Please use this identifier to cite or link to this item: http://hdl.handle.net/1893/27420
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dc.contributor.authorTetzlaff, Doertheen_UK
dc.contributor.authorPiovano, Theaen_UK
dc.contributor.authorAla-Aho, Perttien_UK
dc.contributor.authorSmith, Aaronen_UK
dc.contributor.authorCarey, Sean Ken_UK
dc.contributor.authorMarsh, Philipen_UK
dc.contributor.authorWookey, Philip Aen_UK
dc.contributor.authorStreet, Lorna Een_UK
dc.contributor.authorSoulsby, Chrisen_UK
dc.date.accessioned2018-06-21T00:04:14Z-
dc.date.available2018-06-21T00:04:14Z-
dc.date.issued2018-06-15en_UK
dc.identifier.urihttp://hdl.handle.net/1893/27420-
dc.description.abstractUse of isotopes to quantify the temporal dynamics of the transformation of precipitation into run‐off has revealed fundamental new insights into catchment flow paths and mixing processes that influence biogeochemical transport. However, catchments underlain by permafrost have received little attention in isotope‐based studies, despite their global importance in terms of rapid environmental change. These high‐latitude regions offer limited access for data collection during critical periods (e.g., early phases of snowmelt). Additionally, spatio‐temporal variable freeze–thaw cycles, together with the development of an active layer, have a time variant influence on catchment hydrology. All of these characteristics make the application of traditional transit time estimation approaches challenging. We describe an isotope‐based study undertaken to provide a preliminary assessment of travel times at Siksik Creek in the western Canadian Arctic. We adopted a model–data fusion approach to estimate the volumes and isotopic characteristics of snowpack and meltwater. Using samples collected in the spring/summer, we characterize the isotopic composition of summer rainfall, melt from snow, soil water, and stream water. In addition, soil moisture dynamics and the temporal evolution of the active layer profile were monitored. First approximations of transit times were estimated for soil and streamwater compositions using lumped convolution integral models and temporally variable inputs including snowmelt, ice thaw, and summer rainfall. Comparing transit time estimates using a variety of inputs revealed that transit time was best estimated using all available inflows (i.e., snowmelt, soil ice thaw, and rainfall). Early spring transit times were short, dominated by snowmelt and soil ice thaw and limited catchment storage when soils are predominantly frozen. However, significant and increasing mixing with water in the active layer during the summer resulted in more damped steam water variation and longer mean travel times (~1.5 years). The study has also highlighted key data needs to better constrain travel time estimates in permafrost catchments.en_UK
dc.language.isoenen_UK
dc.publisherWileyen_UK
dc.relationTetzlaff D, Piovano T, Ala-Aho P, Smith A, Carey SK, Marsh P, Wookey PA, Street LE & Soulsby C (2018) Using stable isotopes to estimate travel times in a data-sparse Arctic catchment: Challenges and possible solutions. Hydrological Processes, 32 (12), pp. 1936-1952. https://doi.org/10.1002/hyp.13146en_UK
dc.rights© 2018 The Authors. Hydrological Processes Published by John Wiley & Sons Ltd. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.en_UK
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/en_UK
dc.subjectactive layeren_UK
dc.subjectArctic headwatersen_UK
dc.subjectisotopesen_UK
dc.subjectpermafrosten_UK
dc.subjecttransit timesen_UK
dc.titleUsing stable isotopes to estimate travel times in a data-sparse Arctic catchment: Challenges and possible solutionsen_UK
dc.typeJournal Articleen_UK
dc.identifier.doi10.1002/hyp.13146en_UK
dc.citation.jtitleHydrological Processesen_UK
dc.citation.issn1099-1085en_UK
dc.citation.issn0885-6087en_UK
dc.citation.volume32en_UK
dc.citation.issue12en_UK
dc.citation.spage1936en_UK
dc.citation.epage1952en_UK
dc.citation.publicationstatusPublisheden_UK
dc.citation.peerreviewedRefereeden_UK
dc.type.statusVoR - Version of Recorden_UK
dc.contributor.funderNatural Environment Research Councilen_UK
dc.citation.date09/05/2018en_UK
dc.contributor.affiliationUniversity of Aberdeenen_UK
dc.contributor.affiliationUniversity of Aberdeenen_UK
dc.contributor.affiliationUniversity of Aberdeenen_UK
dc.contributor.affiliationUniversity of Aberdeenen_UK
dc.contributor.affiliationMcMaster Universityen_UK
dc.contributor.affiliationUniversity of Waterlooen_UK
dc.contributor.affiliationBiological and Environmental Sciencesen_UK
dc.contributor.affiliationUniversity of Edinburghen_UK
dc.contributor.affiliationUniversity of Aberdeenen_UK
dc.identifier.isiWOS:000435783100015en_UK
dc.identifier.scopusid2-s2.0-85047664400en_UK
dc.identifier.wtid926754en_UK
dc.contributor.orcid0000-0001-5957-6424en_UK
dc.date.accepted2018-04-25en_UK
dcterms.dateAccepted2018-04-25en_UK
dc.date.filedepositdate2018-06-19en_UK
dc.relation.funderprojectPermafrost catchments in transition: hydrological controls on carbon cycling and greenhouse gas budgetsen_UK
dc.relation.funderrefNE/K000284/1en_UK
rioxxterms.apcnot requireden_UK
rioxxterms.typeJournal Article/Reviewen_UK
rioxxterms.versionVoRen_UK
local.rioxx.authorTetzlaff, Doerthe|en_UK
local.rioxx.authorPiovano, Thea|en_UK
local.rioxx.authorAla-Aho, Pertti|en_UK
local.rioxx.authorSmith, Aaron|en_UK
local.rioxx.authorCarey, Sean K|en_UK
local.rioxx.authorMarsh, Philip|en_UK
local.rioxx.authorWookey, Philip A|0000-0001-5957-6424en_UK
local.rioxx.authorStreet, Lorna E|en_UK
local.rioxx.authorSoulsby, Chris|en_UK
local.rioxx.projectNE/K000284/1|Natural Environment Research Council|http://dx.doi.org/10.13039/501100000270en_UK
local.rioxx.freetoreaddate2018-06-19en_UK
local.rioxx.licencehttp://creativecommons.org/licenses/by/4.0/|2018-06-19|en_UK
local.rioxx.filenameTetzlaff_et_al-2018-Hydrological_Processes.pdfen_UK
local.rioxx.filecount1en_UK
local.rioxx.source0885-6087en_UK
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