Research Bibliography
Found 48 results
Filters: Author is Gough, Christopher M. [Clear All Filters]
Climate drives modeled forest carbon cycling resistance and resilience in the Upper Great Lakes Region, USA. Journal of Geophysical Research: Biogeosciences.
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2021. Disturbance‐accelerated succession increases the production of a temperate forest. Ecological Applications.
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2021. An experimental approach for crown to whole-canopy defoliation in forests. Canadian Journal of Forest Research.
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2021. Forest Structural Complexity and Biomass Predict First-Year Carbon Cycling Responses to Disturbance. Ecosystems. 24
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2021. The fortedata R package: open-science datasets from a manipulative experiment testing forest resilience. Earth System Science Data. 13(3):943-952.
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2021. A multidimensional stability framework enhances interpretation and comparison of carbon cycling response to disturbance. Ecosphere. 1267116103(11)
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2021. Power law scaling relationships link canopy structural complexity and height across forest types. Functional Ecology. 108163750851882(22103113)
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2021. Root lateral interactions drive water uptake patterns under water limitation. Advances in Water Resources. :103896.
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2021. Application of multidimensional structural characterization to detect and describe moderate forest disturbance. Ecosphere. 11(6)
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2020. Stand age, disturbance history and the temporal stability of forest production. Forest Ecology and Management. 460:117865.
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2020. Structure and parameter uncertainty in centennial projections of forest community structure and carbon cycling. Global Change Biology. 2639(11):6080-6096.
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2020. Contrasting Development of Canopy Structure and Primary Production in Planted and Naturally Regenerated Red Pine Forests. Forests. 10(7):566.
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2019. Defining a spectrum of integrative trait‐based vegetation canopy structural types. Ecology Letters. 958503710211550851882
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2019. High rates of primary production in structurally complex forests. Ecology. 100(10)
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2019. Effects of canopy structure and species diversity on primary production in upper Great Lakes forests. Oecologia. 18842211098218217142537632627632815132609242981265014892535430649351639730292051897617728313279669172151496619199815257:405-415.
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2018. Forest aging, disturbance and the carbon cycle. New Phytologist. 11520893601651821063897135849211621871824561134551414214063216481771017273619659947400305
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2018. Shifting conceptions of complexity in forest management and silviculture. Forest Ecology and Management.
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2018. Physiographic factors underlie rates of biomass production during succession in Great Lakes forest landscapes. Forest Ecology and Management. 397:157-173.
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2017. Coarse woody debris and the carbon balance of a moderately disturbed forest. Forest Ecology and Management. 361:38-45.
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2016. Evaluating forest subcanopy response to moderate severity disturbance and contribution to ecosystem-level productivity and resilience. Forest Ecology and Management. 376:135-147.
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2016. Joint control of terrestrial gross primary productivity by plant phenology and physiology. Proceedings of the National Academy of Sciences. :201413090.
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2015. The match and mismatch between photosynthesis and land surface phenology of deciduous forests. Agricultural and Forest Meteorology. 214-215:25-38.
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2015. Modeling forest carbon cycle response to tree mortality: Effects of plant functional type and disturbance intensity. Journal of Geophysical Research: Biogeosciences. :n/a-n/a.
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2015. .
2015. Modeling growing season phenology in North American forests using seasonal mean vegetation indices from MODIS. Remote Sensing of Environment. 147:79-88.
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2014.