Jornada Bibliography
The southern Kalahari as a dust source: preliminary results from the field. Eighth International Conference on Aeolian Research (ICAR VIII). :p.326.
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2014. Spatial prediction of ecosystem state transitions on the Taos Plateau. Society for Rangeland Meetings. 88
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2020. 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. WRF-Chem simulation of a Southwest United States dust-on-snow episode . American Geophysical Union Fall Meeting.
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2022. Addressing air quality, agriculture, and climate change across the Southwest and Southern Plains: A roadmap for research, extension, and policy. Bulletin of the American Meteorological Society. 102(7):1394–1401.
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2021. Australian net (1950s-1990) soil organic carbon erosion: implications for CO2 emission and land-atmosphere modelling. Biogeosciences. 11:5235-5244.
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2014. Climate change impacts on wind and water erosion on US rangelands. Journal of Soil and Water Conservation. 74(4):405-418.
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2019. Comparison of soil-aggregate crushing-energy meters. Aeolian Research. 42(100559)
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2020. Consistency of wind erosion assessments across land use and land cover types: a critical analysis. Aeolian Research. 15:153-260.
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2014. Critical standing crop residue amounts for wind erosion control in the inland Pacific Northwest, USA. CATENA. 195
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2020. Dust emission from crusted surfaces: Insights from field measurements and modelling. Aeolian Research. 40:1-14.
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2019. 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. Ecosystem dynamics and aeolian sediment transport in the southern Kalahari. African Journal of Ecology. 58:337-344.
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2020. The effect of roughness elements on wind erosion: The importance of surface shear stress distribution. Journal of Geophysical Research: Atmospheres. 119:6066-6084.
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2014. Enhancing wind erosion monitoring and assessment for US rangelands. Rangelands. 39:85-96.
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2017. The Grassland–Shrubland Regime Shift in the Southwestern United States: Misconceptions and Their Implications for Management. Bioscience. 68(9):678-690.
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2018. Grazing impacts on the susceptibility of rangelands to wind erosion: the effects of stocking rate, stocking strategy and land condition. Aeolian Research. 17:89-99.
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2015. Ground cover, erosion risk and production implications of targeted management practices in Australian mixed farming systems: lessons from the Grain and Graze program. Agricultural Systems. 162:123-135.
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2018. Improving ground cover monitoring for wind erosion assessment using MODIS BRDF parameters. Remote Sensing of Environment. 204:756-768.
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2018. Indicators and benchmarks for wind erosion monitoring, assessment and management. Ecological Indicators. 110(105881)
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2020. An inductive approach to developing ecological site concepts with existing monitoring data. Rangeland Ecology & Management. 83:133-148.
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2022. Land degradation and climate change: building climate resilience in agriculture. Frontiers in Ecology and the Environment. 15:450-459.
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2017. The Land-Potential Knowledge System (LandPKS): mobile apps and collaboration for optimizing climate change investments. Ecosystem Health and Sustainability. 2(3)
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2016. Measuring the social and ecological performance of agricultural innovations on rangelands: Progress and plans for an indicator framework in the LTAR network. Rangelands. :1-11.
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2022. 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. A North American dust emission climatology (2001–2020) calibrated to dust point sources from satellite observations. Aeolian Research. 54:100766.
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2021. A note on the use of drag partition in aeolian transport models. Aeolian Research. 42(100560)
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2020. Parameterizing an aeolian erosion (AERO) model for rangelands. Aeolian Research. 54
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2021. Provoking a Cultural Shift in Data Quality. BioScience.
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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. Resolving dust emission responses to land cover change using an ecological land classification. Aeolian Research. 32:141-153
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2018. Scale invariance of albedo-based wind friction velocity. Journal of Geophysical Research: Atmospheres. 125(16):1-15.
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2020. The significance of carbon-enriched dust for global carbon accounting. Global Change Biology. 18:3275-3278.
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2012. Size distribution of mineral dust emissions from sparsely vegetated and supply-limited dryland soils. Journal of Geophysical Research: Atmospheres. 126(22):e2021JD035478.
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2021. Social vulnerability to climate change in primary producers: a typology approach . Agriculture, Ecosystems and Environment. 186:86-93.
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2014. Soil loss and PM10 emissions from agricultural fields in the Junggar Basin over the past six decades. Journal of Soil and Water Conservation. 77(2):113-125.
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2022. Soil organic carbon dust emission: an omitted global source of atmospheric CO2. Global Change Biology. 19:3238-3244.
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2013. Soil Organic Carbon Erosion is Critical for Land Degradation Neutrality. Environmental Science and Policy. 93:43-52.
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2019. Ten practical questions to improve data quality. Rangelands. :1-12.
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2021. Threshold wind velocity dynamics as a driver of aeolian sediment mass flux. Aeolian Research. 20:45-59.
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2016. A tribute to Michael R. Raupach for contributions to aeolian fluid dynamics. Aeolian Research. 19:37-54.
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2015. Using albedo to reform wind erosion modelling, mapping and monitoring. Aeolian Research. 23
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2016. Vegetation Canopy Gap Size and Height: Critical Indicators for Wind Erosion Monitoring and Management. Rangeland Ecology & Management. 76:78-83.
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