Jornada Bibliography
Using very-large-scale aerial imagery for rangeland monitoring and assessment: some statistical considerations. Rangeland Ecology and Management. 65:330-339.
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2012. A test of critical thresholds and their indicators in a desertification-prone ecosystem: more resilience than we thought. Ecology Letters. 16:339-345.
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2013. A Technique for Estimating Rangeland Canopy-Gap Size Distributions From High-Resolution Digital Imagery. Rangeland Ecology & Management. 65(2):196-207.
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2012. Spatial and temporal variability of plant-available water in calcium carbonate-cemented soils and consequences for arid ecosystem resilience. Oecologia. 163(1):215-226.
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2010. Spatial and temporal patterns of water availability in a grass-shrub ecotone and implications for grassland recovery in arid environments. Ecohydrology. 3:55-67.
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2010. Soil water dynamics at 15 locations distributed across a desert landscape: insights from a 27-yr dataset. Ecosphere. 9(7):36pp.
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2018. Soil processes and properties that distinguish ecological sites and states. Rangelands. 32(6):9-15.
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2010. Scale-dependent feedbacks between patch size and plant reproduction in desert grassland. Ecosystems. 18(1):146-153.
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2015. Sampling design workflows and tools to support adaptive monitoring and management. Rangelands. :1-9.
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2021. Revolutionary land use change in the 21st century: Is (rangeland) science relevant? Rangeland Ecology and Management. 65:590-598.
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2012. Regional ensemble modeling reduces uncertainty for digital soil mapping. Geoderma. 397:114998.
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2021. Reducing sampling uncertainty in aeolian research to improve change detection. Journal of Geophysical Research. 124:1-12.
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2019. Rangeland and pasture monitoring: an approach to interpretation of high-resolution imagery focused on observer calibration for repeatability. Environmental Monitoring and Assessment. 184:3789-3804.
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2012. Parameterizing an aeolian erosion (AERO) model for rangelands. Aeolian Research. 54
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2021. The National Wind Erosion Research Network: Building a standardized long-term data resource for aeolian research, modeling and land management. Aeolian Research. 22:23-36.
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2016. Modeling vegetation heights from high resolution stereo aerial photography: An application for broad-scale rangeland monitoring. Journal of Environmental Management. 144:226-235.
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2014. Legacy effects in linked ecological–soil– geomorphic systems of drylands. Frontiers in Ecology and the Environment. 13(1):13-19.
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2015. Interpretation of high-resolution imagery for detecting vegetation cover composition change after fuels reduction treatments in woodlands. Ecological Indicators. 45:570-578.
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2014. Improving the effectiveness of ecological site descriptions: General state-and-transition models and the Ecosystem Dynamics Interpretive Tool (EDIT). Rangelands. 38:329-335
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2016. Improving Landsat predictions of rangeland fractional cover with multitask learning and uncertainty. Methods in Ecology and Evolution. 12(5):841-846.
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2021. Image interpreter tool: An ArcGIS tool for estimating vegetation cover from high-resolution imagery. Rangelands. 33(4):35-40.
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2011. A holistic strategy for adaptive land management. Journal of Soil and Water Conservation. 67(4):105A-113A.
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2012. The high water-holding capacity of petrocalcic horizons. Soil Science Society of America. 71:812-819.
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2007. Hierarchial analysis of vegetation dynamics over 71 years: soil-rainfall interactions in a Chihuahuan Desert ecosystem. Ecological Applications. 22(3):909-926.
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2012. Generalizing ecological site concepts of the Colorado Plateau for landscape-level applications. Rangelands. 38:342-349
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2016. Fine-Resolution Repeat Topographic Surveying of Dryland Landscapes Using UAS-Based Structure-from-Motion Photogrammetry: Assessing Accuracy and Precision against Traditional Ground-Based Erosion Measurements. Remote Sensing . 9(5):1-24.
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2017. Fine-Resolution Repeat Topographic Surveying of Dryland Landscapes Using UAS-Based Structure-from-Motion Photogrammetry: Assessing Accuracy and Precision against Traditional Ground-Based Erosion Measurements. Remote Sensing. 9:437
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2017. Enhancing wind erosion monitoring and assessment for US rangelands. Rangelands. 39:85-96.
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2017. Ecological site-based assessments of wind and water erosion: Informing accelerated soil erosion management in rangelands. Ecological Applications. 24(6):1405-1420.
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2014. Disentangling road network impacts: the need for a holistic approach. Journal of Soil and Water Conservation. 66(2):31A-36A.
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2011. Digital soil mapping in the absence of field training data: A case study using terrain attributes and semiautomated soil signature derivation to distinguish ecological potential. Applied and Environmental Soil Science. 2001(Article ID 421904):421904.
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2011. Digital mapping of ecological land units using a nationally scalable modeling framework. Soil Science Society of America Journal. 83:666-686.
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2019. Desertification, land use, and the transformation of global drylands. Frontiers in Ecology and the Environment. 13(1):28-36.
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2015. Cross-system comparisons elucidate disturbance complexities and generalities. Ecosphere. 2(7):Article81.
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2011. Assessing transportation infrastructure impacts on rangelands: Test of a standard rangeland assessment protocol. Rangeland Ecology and Management. 63(5):524-536.
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2010. Assessing impacts of roads: Application of a standard assessment protocol. Rangeland Ecology and Management. 66:364-375.
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2013. Adapting to climate change on desert rangelands: A multi-site comparison of grazing behavior plasticity of heritage and improved beef cattle. Journal of Arid Environments. 209:104886.
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2022. Adapting to climate change on desert rangelands: A multi-site comparison of grazing behavior plasticity of heritage and improved beef cattle. Journal of Arid Environments. 209:104886.
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2022. WRF-Chem simulation of a Southwest United States dust-on-snow episode . American Geophysical Union Fall Meeting.
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2022. A technique for estimating rangeland canopy-gap size distributions from high resolution digital imagery. Society for Range Management 65th Annual Meeting. p. 0255
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2011. Studying the impacts of dust emission and dust deposition on snow over the Upper Colorado River Basin using the WRF-Chem-CTSM coupled framework. AGU22 FALL MEETING.
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2022. Real-time LoRaWAN precision ranching technologies: What we've learned. 2022 Society for Range Management Annual Meeting.
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2022. Quantifying accelerated soil erosion through ecological site-based assessments of wind and water erosion. Eighth International Conference on Aeolian Research (ICAR VIII). :p.357.
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2014. Leveraging standardized monitoring data to support grazing land soil erosion assessments. LTAR Annual Meeting.
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2021. The impact of vegetation removal by oil and gas development on wind erosion and dust emission in the Upper Colorado River Basin. AGU22 FALL MEETING.
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2022. Identifying thresholds in pattern-process relationships: a new cross-scale interactions experiment at the Jornada Basin LTER. 2012 LTER All Scientists Meeting. p. 43
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2012. Elevated dust emissions on the Colorado Plateau: Role of grazing vehicle disturbance, and increasing aridity. Society for Range Management Meeting. January 28-February 2, 2018
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2018. Deriving shrub heights from high resolution stereo-pair aerial imagery: An application for broad-scale rangeland monitoring. 65th Annual Meeting of the Society for Range Management. p. 0114
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2011. Deciphering landscape complexity to predict (non)linear responses to extreme climatic events. American Geophysical Union. H54D-04
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2012. Cross-scale interactions drive ecosystem responses to precipitation in the Chihuahuan Desert. 97th Ecological Society of America Meeting. COS 186-2
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2012.