Crop water productivity from cloud-Based landsat helps assess California’s water savings

Daniel Foley; Prasad Thenkabail; Adam Oliphant; Itiya P. Aneece; Pardhasaradhi Teluguntla

doi:10.3390/rs15194894

Crop water productivity from cloud-Based landsat helps assess California’s water savings

Remote Sensing

By: Daniel Foley, Prasad Thenkabail, Adam Oliphant, Itiya P. Aneece, and Pardhasaradhi Teluguntla

https://doi.org/10.3390/rs15194894

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More information: Publisher Index Page (via DOI)
Data Release: USGS data release - Crop Specific Landsat Derived Reference Evapotranspiration, Evaporative Fraction, and Actual Evapotranspiration for 2016 in the California Central Valley
Open Access Version: Publisher Index Page
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Abstract

Demand for food and water are increasing while the extent of arable land and accessible fresh water are decreasing. This poses global challenges as economies continue to develop and the population grows. With agriculture as the leading consumer of water, better understanding how water is used to produce food may help support the increase of Crop Water Productivity (CWP; kg/m³), the ratio of crop output per unit of water input (or crop per drop). Previous large-scale CWP studies have been useful for broad water use modeling at coarser resolutions. However, obtaining more precise CWP, especially for specific crop types in a particular area and growing season as outlined here are important for informing farm-scale water management decision making. Therefore, this study focused on California’s Central Valley utilizing high-spatial resolution satellite imagery of 30 m (0.09 hectares per pixel) to generate more precise CWP for commonly grown and water-intensive irrigated crops. First, two products were modeled and mapped. 1. Landsat based Actual Evapotranspiration (ET_a; mm/d) to determine Crop Water Use (CWU; m³/m²), and 2. Crop Productivity (CP; kg/m²) to estimate crop yield per growing season. Then, CWP was calculated by dividing CP by CWU and mapped. The amount of water that can be saved by increasing CWP of each crop was further calculated. For example, in the 434 million m² study area, a 10% increase in CWP across the 9 crops analyzed had a potential water savings of 31.5 million m³ of water. An increase in CWP is widely considered the best approach for saving maximum quantities of water. This paper proposed, developed, and implemented a workflow of combined methods utilizing cloud computing based remote sensing data. The environmental implications of this work in assessing water savings for food and water security in the 21st century are expected to be significant.

Suggested Citation

Foley, D., Thenkabail, P., Oliphant, A., Aneece, I.P., Pardhasaradhi Teluguntla, 2024, Crop water productivity from cloud-Based landsat helps assess California’s water savings: Remote Sensing, v. 15, no. 29, 4894, 23 p., https://doi.org/10.3390/rs15194894.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Crop water productivity from cloud-Based landsat helps assess California’s water savings
Series title	Remote Sensing
DOI	10.3390/rs15194894
Volume	15
Issue	29
Publication Date	October 09, 2023
Year Published	2024
Language	English
Publisher	MDPI
Contributing office(s)	Western Geographic Science Center
Description	4894, 23 p.
Country	United States
State	California