Jornada Bibliography
Species–specific contributions to moderate resolution vegetation indices derived from sub-decimeter aerial photography – Prospects for phenological monitoring. American Society for Photogrammetry and Remote sensing Proceedings.
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2010. Monitoring agroecosystem productivity and phenology at a national scale: A metric assessment framework. Ecological Indicators. 131
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2021. Phenocams bridge the gap between field and satellite observations: Applications from agroecosystems. US-International Association for Landscape Ecology.
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2018. Spatial autocorrelation of shrub cover in an arid rangleand ecosystem from 1937-2008. IEEE Transactions on Geoscience and Remote Sensing.
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2010. Spatial patterns of grassland-shrubland state transitions: a 74-year record on grazed and protected areas. Ecological. 24(6):1421-1433.
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2014. Bridging field observations and remotely sensed assessments of land surface phenology in the arid southwestern U.S.. 95th Ecological Society of America.
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2010. Plant phenology: Taking the pulse of rangelands. Rangelands. 41:129-134.
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2019. Protection from livestock fails to deter shrub proliferation in a desert landscape with a history of heavy grazing. Ecological Applications. 21(5):1629-1642.
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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. Prospects of phenological monitoring in an arid southwestern U.S. rangeland using field observations with hyperspatial and moderate resolution imagery. American Geophysical Union Fall Meeting.
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2009. Temporal dynamics of shrub proliferation: Linking patches to landscapes. International Journal of Geographical Information Science. 25(6):913-930.
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2011. Breaks in MODIS time series portend vegetation change: verification using long-term data in an arid grassland ecosystem. Ecological Applications. 27:1677-1693.
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2017. Grazing effect on woody plant recruitment in a Sonoran Desert grassland across space and time. US International Association for Landscape Ecology.
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2009. Patterns in reproductive phenology for dryland grasses and shrubs from 1993 to 2010 in the Chihuahuan Desert. 96th ESA Annual Meeting, Earth Stewardship: Preserving and enhancing earth's life-support systems.
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2011. Does livestock grazing influence spatial patterns of woody plant proliferation? Ecological Society of America Abstracts. :COS127-10.
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2009. Climate and phenology network synergies for sustainable agriculture. Ecological Society of America.
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2020. Field validation of 1930s aerial photography: What are we missing? Journal of Arid Environments. 73:844-853.
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2009. An evaluation of soil heterogeneity and representativeness within and across sites in the NEON network. ESA - August 2021 meeting -Virtual.
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2021. Emerging technological and cultural shifts advancing drylands research and management. Frontiers in Ecology and the Environment. 13(1):52-60.
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2015. Vegetation index differencing for broad-scale assessment of productivity under prolonged drought and sequential high rainfall conditions. Remote Sensing. 5(5):327-341.
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2013. Where management and climate variability matter most: An evaluation of metrics for monitoring agroecosystem production and phenology. 2021 Fall Meeting of the American Geophysical Union.
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2021. 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. Phenocams bridge the gap between field and satellite observations in an arid grassland ecosystem. Remote Sensing of Environment. 9, 1071
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2017. Incorporating Radiation Inputs into the Snowmelt Runoff Model. Hydrological Process. 10:1329-1343.
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1996. Response of Snowmelt Hydrology to Climate Change. Water, Air and Soil Pollution. 90:335-343.
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1996. A New Version of the Snowmelt Runoff Model Incorporating Radiation. The Environmental Professional . 19:109-116.
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1997. Regional ensemble modeling reduces uncertainty for digital soil mapping. Geoderma. 397:114998.
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2021. Sex in Ephedra trifurca (Ephredraceae) with relation to Chihuahuan Desert habitats. The American Midland Naturalist. 119:137-142.
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1988. Biodiversity and ecosystem function in soil. Ambio. 26:563-70.
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1997. Composition and digestia kinetics of diets selected by suckling range calves. Proceedings of the Western Section Meeting, American Society of Animal Science. 41:264-267.
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1990. Opportunities to implement manureshed management in the U.S. poultry industry. American Society of Ag.
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2020. Poultry manureshed management: Opportunities and challenges for a vertically integrated industry. Journal of Environmental Quality. :1-12.
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2021. Social-Ecological Processes and Impacts Affect Individual and Social Well-Being in a Rural Western U.S. Landscape. Frontiers in Sustainable Food Systems. 4(Article 38)
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2020. Some aspects of ecological climatology of the Jornada Experimental Range New Mexico. Simulation and Analysis of Dynamics of a Semi-Desert Grassland: An Interdisciplinary Workshop Program Toward Evaluating the Potential Ecological Impact of Weather Modification. :2-74.
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1970. Stable isotopes and soil-geomorphology as indicators of Holocene climate change, northern Chihuahuan Desert. Journal of Arid Environments. 43:357-373.
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1999. Eolian stratigraphy of intrabasinal fault depressions in the northern Hueco and southern TularosaBasins: Evidence for neotectonic activity. New Mexico Geological Society Guidebook, 49th Field Conference, Las Cruces Country II. :79-86.
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1998. Inverted clast stratigraphy in an eolian archaeological environment. Geoarchaeology. 17:665-687.
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2002. Southwest transformation: eras of growth and land change in Las Cruces, New Mexico. Southwestern Geographer. 14:57-87.
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2010. .
1964. Vegetational changes on a semidesert grassland range from 1858 to 1963. Ecological Monographs. 35:139-164.
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1965. .
1980. Community response to removals of plant functional groups and species from a Chihuahuan Desert shrubland. Oikos. 110:67-80.
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2005. Comparative production of Larrea divaricata Cav. on three geomorphic surfaces in southern New Mexico. :40.
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1970. Understanding ecological condition and change on rangelands managed by the Bureau of Land Management: An initial report. Ecological Society of America.
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2020. Comparison of LCTA with an integrated soil and vegetation monitoring protocol for monitoring grassland, shrubland, and savanna ecosystems. 10th Annual Integrated Training Area Management Workshop. :99.
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2001. Monitoring grassland, shrubland and savanna ecosystems: LCTA versus an integrated soil and vegetation monitoring protocol. 86th Annual Meeting, Ecological Society of America. :322.
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2012. Modeling erosion in a southern New Mexico watershed using agwa: Sensitivity to variations of input precision and scale. 65th Annual Meeting of the Society for Range Management. p. 0217
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2011. Simulated distribution of Eragrostis lehmanniana (Lehmann lovegrass): Soil–climate interactions complicate predictions. Ecosphere. 13(3):e3974.
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2022. Explaining abrupt spatial transitions in agro-ecosystem responses to periods of extended drought. 2015 LTER All Scientists Meeting.
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2015.