%0 Generic %A D Zarsky, Jakub %A Stibal, Marek %A Hodson, Andy %A Sattler, Birgit %A Schostag, Morten %A H Hansen, Lars %A S Jacobsen, Carsten %A Psenner, Roland %D 2013 %T Nutrient concentrations in cryoconite sediment, supraglacial meltwater, and surface ice on Aldegondabreen %U https://iop.figshare.com/articles/dataset/___Nutrient_concentrations_in_cryoconite_sediment_supraglacial_meltwater_and_surface_ice_on_Aldegond/1011900 %R 10.6084/m9.figshare.1011900.v1 %2 https://iop.figshare.com/ndownloader/files/1479725 %K Arctic glacier %K nh %K valley glacier %K prokaryotic microbes %K tdn %K geochemical analysis %K tp %K tn %K tc %K supraglacial environments %K 16 S %K detection limit %K doc %K supraglacial meltwater flow %K surface debris particles %K polymerase chain reactions %K aldegondabreen %K bird colonies %K glacier surface %K supraglacial meltwater %K surface debris %K nitrogen cycling %K surface ice %K cryoconite sediment %K Environmental Science %X

Table 3.  Nutrient concentrations in cryoconite sediment, supraglacial meltwater, and surface ice on Aldegondabreen. TC (total carbon), TN (total nitrogen), TP (total phosphorus) in mg g−1 (mean ± sd, n = 3); DOC (dissolved organic carbon) in mg l−1, TDN (total dissolved nitrogen), NO3, NH4+ in μg l−1. b.d. below detection limit; n.d. not determined.

Abstract

The aggregation of surface debris particles on melting glaciers into larger units (cryoconite) provides microenvironments for various microorganisms and metabolic processes. Here we investigate the microbial community on the surface of Aldegondabreen, a valley glacier in Svalbard which is supplied with carbon and nutrients from different sources across its surface, including colonies of seabirds. We used a combination of geochemical analysis (of surface debris, ice and meltwater), quantitative polymerase chain reactions (targeting the 16S ribosomal ribonucleic acid and amoA genes), pyrosequencing and multivariate statistical analysis to suggest possible factors driving the ecology of prokaryotic microbes on the surface of Aldegondabreen and their potential role in nitrogen cycling. The combination of high nutrient input with subsidy from the bird colonies, supraglacial meltwater flow and the presence of fine, clay-like particles supports the formation of centimetre-scale cryoconite aggregates in some areas of the glacier surface. We show that a diverse microbial community is present, dominated by the cyanobacteria, Proteobacteria, Bacteroidetes, and Actinobacteria, that are well-known in supraglacial environments. Importantly, ammonia-oxidizing archaea were detected in the aggregates for the first time on an Arctic glacier.

%I IOP Publishing