A conceptual model of vegetation dynamics for the unique obligate‐seeder eucalypt woodlands of south‐western Australia

Models of vegetation dynamics framed as testable hypotheses provide powerful tools for predicting vegetation change in response to contemporary disturbances or climate change. Synthesizing existing information and applying new data, we develop a conceptual model of vegetation states and transitions...

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Veröffentlicht in:	Austral ecology 2018-09, Vol.43 (6), p.681-695
Hauptverfasser:	Gosper, Carl R., Yates, Colin J., Cook, Garry D., Harvey, Judith M., Liedloff, Adam C., McCaw, W. Lachlan, Thiele, Kevin R., Prober, Suzanne M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aridity Burning Climate change Disturbance Disturbances ecological synthesis Environmental changes fire ecology fire management Flammability Grasses Landscape Recruitment Salt lakes Seed banks Seeds Spatial distribution stand‐replacement disturbance temperate woodland Trees Vegetation Wildfires Woodlands
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container_end_page	695
container_issue	6
container_start_page	681
container_title	Austral ecology
container_volume	43
creator	Gosper, Carl R. Yates, Colin J. Cook, Garry D. Harvey, Judith M. Liedloff, Adam C. McCaw, W. Lachlan Thiele, Kevin R. Prober, Suzanne M.
description	Models of vegetation dynamics framed as testable hypotheses provide powerful tools for predicting vegetation change in response to contemporary disturbances or climate change. Synthesizing existing information and applying new data, we develop a conceptual model of vegetation states and transitions for the previously overlooked woodlands dominated by obligate‐seeder eucalypts of dry to semi‐arid south‐western Australia. These comprise the largest extant temperate woodland globally, are uniquely dominated by a high diversity of obligate‐seeder eucalypts (55 taxa), but are under threat from wildfire. Our conceptual model incorporates four critical ecological processes that also distinguish obligate‐seeder woodlands from temperate woodlands dominated by resprouting eucalypts: (i) a lack of well‐protected epicormic buds results in major disturbances (prominently fire) being stand‐replacing. The pre‐disturbance tree cohort is killed, followed by dense post‐disturbance recruitment from seed shed from a serotinous seed bank; (ii) competition between saplings leads to self‐thinning over a multi‐century timeframe, with surviving individuals having great longevity (regularly >400 years); (iii) multiple processes limit recruitment in the absence of stand‐replacement disturbances, leading to frequent single‐cohort stands. However, unlike the few other obligate‐seeder eucalypt communities, trickle recruitment in very long‐unburnt stands can facilitate indefinite community persistence in the absence of stand‐replacement disturbances; and (iv) discontinuous fuels, relatively low understorey flammability (low grass and often high chenopod cover) and topographic barriers to fire (salt lakes) allow mature woodlands to persist for centuries without burning. Notably though, evidence suggests that flammability peaks at intermediate times since fire, establishing a ‘flammability bottleneck’ (or landscape fire trap) through which regenerating woodlands must pass. Our model provides a framework to support management to conserve obligate‐seeder eucalypt woodlands. Research into reasons for exceptional tree heights relative to ecosystem productivity, the evolution of diverse and dominant obligate‐seeder eucalypts, the paucity of grass, and the recent spatial distribution of fires, will further inform conservation management.
doi_str_mv	10.1111/aec.12613
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Lachlan ; Thiele, Kevin R. ; Prober, Suzanne M.</creator><creatorcontrib>Gosper, Carl R. ; Yates, Colin J. ; Cook, Garry D. ; Harvey, Judith M. ; Liedloff, Adam C. ; McCaw, W. Lachlan ; Thiele, Kevin R. ; Prober, Suzanne M.</creatorcontrib><description>Models of vegetation dynamics framed as testable hypotheses provide powerful tools for predicting vegetation change in response to contemporary disturbances or climate change. Synthesizing existing information and applying new data, we develop a conceptual model of vegetation states and transitions for the previously overlooked woodlands dominated by obligate‐seeder eucalypts of dry to semi‐arid south‐western Australia. These comprise the largest extant temperate woodland globally, are uniquely dominated by a high diversity of obligate‐seeder eucalypts (55 taxa), but are under threat from wildfire. Our conceptual model incorporates four critical ecological processes that also distinguish obligate‐seeder woodlands from temperate woodlands dominated by resprouting eucalypts: (i) a lack of well‐protected epicormic buds results in major disturbances (prominently fire) being stand‐replacing. The pre‐disturbance tree cohort is killed, followed by dense post‐disturbance recruitment from seed shed from a serotinous seed bank; (ii) competition between saplings leads to self‐thinning over a multi‐century timeframe, with surviving individuals having great longevity (regularly >400 years); (iii) multiple processes limit recruitment in the absence of stand‐replacement disturbances, leading to frequent single‐cohort stands. However, unlike the few other obligate‐seeder eucalypt communities, trickle recruitment in very long‐unburnt stands can facilitate indefinite community persistence in the absence of stand‐replacement disturbances; and (iv) discontinuous fuels, relatively low understorey flammability (low grass and often high chenopod cover) and topographic barriers to fire (salt lakes) allow mature woodlands to persist for centuries without burning. Notably though, evidence suggests that flammability peaks at intermediate times since fire, establishing a ‘flammability bottleneck’ (or landscape fire trap) through which regenerating woodlands must pass. Our model provides a framework to support management to conserve obligate‐seeder eucalypt woodlands. 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Lachlan</creatorcontrib><creatorcontrib>Thiele, Kevin R.</creatorcontrib><creatorcontrib>Prober, Suzanne M.</creatorcontrib><title>A conceptual model of vegetation dynamics for the unique obligate‐seeder eucalypt woodlands of south‐western Australia</title><title>Austral ecology</title><description>Models of vegetation dynamics framed as testable hypotheses provide powerful tools for predicting vegetation change in response to contemporary disturbances or climate change. Synthesizing existing information and applying new data, we develop a conceptual model of vegetation states and transitions for the previously overlooked woodlands dominated by obligate‐seeder eucalypts of dry to semi‐arid south‐western Australia. These comprise the largest extant temperate woodland globally, are uniquely dominated by a high diversity of obligate‐seeder eucalypts (55 taxa), but are under threat from wildfire. Our conceptual model incorporates four critical ecological processes that also distinguish obligate‐seeder woodlands from temperate woodlands dominated by resprouting eucalypts: (i) a lack of well‐protected epicormic buds results in major disturbances (prominently fire) being stand‐replacing. The pre‐disturbance tree cohort is killed, followed by dense post‐disturbance recruitment from seed shed from a serotinous seed bank; (ii) competition between saplings leads to self‐thinning over a multi‐century timeframe, with surviving individuals having great longevity (regularly >400 years); (iii) multiple processes limit recruitment in the absence of stand‐replacement disturbances, leading to frequent single‐cohort stands. However, unlike the few other obligate‐seeder eucalypt communities, trickle recruitment in very long‐unburnt stands can facilitate indefinite community persistence in the absence of stand‐replacement disturbances; and (iv) discontinuous fuels, relatively low understorey flammability (low grass and often high chenopod cover) and topographic barriers to fire (salt lakes) allow mature woodlands to persist for centuries without burning. Notably though, evidence suggests that flammability peaks at intermediate times since fire, establishing a ‘flammability bottleneck’ (or landscape fire trap) through which regenerating woodlands must pass. Our model provides a framework to support management to conserve obligate‐seeder eucalypt woodlands. Research into reasons for exceptional tree heights relative to ecosystem productivity, the evolution of diverse and dominant obligate‐seeder eucalypts, the paucity of grass, and the recent spatial distribution of fires, will further inform conservation management.</description><subject>Aridity</subject><subject>Burning</subject><subject>Climate change</subject><subject>Disturbance</subject><subject>Disturbances</subject><subject>ecological synthesis</subject><subject>Environmental changes</subject><subject>fire ecology</subject><subject>fire management</subject><subject>Flammability</subject><subject>Grasses</subject><subject>Landscape</subject><subject>Recruitment</subject><subject>Salt lakes</subject><subject>Seed banks</subject><subject>Seeds</subject><subject>Spatial distribution</subject><subject>stand‐replacement disturbance</subject><subject>temperate woodland</subject><subject>Trees</subject><subject>Vegetation</subject><subject>Wildfires</subject><subject>Woodlands</subject><issn>1442-9985</issn><issn>1442-9993</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp1kL9OwzAQhy0EEqUw8AaWmBja2omT2mNUlT9SJRaYLde-tKncONgOVZh4BJ6RJyEliI1b7obvfnf6ELqmZEr7minQU5rkND1BI8pYMhFCpKd_M8_O0UUIO0IIzwUdofcCa1draGKrLN47Axa7Er_BBqKKlaux6Wq1r3TApfM4bgG3dfXaAnZrW21UhK-PzwBgwGNotbJdE_HBOWNVbcIxKrg2bnvoACGCr3HRhuiVrdQlOiuVDXD128fo5W75vHiYrJ7uHxfFaqITMU8nGSFZNudGkJzzdQqQs4TNtdIiAxDCECU4BUGU5owToQnjOaPEGEEpLzNIx-hmyG286x8PUe5c6-v-pEyIoJnIWSp66nagtHcheChl46u98p2kRB7Vyl6t_FHbs7OBPVQWuv9BWSwXw8Y3HNZ9rQ</recordid><startdate>201809</startdate><enddate>201809</enddate><creator>Gosper, Carl R.</creator><creator>Yates, Colin J.</creator><creator>Cook, Garry D.</creator><creator>Harvey, Judith M.</creator><creator>Liedloff, Adam C.</creator><creator>McCaw, W. 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Lachlan</creatorcontrib><creatorcontrib>Thiele, Kevin R.</creatorcontrib><creatorcontrib>Prober, Suzanne M.</creatorcontrib><collection>CrossRef</collection><collection>Animal Behavior Abstracts</collection><collection>Chemoreception Abstracts</collection><collection>Ecology Abstracts</collection><collection>Entomology Abstracts (Full archive)</collection><collection>Technology Research Database</collection><collection>Environmental Sciences and Pollution Management</collection><collection>Engineering Research Database</collection><collection>Biotechnology and BioEngineering Abstracts</collection><jtitle>Austral ecology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Gosper, Carl R.</au><au>Yates, Colin J.</au><au>Cook, Garry D.</au><au>Harvey, Judith M.</au><au>Liedloff, Adam C.</au><au>McCaw, W. Lachlan</au><au>Thiele, Kevin R.</au><au>Prober, Suzanne M.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A conceptual model of vegetation dynamics for the unique obligate‐seeder eucalypt woodlands of south‐western Australia</atitle><jtitle>Austral ecology</jtitle><date>2018-09</date><risdate>2018</risdate><volume>43</volume><issue>6</issue><spage>681</spage><epage>695</epage><pages>681-695</pages><issn>1442-9985</issn><eissn>1442-9993</eissn><abstract>Models of vegetation dynamics framed as testable hypotheses provide powerful tools for predicting vegetation change in response to contemporary disturbances or climate change. Synthesizing existing information and applying new data, we develop a conceptual model of vegetation states and transitions for the previously overlooked woodlands dominated by obligate‐seeder eucalypts of dry to semi‐arid south‐western Australia. These comprise the largest extant temperate woodland globally, are uniquely dominated by a high diversity of obligate‐seeder eucalypts (55 taxa), but are under threat from wildfire. Our conceptual model incorporates four critical ecological processes that also distinguish obligate‐seeder woodlands from temperate woodlands dominated by resprouting eucalypts: (i) a lack of well‐protected epicormic buds results in major disturbances (prominently fire) being stand‐replacing. The pre‐disturbance tree cohort is killed, followed by dense post‐disturbance recruitment from seed shed from a serotinous seed bank; (ii) competition between saplings leads to self‐thinning over a multi‐century timeframe, with surviving individuals having great longevity (regularly >400 years); (iii) multiple processes limit recruitment in the absence of stand‐replacement disturbances, leading to frequent single‐cohort stands. However, unlike the few other obligate‐seeder eucalypt communities, trickle recruitment in very long‐unburnt stands can facilitate indefinite community persistence in the absence of stand‐replacement disturbances; and (iv) discontinuous fuels, relatively low understorey flammability (low grass and often high chenopod cover) and topographic barriers to fire (salt lakes) allow mature woodlands to persist for centuries without burning. Notably though, evidence suggests that flammability peaks at intermediate times since fire, establishing a ‘flammability bottleneck’ (or landscape fire trap) through which regenerating woodlands must pass. Our model provides a framework to support management to conserve obligate‐seeder eucalypt woodlands. Research into reasons for exceptional tree heights relative to ecosystem productivity, the evolution of diverse and dominant obligate‐seeder eucalypts, the paucity of grass, and the recent spatial distribution of fires, will further inform conservation management.</abstract><cop>Richmond</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1111/aec.12613</doi><tpages>15</tpages><orcidid>https://orcid.org/0000-0002-0962-5117</orcidid></addata></record>
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source	Wiley Online Library Journals Frontfile Complete
subjects	Aridity Burning Climate change Disturbance Disturbances ecological synthesis Environmental changes fire ecology fire management Flammability Grasses Landscape Recruitment Salt lakes Seed banks Seeds Spatial distribution stand‐replacement disturbance temperate woodland Trees Vegetation Wildfires Woodlands
title	A conceptual model of vegetation dynamics for the unique obligate‐seeder eucalypt woodlands of south‐western Australia
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