Jornada Bibliography
An introduction to the special issue on ecological sites. Rangeland. 32(6):3-4.
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2010. An introduction to the special issue on ecological sites. Rangeland. 32(6):3-4.
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2010. An Introduction to the Special Issue “Ecological Sites for Landscape Management". Rangelands. 38(38:311-312)
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2016. An Introduction to the Special Issue “Ecological Sites for Landscape Management". Rangelands. 38(38:311-312)
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2016. Introduction to special section on mineral dust: outstanding problems in quantifying the radiative impact of mineral dust. Journal of Geophysics Research. 106:15-18.
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2001. 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. The interactive role of wind and water in functioning of drylands: what does the future hold? BioScience. 68(9):670-677.
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2018. The interactive effects of press/pulse intensity and duration on regime shifts at multiple scales. Ecological Monographs. 87:198-218.
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2017. Integrating two remote sensing-based hydrological models and MODIS data to improve water supply forecasts in the Rio Grande Basin. Hydrology: Science & Practice for the 21st Century. 1:453-457.
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2004. Integrating space and time: A case for phenological context in grazing studies and management. Frontiers of Agricultural Science and Engineering. 5:44-56.
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2018. Integrating remotely-sensed imagery and existing multi-scale field data to derive rangeland indicators: an application of Bayesian additive regression trees. Rangeland Ecology and Management. 70:644-655.
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2017. Integrating remotely-sensed imagery and existing multi-scale field data to derive rangeland indicators: an application of Bayesian additive regression trees. Rangeland Ecology and Management. 70:644-655.
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2017. Integrating human dimensions within the LTAR Network to achieve agroecological system transformation. Rangelands.
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2021. Integrating human dimensions within the LTAR Network to achieve agroecological system transformation. Rangelands.
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2021. An integrated View of Complex Landscapes: A Big Data-Model Integration Approach to Transdisciplinary Science. Bioscience. 68:653-669.
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2018. An integrated View of Complex Landscapes: A Big Data-Model Integration Approach to Transdisciplinary Science. Bioscience. 68:653-669.
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2018. An integrated View of Complex Landscapes: A Big Data-Model Integration Approach to Transdisciplinary Science. Bioscience. 68:653-669.
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2018. An integrated View of Complex Landscapes: A Big Data-Model Integration Approach to Transdisciplinary Science. Bioscience. 68:653-669.
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2018. An integrated framework for science-based arid land management. Journal of Arid Environments. 65:319-335.
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2006. An integrated framework for science-based arid land management. Journal of Arid Environments. 65:319-335.
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2006. Innovation in rangeland monitoring: annual, 30 m, plant functional type percent cover maps for U.S. rangelands, 1984–2017. Ecosphere. 9(9):1-19.
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2018. Innovation in rangeland monitoring: annual, 30 m, plant functional type percent cover maps for U.S. rangelands, 1984–2017. Ecosphere. 9(9):1-19.
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2018. The influence of soil water potential on the perennial vegetation of a desert arroyo. The Southwestern Naturalist. 19:241-248.
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1974. Influence of small-scale disturbances by kangaroo rates on Chihuahuan Desert ants. Oecologia. 125:142-149.
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2000. Influence of ruminally dispensed monensin and forage maturity on intake and digestion. Journal of Range Management. 46:214-220.
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1993. The influence of landscape position on temporal variability in four North American ecosystems. American Naturalist. 138:341-348.
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1991. The influence of landscape position on temporal variability in four North American ecosystems. American Naturalist. 138:341-348.
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1991. Influence of an exotic species, acroptilon repens (L.) DC. on the initial survival and growth of native grasses. Plant Ecology. 166:157-166.
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2003. An inductive approach to developing ecological site concepts with existing monitoring data. Rangeland Ecology & Management. 83:133-148.
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2022. An inductive approach to developing ecological site concepts with existing monitoring data. Rangeland Ecology & Management. 83:133-148.
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2022. Indicators and benchmarks for wind erosion monitoring, assessment and management. Ecological Indicators. 110(105881)
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2020. Indicators and benchmarks for wind erosion monitoring, assessment and management. Ecological Indicators. 110(105881)
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2020. Indicator patches: exploiting spatial heterogeneity to improve monitoring systems. Rangeland Journal. 31:385-394.
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2009. Indicator patches: exploiting spatial heterogeneity to improve monitoring systems. Rangeland Journal. 31:385-394.
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2009. Increase in number of dominant plants and dominance-classes on a grassland in the northern Chihuahuan Desert. Journal of Range Management. 40:136-139.
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1987. Incorporating Radiation Inputs into the Snowmelt Runoff Model. Hydrological Process. 10:1329-1343.
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1996. Incorporating hydrologic data and ecohydrologic relationships into ecological site descriptions. Rangeland Ecology and Management. 69:4-19.
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2016. Incorporating hydrologic data and ecohydrologic relationships into ecological site descriptions. Rangeland Ecology and Management. 69:4-19.
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2016. Incorporating hydrologic data and ecohydrologic relationships into ecological site descriptions. Rangeland Ecology and Management. 69:4-19.
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2016. 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 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. 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. 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. Improved satellite snow mapping, snowmelt runoff forecasting, and climate change in simulations in the upper Rio Grande basin. World Resource Review. 15:25-41.
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2003. An improved protocol for micropropagation of saltbush (atriplex) species. Native Plant Journal. 11:53-56.
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2010. Importance of Forbs on Southwestern Ranges. Rangelands. 2:35-36.
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1980. Impacts of biological soil crust disturbance and composition on C and N loss from water erosion. Biogeochemistry. 77:247-263.
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2006. Impacts of biological soil crust disturbance and composition on C and N loss from water erosion. Biogeochemistry. 77:247-263.
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2006. Impacts of atmospheric nutrient deposition on marine productivity: Roles of nitrogen, phosphorus, and iron. Global Biogeochemical Cycles. 25:GB2022.
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2011.