Your search keyword '"Sujay V Kumar"' showing total 6 results

1. 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

2. 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

3. Irrigation Signals Detected From SMAP Soil Moisture Retrievals

Author

Patricia M. Lawston, Joseph A. Santanello, and Sujay V. Kumar

Published

2017

4. 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

5. Rivers and Floodplains as Key Components of Global Terrestrial Water Storage Variability

Author

Matthew Rodell, Augusto Getirana, Sujay V. Kumar, and Manuela Girotto

Subjects

Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Floodplain, Amazon rainforest, 0208 environmental biotechnology, Central asia, Tropics, 02 engineering and technology, 01 natural sciences, Arid, 020801 environmental engineering, Latitude, Geophysics, General Earth and Planetary Sciences, Environmental science, Physical geography, Surface water, Terrestrial water storage, 0105 earth and related environmental sciences

Abstract

This study quantifies the contribution of rivers and floodplains to terrestrial water storage (TWS) variability. We use state-of-the-art models to simulate land surface processes and river dynamics and to separate TWS into its main components. Based on a proposed impact index, we show that surface water storage (SWS) contributes 8% of TWS variability globally, but that contribution differs widely among climate zones. Changes in SWS are a principal component of TWS variability in the tropics, where major rivers flow over arid regions and at high latitudes. SWS accounts for ~22–27% of TWS variability in both the Amazon and Nile Basins. Changes in SWS are negligible in the Western U.S., Northern Africa, Middle East, and central Asia. Based on comparisons with Gravity Recovery and Climate Experiment-based TWS, we conclude that accounting for SWS improves simulated TWS in most of South America, Africa, and Southern Asia, confirming that SWS is a key component of TWS variability.

Published

2017

6. Anthropogenic Influences Alter the Response and Seasonality of Evapotranspiration: A Case Study Over Two High Mountain Asia Basins

Author

Fadji Z. Maina and Sujay V. Kumar

Subjects

HIGH Mountain Asia, greening, evapotranspiration, irrigation, warming, climate change, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Earth's vegetation has been increasing over the past decades, altering water and energy cycles by changing evapotranspiration (ET). Greening, caused by climatic and anthropogenic factors, has high rates in High Mountain Asia (HMA). Here we focus on two HMA basins (the Yangtze and the Ganges‐Brahmaputra) to contrast the impacts of climate‐ and human‐induced greening on ET. Though the rate of greening is similar in both basins, anthropogenic influences lead to dissimilar responses in ET. In the Yangtze, climate‐induced greening increases ET, with the increase in moisture being high enough to meet the ET demand. In the Ganges‐Brahmaputra, irrigation‐induced greening does not alter annual ET, only pre‐monsoon ET increases. The dry season declines in water storage due to pumping decrease ET, while laboriously meeting the demand. This study provides a representative example of the contrasting influences of climate induced and anthropogenic driven processes on the seasonality of ET.

Published

2024