Variations in Sr and Nd Isotopic Ratios of Mineral Particles in Cryoconite in Western Greenland

Nagatsuka, Naoko; Takeuchi, Nozomu; Uetake, Jun; Shimada, Ryoko; Onuma, Yukihiko; Tanaka, Sota; Nakano, Takanori

doi:10.3389/feart.2016.00093

Cited by 23 publications

(30 citation statements)

References 51 publications

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“…S7 in the supplements). Therefore, meltout is the main source of dust on the ice surface, which is also supported by a study of the isotopic composition (Nagatsuka and others, 2016).…”

Section: Meltout Of Impuritiesmentioning

confidence: 61%

Albedo reduction of ice caused by dust and black carbon accumulation: a model applied to the K-transect, West Greenland

Goelles

Bøggild

2017

J. Glaciol.

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ABSTRACT. Surface melt in the ablation zone is dominated by atmospheric temperature and surface albedo. We developed a surface mass-balance model with a dynamic component of glacier ice albedo which includes surface properties, clouds and the angle of the sun. The ice albedo reduction is mainly caused by impurity accumulation of non-biological origin such as dust and black carbon (BC), which is currently not included in other surface mass-balance models. Simulations show that dust from meltout is the main source of impurity mass at the melting glacier ice surface, and current rates of atmospheric deposition of dust play only a minor role. However, for BC the atmospheric deposition is the main source where ice melt rates are below 1 m, and atmospheric deposition is most likely from intercontinental transport due to the scarce population and lack of forests in Greenland.

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“…S7 in the supplements). Therefore, meltout is the main source of dust on the ice surface, which is also supported by a study of the isotopic composition (Nagatsuka and others, 2016).…”

Section: Meltout Of Impuritiesmentioning

confidence: 61%

Albedo reduction of ice caused by dust and black carbon accumulation: a model applied to the K-transect, West Greenland

Goelles

Bøggild

2017

J. Glaciol.

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“…Previous studies reported that mineral dust on glaciers in northwestern and south-western Greenland is mainly supplied from local ground surfaces (e.g. moraine near the glacier) rather than the distant areas (Nagatsuka et al, , 2016. Therefore, the algal spores, which were washed out from the glacier and stayed on the ground, may be supplied with dust around the glacier by wind.…”

Section: Origin Of Snow Algae and Their Growth Condition On The Qaanamentioning

confidence: 99%

Observations and modelling of algal growth on a snowpack in north-western Greenland

Onuma¹,

Takeuchi²,

Tanaka³

et al. 2018

The Cryosphere

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Abstract. Snow algal bloom is a common phenomenon on melting snowpacks in polar and alpine regions and can substantially increase snow melt rates due to the effect of albedo reduction on the snow surface. In order to reproduce algal growth on the snow surface using a numerical model, temporal changes in snow algal abundance were investigated on the Qaanaaq Glacier in north-western Greenland from June to August 2014. Snow algae first appeared at the study sites in late June, which was approximately 94 h after air temperatures exceeded the melting point. Algal abundance increased exponentially after this appearance, but the increasing rate became slow after late July, and finally reached 3.5 × 10 7 cells m −2 in early August. We applied a logistic model to the algal growth curve and found that the algae could be reproduced with an initial cell concentration of 6.9 × 10 2 cells m −2 , a growth rate of 0.42 d −1 , and a carrying capacity of 3.5 × 10 7 cells m −2 on this glacier. This model has the potential to simulate algal blooms from meteorological data sets and to evaluate their impact on the melting of seasonal snowpacks and glaciers.

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“…On all of the study glaciers, filamentous cyanobacteria genus Phormidesmis (mostly P. priestleyi) was abundant in all size fractions of granules. P. priestleyi has been isolated from Antarctic lake originally (Taton et al 2010), and has also been reported from many of Arctic glaciers (Chrismas et al 2016, Gokul et al 2016, Uetake et al 2016, Anesio et al 2017, Cameron et al 2017. Relative abundance and SIMPER similarity of this genus largely increased in larger than size 250, which Uetake et al (2016) pointed out as the distinct boundary of carbon ratio and species diversity in cryoconite granules (SI Table 3 Despite of the high abundance of this genus, 16S rRNA gene network analysis showed that abundance of P. priestleyi are poorly connected to other bacteria (Gokul et al 2016).…”

Section: : Cyanobacteria Characterizing Cryoconite Granulesmentioning

confidence: 99%

“…On the glacier surface, the size of cryoconite granules usually varied from μ m to mm in diameter, because filamentous cyanobacteria interweave their cells to make a granule and granule size is changed by degree of microbial growth. 16S rRNA gene amplicon sequencing of bacterial community in different granule size on a Greenland glacier revealed that the communities were distinctive among the size (diameter) of the granules and their diversity largely differed between granules of larger and smaller than 250 μm in diameter (Uetake et al 2016). However, this study was done on a single glacier and it is difficult to presume spatial variation of microbial communities with granule size changes, because microbial communities are quite different even in adjacent glaciers (Edward et al 2011, Lutz et al 2016.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, at first, in order to know spatial difference of bacterial changes with granule growth across glaciers, we focused on bacterial community based on 16S rRNA gene sequencing in 4 different sizes (30-249 μm, 250-750 μm, 750-1599 μm, more than 1600 μm) of cryoconite granules collected from cryoconite holes on 10 different neighborhood glaciers of previous study site in Uetake et al (2016). Secondary, differences of microbial communities with granule size would change susceptibility to environmental factors, because firm aggregated granule is more stable and nutrients are potentially supply from in situ nutrient cycle such as nitrogen fixation ) and nitrification and denitrification processes (Segawa et al 2014).…”

Section: Introductionmentioning

confidence: 99%

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Bacterial community changes with cryoconite granule size and their susceptibility to exogenous nutrients on 10 glaciers in northwestern Greenland

Uetake

Nagatsuka

Onuma

et al. 2019

Preprint

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Cryoconite granules, which are dark-colored biological aggregates on glaciers, effectively accelerate the melting of glacier ice. Bacterial community varies with granule size, however, community change in space and their susceptibility to environmental factors has not been described yet.Therefore, we focused on bacterial community from 4 different granule sizes (30-249 μm, 250-750 μm, 750-1599 μm, more than 1600 μm diameter) in 10 glaciers in northwestern Greenland and their susceptibility for exogenous nutrients in cryoconite hole. A filamentous cyanobacterium Phormidesmis priestleyi, which has been frequently reported from glaciers in Arctic was abundant (10-26%) across any size of granules on most of glaciers. Bacterial community across glaciers became similar with size increase, and whence smallest size fractions contain more unique genera in each glacier. Multivariate analysis suggests that phosphate, which is significantly higher in one glacier (Scarlet Heart Glacier), is primary associated with bacterial beta diversity. Correlation coefficients between abundance of major genera and nutrients largely changed with granule size, suggesting that nutrients susceptibility to genera changes with growth process of granule (e.g. P.priestleyi was affected by nitrate in early growth stage).

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Variations in Sr and Nd Isotopic Ratios of Mineral Particles in Cryoconite in Western Greenland

Cited by 23 publications

References 51 publications

Albedo reduction of ice caused by dust and black carbon accumulation: a model applied to the K-transect, West Greenland

Albedo reduction of ice caused by dust and black carbon accumulation: a model applied to the K-transect, West Greenland

Observations and modelling of algal growth on a snowpack in north-western Greenland

Bacterial community changes with cryoconite granule size and their susceptibility to exogenous nutrients on 10 glaciers in northwestern Greenland

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