triple-window algorithm is evaluated only for nighttime against ground observations and against the Sun and Pinker split-window (SP-SW) algorithm. The ground observations used are from the Atmospheric Radiation Measurement Program (ARM) Central Facility, Southern Great Plains site (April 1997–March 1998); from five Surface Radiation Budget Network (SURFRAD) stations (1996–2000); and from the Oklahoma Mesonet. The independent algorithms used for comparison include the National Oceanic and Atmospheric Administration/National Environmental Satellite, Data and Information Service operational method and the following split-window algorithms: that of Price, that of Prata and Platt, two versions of that of Ulivieri, that of Vidal, two versions of that of Sobrino, that of Coll and others, the generalized split-window algorithm as described by Becker and Li and by Wan and Dozier, and the Becker and Li algorithm with water vapor correction. The evaluation against the ARM and SURFRAD observations indicates that the LST retrievals from the SP-SW algorithm are in closer agreement with the ground observations than are the other algorithms tested. When evaluated against observations from the Oklahoma Mesonet, the triple-window algorithm is found to perform better than the split-window algorithm during nighttime. [ABSTRACT FROM AUTHOR]

Published

2009

38. Description and Evaluation of the Characteristics of the NCAR High-Resolution Land Data Assimilation System.

Author

Fei Chen, Manning, Kevin W., LeMone, Margaret A., Trier, Stanley B., Alfieri, Joseph G., Roberts, Rita, Tewari, Mukul, Niyogi, Dev, Horst, Thomas W., Oncley, Steven P., Basara, Jeffrey B., and Blanken, Peter D.

Subjects

*CLIMATOLOGY, *LAND use, *METEOROLOGICAL research, *ATMOSPHERIC pressure, *TEMPERATURE, *SOIL moisture, *EVAPORATION (Meteorology)

Abstract

This paper describes important characteristics of an uncoupled high-resolution land data assimilation system (HRLDAS) and presents a systematic evaluation of 18-month-long HRLDAS numerical experiments, conducted in two nested domains (with 12- and 4-km grid spacing) for the period from 1 January 2001 to 30 June 2002, in the context of the International H2O Project (IHOP_2002). HRLDAS was developed at the National Center for Atmospheric Research (NCAR) to initialize land-state variables of the coupled Weather Research and Forecasting (WRF)–land surface model (LSM) for high-resolution applications. Both uncoupled HRDLAS and coupled WRF are executed on the same grid, sharing the same LSM, land use, soil texture, terrain height, time-varying vegetation fields, and LSM parameters to ensure the same soil moisture climatological description between the two modeling systems so that HRLDAS soil state variables can be used to initialize WRF–LSM without conversion and interpolation. If HRLDAS is initialized with soil conditions previously spun up from other models, it requires roughly 8–10 months for HRLDAS to reach quasi equilibrium and is highly dependent on soil texture. However, the HRLDAS surface heat fluxes can reach quasi-equilibrium state within 3 months for most soil texture categories. Atmospheric forcing conditions used to drive HRLDAS were evaluated against Oklahoma Mesonet data, and the response of HRLDAS to typical errors in each atmospheric forcing variable was examined. HRLDAS-simulated finescale (4 km) soil moisture, temperature, and surface heat fluxes agreed well with the Oklahoma Mesonet and IHOP_2002 field data. One case study shows high correlation between HRLDAS evaporation and the low-level water vapor field derived from radar analysis. [ABSTRACT FROM AUTHOR]

Published

2007

39. Statewide Monitoring of the Mesoscale Environment: A Technical Update on the Oklahoma Mesonet.

Author

McPherson, Renee A., Fiebrich, Christopher A., Crawford, Kenneth C., Elliott, Ronald L., Kilby, James R., Grimsley, David L., Martinez, Janet E., Basara, Jeffrey B., Illston, Bradley G., Morris, Dale A., Kloesel, Kevin A., Stadler, Stephen J., Melvin, Andrea D., Sutherland, Albert J., Shrivastava, Himanshu, Carlson, J. D., Wolfinbarger, J. Michael, Bostic, Jared P., and Demko, David B.

Subjects

*ENVIRONMENTAL monitoring, *METEOROLOGICAL stations, *QUALITY assurance, *ONLINE data processing, *DECISION making, *COMPUTERS in engineering, *EQUIPMENT & supplies

Abstract

Established as a multipurpose network, the Oklahoma Mesonet operates more than 110 surface observing stations that send data every 5 min to an operations center for data quality assurance, product generation, and dissemination. Quality-assured data are available within 5 min of the observation time. Since 1994, the Oklahoma Mesonet has collected 3.5 billion weather and soil observations and produced millions of decision-making products for its customers. [ABSTRACT FROM AUTHOR]

Published

2007

40. Verification of a Mesoscale Data-Assimilation and Forecasting System for the Oklahoma City Area during the Joint Urban 2003 Field Project.

Author

Yubao Liu, Fei Chen, Warner, Thomas, and Basara, Jeffrey

Subjects

*ATMOSPHERE, *FORECASTING, *ATMOSPHERIC models, *AMBIENCE (Environment), *METEOROLOGICAL instruments, *METEOROLOGICAL services, *RESEARCH

Abstract

The National Center for Atmospheric Research (NCAR) and the U.S. Army Test and Evaluation Command have developed a multiscale, rapid-cycling, real-time, four-dimensional data-assimilation and forecasting system that has been in operational use at five Army test ranges since 2001. This system was employed to provide operational modeling support for the Joint Urban 2003 (JU2003) Dispersion Experiment, conducted in Oklahoma City, Oklahoma, during July 2003. To better support this mission, modifications were made to the nonlocal boundary layer (BL) parameterization (known as the Medium Range Forecast scheme) of the fifth-generation Pennsylvania State University–NCAR Mesoscale Model, in order to improve BL forecasts. The NCEP–Oregon State University–Air Force–Hydrologic Research Laboratory land surface model was also improved to better represent urban forcing. Verification of the operational model runs and retrospectively simulated cases show 1) a significantly reduced low bias in the forecast surface wind speed and 2) more realistic daytime BL heights. During JU2003, the forecast urban heat island, urban dry bubble, and urban BL height agree reasonably well with observations and conceptual models. An analysis of three-dimensional atmospheric structures, based on model analyses for eight clear-sky days during the field program, reveals some interesting features of the Oklahoma City urban BL, including complex thermally induced circulations and associated convergence/divergence zones, a nocturnal thermal shadow downwind of the urban area, and the reduction of low-level jet wind speeds by more vigorous nocturnal mixing over the city. [ABSTRACT FROM AUTHOR]

Published

2006

41. A Multiscale Remote Sensing Model for Disaggregating Regional Fluxes to Micrometeorological Scales.

Author

Norman, J. M., Mecikalski, John R., Torn, Ryan D., Kustas, William P., Basara, Jeffrey B., and Anderson, Martha C.

Subjects

*MICROMETEOROLOGY, *ALGORITHMS, *ATMOSPHERIC models, *LANDSAT satellites, *REMOTE sensing, GEOSTATIONARY Operational Environmental Satellite (GOES)

Abstract

Disaggregation of regional-scale (103 m) flux estimates to micrometeorological scales (101–102 m) facilitates direct comparison between land surface models and ground-based observations. Inversely, it also provides a means for upscaling flux-tower information into a regional context. The utility of the Atmosphere–Land Exchange Inverse (ALEXI) model and associated disaggregation technique (DisALEXI) in effecting regional to local downscaling is demonstrated in an application to thermal imagery collected with the Geostationary Operational Environmental Satellite (GOES) (5-km resolution) and Landsat (60-m resolution) over the state of Oklahoma on 4 days during 2000–01. A related algorithm (DisTrad) sharpens thermal imagery to resolutions associated with visible–near-infrared bands (30 m on Landsat), extending the range in scales achievable through disaggregation. The accuracy and utility of this combined multiscale modeling system is evaluated quantitatively in comparison with measurements made with flux towers in the Oklahoma Mesonet and qualitatively in terms of enhanced information content that emerges at high resolution where flux patterns can be identified with recognizable surface phenomena. Disaggregated flux fields at 30-m resolution were reaggregated over an area approximating the tower flux footprint and agreed with observed fluxes to within 10%. In contrast, 5-km flux predictions from ALEXI showed a higher relative error of 17% because of the gross mismatch in scale between model and measurement, highlighting the efficacy of disaggregation as a means for validating regional-scale flux predictions over heterogeneous landscapes. Sharpening the thermal inputs to DisALEXI with DisTrad did not improve agreement with observations in comparison with a simple bilinear interpolation technique because the sharpening interval associated with Landsat (60–30 m) was much smaller than the dominant scale of heterogeneity (200–500 m) in the scenes studied. Greater benefit is expected in application to Moderate Resolution Imaging Spectroradiometer (MODIS) data, where the potential sharpening interval (1 km to 250 m) brackets the typical agricultural field scale. Thermal sharpening did, however, significantly improve output in terms of visual information content and model convergence rate. [ABSTRACT FROM AUTHOR]

Published

2004

42. The Oklahoma Mesonet's Skin Temperature Network.

Author

Fiebrich, Christopher A., Martinez, Janet B., Brotzge, Jerald A., and Basara, Jeffrey B.

Subjects

*TEMPERATURE measurements, *INFRARED detectors, *ENVIRONMENTAL monitoring, *CALIBRATION

Abstract

In 1999, the Oklahoma Mesonet deployed infrared temperature (IRT) sensors at 89 of its environmental monitoring stations. A 3-yr dataset collected since that time provides a unique opportunity to analyze longer-term, continuous, mesoscale observations of skin temperature across a large area. Several limitations of the sensor have been identified and include 1) failure of the calibration equation during the cold season, 2) difficulty in keeping the sensor's lens clean at remote sites, and 3) limited representativeness of local conditions due to the sensor's narrow field of view. Despite these limitations, the Oklahoma Mesonet's skin temperature network provides a wealth of information that can be used to better understand many land–atmosphere interactions. Not only can the observations be used to estimate the partitioning of latent and sensible heat flux, they also provide beneficial “ground truth” estimates to validate remotely sensed estimates of skin temperature. This manuscript describes the IRT sensor, evaluates its performance, and provides analysis of time series data and observed spatial variability across Oklahoma. [ABSTRACT FROM AUTHOR]

Published

2003

43. Development of a Flash Drought Intensity Index.

Author

Otkin, Jason A., Zhong, Yafang, Hunt, Eric D., Christian, Jordan I., Basara, Jeffrey B., Nguyen, Hanh, Wheeler, Matthew C., Ford, Trent W., Hoell, Andrew, Svoboda, Mark, and Anderson, Martha C.

Subjects

*DROUGHT management, *DROUGHTS, *SOIL moisture, *SOIL testing, *CROP yields

Abstract

Flash droughts are characterized by a period of rapid intensification over sub-seasonal time scales that culminates in the rapid emergence of new or worsening drought impacts. This study presents a new flash drought intensity index (FDII) that accounts for both the unusually rapid rate of drought intensification and its resultant severity. The FDII framework advances our ability to characterize flash drought because it provides a more complete measure of flash drought intensity than existing classification methods that only consider the rate of intensification. The FDII is computed using two terms measuring the maximum rate of intensification (FD_INT) and average drought severity (DRO_SEV). A climatological analysis using soil moisture data from the Noah land surface model from 1979–2017 revealed large regional and interannual variability in the spatial extent and intensity of soil moisture flash drought across the US. Overall, DRO_SEV is slightly larger over the western and central US where droughts tend to last longer and FD_INT is ~75% larger across the eastern US where soil moisture variability is greater. Comparison of the FD_INT and DRO_SEV terms showed that they are strongly correlated (r = 0.82 to 0.90) at regional scales, which indicates that the subsequent drought severity is closely related to the magnitude of the rapid intensification preceding it. Analysis of the 2012 US flash drought showed that the FDII depiction of severe drought conditions aligned more closely with regions containing poor crop conditions and large yield losses than that captured by the intensification rate component (FD_INT) alone. [ABSTRACT FROM AUTHOR]

Published

2021