Nationally Representative Plot Network Reveals Contrasting Drivers of Net Biomass Change in Secondary and Old-Growth Forests

Uncertainty about the mechanisms driving biomass change at broad spatial scales limits our ability to predict the response of forest biomass storage to global change. Here we use a spatially representative network of 874 forest plots in New Zealand to examine whether commonly hypothesised drivers of...

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Veröffentlicht in:	Ecosystems (New York) 2017-08, Vol.20 (5), p.944-959
Hauptverfasser:	Holdaway, Robert J., Easdale, Tomás A., Carswell, Fiona E., Richardson, Sarah J., Peltzer, Duane A., Mason, Norman W. H., Brandon, Andrea M., Coomes, David A.
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Sprache:	eng
Schlagworte:	Analysis Anthropogenic factors Automobile drivers Biomass Biomedical and Life Sciences Change detection Climate Climate models Dead wood Disturbance Ecology Environmental Management Forest biomass Forests Geoecology/Natural Processes Growth Hydrology/Water Resources Life Sciences Nutrients Old growth forests Original Articles Plant diversity Plant growth Plant Sciences Pools Zoology
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creator	Holdaway, Robert J. Easdale, Tomás A. Carswell, Fiona E. Richardson, Sarah J. Peltzer, Duane A. Mason, Norman W. H. Brandon, Andrea M. Coomes, David A.
description	Uncertainty about the mechanisms driving biomass change at broad spatial scales limits our ability to predict the response of forest biomass storage to global change. Here we use a spatially representative network of 874 forest plots in New Zealand to examine whether commonly hypothesised drivers of forest biomass and biomass change (diversity, disturbance, nutrients and climate) differ between old-growth and secondary forests at a national scale. We calculate biomass stocks and net biomass change for live above-ground biomass, belowground biomass, deadwood and litter pools. We combine these data with plot-level information on forest type, tree diversity, plant functional traits, climate and disturbance history, and use structural equation models to identify the major drivers of biomass change. Over the period 2002–2014, secondary forest biomass increased by 2.78 (1.68–3.89) Mg ha⁻¹ y⁻¹, whereas no significant change was detected in old-growth forests (+0.28; –0.72 to 1.29 Mg ha⁻¹ y⁻¹). The drivers of biomass and biomass change differed between secondary and old-growth forests. Plot-level biomass change of old-growth forest was driven by recent disturbance (large tree mortality within the last decade), whereas biomass change of secondary forest was determined by current biomass and past anthropogenic disturbance. Climate indirectly affected biomass change through its relationship with past anthropogenic disturbance. Our results highlight the importance of disturbance and disturbance history in determining broad-scale patterns of forest biomass change and suggest that explicitly modelling processes driving biomass change within secondary and old-growth forests is essential for predicting future changes in global forest biomass.
doi_str_mv	10.1007/s10021-016-0084-x
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We combine these data with plot-level information on forest type, tree diversity, plant functional traits, climate and disturbance history, and use structural equation models to identify the major drivers of biomass change. Over the period 2002–2014, secondary forest biomass increased by 2.78 (1.68–3.89) Mg ha⁻¹ y⁻¹, whereas no significant change was detected in old-growth forests (+0.28; –0.72 to 1.29 Mg ha⁻¹ y⁻¹). The drivers of biomass and biomass change differed between secondary and old-growth forests. Plot-level biomass change of old-growth forest was driven by recent disturbance (large tree mortality within the last decade), whereas biomass change of secondary forest was determined by current biomass and past anthropogenic disturbance. Climate indirectly affected biomass change through its relationship with past anthropogenic disturbance. 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H.</au><au>Brandon, Andrea M.</au><au>Coomes, David A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Nationally Representative Plot Network Reveals Contrasting Drivers of Net Biomass Change in Secondary and Old-Growth Forests</atitle><jtitle>Ecosystems (New York)</jtitle><stitle>Ecosystems</stitle><date>2017-08-01</date><risdate>2017</risdate><volume>20</volume><issue>5</issue><spage>944</spage><epage>959</epage><pages>944-959</pages><issn>1432-9840</issn><eissn>1435-0629</eissn><abstract>Uncertainty about the mechanisms driving biomass change at broad spatial scales limits our ability to predict the response of forest biomass storage to global change. Here we use a spatially representative network of 874 forest plots in New Zealand to examine whether commonly hypothesised drivers of forest biomass and biomass change (diversity, disturbance, nutrients and climate) differ between old-growth and secondary forests at a national scale. We calculate biomass stocks and net biomass change for live above-ground biomass, belowground biomass, deadwood and litter pools. We combine these data with plot-level information on forest type, tree diversity, plant functional traits, climate and disturbance history, and use structural equation models to identify the major drivers of biomass change. Over the period 2002–2014, secondary forest biomass increased by 2.78 (1.68–3.89) Mg ha⁻¹ y⁻¹, whereas no significant change was detected in old-growth forests (+0.28; –0.72 to 1.29 Mg ha⁻¹ y⁻¹). The drivers of biomass and biomass change differed between secondary and old-growth forests. Plot-level biomass change of old-growth forest was driven by recent disturbance (large tree mortality within the last decade), whereas biomass change of secondary forest was determined by current biomass and past anthropogenic disturbance. Climate indirectly affected biomass change through its relationship with past anthropogenic disturbance. Our results highlight the importance of disturbance and disturbance history in determining broad-scale patterns of forest biomass change and suggest that explicitly modelling processes driving biomass change within secondary and old-growth forests is essential for predicting future changes in global forest biomass.</abstract><cop>New York</cop><pub>Springer Science + Business Media</pub><doi>10.1007/s10021-016-0084-x</doi><tpages>16</tpages><oa>free_for_read</oa></addata></record>
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subjects	Analysis Anthropogenic factors Automobile drivers Biomass Biomedical and Life Sciences Change detection Climate Climate models Dead wood Disturbance Ecology Environmental Management Forest biomass Forests Geoecology/Natural Processes Growth Hydrology/Water Resources Life Sciences Nutrients Old growth forests Original Articles Plant diversity Plant growth Plant Sciences Pools Zoology
title	Nationally Representative Plot Network Reveals Contrasting Drivers of Net Biomass Change in Secondary and Old-Growth Forests
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