Jornada Bibliography
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Selection of models of invasive species dynamics. Weed Technology. 18:1236-1239.
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2004. Long-term trends in precipitation and surface water chemistry. Long-Term Trends in Ecological Systems: A Basis for Understanding Responses to Global Change. :115-161.
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2013. Landscape Diversity. Encyclopedia of Biodiversity. 4:476-487.
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2013. Desertification of Rangelands. Climate Vulnerability: Understanding and Addressing Threats to Essential Resources. 4:239-258.
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2013. The Jornada Basin long term ecological research program. 2015 LTER All Scientists Meeting.
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2015. Harnessing the power of big data in ecology by machine learning. 10th Internationl Conference on Ecological Informatics.
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2018. Plant species richness in multiyear wet and dry periods in the Chihuahuan Desert. Climate. 9(8):130.
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2021. Landscape-scale consequences of patch-scale invasion success or failure. US-International Association for Landscape Ecology. :109.
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2002. Analysis of desert plant community growth patterns with high temporal resolution satellite spectra. Journal of Applied Ecology. 34:418-432.
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1997. Long-term trends in human demography and economy across sites. Long-Term Trends in Ecological Systems: A Basis for Understanding Responses to Global Change. :162-190.
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2013. Recruitment potential of two perennial grasses with different growth forms at a semiarid-arid transition zone. American Journal of Botany. 89:1616-1623.
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2002. Long-term trends in production, abundance, and richness of plants and animals. Long-Term Trends in Ecological Systems: A Basis for Understanding Responses to Global Change. :191-205.
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2018. Responses to climate change in hot desert ecosystems: connecting local to global scales. 96th Ecological Society of America Annual Meeting.
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2011. Plant species dominance at a grassland-shrubland ecotone: An individual-based gap dynamics model of herbaceous and woody species. Ecological Modelling. 152:5-32.
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2002. Long-Term Research at the Jornada Basin (LTER VII). LTER All Scientists Meeting 2018.
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2018. Introduction: Approaches to scaling information from plots or regions to landscapes. US-International Association for Landscape Ecology. :81.
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2002. Long-term research across sites, ecosystems, and disciplines: synthesis and research needs. Long-Term Trends in Ecological Systems: A Basis for Understanding Responses to Global Change. :226-233.
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2013. Can we use the past as a lens to the future? Using historic events to predict regional grassland and shrubland responses to multi-year drought or wet periods under climate change 100th Annual Meeting of the Ecological Society of America.
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2015. Developing an integrated knowledge landscape map using a trans-disciplinary approach. LTER All Scientists Meeting.
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2011. A toolkit for ecosystems ecologists in the time of big science. Ecosystems. 20:259-266.
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2017. Long-term trends in ecological systems: An introduction to cross-site comparisons and relevance to global change studies. Long-Term Trends in Ecological Systems: A Basis for Understanding Responses to Global Change. :1-20.
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2011. Ecological theory and practice in arid and semiarid ecosystems: a tale of two LTER sites. 59:151-180.
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2021. Modifying connectivity to promote state change reversal: the importance of geomorphic context and plant–soil feedbacks. Ecology. 101(9):e03069.
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2020. Perspectives on global change theory. Ecological Society of America Abstracts. SYMP 2-7
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2011. Harnessing the power of AI technologies for ecology: The knowledge learning analysis system (KLAS) for spatially-distributed, continuous ecological data. Ecological Society of America.
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2020. Deciphering the past to inform the future: preparing for the next (“really big”) extreme event. Frontiers in Ecology and the Environment. :10.1002/fee.2194.
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2020. Grassland simulation models: A synthesis of current models and future challenges. Handbook of Ecological Models Used in Ecosystem and Environmental Management. :175-201.
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2012. Living in an increasingly connected world: a framework for continental-scale environmental science. Frontiers in Ecology and the Environment. 6:229-237.
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2011. How can science be general, yet specific: The conundrum of rangeland science in the 21st Century. Rangeland Ecology and Management. 65:613-622.
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2012. Understanding vegetation dynamics provides insights to sustainable invasive plant management and remediation strategies. 7th International Conference on the Ecology and Management of Alien Plant Invasions (ESA/WSSA Joint Meeting). :68.
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2003. Ecology in a connect world: A vision for a "network of networks". Frontiers in Ecology and the Environment. 6:227.
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2011. Can connectivity-mediated feedbacks to vegetation explain surprising ecological responses to catastrophic events? Ecological Society of America.
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2018. Directional climate change and potential reversal of desertification in arid and semiarid ecosystems. Global Change Biology. 18(1):151-163.
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2012. Simulation of disturbances and recovery in shortgrass steppe plant communities. Ecology of the Shortgrass Steepe: A long-term perspective. :119-131.
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2011. Factors controlling denitrification in a Chihuahuan Desert ecosystem. Soil Science Society of America Journal. 55:1694-1701.
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1991. Nitrogen loss from deserts in the southwestern United States. Biogeochemistry. 10:67-79.
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1990. Denitrification: enzyme content and activity in desert soils. Soil Biology and Biochemistry. 23:845-855.
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1990. Review of Vesicular Stomatitis in the United States with Focus on 2019 and 2020 Outbreaks. Pathogens . 10(8):993.
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2021. Phylogeny and life history evolution of Prodoxus yucca moths (Lepidoptera: Prodoxidae). Systematic Entomology. DOI: 10.1111/j.1365-3113.2005.00301.x
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2000. Interpreting Indications of Rangeland Health, Version 4. Society for Range Management Annual Meeting Abstracts.
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2006. Interpreting indicators of rangeland health, version 5. Interpreting Indicators of Rangeland Health, Version 5. :202.
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2020.