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dc.contributor.authorZagajewski, Bogdan
dc.contributor.authorKycko, Marlena
dc.contributor.authorTømmervik, Hans
dc.contributor.authorBochenek, Zbigniew
dc.contributor.authorWojtun, Bronislaw
dc.contributor.authorBjerke, Jarle W.
dc.contributor.authorKlos, Andrzej
dc.coverage.spatialSvalbard, Norway,nb_NO
dc.date.accessioned2019-01-09T12:07:24Z
dc.date.available2019-01-09T12:07:24Z
dc.date.issued2018
dc.identifier.issn0001-6977
dc.identifier.urihttp://hdl.handle.net/11250/2579938
dc.description.abstractRemote sensing, which is based on a reflected electromagnetic spectrum, offers a wide range of research methods. It allows for the identification of plant properties, e.g., chlorophyll, but a registered signal not only comes from green parts but also from dry shoots, soil, and other objects located next to the plants. It is, thus, important to identify the most applicable remote-acquired indices for chlorophyll detection in polar regions, which play a primary role in global monitoring systems but consist of areas with high and low accessibility. This study focuses on an analysis of in situ-acquired hyperspectral properties, which was verified by simultaneously measuring the chlorophyll concentration in three representative arctic plant species, i.e., the prostrate deciduous shrub Salix polaris, the herb Bistorta vivipara, and the prostrate semievergreen shrub Dryas octopetala. This study was conducted at the high Arctic archipelago of Svalbard, Norway. Of the 23 analyzed candidate vegetation and chlorophyll indices, the following showed the best statistical correlations with the optical measurements of chlorophyll concentration: Vogelmann red edge index 1, 2, 3 (VOG 1, 2, 3), Zarco-Tejada and Miller index (ZMI), modified normalized difference vegetation index 705 (mNDVI 705), modified normalized difference index (mND), red edge normalized difference vegetation index (NDVI 705), and Gitelson and Merzlyak index 2 (GM 2). An assessment of the results from this analysis indicates that S. polaris and B. vivipara were in good health, while the health status of D. octopetala was reduced. This is consistent with other studies from the same area. There were also differences between study sites, probably as a result of local variation in environmental conditions. All these indices may be extracted from future satellite missions like EnMAP (Environmental Mapping and Analysis Program) and FLEX (Fluorescence Explorer), thus, enabling the efficient monitoring of vegetation condition in vast and inaccessible polar areasnb_NO
dc.language.isoengnb_NO
dc.rightsNavngivelse 4.0 Internasjonal*
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/deed.no*
dc.subjectArctic plantsnb_NO
dc.subjectASD FieldSpecnb_NO
dc.subjectremote sensing indicesnb_NO
dc.subjectremote sensingnb_NO
dc.titleFeasibility of hyperspectral vegetation indices for the detection of chlorophyll concentration in three high Arctic plants: Salix polaris, Bistorta vivipara, and Dryas octopetalanb_NO
dc.typePeer reviewednb_NO
dc.typeJournal article
dc.rights.holder© The Author(s) 2018.nb_NO
dc.subject.nsiVDP::Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480nb_NO
dc.source.volume87nb_NO
dc.source.journalActa Societatis Botanicorum Poloniaenb_NO
dc.source.issue4nb_NO
dc.identifier.doi10.5586/asbp.3604


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