Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance

Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance

Carbon (C) cycling processes are particularly dynamic following disturbance, with initial responses often indicative of longer-term change. In northern Michigan, USA, we initiated the Forest Resilience Threshold Experiment (FoRTE) to identify the processes that sustain or lead to the decline of C cy...

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Bibliographic Details
Main Authors: Maxim S. Grigri, Jeff W. Atkins, Christoph Vogel, Ben Bond-Lamberty, Christopher M. Gough
Format: Article
Language:English
Published: MDPI AG 2020-12-01
Series:Forests
Subjects:
disturbance
aboveground net primary production
carbon cycle
eastern forests
disturbance severity
disturbance type
Online Access:https://www.mdpi.com/1999-4907/11/12/1306
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spelling doaj-1ab9351b183f413c82f4580de4249ec22020-12-06T00:02:13ZengMDPI AGForests1999-49072020-12-01111306130610.3390/f11121306Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting DisturbanceMaxim S. Grigri0Jeff W. Atkins1Christoph Vogel2Ben Bond-Lamberty3Christopher M. Gough4Department of Biology, Virginia Commonwealth University, Richmond, VA 23059, USADepartment of Biology, Virginia Commonwealth University, Richmond, VA 23059, USABiological Station, University of Michigan, Pellston, MI 49769, USAPacific Northwest National Laboratory, Joint Global Change Research Institute, 5825 University Research Ct, College Park, MD 20740, USADepartment of Biology, Virginia Commonwealth University, Richmond, VA 23059, USACarbon (C) cycling processes are particularly dynamic following disturbance, with initial responses often indicative of longer-term change. In northern Michigan, USA, we initiated the Forest Resilience Threshold Experiment (FoRTE) to identify the processes that sustain or lead to the decline of C cycling rates across multiple levels (0, 45, 65 and 85% targeted gross leaf area index loss) of disturbance severity and, in response, to separate disturbance types preferentially targeting large or small diameter trees. Simulating the effects of boring insects, we stem girdled > 3600 trees below diameter at breast height (DBH), immediately and permanently disrupting the phloem. Weekly DBH measurements of girdled and otherwise healthy trees (<i>n</i> > 700) revealed small but significant increases in daily aboveground wood net primary production (ANPP<sub>w</sub>) in the 65 and 85% disturbance severity treatments that emerged six weeks after girdling. However, we observed minimal change in end-of-season leaf area index and no significant differences in annual ANPP<sub>w</sub> among disturbance severities or between disturbance types, suggesting continued C fixation by girdled trees sustained stand-scale wood production in the first growing season after disturbance. We hypothesized higher disturbance severities would favor the growth of early successional species but observed no significant difference between early and middle to late successional species’ contributions to ANPP<sub>w</sub> across the disturbance severity gradient. We conclude that ANPP<sub>w</sub> stability immediately following phloem disruption is dependent on the continued, but inevitably temporary, growth of phloem-disrupted trees. Our findings provide insight into the tree-to-ecosystem mechanisms supporting stand-scale wood production stability in the first growing season following a phloem-disrupting disturbance.https://www.mdpi.com/1999-4907/11/12/1306disturbanceaboveground net primary productioncarbon cycleeastern forestsdisturbance severitydisturbance type
collection DOAJ
language English
format Article
sources DOAJ
author Maxim S. Grigri
Jeff W. Atkins
Christoph Vogel
Ben Bond-Lamberty
Christopher M. Gough
spellingShingle Maxim S. Grigri
Jeff W. Atkins
Christoph Vogel
Ben Bond-Lamberty
Christopher M. Gough
Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance
Forests
disturbance
aboveground net primary production
carbon cycle
eastern forests
disturbance severity
disturbance type
author_facet Maxim S. Grigri
Jeff W. Atkins
Christoph Vogel
Ben Bond-Lamberty
Christopher M. Gough
author_sort Maxim S. Grigri
title Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance
title_short Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance
title_full Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance
title_fullStr Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance
title_full_unstemmed Aboveground Wood Production Is Sustained in the First Growing Season after Phloem-Disrupting Disturbance
title_sort aboveground wood production is sustained in the first growing season after phloem-disrupting disturbance
publisher MDPI AG
series Forests
issn 1999-4907
publishDate 2020-12-01
description Carbon (C) cycling processes are particularly dynamic following disturbance, with initial responses often indicative of longer-term change. In northern Michigan, USA, we initiated the Forest Resilience Threshold Experiment (FoRTE) to identify the processes that sustain or lead to the decline of C cycling rates across multiple levels (0, 45, 65 and 85% targeted gross leaf area index loss) of disturbance severity and, in response, to separate disturbance types preferentially targeting large or small diameter trees. Simulating the effects of boring insects, we stem girdled > 3600 trees below diameter at breast height (DBH), immediately and permanently disrupting the phloem. Weekly DBH measurements of girdled and otherwise healthy trees (<i>n</i> > 700) revealed small but significant increases in daily aboveground wood net primary production (ANPP<sub>w</sub>) in the 65 and 85% disturbance severity treatments that emerged six weeks after girdling. However, we observed minimal change in end-of-season leaf area index and no significant differences in annual ANPP<sub>w</sub> among disturbance severities or between disturbance types, suggesting continued C fixation by girdled trees sustained stand-scale wood production in the first growing season after disturbance. We hypothesized higher disturbance severities would favor the growth of early successional species but observed no significant difference between early and middle to late successional species’ contributions to ANPP<sub>w</sub> across the disturbance severity gradient. We conclude that ANPP<sub>w</sub> stability immediately following phloem disruption is dependent on the continued, but inevitably temporary, growth of phloem-disrupted trees. Our findings provide insight into the tree-to-ecosystem mechanisms supporting stand-scale wood production stability in the first growing season following a phloem-disrupting disturbance.
topic disturbance
aboveground net primary production
carbon cycle
eastern forests
disturbance severity
disturbance type
url https://www.mdpi.com/1999-4907/11/12/1306
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