Please use this identifier to cite or link to this item: https://hdl.handle.net/1959.11/21083
Full metadata record
DC FieldValueLanguage
dc.contributor.authorWilson, Brianen
dc.contributor.authorKing, Dacreen
dc.contributor.authorGrowns, Ivoren
dc.contributor.authorVeeragathipillai, Manoharanen
dc.date.accessioned2017-05-25T09:46:00Z-
dc.date.issued2017-
dc.identifier.citationSoil Research, 55(4), p. 376-388en
dc.identifier.issn1838-6768en
dc.identifier.issn1838-675Xen
dc.identifier.urihttps://hdl.handle.net/1959.11/21083-
dc.description.abstractSoils represent a significant component of the global terrestrial carbon cycle. Historical soil carbon depletion resulting from soil and land management offers an opportunity to store additional carbon to offset greenhouse gas emissions as part of our international response to climate change. However, our ability to reliably measure, estimate and predict soil carbon storage is hindered by a range of sources of variability, not least of which is change through time. In the present study, we assessed temporal changes in soil organic carbon (SOC) and its component fractions in response to climate alone and in the absence of land use change at any given site by examining a series of soil monitoring sites across a basalt landscape in north-west New South Wales under a range of land use types over a 3-year period (March-April 2008 and March-April 2011), where a significant rainfall event had occurred in the intervening time (2010). Across the dataset, woodland soils contained the largest carbon concentration (SOC%) and total organic carbon stock (TOCs) compared with other non-wooded land use systems, which themselves were statistically similar. However, larger carbon quantities were restricted largely to the surface (0-10 cm) soil layers. Between 2008 and 2011, significant increases in SOC% and TOCs were detected, but again these were restricted to the woodland sites. No change in particulate organic carbon (POC) was detected between the two sampling times, but both humic organic carbon (HOC) and resistant organic carbon (ROC) increased in woodland soils between the two sampling times. Increased HOC we attribute to microbial processing of soil carbon following the 2010-11 rainfall event. However, we suggest that increased ROC results from limitations in mid-infrared calibration datasets and estimations. We conclude that the quantity of soil carbon and its component fractions is, indeed, driven by climatic factors, but that these effects are moderated by aboveground land use and SOC inputs.en
dc.languageenen
dc.publisherCSIRO Publishingen
dc.relation.ispartofSoil Researchen
dc.titleClimatically driven change in soil carbon across a basalt landscape is restricted to non-agricultural land use systemsen
dc.typeJournal Articleen
dc.identifier.doi10.1071/sr16205en
dc.subject.keywordsCarbon Sequestration Scienceen
local.contributor.firstnameBrianen
local.contributor.firstnameDacreen
local.contributor.firstnameIvoren
local.contributor.firstnameManoharanen
local.subject.for2008050301 Carbon Sequestration Scienceen
local.subject.seo2008961403 Forest and Woodlands Soilsen
local.subject.seo2008961402 Farmland, Arable Cropland and Permanent Cropland Soilsen
local.profile.schoolSchool of Environmental and Rural Scienceen
local.profile.schoolSchool of Environmental and Rural Scienceen
local.profile.emailbwilson7@une.edu.auen
local.profile.emailigrowns@une.edu.auen
local.output.categoryC1en
local.record.placeauen
local.record.institutionUniversity of New Englanden
local.identifier.epublicationsrecordune-20170117-163017en
local.publisher.placeAustraliaen
local.format.startpage376en
local.format.endpage388en
local.identifier.scopusid85019559945en
local.peerreviewedYesen
local.identifier.volume55en
local.identifier.issue4en
local.contributor.lastnameWilsonen
local.contributor.lastnameKingen
local.contributor.lastnameGrownsen
local.contributor.lastnameVeeragathipillaien
dc.identifier.staffune-id:bwilson7en
dc.identifier.staffune-id:igrownsen
local.profile.orcid0000-0002-7983-0909en
local.profile.orcid0000-0002-8638-0045en
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
local.identifier.unepublicationidune:21276en
local.identifier.handlehttps://hdl.handle.net/1959.11/21083en
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
local.title.maintitleClimatically driven change in soil carbon across a basalt landscape is restricted to non-agricultural land use systemsen
local.output.categorydescriptionC1 Refereed Article in a Scholarly Journalen
local.search.authorWilson, Brianen
local.search.authorKing, Dacreen
local.search.authorGrowns, Ivoren
local.search.authorVeeragathipillai, Manoharanen
local.uneassociationUnknownen
local.year.published2017en
local.fileurl.closedpublishedhttps://rune.une.edu.au/web/retrieve/9a824444-2907-4692-b5e6-edc2beb3f682en
local.subject.for2020410601 Land capability and soil productivityen
local.subject.for2020410101 Carbon sequestration scienceen
local.subject.for2020410604 Soil chemistry and soil carbon sequestration (excl. carbon sequestration science)en
local.subject.seo2020180605 Soilsen
local.codeupdate.date2022-02-09T10:51:14.015en
local.codeupdate.epersonbwilson7@une.edu.auen
local.codeupdate.finalisedtrueen
local.original.for2020410101 Carbon sequestration scienceen
local.original.seo2020undefineden
local.original.seo2020180605 Soilsen
Appears in Collections:Journal Article
School of Environmental and Rural Science
Files in This Item:
2 files
File Description SizeFormat 
Show simple item record

SCOPUSTM   
Citations

6
checked on Aug 3, 2024

Page view(s)

2,666
checked on Aug 11, 2024
Google Media

Google ScholarTM

Check

Altmetric


Items in Research UNE are protected by copyright, with all rights reserved, unless otherwise indicated.