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Dr. Xulin Guo is a professor at the Department of Geography and Planning. She has a BSc in Forest Management, a MSc. in Forest Economics from the Beijing Forest University, and a PhD in Remote Sensing and Biogeography from the University of Kansas. Her research focuses on the remote sensing of grasslands, beginning with her PhD program on the tall grass prairie, and moving to the mixed grass prairie in 2001. She participated in special international collaborative projects for grasslands in Inner Mongolia and Tibet, and has collaborated on grassland and forest management and monitoring plans with the Ministry of Saskatchewan. She has also conducted grassland research for the Natural Sciences and Engineering Research Council of Canada for many consecutive years. In 2019, she received the John H. Warkentin Award for Scholarly Contributions to Geography in the Western Interior by the Prairie Division’s Canadian Association of Geographers.
It is important to protect forest and grassland ecosystems because they are ecologically rich and provide numerous ecosystem services. Upscaling monitoring from local to global scale is imperative in reaching this goal. The SDG Agenda does not include indicators that directly quantify ecosystem health. Remote sensing and Geographic Information Systems (GIS) can bridge the gap for large-scale ecosystem health assessment. We systematically reviewed field-based and remote-based measures of ecosystem health for forests and grasslands, identified the most important ones and provided an overview on remote sensing and GIS-based measures. We included 163 English language studies within terrestrial non-tropical biomes and used a pre-defined classification system to extract ecological stressors and attributes, collected corresponding indicators, measures, and proxy values. We found that the main ecological attributes of each ecosystem contribute differently in the literature, and that almost half of the examined studies used remote sensing to estimate indicators. The major stressor for forests was “climate change”, followed by “insect infestation”; for grasslands it was “grazing”, followed by “climate change”. “Biotic interactions, composition, and structure” was the most important ecological attribute for both ecosystems. “Fire disturbance” was the second most important for forests, while for grasslands it was “soil chemistry and structure”. Less than a fifth of studies used vegetation indices; NDVI was the most common. There are monitoring inconsistencies from the broad range of indicators and measures. Therefore, we recommend a standardized field, GIS, and remote sensing-based approach to monitor ecosystem health and integrity and facilitate land managers and policy-makers.
Irini Soubry; Thuy Doan; Thuan Chu; Xulin Guo. A Systematic Review on the Integration of Remote Sensing and GIS to Forest and Grassland Ecosystem Health Attributes, Indicators, and Measures. Remote Sensing 2021, 13, 3262 .
AMA StyleIrini Soubry, Thuy Doan, Thuan Chu, Xulin Guo. A Systematic Review on the Integration of Remote Sensing and GIS to Forest and Grassland Ecosystem Health Attributes, Indicators, and Measures. Remote Sensing. 2021; 13 (16):3262.
Chicago/Turabian StyleIrini Soubry; Thuy Doan; Thuan Chu; Xulin Guo. 2021. "A Systematic Review on the Integration of Remote Sensing and GIS to Forest and Grassland Ecosystem Health Attributes, Indicators, and Measures." Remote Sensing 13, no. 16: 3262.
Woody plant encroachment (WPE), the expansion of native and non-native trees and shrubs into grasslands, has led to degradation worldwide. In the Canadian prairies, western snowberry and wolfwillow shrubs are common encroachers, whose cover is currently unknown. As the use of remote sensing in grassland monitoring increases, opportunities to detect and map these woody species are enhanced. Therefore, the purpose of this study is to identify the optimal season for detection of the two shrubs, to determine the sensitive wavelengths and bands that allow for their separation, and to investigate differences in separability potential between a hyperspectral and broadband multispectral approach. We do this by using spring, summer, and fall field-based spectra of both shrubs for the calculation of spectral separability metrics and for the simulation of broadband spectra. Our results show that the summer offers higher discrimination between the two species, especially when using the red and blue spectral regions and to a lesser extent the green region. The fall season fails to provide significant spectral separation along the wavelength spectrum. Moreover, there is no significant difference in the results from the hyperspectral or broadband approach. Nevertheless, cross-validation with satellite imagery is needed to confirm the current results.
Irini Soubry; Xulin Guo. Seasonal Spectral Separation of Western Snowberry and Wolfwillow in Grasslands with Field Spectroradiometer and Simulated Multispectral Bands. Environments 2021, 8, 60 .
AMA StyleIrini Soubry, Xulin Guo. Seasonal Spectral Separation of Western Snowberry and Wolfwillow in Grasslands with Field Spectroradiometer and Simulated Multispectral Bands. Environments. 2021; 8 (7):60.
Chicago/Turabian StyleIrini Soubry; Xulin Guo. 2021. "Seasonal Spectral Separation of Western Snowberry and Wolfwillow in Grasslands with Field Spectroradiometer and Simulated Multispectral Bands." Environments 8, no. 7: 60.
Woody plant encroachment (WPE), the expansion of native and non-native trees and shrubs into grasslands, is a less studied factor that leads to declines in grassland ecosystem health. With the increasing application of remote sensing in grassland monitoring and measuring, it is still difficult to detect WPE at its early stages when its spectral signals are not strong enough. Even at late stages, woody species have strong vegetation characteristics that are commonly categorized as healthy ecosystems. We focus on how shrub encroachment can be detected through remote sensing by looking at the biophysical and spectral properties of the WPE grassland ecosystem, investigating the appropriate season and wavelengths that identify shrub cover, testing the spectral separability of different shrub cover groups and by revealing the lowest shrub cover that can be detected by remote sensing. Biophysical results indicate spring as the best season to distinguish shrubs in our study area. The earliest shrub encroachment can be identified most likely only when the cover reaches between 10% and 25%. A correlation between wavelength spectra and shrub cover indicated four regions that are statistically significant, which differ by season. Furthermore, spectral separability of shrubs increases with their cover; however, good separation is only possible for pure shrub pixels. From the five separability metrics used, Transformed divergence and Jeffries-Matusita distance have better interpretations. The spectral regions for pure shrub pixel separation are slightly different from those derived by correlation and can be explained by the influences from land cover mixtures along our study transect.
Irini Soubry; Xulin Guo. Identification of the Optimal Season and Spectral Regions for Shrub Cover Estimation in Grasslands. Sensors 2021, 21, 3098 .
AMA StyleIrini Soubry, Xulin Guo. Identification of the Optimal Season and Spectral Regions for Shrub Cover Estimation in Grasslands. Sensors. 2021; 21 (9):3098.
Chicago/Turabian StyleIrini Soubry; Xulin Guo. 2021. "Identification of the Optimal Season and Spectral Regions for Shrub Cover Estimation in Grasslands." Sensors 21, no. 9: 3098.