Your search keyword '"Kristi R. Arsenault"' showing total 70 results

1. Enabling Advanced Snow Physics Within Land Surface Models Through an Interoperable Model‐Physics Coupling Framework

Author

Mahdi Navari, Sujay Kumar, Shugong Wang, James Geiger, David M. Mocko, Kristi R. Arsenault, and Eric M. Kemp

Subjects

snow model, interoperable coupling, Crocus, Noah‐MP LSM, Noah LSM, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Accurate estimation of snow accumulation and melt is a critical part of decision‐making in snow‐dominated watersheds. In this study, we demonstrate a flexible methodology to couple a detailed snow model, Crocus, separately to two different land surface models (LSMs), Noah‐MP and Noah. The original LSMs and the coupled models (Noah‐MP‐Crocus and Noah‐Crocus) are used to simulate snow depth, snow water equivalent, and other water and energy states and fluxes. The results of simulations are compared against a wide range of independent gridded and point scale reference data sets. Our results show that coupling the detailed snow model, Crocus, with the LSMs improves the snow depth and snow water equivalent relative to independent observations. Overall, larger improvements are obtained with coupling Crocus to the Noah LSM, with the coupled Noah‐Crocus configuration reducing the RMSE and bias of snow depth from 2% to 12% and 57% to 75%, respectively, relative to Snow Data Assimilation System (SNODAS) and snow product from the University of Arizona. On the other hand, smaller improvements are obtained by coupling Crocus with Noah‐MP. The Coupled Noah‐MP‐Crocus reduces the snow depth bias but slightly degrades the RMSE of snow depth and snow water equivalent. The corresponding impacts in other water budget terms such as evapotranspiration, soil moisture, and streamflow, however, are mixed, pointing to the significant need to improve the coupling assumptions of these processes within land models. Overall, the interoperable coupling framework demonstrated here offers the opportunity to include more detailed snow physics and processes, and to advance data assimilation systems through improved exploitation of information from snow remote sensing instruments.

Published

2024

2. Assimilation of Remotely Sensed Leaf Area Index Enhances the Estimation of Anthropogenic Irrigation Water Use

Author

Wanshu Nie, Sujay V. Kumar, Christa D. Peters‐Lidard, Benjamin F. Zaitchik, Kristi R. Arsenault, Rajat Bindlish, and Pang‐Wei Liu

Subjects

irrigation, data assimilation, leaf area index, Noah‐MP, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Representation of irrigation in Earth System Models has advanced over the past decade, yet large uncertainties persist in the effective simulation of irrigation practices, particularly over locations where the on‐ground practices and climate impacts are less reliably known. Here we investigate the utility of assimilating remotely sensed vegetation data for improving irrigation water use and associated fluxes within a land surface model. We show that assimilating optical sensor‐based leaf area index estimates significantly improves the simulation of irrigation water use when compared to the USGS ground reports. For heavily irrigated areas, assimilation improves the evaporative fluxes and gross primary production (GPP) simulations, with the median correlation increasing by 0.1–1.1 and 0.3–0.6, respectively, as compared to the reference datasets. Further, bias improvements in the range of 14–35 mm mo−1 and 10–82 g m−2 mo−1 are obtained in evaporative fluxes and GPP as a result of incorporating vegetation constraints, respectively. These results demonstrate that the use of remotely sensed vegetation data is an effective, observation‐informed, globally applicable approach for simulating irrigation and characterizing its impacts on water and carbon states.

Published

2022

3. Uncertainties in Evapotranspiration Estimates over West Africa

Author

Hahn Chul Jung, Augusto Getirana, Kristi R. Arsenault, Thomas R.H. Holmes, and Amy McNally

Subjects

evapotranspiration, uncertainty, land surface model, West Africa, Science

Abstract

An evapotranspiration (ET) ensemble composed of 36 land surface model (LSM) experiments and four diagnostic datasets (GLEAM, ALEXI, MOD16, and FLUXNET) is used to investigate uncertainties in ET estimate over five climate regions in West Africa. Diagnostic ET datasets show lower uncertainty estimates and smaller seasonal variations than the LSM-based ET values, particularly in the humid climate regions. Overall, the impact of the choice of LSMs and meteorological forcing datasets on the modeled ET rates increases from north to south. The LSM formulations and parameters have the largest impact on ET in humid regions, contributing to 90% of the ET uncertainty estimates. Precipitation contributes to the ET uncertainty primarily in arid regions. The LSM-based ET estimates are sensitive to the uncertainty of net radiation in arid region and precipitation in humid region. This study serves as support for better determining water availability for agriculture and livelihoods in Africa with earth observations and land surface models.

Published

2019

4. Generating Observation-Based Snow Depletion Curves for Use in Snow Cover Data Assimilation

Author

Kristi R. Arsenault and Paul R. Houser

Subjects

snow cover, snow depletion curve, MODIS, data assimilation, land surface model, Geology, QE1-996.5

Abstract

Snow depletion curves (SDC) are functions that are used to show the relationship between snow covered area and snow depth or water equivalent. Previous snow cover data assimilation (DA) studies have used theoretical SDC models as observation operators to map snow depth to snow cover fraction (SCF). In this study, a new approach is introduced that uses snow water equivalent (SWE) observations and satellite-based SCF retrievals to derive SDC relationships for use in an Ensemble Kalman filter (EnKF) to assimilate snow cover estimates. A histogram analysis is used to bin the SWE observations, which the corresponding SCF observations are then averaged within, helping to constrain the amount of data dispersion across different temporal and regional conditions. Logarithmic functions are linearly regressed with the binned average values, for two U.S. mountainous states: Colorado and Washington. The SDC-based logarithmic functions are used as EnKF observation operators, and the satellite-based SCF estimates are assimilated into a land surface model. Assimilating satellite-based SCF estimates with the observation-based SDC shows a reduction in SWE-related RMSE values compared to the model-based SDC functions. In addition, observation-based SDC functions were derived for different intra-annual and physiographic conditions, and landcover and elevation bands. Lower SWE-based RMSE values are also found with many of these categorical observation-based SDC EnKF experiments. All assimilation experiments perform better than the open-loop runs, except for the Washington region’s 2004⁻2005 snow season, which was a major drought year that was difficult to capture with the ensembles and observations.

Published

2018

5. NASA's NMME-Based S2S Hydrologic Forecast System for Food Insecurity Early Warning in Southern Africa

Author

Abheera Hazra, Amy McNally, Kimberly Slinski, Kristi R. Arsenault, Shraddhanand Shukla, Augusto Getirana, Jossy P. Jacob, Daniel P. Sarmiento, Christa Peters-Lidard, Sujay V. Kumar, and Randal D. Koster

Subjects

Life Sciences (General), Earth Resources and Remote Sensing

Abstract

In situ hydrologic monitoring over regions most susceptible to food insecurity can be a challenge in current times due to various socio-economic and political issues in combination with environmental factors such as ongoing famine or drought. Hydrologic monitoring and initializing forecasts based on remotely sensed and analyzed data can contribute significantly to early warning in such regions. Routine hydrologic forecasts, as provided by NASA’s Hydrologic Forecasting and Analysis System (NHyFAS), are a recent addition to early warning systems. A custom instance of NHyFAS, termed FLDAS-Forecast, is used by FEWS NET’s Land Data Assimilation System (FLDAS). The FLDAS-Forecast’s dynamic forecasting component was originally set up with Goddard Earth Observing System (GEOS) forecast inputs and has been recently expanded with precipitation forecast forcing from the North American Multi-Model Ensemble (NMME). This paper describes the improvements in seasonal hydrologic forecasts produced with this updated system. Evaluations in this study focus on soil moisture across southern Africa’s growing season. Soil moisture forecasts are benchmarked and evaluated relative to climatology-based forecasts and historic runs, which are driven by observation-based meteorological forcing fields, and they are verified with remotely sensed observations of soil moisture and vegetation. Through multiple deterministic and probabilistic skill assessments, we show that using the larger ensemble of NMME precipitation inputs in the forecast system results in higher quality hydrologic forecasts than are allowed by climatology- or GEOS-only-based forecasts. Further, the near-real-time NMME-based rootzone soil moisture forecasts were able to correctly predict developing drought conditions over southern Africa through late 2019 and into early 2020.

Published

2022

6. Towards Effective Drought Monitoring in the Middle East and North Africa (Mena) Region: Implications From Assimilating Leaf Area Index and Soil Moisture Into the Noah-Mp Land Surface Model for Morocco

Author

Wanshu Nie, Sujay V. Kumar, Kristi R. Arsenault, Christa D. Peters-Lidard, Iliana E. Mladenova, Karim Bergaoui, Abheera Hazra, Benjamin F. Zaitchik, Sarith P. Mahanama, Rachael McDonnell, David M. Mocko, and Mahdi Navari

Subjects

Earth Resources and Remote Sensing

Abstract

The Middle East and North Africa (MENA) region has experienced more frequent and severe drought events in recent decades, leading to increasingly pressing concerns over already strained food and water security. An effective drought monitoring and early warning system is thus critical to support risk mitigation and management by countries in the region. Here we investigate the potential for assimilation of leaf area index (LAI) and soil moisture observations to improve the representation of the overall hydrological and carbon cycles and drought by an advanced land surface model. The results reveal that assimilating soil moisture does not meaningfully improve model representation of the hydrological and biospheric processes for this region, but instead it degrades the simulation of the interannual variation in evapotranspiration (ET) and carbon fluxes, mainly due to model weaknesses in representing prognostic phenology. However, assimilating LAI leads to greater improvement, especially for transpiration and carbon fluxes, by constraining the timing of simulated vegetation growth response to evolving climate conditions. LAI assimilation also helps to correct for the erroneous interaction between the prognostic phenology and irrigation during summertime, effectively reducing a large positive bias in ET and carbon fluxes. Independently assimilating LAI or soil moisture alters the categorization of drought, with the differences being greater for more severe drought categories. We highlight the vegetation representation in response to changing land use and hydroclimate as one of the key processes to be captured for building a successful drought early warning system for the MENA region.

Published

2022

7. Skillful Seasonal Forecasts of Land Carbon Uptake in Northern Mid- and High Latitudes

Author

Eunjee Lee, Randal D Koster, Lesley E Ott, Joanna Joiner, Fan-Wei Zeng, Jana Kolassa, Rolf H Reichle, Kristi R Arsenault, Abheera Hazra, and Shraddhanand Shukla

Subjects

Meteorology And Climatology

Abstract

Here we present a first look at the Gross Primary Production (GPP) forecast skill levels achievable with a state-of-the-art subseasonal-to-seasonal (S2S) forecast system. Using NASA’s retrospective S2S ensemble forecast in conjunction with a terrestrial biosphere model, and using an independent, remote sensing-based dataset for validation, we demonstrate an ability to accurately forecast spring-summer carbon uptake at multi-month leads. Averaged across mid-and high latitudes of the Northern Hemisphere land, the GPP forecast initialized on January 1 produces statistically significant skill through summer. The skill achieved, however, is spatially variable, with some regions appearing to extract skill from accurate forecasts of snowpack removal and others extracting skill from the initialization of carbon and nitrogen states. Our results reveal some heretofore unexplored facets of climate predictability and provide a look at what might be possible with future S2S forecast systems that are fully integrated with biogeochemical cycles.

Published

2022

8. The 2019-2020 Australian drought and bushfires altered the partitioning of hydrological fluxes

Author

Sujay V. Kumar, Thomas Holmes, Niels Andela, Imtiaz Dharssi, Vinodkumar, Christopher Hain, Christa Peters-Lidard, Sarith P. Mahanama, Kristi R. Arsenault, Wanshu Nie, and Augusto Getirana

Subjects

Earth Resources And Remote Sensing

Abstract

Though coarse in spatial resolution, the nearly all weather measurements from passive microwave sensors can help in improving the spatiotemporal coverage of optical and thermal infrared sensors for monitoring vegetation changes on the land surface. This study demonstrates the use of vegetation optical depth retrievals from the Soil Moisture Active Passive mission for capturing the vegetation alterations from the recent 2019-2020 Australian bushfires and drought. The impact of vegetation disturbance s on terrestrial water budget is examined by assimilating the vegetation optical depth retrievals into a dynamic phenology model. The results demonstrate that assimilating vegetation optical depth observations lead to improved simulation of evapotranspiration, runoff, and soil moisture states. The study also demonstrates that the vegetation changes from the 2019-2020 Australian drought and fires led to significant modifications in the partitioning of evaporative and runoff fluxes, resulting in increased bare soil evaporation, reduced transpiration, and higher runoff.

Published

2021

9. Developing a Hydrological Monitoring and Sub-Seasonal to Seasonal Forecasting System for South and Southeast Asian River Basins

Author

Yifan Zhou, Benjamin F Zaitchik, Sujay V Kumar, Kristi R Arsenault, Mir A Matin, Faisal M Qamer, Ryan A Zamora, and Kiran Shakya

Subjects

Earth Resources And Remote Sensing

Abstract

South and Southeast Asia is subject to significant hydrometeorological extremes, including drought. Under rising temperatures, growing populations, and an apparent weakening of the South Asian monsoon in recent decades, concerns regarding drought and its potential impacts on water and food security are on the rise. Reliable sub-seasonal to seasonal (S2S) hydrological forecasts could, in principle, help governments and international organizations to better assess risk and act in the face of an oncoming drought. Here, we leverage recent improvements in S2S meteorological forecasts and the growing power of Earth Observations to provide more accurate monitoring of hydrological states for forecast initialization. Information from both sources is merged in a South and Southeast Asia sub-seasonal to seasonal hydrological forecasting system (SAHFS-S2S), developed collaboratively with the NASA SERVIR program and end-users across the region. This system applies the Noah-MultiParameterization (NoahMP) Land Surface Model (LSM) in the NASA Land Information System (LIS), driven by downscaled meteorological fields from the Global Data Assimilation System (GDAS) and Climate Hazards InfraRed Precipitation products (CHIRP and CHIRPS) to optimize initial conditions. The NASA Goddard Earth Observing System Model - sub-seasonal to seasonal (GEOS-S2S) forecasts, downscaled using the National Center for Atmospheric Research (NCAR) General Analog Regression Downscaling (GARD) tool and quantile mapping, are then applied to drive 5-km resolution hydrological forecasts to a 9-month forecast time horizon. Results show that the skillful predictions of root zone soil moisture can be made one to two months in advance for forecasts initialized in rainy seasons and up to 8 months when initialized in dry seasons. The memory of accurate initial conditions can positively contribute to forecast skills throughout the entire 9-month prediction period in areas with limited precipitation. This SAHFS-S2S has been operationalized at the International Centre for Integrated Mountain Development (ICIMOD) to support drought monitoring and warning needs in the region.

Published

2021

10. Supporting Information for 'The 2019-2020 Australian Drought and Bushfires Altered the Partitioning of Hydrological Fluxes

Author

Sujay V Kumar, Thomas Holmes, Niels Andela, Imtiaz Dharssi, Fnu Vinodkumar, Christopher Hain, Christa Peters-lidard, Sarith P Mahanama, Kristi R Arsenault, Wanshu Nie, and Augusto Getirana

Subjects

Meteorology And Climatology

Abstract

The model configuration employs the modified International Geosphere Biosphere Programme (IGBP) MODIS 20 category landcover data, soil parameters derived from the International Soil Reference and Information Centre, and the Shuttle Radar Topography Mission based elevation, slope, and aspect data. Statistical downscaling approaches are used to transform the coarse resolution MERRA2 meteorological inputs to 1km. The input meteorological fields of air temperature, humidity, surface pressure, wind, downward shortwave radiation, and downward longwave radiation are downscaled to 1km by adjusting for terrain differences in elevation, slope, and aspect. The high resolution monthly precipitation climatology from WorldClim is used to spatially disaggregate input MERRA2 precipitation to 1km. The initial conditions for the model simulations are generated from a long spinup of NoahMP starting from year 2000. All model integrations and evaluations are conducted using the NASA Land Information System and the Land surface Verification Toolkit.

Published

2020

11. Irrigation Water Demand Sensitivity to Climate Variability across the Contiguous United States

Author

Wanshu Nie, Benjamin F Zaitchik, Matthew Rodell, Sujay V Kumar, Kristi R. Arsenault, and Hamada S. Badr

Subjects

Earth Resources And Remote Sensing

Abstract

Climate variability is an important driver of irrigation water use in many regions. Efforts to anticipate climate change impacts on future water availability can benefit from understanding how irrigation water demand has responded to these drivers to date. Here we apply satellite derived data, meteorological reanalysis, an advanced land surface model, and available state level reports to quantify irrigation demand sensitivities to temperature and precipitation across the Contiguous United States, for the period of 2002-2017. As expected, strong negative correlations are found between precipitation and irrigation withdrawals, both simulated and reported. Temperature sensitivities, however, vary by region and season, as do the interactive effects of temperature and precipitation on irrigation. Climate-induced irrigation variability is largest in transitional climate zones. These transitional zones are generally separate from the regions where rates of irrigation withdrawals are greatest, such that climate-induced variability in irrigation demand represents a water resource consideration that is distinct from chronic over pumping.

Published

2020

12. NCA-LDAS: Overview and Analysis of Hydrologic Trends for the National Climate Assessment

Author

Michael F. Jasinski, Jordan S. Borak, Sujay V. Kumar, David M. Mocko, Christa D. Peters-Lidard, Matthew Rodell, Hualan Rui, Hiroko K. Beaudoing, Bruce E. Vollmer, Kristi R. Arsenault, Bailing Li, John D. Bolten, and Natthachet Tangdamrongsub

Subjects

Earth Resources And Remote Sensing, Geosciences (General)

Abstract

Terrestrial hydrologic trends over the conterminous United States are estimated for 1980–2015 using the National Climate Assessment Land Data Assimilation System (NCA-LDAS) reanalysis. NCA-LDAS employs the uncoupled Noah version 3.3 land surface model at 0.125° 3 0.125° forced with NLDAS-2 meteorology, rescaled Climate Prediction Center precipitation, and assimilated satellite-based soil moisture, snow depth, and irrigation products. Mean annual trends are reported using the nonparametric Mann–Kendall test at p < 0.1 significance. Results illustrate the interrelationship between regional gradients in forcing trends and trends in other land energy and water stores and fluxes. Mean precipitation trends range from +3 to +9 mm/yr in the upper Great Plains and Northeast to -1 to -9 mm/yr in the West and South, net radiation flux trends range from +0.05 to +0.20 W/sq. m yr in the East to -0.05 to -0.20 W/sq. m yr in the West, and U.S.-wide temperature trends average about +0.03K/yr. Trends in soil moisture, snow cover, latent and sensible heat fluxes, and runoff are consistent with forcings, contributing to increasing evaporative fraction trends from west to east. Evaluation of NCA-LDAS trends compared to independent data indicates mixed results. The RMSE of U.S.-wide trends in number of snow cover days improved from 3.13 to 2.89 days/yr while trend detection increased 11%. Trends in latent heat flux were hardly affected, with RMSE decreasing only from 0.17 to 0.16 W/sq. m yr, while trend detection increased 2%. NCA-LDAS runoff trends degraded significantly from 2.6 to 16.1 mm/yr while trend detection was unaffected. Analysis also indicated that NCA-LDAS exhibits relatively more skill in low precipitation station density areas, suggesting there are limits to the effectiveness of satellite data assimilation in densely gauged regions. Overall, NCA-LDAS demonstrates capability for quantifying physically consistent, U.S. hydrologic climate trends over the satellite era.

Published

2019

13. Improving Surface Soil Moisture Estimates in West Africa Through GRACE Data Assimilation

Author

Hahn Chul Jung, Augusto Getirana, Kristi R Arsenault, Sujay Kumar, and Issoufou Maigary

Subjects

Earth Resources And Remote Sensing

Abstract

Recent annual trends of precipitation and terrestrial water storage (TWS) in West Africa have been increasing over the past decade. Despite a significant impact of soil moisture on the TWS in West Africa, there is little research on the recent spatial and temporal behaviors of surface soil moisture (SSM) along with the hydrological trends and variability in West Africa. In this study, we assimilate TWS estimates from the Gravity Recovery and Climate Experiment (GRACE) mission into the Catchment Land Surface Model (CLSM) and evaluate its impacts on SSM simulations for the years, 2002–2017. The evaluation is performed using reference datasets: the African Monsoon Multidisciplinary Analysis (AMMA) in situ soil moisture observations, three currently available microwave satellite SSM observations from the Advanced Scatterometer (ASCAT), the Soil Moisture Ocean Salinity (SMOS), and the Soil Moisture Active Passive (SMAP) satellites and also the triple collocation analysis (TCA). Overall, modeled SSM shows good agreement with the reference datasets in terms of the anomaly SSM correlations. However, both modeled and ASCAT SSM are limited in their representation of the drying rates, as observed by ground observations, SMOS and SMAP estimates. Further, GRACE data assimilation results in improved SSM simulations in the humid regions with large annual TWS variability. This study demonstrates the utility of land data assimilation to inform hydrological conditions in West Africa, where soil moisture monitoring is necessary for water resource and livestock management.

Published

2019

14. Developing a hydrological monitoring and sub-seasonal to seasonal forecasting system for South and Southeast Asian river basins

Author

Kristi R. Arsenault, Sujay V. Kumar, R. Zamora, Faisal Mueen Qamer, Mir A. Matin, Yifan Zhou, Kiran Shakya, and Benjamin F. Zaitchik

Subjects

010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Drainage basin, 02 engineering and technology, Monsoon, Southeast asian, 01 natural sciences, lcsh:Technology, lcsh:TD1-1066, Data assimilation, Hydrometeorology, Precipitation, lcsh:Environmental technology. Sanitary engineering, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, geography, geography.geographical_feature_category, lcsh:T, lcsh:Geography. Anthropology. Recreation, 020801 environmental engineering, Land information system, lcsh:G, Climatology, Environmental science, Downscaling

Abstract

South and Southeast Asia is subject to significant hydrometeorological extremes, including drought. Under rising temperatures, growing populations, and an apparent weakening of the South Asian monsoon in recent decades, concerns regarding drought and its potential impacts on water and food security are on the rise. Reliable sub-seasonal to seasonal (S2S) hydrological forecasts could, in principle, help governments and international organizations to better assess risk and act in the face of an oncoming drought. Here, we leverage recent improvements in S2S meteorological forecasts and the growing power of Earth Observations to provide more accurate monitoring of hydrological states for forecast initialization. Information from both sources is merged in a South and Southeast Asia sub-seasonal to seasonal hydrological forecasting system (SAHFS-S2S), developed collaboratively with the NASA SERVIR program and end-users across the region. This system applies the Noah-MultiParameterization (NoahMP) Land Surface Model (LSM) in the NASA Land Information System (LIS), driven by downscaled meteorological fields from the Global Data Assimilation System (GDAS) and Climate Hazards InfraRed Precipitation products (CHIRP and CHIRPS) to optimize initial conditions. The NASA Goddard Earth Observing System Model - sub-seasonal to seasonal (GEOS-S2S) forecasts, downscaled using the National Center for Atmospheric Research (NCAR) General Analog Regression Downscaling (GARD) tool and quantile mapping, are then applied to drive 5-km resolution hydrological forecasts to a 9-month forecast time horizon. Results show that the skillful predictions of root zone soil moisture can be made one to two months in advance for forecasts initialized in rainy seasons and up to 8 months when initialized in dry seasons. The memory of accurate initial conditions can positively contribute to forecast skills throughout the entire 9-month prediction period in areas with limited precipitation. This SAHFS-S2S has been operationalized at the International Centre for Integrated Mountain Development (ICIMOD) to support drought monitoring and warning needs in the region.

Published

2021

15. Upper Blue Nile Basin Water Budget from a Multi-Model Perspective

Author

Hahn Chul Jung, Augusto Getirana, Frederick Policelli, Amy McNally, Kristi R Arsenault, Sujay Kumar, Tsegaye Tadesse, and Christa D Peters-Lidard

Subjects

Earth Resources And Remote Sensing

Abstract

Improved understanding of the water balance in the Blue Nile is of critical importance because of increasingly frequent hydroclimatic extremes under a changing climate. The intercomparison and evaluation of multiple land surface models (LSMs) associated with different meteorological forcing and precipitation datasets can offer a moderate range of water budget variable estimates. In this context, two LSMs, Noah version 3.3 (Noah3.3) and Catchment LSM version Fortuna 2.5 (CLSMF2.5) coupled with the Hydrological Modeling and Analysis Platform (HyMAP) river routing scheme are used to produce hydrological estimates over the region. The two LSMs were forced with different combinations of two reanalysis-based meteorological datasets from the Modern-Era Retrospective analysis for Research and Applications datasets (i.e., MERRA-Land and MERRA-2) and three observation-based precipitation datasets, generating a total of 16 experiments. Modeled evapotranspiration (ET), streamflow, and terrestrial water storage estimates were evaluated against the Atmosphere-Land Exchange Inverse (ALEXI) ET, in-situ streamflow observations, and NASA Gravity Recovery and Climate Experiment (GRACE) products, respectively. Results show that CLSMF2.5 provided better representation of the water budget variables than Noah3.3 in terms of Nash-Sutcliffe coefficient when considering all meteorological forcing datasets and precipitation datasets. The model experiments forced with observation-based products, the Climate Hazards group Infrared Precipitation with Stations (CHIRPS) and the Tropical Rainfall Measuring Mission (TRMM) Multi-Satellite Precipitation Analysis (TMPA), outperform those run with MERRA-Land and MERRA-2 precipitation. The results presented in this paper would suggest that the Famine Early Warning Systems Network (FEWS NET) Land Data Assimilation System incorporate CLSMF2.5 and HyMAP routing scheme to better represent the water balance in this region.

Published

2017

16. Better Advance Warnings of Drought: A New NASA Hydrological Forecast System

Author

Bala Narapusetty, Chris Funk, Mahdi Navari, Gregory Husak, David Mocko, John B. Eylander, Michael Shaw, Benjamin F. Zaitchik, Jeanne Roningen, Randal D. Koster, Sujay V. Kumar, Rachael McDonnell, Tamuka Magadzire, Laura Harrison, Hamada S. Badr, Shugong Wang, Gideon Galu, Christa D. Peters-Lidard, Augusto Getirana, Kristi R. Arsenault, James P. Verdin, Amy McNally, Shraddhanand Shukla, Alkhalil Adoum, Abheera Hazra, Hahn Chul Jung, and Karim Bergaoui

Subjects

Atmospheric Science

Published

2020

17. The NASA Hydrological Forecast System for Food and Water Security Applications

Author

Jeanne Roningen, Christa D. Peters-Lidard, Augusto Getirana, Gideon Galu, Kristi R. Arsenault, Tamuka Magadzire, Shugong Wang, Michael Shaw, Chris Funk, Laura Harrison, Abheera Hazra, Rachael McDonnell, Bala Narapusetty, Hamada S. Badr, John Eylander, Shraddhanand Shukla, Randal D. Koster, Gregory Husak, Karim Bergaoui, Hahn Chul Jung, Alkhalil Adoum, James P. Verdin, Amy McNally, Benjamin F. Zaitchik, Mahdi Navari, David Mocko, and Sujay V. Kumar

Subjects

Atmospheric Science, Food security, Hydrology (agriculture), Water security, Warning system, Agriculture, business.industry, Flooding (psychology), Water storage, Environmental science, Famine, Water resource management, business

Abstract

Many regions in Africa and the Middle East are vulnerable to drought and to water and food insecurity, motivating agency efforts such as the U.S. Agency for International Development’s (USAID) Famine Early Warning Systems Network (FEWS NET) to provide early warning of drought events in the region. Each year these warnings guide life-saving assistance that reaches millions of people. A new NASA multimodel, remote sensing–based hydrological forecasting and analysis system, NHyFAS, has been developed to support such efforts by improving the FEWS NET’s current early warning capabilities. NHyFAS derives its skill from two sources: (i) accurate initial conditions, as produced by an offline land modeling system through the application and/or assimilation of various satellite data (precipitation, soil moisture, and terrestrial water storage), and (ii) meteorological forcing data during the forecast period as produced by a state-of-the-art ocean–land–atmosphere forecast system. The land modeling framework used is the Land Information System (LIS), which employs a suite of land surface models, allowing multimodel ensembles and multiple data assimilation strategies to better estimate land surface conditions. An evaluation of NHyFAS shows that its 1–5-month hindcasts successfully capture known historic drought events, and it has improved skill over benchmark-type hindcasts. The system also benefits from strong collaboration with end-user partners in Africa and the Middle East, who provide insights on strategies to formulate and communicate early warning indicators to water and food security communities. The additional lead time provided by this system will increase the speed, accuracy, and efficacy of humanitarian disaster relief, helping to save lives and livelihoods.

Published

2020

18. GRACE Improves Seasonal Groundwater Forecast Initialization over the United States

Author

Himanshu Save, Sujay V. Kumar, Benjamin F. Zaitchik, Augusto Getirana, Kristi R. Arsenault, Matthew Rodell, Srinivas Bettadpur, and Hiroko Kato Beaudoing

Subjects

Atmospheric Science, Irrigation, Data assimilation, Climatology, Initialization, Environmental science, Hindcast, Groundwater, Terrestrial water storage, Groundwater storage

Abstract

We evaluate the impact of Gravity Recovery and Climate Experiment data assimilation (GRACE-DA) on seasonal hydrological forecast initialization over the United States, focusing on groundwater storage. GRACE-based terrestrial water storage (TWS) estimates are assimilated into a land surface model for the 2003–16 period. Three-month hindcast (i.e., forecast of past events) simulations are initialized using states from the reference (no data assimilation) and GRACE-DA runs. Differences between the two initial hydrological condition (IHC) sets are evaluated for two forecast techniques at 305 wells where depth to water table measurements are available. Results show that using GRACE-DA-based IHC improves seasonal groundwater forecast performance in terms of both RMSE and correlation. While most regions show improvement, degradation is common in the High Plains, where withdrawals for irrigation practices affect groundwater variability more strongly than the weather variability, which demonstrates the need for simulating such activities. These findings contribute to recent efforts toward an improved U.S. drought monitoring and forecast system.

Published

2020

19. Modelling the irrigation water demand through integration of irrigation scheme with NASA-Land Information System Framework (LISF) in India

Author

Manika Gupta, Prashant K Srivastava, Kristi R Arsenault, and Atul K Sahai

Abstract

The current study provides the irrigation water estimate based on incorporation of satellite-derived irrigation scheme and crop datasets into the NASA-Land Information System Framework (LISF) in India. NOAH 3.3 land surface model within NASA-LISF was run at 0.05-degree resolution for nine years from 2011 to 2019. The irrigation scheme accurately captures the seasonality and the two growing seasons that is December-March and August-November. The MODIS leaf area index product helps to regulate the seasonality and estimated irrigation amount and timing is based on 50% depletion of soil moisture at the field capacity in the rootzone. The results show that the evapotranspiration (ET) and latent heat flux (LE) have increased significantly in the cropped region with improvement in correlation with the MODIS ET and LE products. The study also shows an improvement in soil moisture simulation at the test sites (Varanasi and Gujarat). Besides, successfully demonstrating the irrigation timing and quantity, the present study can also be relevant to hydrological and energy fluxes studies of areas that still lack proper quantification of agricultural practices utilizing irrigation.

Published

2022

20. NASA’s NMME-based S2S hydrologic forecast system for food insecurity early warning in southern Africa

Author

Abheera Hazra, Amy McNally, Kimberly Slinski, Kristi R. Arsenault, Shraddhanand Shukla, Augusto Getirana, Jossy P. Jacob, Daniel P. Sarmiento, Christa Peters-Lidard, Sujay V. Kumar, and Randal D. Koster

Subjects

Water Science and Technology

Published

2023

21. Automated model integration at source code level: An approach to implementing models into the NASA Land Information System

Author

Shugong Wang, Sujay V. Kumar, David M. Mocko, Kristi R. Arsenault, James V. Geiger, and Christa D. Peters-Lidard

Subjects

Environmental Engineering, Ecological Modeling, Software

Published

2023

22. Impacts of snow cover fraction data assimilation on modeled energy and moisture budgets

Author

Kristi R. Arsenault, Paul R. Houser, Gabriëlle J. M. De Lannoy, and Paul A. Dirmeyer

Published

2013

23. Evaluating ESA CCI Soil Moisture in East Africa

Author

Amy McNally, Shraddhanand Shukla, Kristi R Arsenault, Shugong Wang, Christa D Peters-lidard, and James P Verdin

Subjects

Meteorology And Climatology, Earth Resources And Remote Sensing

Abstract

To assess growing season conditions where ground based observations are limited or unavailable, food security and agricultural drought monitoring analysts rely on publicly available remotely sensed rainfall and vegetation greenness. There are also remotely sensed soil moisture observations from missions like the European Space Agency (ESA) Soil Moisture and Ocean Salinity (SMOS) and NASAs Soil Moisture Active Passive (SMAP), however these time series are still too short to conduct studies that demonstrate the utility of these data for operational applications, or to provide historical context for extreme wet or dry events. To promote the use of remotely sensed soil moisture in agricultural drought and food security monitoring, we use East Africa as a case study to evaluate the quality of a 30+ year time series of merged active-passive microwave soil moisture from the ESA Climate Change Initiative (CCI-SM). Compared to the Normalized Difference Vegetation index (NDVI) and modeled soil moisture products, we found substantial spatial and temporal gaps in the early part of the CCI-SM record, with adequate data coverage beginning in 1992. From this point forward, growing season CCI-SM anomalies were well correlated (R greater than 0.5) with modeled, seasonal soil moisture, and in some regions, NDVI. We use correlation analysis and qualitative comparisons at seasonal time scales to show that remotely sensed soil moisture can add information to a convergence of evidence framework that traditionally relies on rainfall and NDVI in moderately vegetated regions.

Published

2016

24. The efficacy of seasonal terrestrial water storage forecasts for predicting vegetation activity over Africa

Author

Christa D. Peters-Lidard, Kristi R. Arsenault, Abheera Hazra, Benjamin I. Cook, K. Slinski, and Amy McNally

Subjects

Hydrology, Atmospheric Science, medicine, Environmental science, medicine.symptom, Vegetation (pathology), Terrestrial water storage

Abstract

Terrestrial water storage (TWS) provides important information on terrestrial hydroclimate and may have value for seasonal forecasting because of its strong persistence. We use the NASA Hydrological Forecast and Analysis System (NHyFAS) to investigate TWS forecast skill over Africa and assess its value for predicting vegetation activity from satellite estimates of leaf area index (LAI). Forecast skill is high over East and Southern Africa, extending up to 3–6 months in some cases, with more modest skill over West Africa. Highest skill generally occurs during the dry season or beginning of the wet season when TWS anomalies from the previous wet season are most likely to carry forward in time. In East Africa, this occurs prior to and during the transition into the spring “Long Rains” from January–March, while in Southern Africa this period of highest skill starts at the beginning of the dry season in April and extends through to the start of the wet season in October. TWS is highly and positively correlated with LAI, and a logistic regression model shows high cross-validation skill in predicting above or below normal LAI using TWS. Combining the LAI regression model with the NHyFAS forecasts, 1-month lead LAI predictions have high accuracy over East and Southern Africa, with reduced but significant skill at 3-month leads over smaller sub-regions. This highlights the potential value of TWS as an additional source of information for seasonal forecasts over Africa, with direct applications to some of the most vulnerable agricultural regions on the continent.

Published

2021

25. Assimilating GRACE Into a Land Surface Model in the Presence of an Irrigation‐Induced Groundwater Trend

Author

Augusto Getirana, Kristi R. Arsenault, Wanshu Nie, Matthew Rodell, Sujay V. Kumar, Benjamin F. Zaitchik, and Bailing Li

Subjects

Hydrology, Irrigation, Data assimilation, Environmental science, High plains aquifer, Groundwater, Water Science and Technology

Published

2019

26. Improving surface soil moisture estimates in West Africa through GRACE data assimilation

Author

Sujay V. Kumar, Augusto Getirana, Kristi R. Arsenault, Hahn Chul Jung, and Issoufou Maigary

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Anomaly (natural sciences), 0207 environmental engineering, Drainage basin, 02 engineering and technology, Scatterometer, Monsoon, 01 natural sciences, Data assimilation, Climatology, Environmental science, Satellite, Precipitation, 020701 environmental engineering, Water content, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Recent annual trends of precipitation and terrestrial water storage (TWS) in West Africa have been increasing over the past decade. Despite a significant impact of soil moisture on the TWS in West Africa, there is little research on the recent spatial and temporal behaviors of surface soil moisture (SSM) along with the hydrological trends and variability in West Africa. In this study, we assimilate TWS estimates from the Gravity Recovery and Climate Experiment (GRACE) mission into the Catchment Land Surface Model (CLSM) and evaluate its impacts on SSM simulations for the years, 2002–2017. The evaluation is performed using reference datasets: the African Monsoon Multidisciplinary Analysis (AMMA) in situ soil moisture observations, three currently available microwave satellite SSM observations from the Advanced Scatterometer (ASCAT), the Soil Moisture Ocean Salinity (SMOS), and the Soil Moisture Active Passive (SMAP) satellites and also the triple collocation analysis (TCA). Overall, modeled SSM shows good agreement with the reference datasets in terms of the anomaly SSM correlations. However, both modeled and ASCAT SSM are limited in their representation of the drying rates, as observed by ground observations, SMOS and SMAP estimates. Further, GRACE data assimilation results in improved SSM simulations in the humid regions with large annual TWS variability. This study demonstrates the utility of land data assimilation to inform hydrological conditions in West Africa, where soil moisture monitoring is necessary for water resource and livestock management.

Published

2019

27. NCA-LDAS: Overview and Analysis of Hydrologic Trends for the National Climate Assessment

Author

Bruce Vollmer, Sujay V. Kumar, Natthachet Tangdamrongsub, Matthew Rodell, Michael F. Jasinski, Christa D. Peters-Lidard, Kristi R. Arsenault, Bailing Li, David Mocko, John D. Bolten, Hiroko Kato Beaudoing, Hualan Rui, and Jordan Borak

Subjects

Atmospheric Science, Data assimilation, Remote sensing (archaeology), Climatology, Hydrological modelling, Environmental science, Article

Abstract

Terrestrial hydrologic trends over the conterminous United States are estimated for 1980–2015 using the National Climate Assessment Land Data Assimilation System (NCA-LDAS) reanalysis. NCA-LDAS employs the uncoupled Noah version 3.3 land surface model at 0.125° × 0.125° forced with NLDAS-2 meteorology, rescaled Climate Prediction Center precipitation, and assimilated satellite-based soil moisture, snow depth, and irrigation products. Mean annual trends are reported using the nonparametric Mann–Kendall test at p < 0.1 significance. Results illustrate the interrelationship between regional gradients in forcing trends and trends in other land energy and water stores and fluxes. Mean precipitation trends range from +3 to +9 mm yr−1 in the upper Great Plains and Northeast to −1 to −9 mm yr−1 in the West and South, net radiation flux trends range from +0.05 to +0.20 W m−2 yr−1 in the East to −0.05 to −0.20 W m−2 yr−1 in the West, and U.S.-wide temperature trends average about +0.03 K yr−1. Trends in soil moisture, snow cover, latent and sensible heat fluxes, and runoff are consistent with forcings, contributing to increasing evaporative fraction trends from west to east. Evaluation of NCA-LDAS trends compared to independent data indicates mixed results. The RMSE of U.S.-wide trends in number of snow cover days improved from 3.13 to 2.89 days yr−1 while trend detection increased 11%. Trends in latent heat flux were hardly affected, with RMSE decreasing only from 0.17 to 0.16 W m−2 yr−1, while trend detection increased 2%. NCA-LDAS runoff trends degraded significantly from 2.6 to 16.1 mm yr−1 while trend detection was unaffected. Analysis also indicated that NCA-LDAS exhibits relatively more skill in low precipitation station density areas, suggesting there are limits to the effectiveness of satellite data assimilation in densely gauged regions. Overall, NCA-LDAS demonstrates capability for quantifying physically consistent, U.S. hydrologic climate trends over the satellite era.

Published

2019

28. Contribution of Meteorological Downscaling to Skill and Precision of Seasonal Drought Forecasts

Author

Ethan Gutmann, Benjamin F. Zaitchik, R. Zamora, Matthew Rodell, Sujay V. Kumar, Augusto Getirana, and Kristi R. Arsenault

Subjects

Atmospheric Science, Climatology, Environmental science, Downscaling

Abstract

Research in meteorological prediction on sub-seasonal to seasonal (S2S) timescales has seen growth in recent years. Concurrent with this, demand for seasonal drought forecasting has risen. While there is obvious synergy between these fields, S2S meteorological forecasting has typically focused on low resolution global models, while the development of drought can be sensitive to the local expression of weather anomalies and their interaction with local surface properties and processes. This suggests that downscaling might play an important role in the application of meteorological S2S forecasts to skillful forecasting of drought. Here, we apply the Generalized Analog Regression Downscaling (GARD) algorithm to downscale meteorological hindcasts from the NASA Goddard Earth Observing System (GEOS) global S2S forecast system. Downscaled meteorological fields are then applied to drive offline simulations with the Catchment Land Surface Model (CLSM) to forecast United States Drought Monitor (USDM) style drought indicators derived from simulated surface hydrology variables. We compare the representation of drought in these downscaled hindcasts to hindcasts that are not downscaled, using the North American Land Data Assimilation System Phase 2 (NLDAS-2) dataset as an observational reference. We find that downscaling using GARD improves hindcasts of temperature and temperature anomalies, but the results for precipitation are mixed and generally small. Overall, GARD downscaling led to improved hindcast skill for total drought across the Contiguous United States (CONUS), and improvements were greatest for extreme (D3) and exceptional (D4) drought categories.

Published

2021

29. Towards Effective Drought Monitoring in the Middle East and North Africa (MENA) Region: Implications from Assimilating Leaf Area Index and Soil Moisture into the Noah-MP Land Surface Model for Morocco

Author

Sarith Mahanama, Iliana E. Mladenova, Rachael McDonnell, Abheera Hazra, Mahdi Navari, Karim Bergaoui, David Mocko, Christa D. Peters-Lidard, Kristi R. Arsenault, Wanshu Nie, Sujay V. Kumar, and Benjamin F. Zaitchik

Subjects

Land use, Phenology, Climatology, Evapotranspiration, Early warning system, Environmental science, Vegetation, Leaf area index, Water content, Carbon cycle

Abstract

The Middle East and North Africa (MENA) region has experienced more frequent and severe drought events in recent decades, leading to increasingly pressing concerns over already strained food and water security. An effective drought monitoring and early warning system is thus critical to support risk mitigation and management by countries in the region. Here we investigate the potential for assimilation of leaf area index (LAI) and soil moisture observations to improve representation of the overall hydrological and carbon cycles and drought by an advanced land surface model. The results reveal that assimilating soil moisture does not meaningfully improve model representation of the hydrological and biospheric processes for this region, but rather it degrades simulation of interannual variation of evapotranspiration (ET) and carbon fluxes, mainly due to model weaknesses in representing dynamic phenology. However, assimilating LAI leads to greater improvement, especially for transpiration and carbon fluxes, by constraining the timing of simulated vegetation growth response to evolving climate conditions. LAI assimilation also helps to correct for the erroneous interaction between the dynamic phenology and irrigation during summertime, effectively reducing a large positive bias in ET and carbon fluxes. Independently assimilating LAI or soil moisture alters the categorization of drought, with the differences being greater for more severe drought categories. We highlight the vegetation representation in response to changing land use and hydroclimate as one of the key processes to be captured for building a successful drought early warning system for the MENA region.

Published

2021

30. Irrigation Water Demand Sensitivity to Climate Variability Across the Contiguous United States

Author

Benjamin F. Zaitchik, Matthew Rodell, Wanshu Nie, Sujay V. Kumar, Hamada S. Badr, and Kristi R. Arsenault

Subjects

Hydrology, Irrigation, Environmental science, Climate sensitivity, Sensitivity (control systems), Irrigation water, Groundwater, Water Science and Technology

Published

2021

31. Vegetation Monitoring Optimization With Normalized Difference Vegetation Index and Evapotranspiration Using Remote Sensing Measurements and Land Surface Models Over East Africa

Author

M. E. Budde, Shahriar Pervez, James Rowland, Amy McNally, and Kristi R. Arsenault

Subjects

lcsh:GE1-350, Food security, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Flooding (psychology), triple collocation, evapotranspiration, normalized difference vegetation index, 02 engineering and technology, vegetation monitoring, Livelihood, East Africa, 01 natural sciences, Normalized Difference Vegetation Index, 020801 environmental engineering, Natural hazard, Evapotranspiration, medicine, Environmental science, Physical geography, Moderate-resolution imaging spectroradiometer, medicine.symptom, Vegetation (pathology), lcsh:Environmental sciences, 0105 earth and related environmental sciences

Abstract

The majority of people in East Africa rely on the agro-pastoral system for their livelihood, which is highly vulnerable to droughts and flooding. Agro-pastoral droughts are endemic to the region and are considered the main natural hazard that contributes to food insecurity. Drought begins with rainfall deficit, gradually leading to soil moisture deficit, higher land surface temperature, and finally impacts to vegetation growth. Therefore, monitoring vegetation conditions is essential in understanding the progression of drought, potential effects on food security, and providing early warning information needed for drought mitigation decisions. Because vegetation processes couple the land and atmosphere, monitoring of vegetation conditions requires consideration of both water provision and demand. While there is consensus in using either the Normalized Difference Vegetation Index (NDVI) or evapotranspiration (ET) for vegetation monitoring, a comprehensive assessment optimizing the use of both has not yet been done. Moreover, the evaluation methods for understanding the relationships between NDVI and ET for vegetation monitoring are also limited. Taking these gaps into account we have developed a framework to optimize vegetation monitoring using both NDVI and ET by identifying where they perform the best by using triple collocation and cross-correlation methods. We estimated the random error structure in Moderate Resolution Imaging Spectroradiometer (MODIS) NDVI; ET from the Operational Simplified Surface Energy Balance (SSEBop) model; and ET from land surface models (LSMs). LSM ET and SSEBop ET have been found to be better indicators for vegetation monitoring during extreme drought events, while NDVI could provide better information on vegetation condition during wetter than normal conditions. The random error structures of these variables suggest that LSM ET is most likely to provide important information for vegetation monitoring over low and high ends of the vegetation fraction areas. Over moderate vegetative areas, any of these variables could provide important vegetation information for drought characterization and food security assessments. While this study provides a framework for optimizing vegetation monitoring for drought and food security assessments over East Africa, the framework can be adopted to optimize vegetation monitoring over any other drought and food insecure region of the world.

Published

2021

32. The 2019–2020 Australian Drought and Bushfires Altered the Partitioning of Hydrological Fluxes

Author

Wanshu Nie, Sujay V. Kumar, Vinodkumar, Augusto Getirana, Kristi R. Arsenault, Christopher Hain, Thomas R. H. Holmes, Niels Andela, I. Dharssi, Christa D. Peters-Lidard, and Sarith Mahanama

Subjects

Geophysics, Data assimilation, Phenology, Evapotranspiration, General Earth and Planetary Sciences, Environmental science, Vegetation, Atmospheric sciences, Surface runoff, Water content, Water budget, Transpiration

Abstract

Though coarse in spatial resolution, the nearly all weather measurements from passive microwave sensors can help in improving the spatio‐temporal coverage of optical and thermal infrared sensors for monitoring vegetation changes on the land surface. This study demonstrates the use of vegetation optical depth (VOD) retrievals from the Soil Moisture Active Passive mission for capturing the vegetation alterations from the recent 2019 to 2020 Australian bushfires and drought. The impact of vegetation disturbances on terrestrial water budget is examined by assimilating the VOD retrievals into a dynamic phenology model. The results demonstrate that assimilating VOD observations lead to improved simulation of evapotranspiration, runoff, and soil moisture states. The study also demonstrates that the vegetation changes from the 2019 to 2020 Australian drought and fires led to significant modifications in the partitioning of evaporative and runoff fluxes, resulting in increased bare soil evaporation, reduced transpiration, and higher runoff.

Published

2021

33. Potential of GPM IMERG Precipitation Estimates to Monitor Natural Disaster Triggers in Urban Areas: The Case of Rio de Janeiro, Brazil

Author

Augusto Getirana, Kristi R. Arsenault, Marta Ottoni, Dalia Kirschbaum, Felipe Mandarino, and Sana Khan

Subjects

landslide, extreme events, natural disaster, 010504 meteorology & atmospheric sciences, Science, 0208 environmental biotechnology, 02 engineering and technology, Land cover, urban flood, precipitation, 01 natural sciences, IMERG, soil moisture, total runoff, Hydrometeorology, Precipitation, 0105 earth and related environmental sciences, Flood myth, Storm, 020801 environmental engineering, Climatology, General Earth and Planetary Sciences, Environmental science, Spatial variability, Surface runoff, Global Precipitation Measurement

Abstract

Extreme rainfall can be a catastrophic trigger for natural disaster events at urban scales. However, there remains large uncertainties as to how satellite precipitation can identify these triggers at a city scale. The objective of this study is to evaluate the potential of satellite-based rainfall estimates to monitor natural disaster triggers in urban areas. Rainfall estimates from the Global Precipitation Measurement (GPM) mission are evaluated over the city of Rio de Janeiro, Brazil, where urban floods and landslides occur periodically as a result of extreme rainfall events. Two rainfall products derived from the Integrated Multi-satellite Retrievals for GPM (IMERG), the IMERG Early and IMERG Final products, are integrated into the Noah Multi-Parameterization (Noah-MP) land surface model in order to simulate the spatial and temporal dynamics of two key hydrometeorological disaster triggers across the city over the wet seasons during 2001–2019. Here, total runoff (TR) and rootzone soil moisture (RZSM) are considered as flood and landslide triggers, respectively. Ground-based observations at 33 pluviometric stations are interpolated, and the resulting rainfall fields are used in an in-situ precipitation-based simulation, considered as the reference for evaluating the IMERG-driven simulations. The evaluation is performed during the wet seasons (November-April), when average rainfall over the city is 4.4 mm/day. Results show that IMERG products show low spatial variability at the city scale, generally overestimate rainfall rates by 12–35%, and impacts on TR and RZSM vary spatially mostly as a function of land cover and soil types. Results based on statistical and categorical metrics show that IMERG skill in detecting extreme events is moderate, with IMERG Final performing slightly better for most metrics. By analyzing two recent storms, we observe that IMERG detects mostly hourly extreme events, but underestimates rainfall rates, resulting in underestimated TR and RZSM. An evaluation of normalized time series using percentiles shows that both satellite products have significantly improved skill in detecting extreme events when compared to the evaluation using absolute values, indicating that IMERG precipitation could be potentially used as a predictor for natural disasters in urban areas.

Published

2020

34. Supplementary material to 'Developing a hydrological monitoring and sub-seasonal to seasonal forecasting system for South and Southeast Asian river basins'

Author

Yifan Zhou, Benjamin F. Zaitchik, Sujay V. Kumar, Kristi R. Arsenault, Mir A. Matin, Faisal M. Qamer, Ryan A. Zamora, and Kiran Shakya

Published

2020

35. Towards the Development of a High-resolution, Global Streamflow and Flood Forecasting System – An U.S. Interagency Collaboration Effort

Author

Kimberly McCormack, Sujay V. Kumar, Mario Morales-Hernández, Shih-Chieh Kao, Christa D. Peters-Lidard, Jerry Wegiel, KJ Evans, S. Gangrade, Kristi R. Arsenault, M. Wahl, and Ahmad A. Tavakoly

Subjects

Meteorology, Streamflow, Flood forecasting, Resolution (electron density), Environmental science

Abstract

This work provides an envisioned overview of scientific collaboration among multiple United States agencies including the National Aeronautics and Space Administration (NASA), U.S. Army Engineer Research and Development Center (ERDC), Oak Ridge National Laboratory (ORNL), and National Geospatial-Intelligence Agency (NGA) for the integration of existing data and model capabilities to support global scale water security applications. The primary objective is to develop a high-resolution, operational streamflow and flood forecasting system at the global scale, leveraging multiple process-based models, remote sensing data assimilation, and high-performance computing techniques. We present a preliminary case study that demonstrates the integration of the modeling framework using NASA’s Land Information System (LIS), ERDC’s Streamflow Prediction Tool (SPT), and ORNL’s GPU-accelerated 2D flood model (TRITON). Using the high-resolution terrain data from NGA, a historic flood event that occurred in March 2019 at Offutt Air Force Base in Nebraska, USA, was simulated on ORNL’s supercomputer, Summit. This benchmark test case is used to validate the modeling framework and to help establish a roadmap for the expanded modeling efforts at the global scale. In a broader sense, the proposed infrastructure will enable decision-makers to address issues such as transboundary water conflicts, flood and drought monitoring, and sustainable water resources management and to study their impacts on human, water-energy and natural systems in the short, medium and long term.

Published

2020

36. Satellite Gravimetry Improves Seasonal Streamflow Forecast Initialization in Africa

Author

Shraddhanand Shukla, Augusto Getirana, Kristi R. Arsenault, Hahn Chul Jung, Sujay V. Kumar, Bako Mamane, Issoufou Maigari, and Christa D. Peters-Lidard

Subjects

Satellite gravimetry, Data assimilation, Climatology, Streamflow, Initialization, Environmental science, Terrestrial water storage, Water Science and Technology, West africa

Published

2020

37. Algorithm and Data Improvements for Version 2.1 of the Climate Hazards Center’s InfraRed Precipitation with Stations Data Set

Author

Shraddhanand Shukla, Udo Schneider, Martin Landsfeld, Andreas Becker, Kristi R. Arsenault, Laura Harrison, Frank Davenport, Pete Peterson, Amy McNally, Diego Pedreros, and Chris Funk

Subjects

Data set, Warning system, Meteorology, Long period, Geological survey, Environmental science, Center (algebra and category theory), Precipitation

Abstract

To support global drought early warning, the Climate Hazards Center (CHC) at the University of California, Santa Barbara developed the Climate Hazards center InfraRed Precipitation with Stations (CHIRPS) dataset, in collaboration with the US Geological Survey and NASA SERVIR. Specifically designed to support early warning applications, CHIRPS has high a spatial resolution (0.05°), a long period of record (1981 to the near present), and relatively low latencies. Here we will describe a brief formal analysis of distributional bias in CHIRPS2.0. This analysis reveals, as expected, that CHIRPS2.0 means are very similar to observed station data. However, a closer look suggests that low precipitation values are underestimated and high values are over-estimated in the CHIRPS2.0. We describe a potential correction for this below.

Published

2020

38. Parameter Sensitivity of the Noah-MP Land Surface Model with Dynamic Vegetation

Author

Kristi R. Arsenault, Soni Yatheendradas, Grey Nearing, Shugong Wang, and Christa D. Peters-Lidard

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, 02 engineering and technology, Soil carbon, Vegetation, Sensible heat, Atmospheric sciences, 01 natural sciences, 020801 environmental engineering, Dynamic simulation, Data assimilation, FluxNet, Latent heat, Environmental science, Sensitivity (control systems), 0105 earth and related environmental sciences

Abstract

The Noah land surface model with multiple parameterization options (Noah-MP) includes a routine for the dynamic simulation of vegetation carbon assimilation and soil carbon decomposition processes. To use remote sensing observations of vegetation to constrain simulations from this model, it is necessary first to understand the sensitivity of the model to its parameters. This is required for efficient parameter estimation, which is both a valuable way to use observations and also a first or concurrent step in many state-updating data assimilation procedures. We use variance decomposition to assess the sensitivity of estimates of sensible heat, latent heat, soil moisture, and net ecosystem exchange made by certain standard Noah-MP configurations that include the dynamic simulation of vegetation and carbon to 43 primary user-specified parameters. This is done using 32 years’ worth of data from 10 international FluxNet sites. Findings indicate that there are five soil parameters and six (or more) vegetation parameters (depending on the model configuration) that act as primary controls on these states and fluxes.

Published

2018

39. Upper Blue Nile basin water budget from a multi-model perspective

Author

Augusto Getirana, Kristi R. Arsenault, Frederick Policelli, Amy McNally, Tsegaye Tadesse, Sujay V. Kumar, Christa D. Peters-Lidard, and Hahn Chul Jung

Subjects

010504 meteorology & atmospheric sciences, Meteorology, 0208 environmental biotechnology, Context (language use), 02 engineering and technology, 01 natural sciences, Article, 020801 environmental engineering, Routing (hydrology), Water balance, Data assimilation, Climatology, Streamflow, Evapotranspiration, Environmental science, Precipitation, HyMap, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Improved understanding of the water balance in the Blue Nile is of critical importance because of increasingly frequent hydroclimatic extremes under a changing climate. The intercomparison and evaluation of multiple land surface models (LSMs) associated with different meteorological forcing and precipitation datasets can offer a moderate range of water budget variable estimates. In this context, two LSMs, Noah version 3.3 (Noah3.3) and Catchment LSM version Fortuna 2.5 (CLSMF2.5) coupled with the Hydrological Modeling and Analysis Platform (HyMAP) river routing scheme are used to produce hydrological estimates over the region. The two LSMs were forced with different combinations of two reanalysis-based meteorological datasets from the Modern-Era Retrospective analysis for Research and Applications datasets (i.e., MERRA-Land and MERRA-2) and three observation-based precipitation datasets, generating a total of 16 experiments. Modeled evapotranspiration (ET), streamflow, and terrestrial water storage estimates were evaluated against the Atmosphere-Land Exchange Inverse (ALEXI) ET, in-situ streamflow observations, and NASA Gravity Recovery and Climate Experiment (GRACE) products, respectively. Results show that CLSMF2.5 provided better representation of the water budget variables than Noah3.3 in terms of Nash-Sutcliffe coefficient when considering all meteorological forcing datasets and precipitation datasets. The model experiments forced with observation-based products, the Climate Hazards group Infrared Precipitation with Stations (CHIRPS) and the Tropical Rainfall Measuring Mission (TRMM) Multi-Satellite Precipitation Analysis (TMPA), outperform those run with MERRA-Land and MERRA-2 precipitation. The results presented in this paper would suggest that the Famine Early Warning Systems Network (FEWS NET) Land Data Assimilation System incorporate CLSMF2.5 and HyMAP routing scheme to better represent the water balance in this region.

Published

2017

40. Recognizing the Famine Early Warning Systems Network: Over 30 Years of Drought Early Warning Science Advances and Partnerships Promoting Global Food Security

Author

James Rowland, Kristi R. Arsenault, M. F. Landsfeld, Gregory Husak, Shraddhanand Shukla, Pete Peterson, Diriba Korecha, Gideon Galu, Miliaritiana L. Robjhon, Steven J. Fuhrman, Chris Funk, M. Rodriguez, Inbal Becker-Reshef, Wassila M. Thiaw, M. E. Budde, Nicholas S. Novella, James P. Verdin, Amy McNally, Aklhalil Adoum, Curt Reynolds, Christa D. Peters-Lidard, Andrew Hoell, Diego Pedreros, Jossy P. Jacob, Endalkachew Bekele, Tamuka Magadzire, Laura Harrison, Frank Davenport, Laboratoire des sciences de l'ingénieur, de l'informatique et de l'imagerie (ICube), École Nationale du Génie de l'Eau et de l'Environnement de Strasbourg (ENGEES)-Université de Strasbourg (UNISTRA)-Institut National des Sciences Appliquées - Strasbourg (INSA Strasbourg), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Institut National de Recherche en Informatique et en Automatique (Inria)-Les Hôpitaux Universitaires de Strasbourg (HUS)-Centre National de la Recherche Scientifique (CNRS)-Matériaux et Nanosciences Grand-Est (MNGE), Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Réseau nanophotonique et optique, and Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Atmospheric Science, Economic growth, education.field_of_study, Food security, 010504 meteorology & atmospheric sciences, Warning system, Population, 0207 environmental engineering, 02 engineering and technology, Livelihood, 01 natural sciences, Famine, Business, 020701 environmental engineering, education, [SDU.OTHER]Sciences of the Universe [physics]/Other, 0105 earth and related environmental sciences

Abstract

On a planet with a population of more than 7 billion, how do we identify the millions of drought-afflicted people who face a real threat of livelihood disruption or death without humanitarian assistance? Typically, these people are poor and heavily dependent on rainfed agriculture and livestock. Most live in Africa, Central America, or Southwest Asia. When the rains fail, incomes diminish while food prices increase, cutting off the poorest (most often women and children) from access to adequate nutrition. As seen in Ethiopia in 1984 and Somalia in 2011, food shortages can lead to famine. Yet these slow-onset disasters also provide opportunities for effective intervention, as seen in Ethiopia in 2015 and Somalia in 2017. Since 1985, the U.S. Agency for International Development’s Famine Early Warning Systems Network (FEWS NET) has been providing evidence-based guidance for effective humanitarian relief efforts. FEWS NET depends on a Drought Early Warning System (DEWS) to help understand, monitor, model, and predict food insecurity. Here we provide an overview of FEWS NET’s DEWS using examples from recent climate extremes. While drought monitoring and prediction provides just one part of FEWS NET’s monitoring system, it draws from many disciplines—remote sensing, climate prediction, agroclimatic monitoring, and hydrologic modeling. Here we describe FEWS NET’s multiagency multidisciplinary DEWS and Food Security Outlooks. This DEWS uses diagnostic analyses to guide predictions. Midseason droughts are monitored using multiple cutting-edge Earth-observing systems. Crop and hydrologic models can translate these observations into impacts. The resulting information feeds into FEWS NET reports, helping to save lives by motivating and targeting timely humanitarian assistance.

Published

2019

41. Evaluating ESA CCI soil moisture in East Africa

Author

Shraddhanand Shukla, Kristi R. Arsenault, Christa D. Peters-Lidard, James P. Verdin, Amy McNally, and Shugong Wang

Subjects

Hydrology, Global and Planetary Change, 010504 meteorology & atmospheric sciences, business.industry, 0208 environmental biotechnology, Climate change, Growing season, Context (language use), 02 engineering and technology, Vegetation, Management, Monitoring, Policy and Law, 01 natural sciences, Article, Normalized Difference Vegetation Index, 020801 environmental engineering, Agriculture, Soil water, Environmental science, Computers in Earth Sciences, business, Water content, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

To assess growing season conditions where ground based observations are limited or unavailable, food security and agricultural drought monitoring analysts rely on publicly available remotely sensed rainfall and vegetation greenness. There are also remotely sensed soil moisture observations from missions like the European Space Agency (ESA) Soil Moisture and Ocean Salinity (SMOS) and NASA's Soil Moisture Active Passive (SMAP), however these time series are still too short to conduct studies that demonstrate the utility of these data for operational applications, or to provide historical context for extreme wet or dry events. To promote the use of remotely sensed soil moisture in agricultural drought and food security monitoring, we use East Africa as a case study to evaluate the quality of a 30+ year time series of merged active-passive microwave soil moisture from the ESA Climate Change Initiative (CCI-SM). Compared to the Normalized Difference Vegetation index (NDVI) and modeled soil moisture products, we found substantial spatial and temporal gaps in the early part of the CCI-SM record, with adequate data coverage beginning in 1992. From this point forward, growing season CCI-SM anomalies were well correlated (R0.5) with modeled, seasonal soil moisture, and in some regions, NDVI. We use correlation analysis and qualitative comparisons at seasonal time scales to show that remotely sensed soil moisture can add information to a convergence of evidence framework that traditionally relies on rainfall and NDVI in moderately vegetated regions.

Published

2016

42. The Land surface Data Toolkit (LDTv7.2) – a data fusion environment for land data assimilation systems

Author

Kristi R. Arsenault, Sujay V. Kumar, James V. Geiger, Shugong Wang, Eric Kemp, David M. Mocko, Hiroko Kato Beaudoing, Augusto Getirana, Mahdi Navari, Bailing Li, Jossy Jacob, Jerry Wegiel, and Christa Peters-Lidard

Abstract

The effective applications of land surface model (LSM) and hydrologic models pose a varied set of data input and processing needs, ranging from ensuring consistency checks to more derived data processing and analytics. This article describes the development of the Land surface Data Toolkit (LDT), which is an integrated framework designed specifically for processing input data to execute LSMs and hydrological models. LDT not only serves as a pre-processor to the NASA Land Information System (LIS), which is an integrated framework designed for multi-model LSM simulations and data assimilation (DA) integrations, but also as a land surface-based observation and DA input processor. It offers a variety of user options and inputs to processing datasets for use within LIS and stand alone models. The LDT design facilitates the use of common data formats and conventions. LDT is also capable of processing LSM initial conditions, meteorological boundary conditions and ensuring data quality for inputs to LSMs and DA routines. The machine learning layer in LDT facilitates the use of modern data science algorithms for developing data-driven predictive models. Through the use of an object-oriented framework design, LDT provides extensible features for the continued development of support for different types of observational data sets and data analytics algorithms to aid land surface modelling and data assimilation.

Published

2018

43. Quantifying the Added Value of Snow Cover Area Observations in Passive Microwave Snow Depth Data Assimilation

Author

Yuqiong Liu, Christa D. Peters-Lidard, David Mocko, Sujay V. Kumar, Augusto Getirana, and Kristi R. Arsenault

Subjects

Atmospheric Science, Data assimilation, Meteorology, Streamflow, Snowmelt, Environmental science, Moderate-resolution imaging spectroradiometer, Snowpack, Snow, Snow cover, Microwave, Remote sensing

Abstract

Accurate determination of snow conditions is important for several water management applications, partly because of the significant influence of snowmelt on seasonal streamflow prediction. This article examines an approach using snow cover area (SCA) observations as snow detection constraints during the assimilation of snow depth retrievals from passive microwave sensors. Two different SCA products [the Interactive Multisensor Snow and Ice Mapping System (IMS) and the Moderate Resolution Imaging Spectroradiometer (MODIS)] are employed jointly with the snow depth retrievals from a variety of sensors for data assimilation in the Noah land surface model. The results indicate that the use of MODIS data is effective in obtaining added improvements (up to 6% improvement in aggregate RMSE) in snow depth fields compared to assimilating passive microwave data alone, whereas the impact of IMS data is small. The improvements in snow depth fields are also found to translate to small yet systematic improvements in streamflow estimates, especially over the western United States, the upper Missouri River, and parts of the Northeast and upper Mississippi River. This study thus demonstrates a simple approach for exploiting the information from SCA observations in data assimilation.

Published

2015

44. Blending satellite-based snow depth products with in situ observations for streamflow predictions in the Upper Colorado River Basin

Author

Sujay V. Kumar, Kristi R. Arsenault, Christa D. Peters-Lidard, David Mocko, and Yuqiong Liu

Subjects

Radiometer, Meteorology, SNOTEL, Streamflow, Environmental science, Satellite, Terrain, Moderate-resolution imaging spectroradiometer, Snowpack, Snow, Water Science and Technology

Abstract

In snowmelt-driven river systems, it is critical to enable reliable predictions of the spatiotemporal variability in seasonal snowpack to support local and regional water management. Previous studies have shown that assimilating satellite-station blended snow depth data sets can lead to improved snow predictions, which however do not always translate into improved streamflow predictions, especially in complex mountain regions. In this study, we explore how an existing optimal interpolation-based blending strategy can be enhanced to reduce biases in satellite snow depth products for improving streamflow predictions. Two major new considerations are explored, including: (1) incorporating terrain aspect and (2) incorporating areal snow coverage information. The methodology is applied to the bias reduction of the Advanced Microwave Scanning Radiometer for the Earth Observing System (AMSR-E) snow depth estimates, which are then assimilated into the Noah land surface model via the ensemble Kalman Filtering (EnKF) for streamflow predictions in the Upper Colorado River Basin. Our results indicate that using only observations from low-elevation stations such as the Global Historical Climatology Network (GHCN) in the bias correction can lead to underestimation in streamflow, while using observations from high-elevation stations (e.g., the Snow Telemetry (SNOTEL) network) along with terrain aspect is critically important for achieving reliable streamflow predictions. Additionally incorporating areal snow coverage information from the Moderate Resolution Imaging Spectroradiometer (MODIS) can slightly improve the streamflow results further.

Published

2015

45. Calculating Crop Water Requirement Satisfaction in the West Africa Sahel with Remotely Sensed Soil Moisture

Author

Gregory Husak, Molly E. Brown, James P. Verdin, Amy McNally, Soni Yatheendradas, Kristi R. Arsenault, Mark L. Carroll, Christa D. Peters-Lidard, and Chris Funk

Subjects

Hydrology, Atmospheric Science, Warning system, business.industry, Hydrological modelling, Agricultural engineering, West africa, Crop, Data assimilation, Agriculture, Famine, Environmental science, business, Water content

Abstract

The Soil Moisture Active Passive (SMAP) mission will provide soil moisture data with unprecedented accuracy, resolution, and coverage, enabling models to better track agricultural drought and estimate yields. In turn, this information can be used to shape policy related to food and water from commodity markets to humanitarian relief efforts. New data alone, however, do not translate to improvements in drought and yield forecasts. New tools will be needed to transform SMAP data into agriculturally meaningful products. The objective of this study is to evaluate the possibility and efficiency of replacing the rainfall-derived soil moisture component of a crop water stress index with SMAP data. The approach is demonstrated with 0.1°-resolution, ~10-day microwave soil moisture from the European Space Agency and simulated soil moisture from the Famine Early Warning Systems Network Land Data Assimilation System. Over a West Africa domain, the approach is evaluated by comparing the different soil moisture estimates and their resulting Water Requirement Satisfaction Index values from 2000 to 2010. This study highlights how the ensemble of indices performs during wet versus dry years, over different land-cover types, and the correlation with national-level millet yields. The new approach is a feasible and useful way to quantitatively assess how satellite-derived rainfall and soil moisture track agricultural water deficits. Given the importance of soil moisture in many applications, ranging from agriculture to public health to fire, this study should inspire other modeling communities to reformulate existing tools to take advantage of SMAP data.

Published

2015

46. A land data assimilation system for sub-Saharan Africa food and water security applications

Author

Shraddhanand Shukla, Pete Peterson, Chris Funk, Sujay V. Kumar, James P. Verdin, Amy McNally, Kristi R. Arsenault, Shugong Wang, and Christa D. Peters-Lidard

Subjects

Statistics and Probability, Data Descriptor, 010504 meteorology & atmospheric sciences, Disaster risk reduction, 0208 environmental biotechnology, Soil science, 02 engineering and technology, Library and Information Sciences, 01 natural sciences, Education, Evapotranspiration, Information system, 0105 earth and related environmental sciences, Warning system, business.industry, Environmental resource management, Natural hazards, Vegetation, 020801 environmental engineering, Computer Science Applications, Water security, Land information system, Environmental science, Famine, Hydrology, Statistics, Probability and Uncertainty, business, Information Systems

Abstract

Seasonal agricultural drought monitoring systems, which rely on satellite remote sensing and land surface models (LSMs), are important for disaster risk reduction and famine early warning. These systems require the best available weather inputs, as well as a long-term historical record to contextualize current observations. This article introduces the Famine Early Warning Systems Network (FEWS NET) Land Data Assimilation System (FLDAS), a custom instance of the NASA Land Information System (LIS) framework. The FLDAS is routinely used to produce multi-model and multi-forcing estimates of hydro-climate states and fluxes over semi-arid, food insecure regions of Africa. These modeled data and derived products, like soil moisture percentiles and water availability, were designed and are currently used to complement FEWS NET’s operational remotely sensed rainfall, evapotranspiration, and vegetation observations. The 30+ years of monthly outputs from the FLDAS simulations are publicly available from the NASA Goddard Earth Science Data and Information Services Center (GES DISC) and recommended for use in hydroclimate studies, early warning applications, and by agro-meteorological scientists in Eastern, Southern, and Western Africa. Machine-accessible metadata file describing the reported data (ISA-Tab format)

Published

2017

47. Assimilation of Remotely Sensed Soil Moisture and Snow Depth Retrievals for Drought Estimation

Author

Ben Livneh, Sujay V. Kumar, G. A. Riggs, Youlong Xia, David Mocko, Michael H. Cosh, Christa D. Peters-Lidard, Michael Ek, Yuqiong Liu, Kristi R. Arsenault, and Rolf H. Reichle

Subjects

Hydrology, Atmospheric Science, Data assimilation, Streamflow, Environmental science, Assimilation (biology), Atmospheric sciences, Snow, Water content

Abstract

The accurate knowledge of soil moisture and snow conditions is important for the skillful characterization of agricultural and hydrologic droughts, which are defined as deficits of soil moisture and streamflow, respectively. This article examines the influence of remotely sensed soil moisture and snow depth retrievals toward improving estimates of drought through data assimilation. Soil moisture and snow depth retrievals from a variety of sensors (primarily passive microwave based) are assimilated separately into the Noah land surface model for the period of 1979–2011 over the continental United States, in the North American Land Data Assimilation System (NLDAS) configuration. Overall, the assimilation of soil moisture and snow datasets was found to provide marginal improvements over the open-loop configuration. Though the improvements in soil moisture fields through soil moisture data assimilation were barely at the statistically significant levels, these small improvements were found to translate into subsequent small improvements in simulated streamflow. The assimilation of snow depth datasets were found to generally improve the snow fields, but these improvements did not always translate to corresponding improvements in streamflow, including some notable degradations observed in the western United States. A quantitative examination of the percentage drought area from root-zone soil moisture and streamflow percentiles was conducted against the U.S. Drought Monitor data. The results suggest that soil moisture assimilation provides improvements at short time scales, both in the magnitude and representation of the spatial patterns of drought estimates, whereas the impact of snow data assimilation was marginal and often disadvantageous.

Published

2014

48. A new approach to satellite-based estimation of precipitation over snow cover

Author

Yuqiong Liu, Ali Behrangi, Kristi R. Arsenault, and Yudong Tian

Subjects

Current (stream), Quantitative precipitation estimation, Climatology, Northern Hemisphere, General Earth and Planetary Sciences, Environmental science, Satellite, Storm, Precipitation, Snowpack, Snow

Abstract

Current satellite-based remote-sensing approaches are largely incapable of estimating precipitation over snow cover. This note reports a proof-of-concept study of a new satellite-based approach to the estimation of precipitation over snow-covered surfaces. The method is based on the principle that precipitation can be inferred from the changes in the snow water equivalent of the snowpack. Using satellite-based snow water equivalent measurements, we derived daily precipitation amounts for the northern hemisphere for three snow-accumulation seasons, and evaluated these against independent reference datasets. The new precipitation estimates captured realistic-looking storm events over largely un-instrumented regions. However, the data are noisy and, on a seasonal scale, the amount of precipitation is believed to be underestimated. Nevertheless, current uncertainty in snow measurements, albeit large (50–100%), is still lower than direct precipitation measurements over snow (100–140%) and therefore this approa...

Published

2014

49. Uncertainties in Evapotranspiration Estimates over West Africa

Author

Augusto Getirana, Kristi R. Arsenault, Thomas R. H. Holmes, Amy McNally, and Hahn Chul Jung

Subjects

010504 meteorology & atmospheric sciences, evapotranspiration, land surface model, 0207 environmental engineering, 02 engineering and technology, Forcing (mathematics), 01 natural sciences, Arid, West africa, FluxNet, Evapotranspiration, Climatology, Net radiation, West Africa, uncertainty, General Earth and Planetary Sciences, Environmental science, lcsh:Q, Precipitation, lcsh:Science, 020701 environmental engineering, 0105 earth and related environmental sciences, Humid climate

Abstract

An evapotranspiration (ET) ensemble composed of 36 land surface model (LSM) experiments and four diagnostic datasets (GLEAM, ALEXI, MOD16, and FLUXNET) is used to investigate uncertainties in ET estimate over five climate regions in West Africa. Diagnostic ET datasets show lower uncertainty estimates and smaller seasonal variations than the LSM-based ET values, particularly in the humid climate regions. Overall, the impact of the choice of LSMs and meteorological forcing datasets on the modeled ET rates increases from north to south. The LSM formulations and parameters have the largest impact on ET in humid regions, contributing to 90% of the ET uncertainty estimates. Precipitation contributes to the ET uncertainty primarily in arid regions. The LSM-based ET estimates are sensitive to the uncertainty of net radiation in arid region and precipitation in humid region. This study serves as support for better determining water availability for agriculture and livelihoods in Africa with earth observations and land surface models.

Published

2019

50. Assimilation of gridded GRACE terrestrial water storage estimates in the North American Land Data Assimilation System

Author

Martha C. Anderson, Sujay V. Kumar, Matthew Rodell, Michael Ek, Augusto Getirana, Kristi R. Arsenault, Michael F. Jasinski, Christopher Hain, Christa D. Peters-Lidard, Michael H. Cosh, Gabrielle De Lannoy, David Mocko, Benjamin F. Zaitchik, Bailing Li, Youlong Xia, and Rolf H. Reichle

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Meteorology, Anomaly (natural sciences), 0208 environmental biotechnology, Drainage basin, Assimilation (biology), 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Data assimilation, Climatology, Evapotranspiration, Environmental science, Water cycle, Groundwater, Terrestrial water storage, 0105 earth and related environmental sciences

Abstract

© 2016 American Meteorological Society. The objective of the North American Land Data Assimilation System (NLDAS) is to provide best-available estimates of near-surface meteorological conditions and soil hydrological status for the continental United States. To support the ongoing efforts to develop data assimilation (DA) capabilities for NLDAS, the results of Gravity Recovery and Climate Experiment (GRACE) DA implemented in a manner consistent with NLDAS development are presented. Following previous work, GRACE terrestrial water storage (TWS) anomaly estimates are assimilated into the NASA Catchment land surface model using an ensemble smoother. In contrast to many earlier GRACE DA studies, a gridded GRACE TWS product is assimilated, spatially distributed GRACE error estimates are accounted for, and the impact that GRACE scaling factors have on assimilation is evaluated. Comparisons with quality-controlled in situ observations indicate that GRACE DA has a positive impact on the simulation of unconfined groundwater variability across the majority of the eastern United States and on the simulation of surface and root zone soil moisture across the country. Smaller improvements are seen in the simulation of snow depth, and the impact of GRACE DA on simulated river discharge and evapotranspiration is regionally variable. The use of GRACE scaling factors during assimilation improved DA results in the western United States but led to small degradations in the eastern United States. The study also found comparable performance between the use of gridded and basin-averaged GRACE observations in assimilation. Finally, the evaluations presented in the paper indicate that GRACE DA can be helpful in improving the representation of droughts. ispartof: Journal of Hydrometeorology vol:17 issue:7 pages:1951-1972 status: published

Published

2016