Fine-scale surficial soil moisture mapping using UAS-based L-band remote sensing in a mixed oak-grassland landscape

Michelle A. Stern; Ryan Ferrell; Lorraine E. Flint; Melina Kozanitas; David Ackerly; Jack Elston; Maciej Stachura; Eryan Dai; James H. Thorne

doi:10.3389/frsen.2024.1337953

Fine-scale surficial soil moisture mapping using UAS-based L-band remote sensing in a mixed oak-grassland landscape

Frontiers in Remote Sensing

By: Michelle A. Stern, Ryan Ferrell, Lorraine E. Flint, Melina Kozanitas, David Ackerly, Jack Elston, Maciej Stachura, Eryan Dai, and James H. Thorne

https://doi.org/10.3389/frsen.2024.1337953

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Abstract

Soil moisture maps provide quantitative information that, along with climate and energy balance, is critical to integrate with hydrologic processes for characterizing landscape conditions. However, soil moisture maps are difficult to produce for natural landscapes because of vegetation cover and complex topography. Satellite-based L-band microwave sensors are commonly used to develop spatial soil moisture data products, but most existing L-band satellites provide only coarse scale (one to tens of kilometers grid size), information that is unsuitable for measuring soil moisture variation at hillslope or watershed-scales. L-band sensors are typically deployed on satellite platforms and aircraft but have been too large to deploy on small uncrewed aircraft systems (UAS). There is a need for greater spatial resolution and development of effective measures of soil moisture across a variety of natural vegetation types. To address these challenges, a novel UAS-based L-band radiometer system was evaluated that has recently been tested in agricultural settings. In this study, L-band UAS was used to map soil moisture at 3–50-m (m) resolution in a 13 square kilometer (km²) mixed grassland-forested landscape in Sonoma County, California. The results represent the first application of this technology in a natural landscape with complex topography and vegetation. The L-band inversion of the radiative transfer model produced soil moisture maps with an average unbiased root mean squared error (ubRMSE) of 0.07 m³/m³ and a bias of 0.02 m³/m³. Improved fine-scale soil moisture maps developed using UAS-based systems may be used to help inform wildfire risk, improve hydrologic models, streamflow forecasting, and early detection of landslides.

Suggested Citation

Stern, M.A., Ferrell, R., Flint, L.E., Kozanitas, M., Ackerly, D., Elston, J., Stachura, M., Dai, E., and Thorne, J.H., 2024, Fine-scale surficial soil moisture mapping using UAS-based L-band remote sensing in a mixed oak-grassland landscape: Frontiers in Remote Sensing, v. 5, 1337953, 12 p., https://doi.org/10.3389/frsen.2024.1337953.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Fine-scale surficial soil moisture mapping using UAS-based L-band remote sensing in a mixed oak-grassland landscape
Series title	Frontiers in Remote Sensing
DOI	10.3389/frsen.2024.1337953
Volume	5
Publication Date	November 20, 2024
Year Published	2024
Language	English
Publisher	Frontiers Media
Contributing office(s)	California Water Science Center
Description	1337953, 12 p.
Country	United States
State	California
County	Sonoma County
City	Santa Rosa
Other Geospatial	Mayacamas Mountains, Pepperwood Preserve