Land-Cover Changes to Surface-Water Buffers in the Midwestern USA: 25 Years of Landsat Data Analyses (1993-2017)

Overview

Journal Remote Sens (Basel)

Date 2021 Jan 8

PMID 33414929

Citations 1

Authors

Tedros M Berhane

Charles R Lane

Samson G Mengistu

Jay Christensen

Heather E Golden

Shi Qiu

Zhe Zhu

Qiusheng Wu

Affiliations

Soon will be listed here.

Abstract

To understand the timing, extent, and magnitude of land use/land cover (LULC) change in buffer areas surrounding Midwestern US waters, we analyzed the full imagery archive (1982-2017) of three Landsat footprints covering ~100,000 km. The study area included urbanizing Chicago, Illinois and St. Louis, Missouri regions and agriculturally dominated landscapes (i.e., Peoria, Illinois). The Continuous Change Detection and Classification algorithm identified 1993-2017 LULC change across three Landsat footprints and in 90 m buffers for ~110,000 surface waters; waters were also size-binned into five groups for buffer LULC change analyses. Importantly, buffer-area LULC change magnitude was frequently much greater than footprint-level change. Surface-water extent in buffers increased by 14-35x the footprint rate and forest decreased by 2-9x. Development in buffering areas increased by 2-4x the footprint-rate in Chicago and Peoria area footprints but was similar to the change rate in the St. Louis area footprint. The LULC buffer-area change varied in waterbody size, with the greatest change typically occurring in the smallest waters (e.g., <0.1 ha). These novel analyses suggest that surface-water buffer LULC change is occurring more rapidly than footprint-level change, likely modifying the hydrology, water quality, and biotic integrity of existing water resources, as well as potentially affecting down-gradient, watershed-scale storages and flows of water, solutes, and particulate matter.

Citing Articles

Headwater streams and inland wetlands: Status and advancements of geospatial datasets and maps across the United States.

Christensen J, Golden H, Alexander L, Pickard B, Fritz K, Lane C Earth Sci Rev. 2023; 235:1-24.

PMID: 36970305 PMC: 10031651. DOI: 10.1016/j.earscirev.2022.104230.

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