Abstract
Soil moisture can vary spatially at the scale of agricultural fields
(~10 -100 m), which is generally too fine to resolve
using passive radiometric methods. Active radar provides an opportunity
for finer resolution measurements; in particular, the interferometric
synthetic aperture radar (InSAR) closure phase parameter is sensitive to
changing soil moisture. We have developed a model showing that
systematic non-zero closure phase can result from scattering from
objects at different depths in a medium of time-varying dielectric, such
as from changes in soil moisture. The model predicts that interference
between surface and subsurface reflections are needed for closure phase
to be non-zero. We find that, under certain circumstances, we can
estimate soil moisture from closure phase using a data reduction
approach that includes a cumulative sum of closure phase over time and
removal of a trend. The correlation between cumulative closure phase and
soil moisture suggests that the closure phase is related to the change
in soil moisture. We examined a large test region in Oklahoma, where the
detrended cumulative closure phase from Sentinel-1 data demonstrates
some agreement with in situ soil moisture measurements. In other
areas, the match is weaker, implying a terrain dependence for the
quality of fit. Cumulative InSAR closure phase promises to provide a
valuable new method to remotely estimate soil moisture.