Your search keyword '"Joseph M. Cook"' showing total 42 results

1. Mapping red algal blooms and their albedo-reducing effect on seasonal snowfields at Hardangervidda, Southern Norway

Author

Lou-Anne Chevrollier, Adrien Wehrlé, Joseph M. Cook, Grégoire Guillet, Liane G. Benning, Alexandre M. Anesio, and Martyn Tranter

Subjects

snow, albedo, uncrewed aerial vehicle, algae, blooms, Science

Abstract

Red snow algae bloom at the surface of snowfields worldwide, and their detection is relevant for ecological, biogeochemical and mass balance studies. In this study, we co-located RGB imagery acquired with a light-weight Uncrewed Aerial Vehicle (UAV) to 129 hyperspectral reflectance spectra from which the snow surface properties were retrieved, thereby enabling high-resolution aerial mapping of algal properties. We present maps of red snow algae abundance and albedo reducing effect over ∼ 9700 m2 of seasonal snowfields across Hardangervidda, Southern Norway, in July and August 2023. The average albedo reducing effect of the algae over the entire area was 0.012 ± 0.005, and attained 0.028 ± 0.004 on a snowfield of ∼ 710 m2. Across snow surfaces with visible blooms only, the algal albedo reducing effect was 0.045 ± 0.003, equivalent to an additional ∼ 3 mm of daily melting under local illumination conditions, and aggregating to 5,500 ± 2,300 kg of daily snowmelt. The intensity and spatial coverage of surface algal blooms were very variable between and within the individual snowfields. Analysis of the UAV imagery suggests that multiple small and distributed samples are at least twice more likely to yield representative estimates of the average snow algal concentration of a snowfield compared to fewer, larger samples. Our study demonstrates the potential of low-cost and easy to deploy UAVs for red snow algal monitoring at the cm to sub-cm scale, which can be used to better understand their spatial ecology and role in albedo reduction.

Published

2025

2. Light absorption and albedo reduction by pigmented microalgae on snow and ice

Author

Lou-Anne Chevrollier, Joseph M. Cook, Laura Halbach, Hans Jakobsen, Liane G. Benning, Alexandre M. Anesio, and Martyn Tranter

Subjects

Glacier modelling, glaciological model experiments, ice biology, melt-surface, snow/ice surface processes, Environmental sciences, GE1-350, Meteorology. Climatology, QC851-999

Abstract

Pigmented microalgae inhabiting snow and ice environments lower the albedo of glacier and ice-sheet surfaces, significantly enhancing surface melt. Our ability to accurately predict their role in glacier and ice-sheet surface mass balance is limited by the current lack of empirical data to constrain their representation in predictive models. Here we present new empirical optical properties for snow and ice algae and incorporate them in a radiative transfer model to investigate their impact on snow and ice surface albedo. We found ice algal cells to be more efficient absorbers than snow algal cells, but their blooms had comparable impact on surface albedo due to the different photic conditions of their habitats. We then used the model to reconstruct the effect of ice algae on bare ice albedo spectra collected at our field site in southern Greenland, where blooms dropped the albedo locally by between 3 and 43%, equivalent to 1–10 L m$^{-2}$ d$^{-1}$ of melted ice. Using the newly parametrized model, future studies could investigate biological albedo reduction and algal quantification from remote hyperspectral and multispectral imagery.

Published

2023

3. Spatially consistent microbial biomass and future cellular carbon release from melting Northern Hemisphere glacier surfaces

Author

Ian T. Stevens, Tristram D. L. Irvine-Fynn, Arwyn Edwards, Andrew C. Mitchell, Joseph M. Cook, Philip R. Porter, Tom O. Holt, Matthias Huss, Xavier Fettweis, Brian J. Moorman, Birgit Sattler, and Andy J. Hodson

Subjects

Geology, QE1-996.5, Environmental sciences, GE1-350

Abstract

Average microbial biomass loads in glacial melt water are similar despite different environmental settings allowing for estimation of regional carbon export from melting glacier surfaces, according to direct observations at eight northern hemisphere glaciers and two Greenland Ice Sheet sites.

Published

2022

4. Pigment signatures of algal communities and their implications for glacier surface darkening

Author

Laura Halbach, Lou-Anne Chevrollier, Eva L. Doting, Joseph M. Cook, Marie B. Jensen, Liane G. Benning, James A. Bradley, Martin Hansen, Lars C. Lund-Hansen, Stiig Markager, Brian K. Sorrell, Martyn Tranter, Christopher B. Trivedi, Matthias Winkel, and Alexandre M. Anesio

Subjects

Medicine, Science

Abstract

Abstract Blooms of pigmented algae darken the surface of glaciers and ice sheets, thereby enhancing solar energy absorption and amplifying ice and snow melt. The impacts of algal pigment and community composition on surface darkening are still poorly understood. Here, we characterise glacier ice and snow algal pigment signatures on snow and bare ice surfaces and study their role in photophysiology and energy absorption on three glaciers in Southeast Greenland. Purpurogallin and astaxanthin esters dominated the glacier ice and snow algal pigment pools (mass ratios to chlorophyll a of 32 and 56, respectively). Algal biomass and pigments impacted chromophoric dissolved organic matter concentrations. Despite the effective absorption of astaxanthin esters at wavelengths where incoming irradiance peaks, the cellular energy absorption of snow algae was 95% lower than anticipated from their pigmentation, due to pigment packaging. The energy absorption of glacier ice algae was consequently ~ 5 × higher. On bare ice, snow algae may have locally contributed up to 13% to total biological radiative forcing, despite contributing 44% to total biomass. Our results give new insights into the impact of algal community composition on bare ice energy absorption and biomass accumulation during snow melt.

Published

2022

5. Dark ice in a warming world: advances and challenges in the study of Greenland Ice Sheet's biological darkening

Author

Laura Halbach, Lou-Anne Chevrollier, Joseph M. Cook, Ian T. Stevens, Martin Hansen, Alexandre M. Anesio, Liane G. Benning, and Martyn Tranter

Subjects

Albedo, BioSNICAR, glacier ice algae, growth, hydrology, model, mortality, weathering crust, Meteorology. Climatology, QC851-999

Abstract

The surface of the Greenland Ice Sheet is darkening, which accelerates its surface melt. The role of glacier ice algae in reducing surface albedo is widely recognised but not well quantified and the feedbacks between the algae and the weathering crust remain poorly understood. In this letter, we summarise recent advances in the study of the biological darkening of the Greenland Ice Sheet and highlight three key research priorities that are required to better understand and forecast algal-driven melt: (i) identifying the controls on glacier ice algal growth and mortality, (ii) quantifying the spatio-temporal variability in glacier ice algal biomass and processes involved in cell redistribution and (iii) determining the albedo feedbacks between algal biomass and weathering crust characteristics. Addressing these key research priorities will allow us to better understand the supraglacial ice-algal system and to develop an integrated model incorporating the algal and physical controls on ice surface albedo.

Published

2022

6. Mineral phosphorus drives glacier algal blooms on the Greenland Ice Sheet

Author

Jenine McCutcheon, Stefanie Lutz, Christopher Williamson, Joseph M. Cook, Andrew J. Tedstone, Aubry Vanderstraeten, Sasha Wilson, Anthony Stockdale, Steeve Bonneville, Alexandre M. Anesio, Marian L. Yallop, James B. McQuaid, Martyn Tranter, and Liane G. Benning

Subjects

Science

Abstract

Abstract Melting of the Greenland Ice Sheet is a leading cause of land-ice mass loss and cryosphere-attributed sea level rise. Blooms of pigmented glacier ice algae lower ice albedo and accelerate surface melting in the ice sheet’s southwest sector. Although glacier ice algae cause up to 13% of the surface melting in this region, the controls on bloom development remain poorly understood. Here we show a direct link between mineral phosphorus in surface ice and glacier ice algae biomass through the quantification of solid and fluid phase phosphorus reservoirs in surface habitats across the southwest ablation zone of the ice sheet. We demonstrate that nutrients from mineral dust likely drive glacier ice algal growth, and thereby identify mineral dust as a secondary control on ice sheet melting.

Published

2021

7. Temporal Variability of Surface Reflectance Supersedes Spatial Resolution in Defining Greenland’s Bare-Ice Albedo

Author

Tristram D. L. Irvine-Fynn, Pete Bunting, Joseph M. Cook, Alun Hubbard, Nicholas E. Barrand, Edward Hanna, Andy J. Hardy, Andrew J. Hodson, Tom O. Holt, Matthias Huss, James B. McQuaid, Johan Nilsson, Kathrin Naegeli, Osian Roberts, Jonathan C. Ryan, Andrew J. Tedstone, Martyn Tranter, and Christopher J. Williamson

Subjects

Greenland ice sheet, reflectance, albedo, MODIS, Sentinel-2, uncrewed aerial vehicle, Science

Abstract

Ice surface albedo is a primary modulator of melt and runoff, yet our understanding of how reflectance varies over time across the Greenland Ice Sheet remains poor. This is due to a disconnect between point or transect scale albedo sampling and the coarser spatial, spectral and/or temporal resolutions of available satellite products. Here, we present time-series of bare-ice surface reflectance data that span a range of length scales, from the 500 m for Moderate Resolution Imaging Spectrometer’s MOD10A1 product, to 10 m for Sentinel-2 imagery, 0.1 m spot measurements from ground-based field spectrometry, and 2.5 cm from uncrewed aerial drone imagery. Our results reveal broad similarities in seasonal patterns in bare-ice reflectance, but further analysis identifies short-term dynamics in reflectance distribution that are unique to each dataset. Using these distributions, we demonstrate that areal mean reflectance is the primary control on local ablation rates, and that the spatial distribution of specific ice types and impurities is secondary. Given the rapid changes in mean reflectance observed in the datasets presented, we propose that albedo parameterizations can be improved by (i) quantitative assessment of the representativeness of time-averaged reflectance data products, and, (ii) using temporally-resolved functions to describe the variability in impurity distribution at daily time-scales. We conclude that the regional melt model performance may not be optimally improved by increased spatial resolution and the incorporation of sub-pixel heterogeneity, but instead, should focus on the temporal dynamics of bare-ice albedo.

Published

2021

8. Glacier Algae: A Dark Past and a Darker Future

Author

Christopher J. Williamson, Karen A. Cameron, Joseph M. Cook, Jakub D. Zarsky, Marek Stibal, and Arwyn Edwards

Subjects

glacier algae, Streptophytes, albedo, terrestrialization, ice, Microbiology, QR1-502

Abstract

“Glacier algae” grow on melting glacier and ice sheet surfaces across the cryosphere, causing the ice to absorb more solar energy and consequently melt faster, while also turning over carbon and nutrients. This makes glacier algal assemblages, which are typically dominated by just three main species, a potentially important yet under-researched component of the global biosphere, carbon, and water cycles. This review synthesizes current knowledge on glacier algae phylogenetics, physiology, and ecology. We discuss their significance for the evolution of early land plants and highlight their impacts on the physical and chemical supraglacial environment including their role as drivers of positive feedbacks to climate warming, thereby demonstrating their influence on Earth’s past and future. Four complementary research priorities are identified, which will facilitate broad advances in glacier algae research, including establishment of reliable culture collections, sequencing of glacier algae genomes, development of diagnostic biosignatures for remote sensing, and improved predictive modeling of glacier algae biological-albedo effects.

Published

2019

9. Derivation of High Spatial Resolution Albedo from UAV Digital Imagery: Application over the Greenland Ice Sheet

Author

Jonathan C. Ryan, Alun Hubbard, Jason E. Box, Stephen Brough, Karen Cameron, Joseph M. Cook, Matthew Cooper, Samuel H. Doyle, Arwyn Edwards, Tom Holt, Tristram Irvine-Fynn, Christine Jones, Lincoln H. Pitcher, Asa K. Rennermalm, Laurence C. Smith, Marek Stibal, and Neal Snooke

Subjects

albedo, digital camera, unmanned aerial vehicle, remote sensing, Greenland Ice Sheet, energy balance modeling, Science

Abstract

Measurements of albedo are a prerequisite for modeling surface melt across the Earth's cryosphere, yet available satellite products are limited in spatial and/or temporal resolution. Here, we present a practical methodology to obtain centimeter resolution albedo products with accuracies of ±5% using consumer-grade digital camera and unmanned aerial vehicle (UAV) technologies. Our method comprises a workflow for processing, correcting and calibrating raw digital images using a white reference target, and upward and downward shortwave radiation measurements from broadband silicon pyranometers. We demonstrate the method with a set of UAV sorties over the western, K-sector of the Greenland Ice Sheet. The resulting albedo product, UAV10A1, covers 280 km2, at a resolution of 20 cm per pixel and has a root-mean-square difference of 3.7% compared to MOD10A1 and 4.9% compared to ground-based broadband pyranometer measurements. By continuously measuring downward solar irradiance, the technique overcomes previous limitations due to variable illumination conditions during and between surveys over glaciated terrain. The current miniaturization of multispectral sensors and incorporation of upward facing radiation sensors on UAV packages means that this technique could become increasingly common in field studies and used for a wide range of applications. These include the mapping of debris, dust, cryoconite and bioalbedo, and directly constraining surface energy balance models.

Published

2017

10. Smartphone Spectrometers

Author

Andrew J.S. McGonigle, Thomas C. Wilkes, Tom D. Pering, Jon R. Willmott, Joseph M. Cook, Forrest M. Mims, and Alfio V. Parisi

Subjects

smartphone spectrometers, smartphone spectroscopy, low cost scientific instrumentation, medical diagnostics, food quality inspection, environmental monitoring, Chemical technology, TP1-1185

Abstract

Smartphones are playing an increasing role in the sciences, owing to the ubiquitous proliferation of these devices, their relatively low cost, increasing processing power and their suitability for integrated data acquisition and processing in a ‘lab in a phone’ capacity. There is furthermore the potential to deploy these units as nodes within Internet of Things architectures, enabling massive networked data capture. Hitherto, considerable attention has been focused on imaging applications of these devices. However, within just the last few years, another possibility has emerged: to use smartphones as a means of capturing spectra, mostly by coupling various classes of fore-optics to these units with data capture achieved using the smartphone camera. These highly novel approaches have the potential to become widely adopted across a broad range of scientific e.g., biomedical, chemical and agricultural application areas. In this review, we detail the exciting recent development of smartphone spectrometer hardware, in addition to covering applications to which these units have been deployed, hitherto. The paper also points forward to the potentially highly influential impacts that such units could have on the sciences in the coming decades.

Published

2018

11. Dark ice in a warming world: advances and challenges in the study of Greenland Ice Sheet's biological darkening

Author

Laura Halbach, Lou-Anne Chevrollier, Joseph M. Cook, Ian T. Stevens, Martin Hansen, Alexandre M. Anesio, Liane G. Benning, and Martyn Tranter

Subjects

Earth-Surface Processes

Abstract

The surface of the Greenland Ice Sheet is darkening, which accelerates its surface melt. The role of glacier ice algae in reducing surface albedo is widely recognised but not well quantified and the feedbacks between the algae and the weathering crust remain poorly understood. In this letter, we summarise recent advances in the study of the biological darkening of the Greenland Ice Sheet and highlight three key research priorities that are required to better understand and forecast algal-driven melt: (i) identifying the controls on glacier ice algal growth and mortality, (ii) quantifying the spatio-temporal variability in glacier ice algal biomass and processes involved in cell redistribution and (iii) determining the albedo feedbacks between algal biomass and weathering crust characteristics. Addressing these key research priorities will allow us to better understand the supraglacial ice-algal system and to develop an integrated model incorporating the algal and physical controls on ice surface albedo.

Published

2023

12. Storage and export of microbial biomass across the western Greenland Ice Sheet

Author

Joseph M. Cook, Karen A. Cameron, Jonathan C. Ryan, Andrew C. Mitchell, Marek Stibal, Sara M. E. Rassner, Arwyn Edwards, Tristram Irvine-Fynn, Kathrin Naegeli, Ian Thomas Stevens, Jason E. Box, Peter Bunting, Alun Hubbard, and Christopher Williamson

Subjects

0301 basic medicine, 010504 meteorology & atmospheric sciences, Earth science, Science, Greenland, Colony Count, Microbial, General Physics and Astronomy, Greenland ice sheet, Biomass, Flux, Fluvial, chemistry.chemical_element, 910 Geography & travel, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Carbon cycle, Carbon Cycle, 03 medical and health sciences, 550 Earth sciences & geology, VDP::Matematikk og Naturvitenskap: 400::Geofag: 450, Photic zone, Ice Cover, Weather, 0105 earth and related environmental sciences, geography, Multidisciplinary, geography.geographical_feature_category, VDP::Mathematics and natural science: 400::Geosciences: 450, General Chemistry, Biogeochemistry, Carbon, Environmental sciences, 030104 developmental biology, chemistry, Environmental science, Ice sheet, Hydrology

Abstract

The Greenland Ice Sheet harbours a wealth of microbial life, yet the total biomass stored or exported from its surface to downstream environments is unconstrained. Here, we quantify microbial abundance and cellular biomass flux within the near-surface weathering crust photic zone of the western sector of the ice sheet. Using groundwater techniques, we demonstrate that interstitial water flow is slow (~10−2 m d−1), while flow cytometry enumeration reveals this pathway delivers 5 × 108 cells m−2 d−1 to supraglacial streams, equivalent to a carbon flux up to 250 g km−2 d−1. We infer that cellular carbon accumulation in the weathering crust exceeds fluvial export, promoting biomass sequestration, enhanced carbon cycling, and biological albedo reduction. We estimate that up to 37 kg km−2 of cellular carbon is flushed from the weathering crust environment of the western Greenland Ice Sheet each summer, providing an appreciable flux to support heterotrophs and methanogenesis at the bed., Microbes that colonise ice sheet surfaces are important to the carbon cycle, but their biomass and transport remains unquantified. Here, the authors reveal substantial microbial carbon fluxes across Greenland’s ice surface, in quantities that may sustain subglacial heterotrophs and fuel methanogenesis.

Published

2021

13. SNICAR-ADv3:A community tool for modeling spectral snow albedo

Author

Mark G. Flanner, Julian B. Arnheim, Joseph M. Cook, Cheng Dang, Cenlin He, Xianglei Huang, Deepak Singh, S. McKenzie Skiles, Chloe A. Whicker, and Charles S. Zender

Subjects

QE1-996.5, Geology

Abstract

The Snow, Ice, and Aerosol Radiative (SNICAR) model has been used in various capacities over the last 15 years to model the spectral albedo of snow with light-absorbing constituents (LACs). Recent studies have extended the model to include an adding-doubling two-stream solver and representations of non-spherical ice particles; carbon dioxide snow; snow algae; and new types of mineral dust, volcanic ash, and brown carbon. New options also exist for ice refractive indices and solar-zenith-angle-dependent surface spectral irradiances used to derive broadband albedo. The model spectral range was also extended deeper into the ultraviolet for studies of extraterrestrial and high-altitude cryospheric surfaces. Until now, however, these improvements and capabilities have not been merged into a unified code base. Here, we document the formulation and evaluation of the publicly available SNICAR-ADv3 source code, web-based model, and accompanying library of constituent optical properties. The use of non-spherical ice grains, which scatter less strongly into the forward direction, reduces the simulated albedo perturbations from LACs by ∼9 %–31 %, depending on which of the three available non-spherical shapes are applied. The model compares very well against measurements of snow albedo from seven studies, though key properties affecting snow albedo are not fully constrained with measurements, including ice effective grain size of the top sub-millimeter of the snowpack, mixing state of LACs with respect to ice grains, and site-specific LAC optical properties. The new default ice refractive indices produce extremely high pure snow albedo (>0.99) in the blue and ultraviolet part of the spectrum, with such values only measured in Antarctica so far. More work is needed particularly in the representation of snow algae, including experimental verification of how different pigment expressions and algal cell concentrations affect snow albedo. Representations and measurements of the influence of liquid water on spectral snow albedo are also needed.

Published

2021

14. Marked Seasonal Changes in the Microbial Production, Community Composition, and Biogeochemistry of Glacial Snowpack Ecosystems in the Maritime Antarctic

Author

Peter Convey, K. R. Redeker, Joseph M. Cook, David A. Pearce, Arwyn Edwards, Andy Hodson, Archana Dayal, and Maria Sabacka

Subjects

Atmospheric Science, Ecology, Paleontology, Soil Science, Biogeochemistry, F800, Forestry, Global change, 15. Life on land, Aquatic Science, Snowpack, Permafrost, Oceanography, 13. Climate action, Paleoceanography, Environmental science, Cryosphere, Ecosystem, 14. Life underwater, Glacial period, Water Science and Technology

Abstract

We describe seasonal changes in the biogeochemistry, microbial community and ecosystem production of two glacial snowpacks in the maritime Antarctic during a cold summer. Frequent snowfall and low, intermittent melt on the glaciers suppressed surface photosynthesis and promoted net heterotrophy. Concentrations of autotrophic cells (algae and cyanobacteria) were therefore low (average: 150 - 500 cells mL-1), and short-term estimates of primary production were almost negligible in early summer (< 0.1 µg C L-1 d-1). However, order of magnitude increases in Chlorophyll a concentrations occurred later, especially within the mid-snowpack and ice layers below. Short-term primary production increased to ca. 1 µg C L-1 d-1 in mid-summer, and reached 53.1 µg C L-1 d-1 in a mid-snow layer close to an active penguin colony. However, there were significantly more bacteria than autotrophs in the snow (typically 103 cells mL-1, but > 104 cells mL-1 in basal ice near the penguin colony). The ratio of bacteria to autotrophs also increased throughout the summer, and short-term bacterial production rates (0.2 – 2000 µg C L-1 d-1) usually exceeded primary production, especially in basal ice (10 – 1400 µg C L-1 d-1). The basal ice represented the least diverse but most productive habitat, and a striking feature was its low pH (down to 3.3). Furthermore, all of the overlying snow cover became increasingly acidic as the summer season progressed, which is attributed to enhanced emissions from wet guano in the penguin colony. The study demonstrates that active microbial communities can be expected, even when snowmelt is intermittent in the Antarctic summer.

Published

2021

15. Microbial abundance and transport in glacial near-surface meltwater

Author

Tristram Irvine-Fynn, Joseph M. Cook, Brian J. Moorman, Tom Holt, Philip R. Porter, Andrew C. Mitchell, Ian Thomas Stevens, Andy Hodson, and Arwyn Edwards

Subjects

Oceanography, Abundance (ecology), Glacial period, Meltwater, Geology

Abstract

Glacier surfaces are active microbial ecosystems which contribute to melt feedback cycles and biogeochemical processes. Despite this recognition, there is a lack of knowledge regarding the transport dynamics and residence time of microbes in this supraglacial habitat. Throughout the ablation season, meltwater is generated across a glacier’s surface and flows through the porous near-surface weathering crust before entering the channelised supraglacial network. Within the weathering crust, solar radiation provides a “photic zone” which, combined with nutrient availability, is conducive for microbial activity. The water flow through this porous near-surface layer provides a transport mechanism for these microbes. However, the nature of controls upon this phenomenon remain unexplored, despite the relevance for cellular export to downstream ecosystems, glacier surface albedo and biogeochemical cycling.To determine potential controls on microbial transport in the weathering crust, we present 913 measurements of microbial cell abundance in supraglacial meltwaters from 11 glaciers across the northern hemisphere. Each measurement is coupled with weathering crust hydraulic conductivity or stream discharge. These data reveal a mean microbial abundance of 2.2 × 104 cells mL-1 (with a range of 103 – 106) in supraglacial meltwaters within the weathering crust and stream channels. Modal microbe size was 1 – 2 μm (56 % of microbes), with 89 % of microbes smaller than 4 μm. No substantiated difference in size distributions between weathering crust and stream meltwaters were observed. No correlation between microbial abundance and near-surface hydraulic conductivity or stream discharge were observed, either across the entire dataset or when considered on a glacier-by-glacier basis. At three glaciers, water temperature and electrical conductivity (a proxy measure for ionic load) were also recorded; but we observe no correlation between these two variables and microbial abundance. Our data suggests weathering crust microbe abundance is consistent across differing glacial environments, and the concentrations entrained in the near-surface equal those seen in supraglacial streams. As such, despite the low transfer rate of meltwater, there appears to be limited evidence for substantial storage or accumulation of biomass in the near-surface weathering crust. Moreover, microbe entrainment does not appear to be driven by primary hydrological controls. Assuming that once liberated within the weathering crust entrained microbes reach channelised supraglacial networks, we estimate a delivery of 1.1 × 109 kg C a-1 to downstream environments globally (excluding Antarctica) to 2100, using existing discharge forecasts. This study represents a crucial first step in examining microbial abundance within, and transport across glacier surfaces and their potential role in biogeochemical process-feedbacks and the inoculation of downstream environments.

Published

2020

16. Radiative forcing by light-absorbing particles in snow

Author

Marie Dumont, Joseph M. Cook, S. McKenzie Skiles, Mark Flanner, and Thomas H. Painter

Subjects

010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Geographic variation, 02 engineering and technology, Environmental Science (miscellaneous), Radiative forcing, Albedo, Atmospheric sciences, Snow, 01 natural sciences, 020801 environmental engineering, Earth system science, Deposition (aerosol physics), Snowmelt, Environmental science, Cryosphere, Social Sciences (miscellaneous), 0105 earth and related environmental sciences

Abstract

As one of the brightest natural surfaces on Earth, the darkening of snow by light-absorbing particles (LAPs) — dust, black carbon or microbial growth — can trigger albedo feedbacks and accelerate snowmelt. Indeed, an increase in black carbon deposition following the industrial revolution has led to the recognition that LAP radiative forcing has contributed to a reduction in the global cryosphere, with corresponding climatic impacts. This Review synthesizes our current understanding of the distribution of radiative forcing by LAPs in snow, and discusses the challenges that need to be overcome to constrain global impacts, including the limited scope of local-scale observations, limitations of remote sensing technology and the representation of LAP-related processes in Earth system models. Snow albedo is impacted by the presence of light-absorbing particles, including black carbon and dust. This Review collates knowledge on the associated radiative forcing, discussing geographic variability, future impacts and challenges for reducing uncertainty.

Published

2018

17. Organic carbon fluxes of a glacier surface: A case study of Foxfonna, a small Arctic glacier

Author

Helen L. Moggridge, Krystyna Kozioł, Andy Hodson, and Joseph M. Cook

Subjects

Total organic carbon, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geography, Planning and Development, Fluvial, Glacier, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Snowmelt, Cryoconite, Dissolved organic carbon, Earth and Planetary Sciences (miscellaneous), Environmental science, Cryosphere, Glacial period, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Arctic glaciers are rapidly responding to global warming by releasing organic carbon (OC) to downstream ecosystems. The glacier surface is arguably the most biologically active and biodiverse glacial habitat and therefore the site of important OC transformation and storage, although rates and magnitudes are poorly constrained. In this paper, we present measurements of OC fluxes associated with atmospheric deposition, ice melt, biological growth, fluvial transport and storage (in superimposed ice and cryoconite debris) for a supraglacial catchment on Foxfonna glacier, Svalbard (Norway), across two consecutive years.We found that in general atmospheric OC input (averaging 0.63 ± 0.25Mg a-1 total organic carbon, i.e. TOC, and 0.40 ± 0.22Mg a-1 dissolved organic carbon, i.e. DOC) exceeded fluvial OC export (0.46 ± 0.04Mg a-1 TOC and 0.36 ± 0.03Mg a-1 DOC). Early in the summer, OC was mobilised in snowmelt but its release was delayed by temporary storage in superimposed ice on the glacier surface. This delayed the export of 28.5% of the TOC in runoff. Biological production in cryoconite deposits was a negligible potential source of OC to runoff, while englacial ice melt was far more important on account of the glacier’s negative ice mass balance (–0.89 and –0.42m a-1 in 2011 and 2012, respectively). However, construction of a detailed OC budget using these fluxes shows an excess of inputs over outputs, resulting in a net retention of OC on the glacier surface at a rate that would require c. 3 years to account for the OC stored as cryoconite debris. © 2018 John Wiley & Sons, Ltd.

Published

2018

18. Near-surface hydraulic conductivity of northern hemisphere glaciers

Author

Joseph M. Cook, Ian Thomas Stevens, Andrew C. Mitchell, Arwyn Edwards, Martin J. Smart, Philip R. Porter, Andy Hodson, Tristram Irvine-Fynn, and Brian J. Moorman

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Water table, Firn, Aquifer, Glacier, 15. Life on land, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, 6. Clean water, Hydraulic conductivity, 13. Climate action, Snow line, Glacial period, Meltwater, Geology, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

The hydrology of near‐surface glacier ice remains a neglected aspect of glacier hydrology despite its role in modulating meltwater delivery to downstream environments. To elucidate the hydrological characteristics of this near‐surface glacial weathering crust, we describe the design and operation of a capacitance‐based piezometer that enables rapid, economical deployment across multiple sites and provides an accurate, high‐resolution record of near‐surface water‐level fluctuations. Piezometers were employed at 10 northern hemisphere glaciers, and through the application of standard bail–recharge techniques, we derive hydraulic conductivity (K) values from 0.003 to 3.519 m day−1, with a mean of 0.185 ± 0.019 m day−1. These results are comparable to those obtained in other discrete studies of glacier near‐surface ice, and for firn, and indicate that the weathering crust represents a hydrologically inefficient aquifer. Hydraulic conductivity correlated positively with water table height but negatively with altitude and cumulative short‐wave radiation since the last synoptic period of either negative air temperatures or turbulent energy flux dominance. The large range of K observed suggests complex interactions between meteorological influences and differences arising from variability in ice structure and crystallography. Our data demonstrate a greater complexity of near‐surface ice hydrology than hitherto appreciated and support the notion that the weathering crust can regulate the supraglacial discharge response to melt production. The conductivities reported here, coupled with typical supraglacial channel spacing, suggest that meltwater can be retained within the weathering crust for at least several days. Not only does this have implications for the accuracy of predictive meltwater run‐off models, but we also argue for biogeochemical processes and transfers that are strongly conditioned by water residence time and the efficacy of the cascade of sediments, impurities, microbes, and nutrients to downstream ecosystems. Because continued atmospheric warming will incur rising snowline elevations and glacier thinning, the supraglacial hydrological system may assume greater importance in many mountainous regions, and consequently, detailing weathering crust hydraulics represents a research priority because the flow path it represents remains poorly constrained.

Published

2018

19. Dark ice dynamics of the south-west Greenland Ice Sheet

Author

Martyn Tranter, Andrew J. Tedstone, Christopher Williamson, Jonathan L. Bamber, Andy Hodson, Xavier Fettweis, and Joseph M. Cook

Subjects

0301 basic medicine, lcsh:GE1-350, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, lcsh:QE1-996.5, Greenland ice sheet, Ice-albedo feedback, Antarctic sea ice, Atmospheric sciences, 01 natural sciences, Arctic ice pack, lcsh:Geology, 03 medical and health sciences, 030104 developmental biology, Climatology, Sea ice thickness, Sea ice, Cryosphere, Environmental science, Sea ice concentration, lcsh:Environmental sciences, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

Runoff from the Greenland Ice Sheet (GrIS) has increased in recent years due largely to changes in atmospheric circulation and atmospheric warming. Albedo reductions resulting from these changes have amplified surface melting. Some of the largest declines in GrIS albedo have occurred in the ablation zone of the south-west sector and are associated with the development of dark ice surfaces. Field observations at local scales reveal that a variety of light-absorbing impurities (LAIs) can be present on the surface, ranging from inorganic particulates to cryoconite materials and ice algae. Meanwhile, satellite observations show that the areal extent of dark ice has varied significantly between recent successive melt seasons. However, the processes that drive such large interannual variability in dark ice extent remain essentially unconstrained. At present we are therefore unable to project how the albedo of bare ice sectors of the GrIS will evolve in the future, causing uncertainty in the projected sea level contribution from the GrIS over the coming decades. Here we use MODIS satellite imagery to examine dark ice dynamics on the south-west GrIS each year from 2000 to 2016. We quantify dark ice in terms of its annual extent, duration, intensity and timing of first appearance. Not only does dark ice extent vary significantly between years but so too does its duration (from 0 to > 80 % of June–July–August, JJA), intensity and the timing of its first appearance. Comparison of dark ice dynamics with potential meteorological drivers from the regional climate model MAR reveals that the JJA sensible heat flux, the number of positive minimum-air-temperature days and the timing of bare ice appearance are significant interannual synoptic controls. We use these findings to identify the surface processes which are most likely to explain recent dark ice dynamics. We suggest that whilst the spatial distribution of dark ice is best explained by outcropping of particulates from ablating ice, these particulates alone do not drive dark ice dynamics. Instead, they may enable the growth of pigmented ice algal assemblages which cause visible surface darkening, but only when the climatological prerequisites of liquid meltwater presence and sufficient photosynthetically active radiation fluxes are met. Further field studies are required to fully constrain the processes by which ice algae growth proceeds and the apparent dependency of algae growth on melt-out particulates.

Published

2017

20. How robust are in situ observations for validating satellite‐derived albedo over the dark zone of the Greenland Ice Sheet?

Author

Samuel H. Doyle, Joseph M. Cook, Jonathan C. Ryan, Marek Stibal, Alun Hubbard, Jason E. Box, and Tristram Irvine-Fynn

Subjects

geography, geography.geographical_feature_category, Pyranometer, 010504 meteorology & atmospheric sciences, Pixel, Greenland Ice Sheet, UAV, Greenland ice sheet, Albedo, 010502 geochemistry & geophysics, Snow, 01 natural sciences, Footprint, remote sensing, Geophysics, MODIS, automated weather stations, General Earth and Planetary Sciences, Satellite, Ice sheet, Geology, albedo, 0105 earth and related environmental sciences, Remote sensing

Abstract

Published version. Source at http://doi.org/10.1002/2017GL073661. ©2017. American Geophysical Union. All Rights Reserved Calibration and validation of satellite‐derived ice sheet albedo data require high‐quality, in situ measurements commonly acquired by up and down facing pyranometers mounted on automated weather stations (AWS). However, direct comparison between ground and satellite‐derived albedo can only be justified when the measured surface is homogeneous at the length‐scale of both satellite pixel and in situ footprint. Here we use digital imagery acquired by an unmanned aerial vehicle to evaluate point‐to‐pixel albedo comparisons across the western, ablating margin of the Greenland Ice Sheet. Our results reveal that in situ measurements overestimate albedo by up to 0.10 at the end of the melt season because the ground footprints of AWS‐mounted pyranometers are insufficient to capture the spatial heterogeneity of the ice surface as it progressively ablates and darkens. Statistical analysis of 21 AWS across the entire Greenland Ice Sheet reveals that almost half suffer from this bias, including some AWS located within the wet snow zone.

Published

2017

21. Algal photophysiology drives darkening and melt of the Greenland Ice Sheet

Author

Christopher Williamson, Andrew J. Tedstone, Marian L. Yallop, Jenine McCutcheon, Joseph M. Cook, Rupert Gordon Perkins, Ewa Poniecka, Tristram Irvine-Fynn, Alexandre M. Anesio, Martyn Tranter, Douglas A. Campbell, and James B. McQuaid

Subjects

Chlorophyll a, 010504 meteorology & atmospheric sciences, Greenland Ice Sheet, Greenland, Greenland ice sheet, Sea Level Rise, Atmospheric sciences, 01 natural sciences, Photophysiology, 03 medical and health sciences, chemistry.chemical_compound, Algae, Microalgae, Cryosphere, Ice Cover, 14. Life underwater, Photosynthesis, Meltwater, 030304 developmental biology, 0105 earth and related environmental sciences, Feedback, Physiological, 0303 health sciences, geography, Multidisciplinary, geography.geographical_feature_category, biology, Ecology, Glacier, 15. Life on land, Albedo, Biological Sciences, biology.organism_classification, melt, cryosphere, Glacier algae, glacier algae, photophysiology, chemistry, 13. Climate action, Physical Sciences, Environmental science, Ice sheet, Environmental Sciences, Melt

Abstract

Significance Processes that darken the surface of the Greenland Ice Sheet (GrIS) enhance energy absorption and accelerate melt, with consequences for global sea-level rise. Here, we demonstrate how summer blooms of “glacier algae” darken the ice surface, significantly impacting the physical integrity of the environment. We identify and quantify the energy regulation mechanisms employed by glacier algae to balance their requirements for photosynthesis and growth with the extreme light and temperature regime of the GrIS, demonstrating how these mechanisms are optimized to darken and melt the ice surface. Our findings are critical for the incorporation of biological feedbacks into predictive models of GrIS surface runoff and provide unique insight into how photoautotrophic life excels within icy environments., Blooms of Zygnematophycean “glacier algae” lower the bare ice albedo of the Greenland Ice Sheet (GrIS), amplifying summer energy absorption at the ice surface and enhancing meltwater runoff from the largest cryospheric contributor to contemporary sea-level rise. Here, we provide a step change in current understanding of algal-driven ice sheet darkening through quantification of the photophysiological mechanisms that allow glacier algae to thrive on and darken the bare ice surface. Significant secondary phenolic pigmentation (11 times the cellular content of chlorophyll a) enables glacier algae to tolerate extreme irradiance (up to ∼4,000 µmol photons⋅m−2⋅s−1) while simultaneously repurposing captured ultraviolet and short-wave radiation for melt generation. Total cellular energy absorption is increased 50-fold by phenolic pigmentation, while glacier algal chloroplasts positioned beneath shading pigments remain low-light–adapted (Ek ∼46 µmol photons⋅m−2⋅s−1) and dependent upon typical nonphotochemical quenching mechanisms for photoregulation. On the GrIS, glacier algae direct only ∼1 to 2.4% of incident energy to photochemistry versus 48 to 65% to ice surface melting, contributing an additional ∼1.86 cm water equivalent surface melt per day in patches of high algal abundance (∼104 cells⋅mL−1). At the regional scale, surface darkening is driven by the direct and indirect impacts of glacier algae on ice albedo, with a significant negative relationship between broadband albedo (Moderate Resolution Imaging Spectroradiometer [MODIS]) and glacier algal biomass (R2 = 0.75, n = 149), indicating that up to 75% of the variability in albedo across the southwestern GrIS may be attributable to the presence of glacier algae.

Published

2020

22. Algal growth and weathering crust state drive variability in western Greenland Ice Sheet ice albedo

Author

Joseph M. Cook, Thomas Gribbin, Martyn Tranter, Andrew J. Tedstone, Jenine McCutcheon, Stefan Hofer, Tristram Irvine-Fynn, and Christopher Williamson

Subjects

010504 meteorology & atmospheric sciences, Energy balance, Greenland ice sheet, Atmospheric sciences, 01 natural sciences, Algal bloom, 03 medical and health sciences, Meltwater, lcsh:Environmental sciences, 030304 developmental biology, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, lcsh:GE1-350, 0303 health sciences, geography, geography.geographical_feature_category, lcsh:QE1-996.5, Glacier, 15. Life on land, Albedo, Weathering crust, Snow, lcsh:Geology, 13. Climate action, Environmental science, GlobalMass

Abstract

One of the primary controls upon the melting of the Greenland Ice Sheet (GrIS) is albedo, a measure of how much solar radiation that hits a surface is reflected without being absorbed. Lower-albedo snow and ice surfaces therefore warm more quickly. There is a major difference in the albedo of snow-covered versus bare-ice surfaces, but observations also show that there is substantial spatio-temporal variability of up to ∼0.4 in bare-ice albedo. Variability in bare-ice albedo has been attributed to a number of processes including the accumulation of light-absorbing impurities (LAIs) and the changing physical properties of the near-surface ice. However, the combined impact of these processes upon albedo remains poorly constrained. Here we use field observations to show that pigmented glacier algae are ubiquitous and cause surface darkening both within and outside the south-west GrIS “dark zone” but that other factors including modification of the ice surface by algal bloom presence, surface topography and weathering crust state are also important in determining patterns of daily albedo variability. We further use observations from an unmanned aerial system (UAS) to examine the scale gap in albedo between ground versus remotely sensed measurements made by Sentinel-2 (S-2) and MODIS. S-2 observations provide a highly conservative estimate of algal bloom presence because algal blooms occur in patches much smaller than the ground resolution of S-2 data. Nevertheless, the bare-ice albedo distribution at the scale of 20 m×20 m S-2 pixels is generally unimodal and unskewed. Conversely, bare-ice surfaces have a left-skewed albedo distribution at MODIS MOD10A1 scales. Thus, when MOD10A1 observations are used as input to energy balance modelling, meltwater production can be underestimated by ∼2 %. Our study highlights that (1) the impact of the weathering crust state is of similar importance to the direct darkening role of light-absorbing impurities upon ice albedo and (2) there is a spatial-scale dependency in albedo measurement which reduces detection of real changes at coarser resolutions.

Published

2020

23. Illuminating the dynamic rare biosphere of the Greenland Ice Sheet's Dark Zone

Author

Karen A. Cameron, Matthew J. Hegarty, Jarishma K. Gokul, Alun Hubbard, Luis A. J. Mur, Marek Stibal, Arwyn Edwards, Tristram Irvine-Fynn, and Joseph M. Cook

Subjects

0301 basic medicine, Rare biosphere, Earth science, 030106 microbiology, Greenland, Greenland ice sheet, Biology, Applied Microbiology and Biotechnology, Microbiology, Carbon cycle, Carbon Cycle, 03 medical and health sciences, Cryoconite, RNA, Ribosomal, 16S, Snow, Freezing, Ice Cover, Ecosystem, geography, geography.geographical_feature_category, Ecology, Microbiota, Northern Hemisphere, 030104 developmental biology, Methylobacterium, Habitat, Seasons, Ice sheet

Abstract

Greenland's Dark Zone is the largest contiguous region of bare terrestrial ice in the Northern Hemisphere and microbial processes play an important role in driving its darkening and thereby amplifying melt and runoff from the ice sheet. However, the dynamics of these microbiota have not been fully identified. Here we present joint 16S rRNA gene and 16S rRNA (cDNA) comparison of input (snow), storage (cryoconite), and output (supraglacial stream water) habitats across the Dark Zone over the melt season. We reveal that all three Dark Zone communities have a preponderance of rare taxa exhibiting high protein synthesis potential (PSP). Furthermore, taxa with high PSP represent highly connected ‘bottlenecks’ within community structure, consistent with their roles as metabolic hubs. Finally, low abundance-high PSP taxa affiliated with Methylobacterium within snow and stream water suggest a novel role for Methylobacterium in the carbon cycle of Greenlandic snowpacks, and importantly, the export of potentially active methylotrophs to the bed of the Greenland Ice Sheet. By comparing the dynamics of bulk and potentially active microbiota in the Dark Zone of the Greenland Ice Sheet we provide novel insights into the mechanisms and impacts of the microbial colonization of this critical region of our melting planet.

Published

2019

24. Illuminating the functional rare biosphere of the Greenland Ice Sheet’s Dark Zone

Author

Jarishma K. Gokul, Marek Stibal, Tristram Irvine-Fynn, Joseph M. Cook, Arwyn Edwards, Alun Hubbard, Karen A. Cameron, Luis A. J. Mur, and Matthew J. Hegarty

Subjects

Rare biosphere, Habitat, Cryoconite, Earth science, Community structure, Greenland ice sheet, Albedo, Snow, Geology, Carbon cycle

Abstract

The Dark Zone of the western Greenland Ice Sheet is the most expansive region of contiguous bare terrestrial ice in the Northern Hemisphere. Microbial processes within the Dark Zone play an important role in driving extensive albedo reduction and amplified melting, yet the composition and function of those consortia have not been fully identified. Here we present the first results from joint 16S rRNA gene and 16S rRNA (cDNA) analysis for the comparison of input (snow), storage (cryoconite), and output (supraglacial stream water) habitats across the Dark Zone over the melt season. Our analysis reveals that all three Dark Zone communities are characterized by a preponderance of rare taxa exhibiting high protein synthesis potential (PSP). Furthermore, taxa with high PSP represent highly connected “bottlenecks” within community structure, consistent with roles as metabolic hubs within their communities. Finally, the detection of low abundance-high PSP taxa affiliated withMethylobacteriumwithin snow and stream water indicates a potential role forMethylobacteriumin the carbon cycle of Greenlandic snowpacks, and importantly, the export of potentially active methylotrophs to the bed of the Greenland Ice Sheet. By comparing the dynamics of bulk and potentially active microbial communities in the Dark Zone of the Greenland Ice Sheet our study provides insight into the mechanisms and impacts of the microbial colonization of this critical region of our melting planet.

Published

2019

25. Nutrient cycling in supraglacial environments of the Dark Zone of the Greenland Ice Sheet

Author

Fotis Sgouridis, Joseph M. Cook, Andrew J. Tedstone, Marian L. Yallop, Jenine McCutcheon, Alexandra Holland, Ewa Poniecka, Alexandre M. Anesio, Christopher Williamson, and Martyn Tranter

Subjects

geography, Nutrient cycle, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Greenland ice sheet, Glacier, 01 natural sciences, Algal bloom, Nutrient, Environmental chemistry, Dissolved organic carbon, Environmental science, Ice sheet, 0105 earth and related environmental sciences, Redfield ratio

Abstract

Glaciers and ice sheets host abundant and dynamic communities of microorganisms on the ice surface (supraglacial environments). Recently, it has been shown that Streptophyte ice algae blooming on the surface ice of the south-west coast of the Greenland Ice Sheet are a significant contributor to the 15-year marked decrease in albedo. Currently little is known about the constraints, such as the nutrient cycling, on this large-scale algal bloom. In this study, we present a preliminary data set that investigates the conversion of dissolved inorganic nutrients to the dissolved organic phase occurring in these darkening surface ice environments. Our results show a clear dominance of the organic phase, with 93 % of the total dissolved nitrogen and 67 % of the total dissolved phosphorus in the organic phase. Correlations between algal abundance and dissolved organic carbon and nitrogen, indicate ice algae are driving the dissolved nutrient phase shift occurring in these supraglacial environments. Dissolved organic nutrient ratios in these supraglacial environments are notably higher than the Redfield Ratio (DON : DOP = 49, 78, 116) and DOC : DOP = 797, 1166, 2013), suggesting these environments may be phosphorus limited.

Published

2019

26. Supplementary material to 'Glacier algae accelerate melt rates on the western Greenland Ice Sheet'

Author

Joseph M. Cook, Andrew J. Tedstone, Christopher Williamson, Jenine McCutcheon, Andrew J. Hodson, Archana Dayal, McKenzie Skiles, Stefan Hofer, Robert Bryant, Owen McAree, Andrew McGonigle, Jonathan Ryan, Alexandre M. Anesio, Tristram D. L. Irvine-Fynn, Alun Hubbard, Edward Hanna, Mark Flanner, Sathish Mayanna, Liane G. Benning, Dirk van As, Marian Yallop, Jim McQuaid, Thomas Gribbin, and Martyn Tranter

Published

2019

27. Metabolome-mediated biocryomorphic evolution promotes carbon fixation in Greenlandic cryoconite holes

Author

Michael Sweet, Joseph M. Cook, Karen A. Cameron, Jarishma K. Gokul, Mark T. Bulling, Luis A. J. Mur, Sophie Charlotte Cook, Tristram Irvine-Fynn, and Arwyn Edwards

Subjects

0301 basic medicine, geography, Biogeochemical cycle, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Carbon fixation, Greenland ice sheet, chemistry.chemical_element, Glacier, Biology, 01 natural sciences, Microbiology, Astrobiology, 03 medical and health sciences, 030104 developmental biology, chemistry, 13. Climate action, Cryoconite, Autotroph, Ice sheet, Carbon, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Microbial photoautotrophs on glaciers engineer the formation of granular microbial‐mineral aggregates termed cryoconite which accelerate ice melt, creating quasi‐cylindrical pits called ‘cryoconite holes’. These act as biogeochemical reactors on the ice surface and provide habitats for remarkably active and diverse microbiota. Evolution of cryoconite holes towards an equilibrium depth is well known, yet interactions between microbial activity and hole morphology are currently weakly addressed. Here, we experimentally perturbed the depths and diameters of cryoconite holes on the Greenland Ice Sheet. Cryoconite holes responded by sensitively adjusting their shapes in three dimensions (‘biocryomorphic evolution’) thus maintaining favourable conditions for net autotrophy at the hole floors. Non‐targeted metabolomics reveals concomitant shifts in cyclic AMP and fucose metabolism consistent with phototaxis and extracellular polymer synthesis indicating metabolomic‐level granular changes in response to perturbation. We present a conceptual model explaining this process and suggest that it results in remarkably robust net autotrophy on the Greenland Ice Sheet. We also describe observations of cryoconite migrating away from shade, implying a degree of self‐regulation of carbon budgets over mesoscales. Since cryoconite is a microbe‐mineral aggregate, it appears that microbial processes themselves form and maintain stable autotrophic habitats on the surface of the Greenland ice sheet.

Published

2016

28. Measuring and Visualizing Solar UV for a Wide Range of Atmospheric Conditions on Hawai'i Island

Author

Joseph M. Cook, Alfio V. Parisi, Forrest M. Mims, Tom D. Pering, William B. Grant, Thomas C. Wilkes, and Andrew J. S. McGonigle

Subjects

010504 meteorology & atmospheric sciences, Health, Toxicology and Mutagenesis, media_common.quotation_subject, Climate, Kilauea, lcsh:Medicine, Left cheek, Biomass smoke, Volcanic Eruptions, Noon, 010502 geochemistry & geophysics, Atmospheric sciences, Manikins, 01 natural sciences, Solar ultraviolet radiation, Hawaii, Article, ultraviolet, Humans, sulfur dioxide, 14. Life underwater, UV Index, Sea level, Mauna Loa Observatory, 0105 earth and related environmental sciences, media_common, Atmosphere, lcsh:R, Public Health, Environmental and Occupational Health, ozone, smoke, 13. Climate action, Sky, Sunlight, Environmental science, Hawai’i

Abstract

Hawai&rsquo, i Island often receives extreme (UV Index &ge, 11) solar ultraviolet radiation (UVR). While the UV Index (UVI) has been measured since 1997 at Hawai&rsquo, i&rsquo, s high-altitude Mauna Loa Observatory (MLO), measurements where people live and recreate are rare. We measured UVI on the face of a rotating mannequin head with UVR sensors at its eyes, ears and cheeks while simultaneously measuring the UVI with a zenith-facing sensor at MLO and seven sites at or near sea level from 19 July to 14 August 2018. The mannequin sensors received higher UVR at midmorning and midafternoon than at noon. For example, at sea level the peak UVI at the left cheek was 5.2 at midmorning and 2.9 at noon, while the horizontal UVI at noon was 12.7. Our measurements were supplemented with wide-angle (190&deg, and 360&deg, ) sky photographs and UV images of the mannequin head. Because the UVI applies to horizontal surfaces, people in tropical and temperate latitudes should be informed that their face may be more vulnerable to UVR at midmorning and midafternoon than at noon. Finally, our instruments provided opportunities to measure unexpected UVR-altering events, including rare biomass smoke over MLO and spectroscopic measurements of substantial UVR-absorbing sulfur dioxide in the eruption plume of the Kilauea volcano.

Published

2019

29. Bio-optical Properties of Terrestrial Snow and Ice

Author

Joseph M. Cook, S. McKenzie Skiles, Mark Flanner, and Christopher Williamson

Subjects

Bio optical, Optics, Materials science, business.industry, Biological particles, sense organs, skin and connective tissue diseases, Polarization (waves), business, Snow, Electromagnetic radiation

Abstract

Bio-optics studies the change in intensity, frequency, polarization and direction of electromagnetic energy after interacting with a biological particle (usually a cell) or a collection of biological particles.

Published

2019

30. Ice algal bloom development on the surface of the Greenland Ice Sheet

Author

Joseph M. Cook, Alexandra Holland, Martyn Tranter, Christopher Williamson, Andrew J. Tedstone, Ewa Poniecka, Marian L. Yallop, Alexandre M. Anesio, and Dan T Fagan

Subjects

0301 basic medicine, Chlorophyll, glacier, 010504 meteorology & atmospheric sciences, Greenland, ice sheet, ice algae, zygnametophyceae, albedo, Greenland ice sheet, Biology, 01 natural sciences, Applied Microbiology and Biotechnology, Microbiology, Algal bloom, cyanobacteria, Carbon Cycle, 03 medical and health sciences, Snow, Snow line, genomics, Cryosphere, Ice Cover, polar, Biomass, Transect, 0105 earth and related environmental sciences, Autotrophic Processes, Ecology, alpine, Eutrophication, cryosphere, Carbon, 030104 developmental biology, Oceanography, 13. Climate action, cyanobacteria, cryosphere, polar, alpine, genomics, Seasons, Bloom, Streptophyta, Research Article

Abstract

It is fundamental to understand the development of Zygnematophycean (Streptophyte) micro-algal blooms within Greenland Ice Sheet (GrIS) supraglacial environments, given their potential to significantly impact both physical (melt) and chemical (carbon and nutrient cycling) surface characteristics. Here, we report on a space-for-time assessment of a GrIS ice algal bloom, achieved by sampling an ∼85 km transect spanning the south-western GrIS bare ice zone during the 2016 ablation season. Cell abundances ranged from 0 to 1.6 × 104 cells ml−1, with algal biomass demonstrated to increase in surface ice with time since snow line retreat (R2 = 0.73, P < 0.05). A suite of light harvesting and photo-protective pigments were quantified across transects (chlorophylls, carotenoids and phenols) and shown to increase in concert with algal biomass. Ice algal communities drove net autotrophy of surface ice, with maximal rates of net production averaging 0.52 ± 0.04 mg C l−1 d−1, and a total accumulation of 1.306 Gg C (15.82 ± 8.14 kg C km−2) predicted for the 2016 ablation season across an 8.24 × 104 km2 region of the GrIS. By advancing our understanding of ice algal bloom development, this study marks an important step toward projecting bloom occurrence and impacts into the future., Space for time assessment of an ice algal bloom occurring in surface ice of the Greenland ice sheet.

Published

2018

31. Supraglacial weathering crust dynamics inferred from cryoconite hole hydrology

Author

Tristram Irvine-Fynn, Andy Hodson, and Joseph M. Cook

Subjects

0301 basic medicine, Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Biogeochemistry, Aquifer, Glacier, Particulates, Radiative forcing, 01 natural sciences, 03 medical and health sciences, 030104 developmental biology, Hydrology (agriculture), 13. Climate action, Cryoconite, Ecosystem, Geomorphology, Geology, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Water levels in cryoconite holes were monitored at high resolution over a 3-week period on Austre Broggerbreen (Svalbard). These data were combined with melt and energy balance modelling, providing insights into the evolution of the glacier's near-surface hydrology and confirming that the hydrology of the near-surface, porous ice known as the 'weathering crust' is dynamic and analogous to a shallow-perched aquifer. A positive correlation between radiative forcing of melt and drainage efficiency was found within the weathering crust. This likely resulted from diurnal contraction and dilation of interstitial pore spaces driven by variations in radiative and turbulent fluxes in the surface energy balance, occasionally causing 'sudden drainage events'. A linear decrease in water levels in cryoconite holes was also observed and attributed to cumulative increases in near-surface ice porosity over the measurement period. The transport of particulate matter and microbes between cryoconite holes through the porous weathering crust is shown to be dependent upon weathering crust hydraulics and particle size. Cryoconite holes therefore yield an indication of the hydrological dynamics of the weathering crust and provide long-term storage loci for cryoconite at the glacier surface. This study highlights the importance of the weathering crust as a crucial component of the hydrology, ecology and biogeochemistry of the glacier ecosystem and glacierized regions and demonstrates the utility of cryoconite holes as natural piezometers on glacier surfaces.

Published

2015

32. Topographic shading influences cryoconite morphodynamics and carbon exchange

Author

Ottavia Cavalli, Angus J. Taggart, Joseph M. Cook, Arwyn Edwards, and Michael Sweet

Subjects

0301 basic medicine, 010504 meteorology & atmospheric sciences, Mesoscale meteorology, carbon cycling, Atmospheric sciences, 01 natural sciences, Carbon cycle, 03 medical and health sciences, biogeochemistry, Cryoconite, Ecosystem, GE1-350, Ecology, Evolution, Behavior and Systematics, QH540-549.5, 0105 earth and related environmental sciences, Earth-Surface Processes, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, biocryomorphology, cellular automata, Biogeochemistry, Sediment, Glacier, Environmental sciences, 030104 developmental biology, Geology, Beach morphodynamics

Abstract

Cryoconite holes are the most active and diverse microbial habitats on glacier and ice-sheet surfaces. In this article the authors demonstrate that the shape of cryoconite holes varies depending on ice-surface topography and that this has implications for the carbon cycling regime within. Net ecosystem production is shown to be controlled primarily by sediment thickness within holes. The authors show that irregular hole shapes are indicative of hole migration away from topographic shade, which promotes carbon fixation at the mesoscale on ice surfaces. A cellular automaton is used in conjunction with sediment-delivery experiments to show that migration is the result of simple sediment transfer processes, implying a relationship between ice-surface evolution and cryoconite biogeochemistry that has not previously been examined.

Published

2018

33. Quantifying bioalbedo:a new physically-based model and critique of empirical methods for characterizing biological influence on ice and snow albedo

Author

Joseph M Cook, Andrew J Hodson, Alex S Gardner, Mark Flanner, Andrew J Tedstone, Christopher Williamson, Tristram DL Irvine-Fynn, Johan Nilsson, Robert Bryant, and Martyn Tranter

Subjects

0303 health sciences, 03 medical and health sciences, 010504 meteorology & atmospheric sciences, 13. Climate action, Astrophysics::Earth and Planetary Astrophysics, 01 natural sciences, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics, 030304 developmental biology, 0105 earth and related environmental sciences

Abstract

The darkening effects of biological impurities on ice and snow have been recognised as a control on the surface energy balance of terrestrial snow, sea ice, glaciers and ice sheets. With a heightened interest in understanding the impacts of a changing climate on snow and ice processes, quantifying the impact of biological impurities on ice and snow albedo (bioalbedo) and its evolution through time is a rapidly growing field of research. However, rigorous quantification of bioalbedo has remained elusive because of difficulties in isolating the biological contribution to ice albedo from that of inorganic impurities and the variable optical properties of the ice itself. For this reason, isolation of the biological signature in reflectance data obtained from aerial/orbital platforms has not been achieved, even when ground-based biological measurements have been available. This paper provides the cell-specific optical properties that are required to model the spectral signatures and broadband darkening of ice. Applying radiative transfer theory, these properties provide the physical basis needed to link biological and glaciological ground measurements with remotely sensed reflectance data. Using these new capabilities we confirm that biological impurities can influence ice albedo, then we identify 10 challenges to the measurement of bioalbedo in the field with the aim of improving future experimental designs to better quantify bioalbedo feedbacks. These challenges are (1) ambiguity in terminology, (2) characterising snow or ice optical properties, (3) characterising solar irradiance, (4) determining optical properties of cells, (5) measuring biomass, (6) characterising vertical distribution of cells, (7) characterising abiotic impurities, (8) surface anisotropy, (9) measuring indirect albedo feedbacks, and (10) measurement and instrument configurations. This paper aims to provide a broad audience of glaciologists and biologists with an overview of radiative transfer and albedo that could support future experimental design.

Published

2017

34. Low-cost 3D printed 1 nm resolution smartphone sensor-based spectrometer: instrument design and application in ultraviolet spectroscopy

Author

Thomas C, Wilkes, Andrew J S, McGonigle, Jon R, Willmott, Tom D, Pering, and Joseph M, Cook

Abstract

We report on the development of a low-cost spectrometer, based on off-the-shelf optical components, a 3D printed housing, and a modified Raspberry Pi camera module. With a bandwidth and spectral resolution of ≈60 nm and 1 nm, respectively, this device was designed for ultraviolet (UV) remote sensing of atmospheric sulphur dioxide (SO

Published

2017

35. In-field metagenome and 16S rRNA gene amplicon nanopore sequencing robustly characterize glacier microbiota

Author

Sara M. E. Rassner, Andre Soares, Luis A. J. Mur, Arwyn Edwards, Samuel M. Nicholls, Birgit Sattler, Joseph M. Cook, Davy T, Hodson Aj, and Aliyah R. Debbonaire

Subjects

Nanopore, Metagenomics, Pyrosequencing, Genomics, Environmental DNA, Nanopore sequencing, Microbiome, Computational biology, Biology, Amplicon

Abstract

In the field of observation, chance favours only the prepared mind (Pasteur). Impressive developments in genomics have led microbiology to its third “Golden Age”. However, conventional metagenomics strategies necessitate retrograde transfer of samples from extreme or remote environments for later analysis, rendering the powerful insights gained retrospective in nature, striking a contrast with Pasteur’s dictum. Here we implement highly portable USB-based nanopore DNA sequencing platforms coupled with field-adapted environmental DNA extraction, rapid sequence library generation and off-line analyses of shotgun metagenome and 16S ribosomal RNA gene amplicon profiles to characterize microbiota dwelling within cryoconite holes upon Svalbard glaciers, the Greenland Ice Sheet and the Austrian Alps. We show in-field nanopore sequencing of metagenomes captures taxonomic composition of supraglacial microbiota, while 16S rRNA Furthermore, comparison of nanopore data with prior 16S rRNA gene V1-V3 pyrosequencing from the same samples, demonstrates strong correlations between profiles obtained from nanopore sequencing and laboratory based sequencing approaches. gene amplicon sequencing resolves bacterial community responses to habitat changes. Finally, we demonstrate the fidelity and sensitivity of in-field sequencing by analysis of mock communities using field protocols. Ultimately, in-field sequencing potentiated by nanopore devices raises the prospect of enhanced agility in exploring Earth’s most remote microbiomes.

Published

2016

36. Environmental Controls on Microbial Abundance and Activity on the Greenland Ice Sheet: A Multivariate Analysis Approach

Author

Jon Telling, Ka Man Mak, Alexandre M. Anesio, Andy Hodson, Marek Stibal, and Joseph M. Cook

Subjects

Biogeochemical cycle, Water flow, Greenland, Soil Science, Greenland ice sheet, Viridiplantae, Biology, Cyanobacteria, Carbon cycle, Ice Cover, Ecosystem, Glacial period, Ecology, Evolution, Behavior and Systematics, Autotrophic Processes, geography, geography.geographical_feature_category, Bacteria, Ecology, Heterotrophic Processes, Glacier, Bacterial Typing Techniques, Phototrophic Processes, Multivariate Analysis, Viruses, Physical geography, Ice sheet

Abstract

Microbes in supraglacial ecosystems have been proposed to be significant contributors to regional and possibly global carbon cycling, and quantifying the biogeochemical cycling of carbon in glacial ecosystems is of great significance for global carbon flow estimations. Here we present data on microbial abundance and productivity, collected along a transect across the ablation zone of the Greenland ice sheet (GrIS) in summer 2010. We analyse the relationships between the physical, chemical and biological variables using multivariate statistical analysis. Concentrations of debris-bound nutrients increased with distance from the ice sheet margin, as did both cell numbers and activity rates before reaching a peak (photosynthesis) or a plateau (respiration, abundance) between 10 and 20 km from the margin. The results of productivity measurements suggest an overall net autotrophy on the GrIS and support the proposed role of ice sheet ecosystems in carbon cycling as regional sinks of CO(2) and places of production of organic matter that can be a potential source of nutrients for downstream ecosystems. Principal component analysis based on chemical and biological data revealed three clusters of sites, corresponding to three 'glacier ecological zones', confirmed by a redundancy analysis (RDA) using physical data as predictors. RDA using data from the largest 'bare ice zone' showed that glacier surface slope, a proxy for melt water flow, accounted for most of the variation in the data. Variation in the chemical data was fully explainable by the determined physical variables. Abundance of phototrophic microbes and their proportion in the community were identified as significant controls of the carbon cycling-related microbial processes.

Published

2011

37. The mass–area relationship within cryoconite holes and its implications for primary production

Author

Andy Hodson, Tristram Irvine-Fynn, Alexandre M. Anesio, Christopher M. Bellas, Jon Telling, and Joseph M. Cook

Subjects

010506 paleontology, 010504 meteorology & atmospheric sciences, Primary (astronomy), Cryoconite, Physical geography, 01 natural sciences, Geology, Primary productivity, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Linear relationships between the mass of sediment present in a cryoconite hole and the hole area are described for a range of glacier and ice-sheet surfaces. The strong relationships found indicate that some mechanism regulates the thickness of the layer of sediment occupying the ‘floor’ of the hole. We find that this regulation process responds immediately to the addition of new debris to a hole and infer that it is caused by lateral thermal conduction from the debris to the hole wall. This causes hole widening by melt, and a redistribution of the debris within then takes place, usually resulting in 0.04–0.20 gcm−2 of debris in a layer of single cryoconite grains. The thinning of the debris layer during hole widening also reduces self-shading and thus maximizes the exposure of cryoconite to solar radiation. We explore the implications of the hole widening for biological production. Net photosynthesis (CO2 fixation) is shown to be favoured by thin debris layers, whilst net heterotrophy (CO2 respiration) occurs when debris layers are in excess of 2–4 mm. We conclude that the carbon balance of cryoconite holes is sensitive to the thickness of the debris and that the thermodynamic equilibration of the debris thickness helps the ecosystem to maximize primary production during the summer.

Published

2010

38. Metabolome-mediated biocryomorphic evolution promotes carbon fixation in Greenlandic cryoconite holes

Author

Joseph M, Cook, Arwyn, Edwards, Mark, Bulling, Luis A J, Mur, Sophie, Cook, Jarishma K, Gokul, Karen A, Cameron, Michael, Sweet, and Tristram D L, Irvine-Fynn

Subjects

Autotrophic Processes, Microbiota, Greenland, Metabolome, Ice Cover, Biological Evolution, Ecosystem, Carbon Cycle

Abstract

Microbial photoautotrophs on glaciers engineer the formation of granular microbial-mineral aggregates termed cryoconite which accelerate ice melt, creating quasi-cylindrical pits called 'cryoconite holes'. These act as biogeochemical reactors on the ice surface and provide habitats for remarkably active and diverse microbiota. Evolution of cryoconite holes towards an equilibrium depth is well known, yet interactions between microbial activity and hole morphology are currently weakly addressed. Here, we experimentally perturbed the depths and diameters of cryoconite holes on the Greenland Ice Sheet. Cryoconite holes responded by sensitively adjusting their shapes in three dimensions ('biocryomorphic evolution') thus maintaining favourable conditions for net autotrophy at the hole floors. Non-targeted metabolomics reveals concomitant shifts in cyclic AMP and fucose metabolism consistent with phototaxis and extracellular polymer synthesis indicating metabolomic-level granular changes in response to perturbation. We present a conceptual model explaining this process and suggest that it results in remarkably robust net autotrophy on the Greenland Ice Sheet. We also describe observations of cryoconite migrating away from shade, implying a degree of self-regulation of carbon budgets over mesoscales. Since cryoconite is a microbe-mineral aggregate, it appears that microbial processes themselves form and maintain stable autotrophic habitats on the surface of the Greenland ice sheet.

Published

2016

39. Cryoconite: The dark biological secret of the cryosphere

Author

Tristram Irvine-Fynn, Joseph M. Cook, Arwyn Edwards, Nozomu Takeuchi, and Clifford, N

Subjects

0301 basic medicine, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Earth science, Geography, Planning and Development, Biogeochemistry, Glacier, Albedo, 01 natural sciences, Biological materials, The arctic, 03 medical and health sciences, 030104 developmental biology, Cryoconite, Earth and Planetary Sciences (miscellaneous), General Earth and Planetary Sciences, Cryosphere, Anthropogenic pollutants, 0105 earth and related environmental sciences

Abstract

Cryoconite is granular sediment found on glacier surfaces comprising both mineral and biological material. Despite long having been recognised as an important glaciological and biological phenomenon cryoconite remains relatively poorly understood. Here, we appraise the literature on cryoconite for the first time, with the aim of synthesising and evaluating current knowledge to direct future investigations. We review the properties of cryoconite, the environments in which it is found, the biology and biogeochemistry of cryoconite, and its interactions with climate and anthropogenic pollutants. We generally focus upon cryoconite in the Arctic in summer, with Antarctic and lower latitude settings examined individually. We then compare the current state-of-the-science with that at the turn of the twentieth century, and suggest directions for future research including specific recommendations for studies at a range of spatial scales and a framework for integrating these into a more holistic understanding of cryoconite and its role in the cryosphere.

Published

2016

40. Photophysiology and albedo-changing potential of the ice algal community on the surface of the Greenland ice sheet

Author

Martyn Tranter, Marian L. Yallop, Nicholas W. Roberts, Joseph M. Cook, Gary L A Barker, James W MacFarlane, Rupert Gordon Perkins, Marek Stibal, Christopher M. Bellas, Jon Telling, Andy Hodson, Dan T Fagan, Alexandre M. Anesio, and Jemma L. Wadham

Subjects

Chlorophyll, Greenland, Greenland ice sheet, Atmospheric sciences, Photosynthesis, Cyanobacteria, Microbiology, Cryoconite, Botany, Freezing, Microalgae, Ice Cover, Absorption (electromagnetic radiation), Chlorophyll fluorescence, Ecology, Evolution, Behavior and Systematics, geography, Carbon Isotopes, geography.geographical_feature_category, biology, Zygnematophyceae, Albedo, biology.organism_classification, Microspectrophotometry, Original Article, Seasons, Ice sheet

Abstract

Darkening of parts of the Greenland ice sheet surface during the summer months leads to reduced albedo and increased melting. Here we show that heavily pigmented, actively photosynthesising microalgae and cyanobacteria are present on the bare ice. We demonstrate the widespread abundance of green algae in the Zygnematophyceae on the ice sheet surface in Southwest Greenland. Photophysiological measurements (variable chlorophyll fluorescence) indicate that the ice algae likely use screening mechanisms to downregulate photosynthesis when exposed to high intensities of visible and ultraviolet radiation, rather than non-photochemical quenching or cell movement. Using imaging microspectrophotometry, we demonstrate that intact cells and filaments absorb light with characteristic spectral profiles across ultraviolet and visible wavelengths, whereas inorganic dust particles typical for these areas display little absorption. Our results indicate that the phototrophic community growing directly on the bare ice, through their photophysiology, most likely have an important role in changing albedo, and subsequently may impact melt rates on the ice sheet.

Published

2012

41. An improved estimate of microbially mediated carbon fluxes from the Greenland Ice Sheet

Author

Edward Hanna, Philippe Huybrechts, Marek Stibal, Marian L. Yallop, Andy Hodson, Joseph M. Cook, Alexandre M. Anesio, Jon Telling, Earth System Sciences, Physical Geography, and Geography

Subjects

0301 basic medicine, Biomass (ecology), 010504 meteorology & atmospheric sciences, Global warming, Greenland ice sheet, Albedo, Atmospheric sciences, 01 natural sciences, Debris, 03 medical and health sciences, 030104 developmental biology, Oceanography, Cryoconite, Carbon fluxes, Ecosystem, Transect, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Microbially mediated carbon fluxes on the surface of the Greenland ice sheet (GrIS) were recently quantified by Hodson and others (2010) using measurements of the surface coverage of debris (cryoconite) and rates of biological production associated with debris near the ice-sheet margin. We present updated models that do not assume the same spatial uniformity in key parameters employed by Hodson and others (2010) because they make use of biomass distribution and biological production data from a 79 km transect of the GrIS. Further, the models presented here also include for the first time biomass associated with both cryoconite holes and surficial algae. The predicted annual carbon flux for a small (1600 km2) section of ice surrounding the field transect is about four times that estimated using spatially uniform biomass and production in this area. When surficial algae are included, the model predicts about 11 times more carbon fixation via photosynthesis per year than the cryoconite-only models. We therefore suggest that supraglacial carbon fluxes from the GrIS have previously been underestimated by more than an order of magnitude and that the hitherto overlooked surficial algal ecosystem can be the most crucial contributor. The GrIS is shown to be in a relatively stable state of net autotrophy according to our model and so a strong link between bare-ice area and total carbon fluxes is evident. The implication is a biomass feedback to surface albedo and enhanced ablation as a result. Climate predictions for the year 2100 show that greater carbon fixation could also result from climate warming.

Published

2012

42. Microbial genomics amidst the Arctic crisis

Author

Sara M. E. Rassner, Melanie C. Hay, Joseph M. Cook, Eleanor Furness, Aliyah R. Debbonaire, Arwyn Edwards, and Karen A. Cameron

Subjects

Genomic data, Climate change, Permafrost, Genomics, Review, Global Warming, Evolution, Molecular, 03 medical and health sciences, Arctic, psychrophiles, 14. Life underwater, Microbial communities: Environmental, Soil Microbiology, 030304 developmental biology, 0303 health sciences, 030306 microbiology, Ecology, Arctic Regions, Microbiota, microbial genomics, General Medicine, 15. Life on land, The arctic, Structure and function, Microbial genomics, Geography, climate change, 13. Climate action, geographic locations

Abstract

The Arctic is warming – fast. Microbes in the Arctic play pivotal roles in feedbacks that magnify the impacts of Arctic change. Understanding the genome evolution, diversity and dynamics of Arctic microbes can provide insights relevant for both fundamental microbiology and interdisciplinary Arctic science. Within this synthesis, we highlight four key areas where genomic insights to the microbial dimensions of Arctic change are urgently required: the changing Arctic Ocean, greenhouse gas release from the thawing permafrost, 'biological darkening' of glacial surfaces, and human activities within the Arctic. Furthermore, we identify four principal challenges that provide opportunities for timely innovation in Arctic microbial genomics. These range from insufficient genomic data to develop unifying concepts or model organisms for Arctic microbiology to challenges in gaining authentic insights to the structure and function of low-biomass microbiota and integration of data on the causes and consequences of microbial feedbacks across scales. We contend that our insights to date on the genomics of Arctic microbes are limited in these key areas, and we identify priorities and new ways of working to help ensure microbial genomics is in the vanguard of the scientific response to the Arctic crisis.