Your search keyword '"Janice Brahney"' showing total 58 results

1. Uranium isotopes of aeolian dust deposited in northern Tibetan Plateau glaciers: Implications for tracing aeolian dust provenance

Author

Xiaoyu Jiao, Zhiwen Dong, Janice Brahney, Eric J.R. Parteli, Fangzhou Li, Marcelli Augusto, and Ting Wei

Subjects

Uranium isotopes, Aeolian dust provenance, (234U/238U) values, Dust budget, Tibetan Plateau glaciers, Science (General), Q1-390

Abstract

Asian dust comprises a large portion of the northern hemisphere atmospheric dust load, thereby exerting substantial influence on the Earth's climate, global biogeochemistry and hydrological cycle through accelerated snow and ice melt. Dust deposited on alpine glaciers encodes information on broad scale atmospheric-environmental processes. The (234U/238U) values of dust fine particulates can reflect the comminuting time and intermediate processes; thus, it provides a new method for the provenance of aeolian dust in the glacial snowpack/cryoconite. Here we present results from a comprehensive survey of uranium isotopic concentrations in dust collected from cryoconites on the glaciers of the northern Tibetan Plateau (TP). These results indicate significant spatial heterogeneity in the (234U/238U) values associated with snowpack/cryoconite dust over a broad range of glaciers in the northern TP. The values of the (234U/238U) ratio in the glaciers of western Qilian Mountains (Qiyi Glacier, Shiyi Glacier, Laohugou Glacier No.12) were the highest, followed by the Tanggula (Dunkemadi Glacier) and Kunlun Mountains (Yuzhufeng Glacier), whereas these values were the lowest in the eastern Qilian Mountains (Jingyangling Snowpack, Dabanshan Snowpack, Lenglongling Glacier). By including the analysis of Sr-Nd isotopic compositions, we find the spatial isotopic distribution reflects a combination of local dust, which is associated with short comminuting times, and dust transported over long ranges. Meteorological data indicate that the dust production in the west and north TP, Alxa arid lands and Gobi Deserts, may have a significant impact on the TP glaciers. Moreover, U-Sr-Nd isotopic composition and end-member mixing models (EMMA) were used in our study to find out the relative contribution of distinct Asian dust sources to the dust budget in the TP glaciers. The results reveal that snowpack/cryoconite dust is derived from both local sources (low comminution signatures) as well as other dust sources in the Asian region. Our study demonstrates the potential of U isotope composition as a dust tracing method. In particular, by investigating this composition on dust collected from glacier snowpack and cryoconite holes, we arrive at a map of the distribution characteristics of (234U/238U) values in different regions of the TP. Our study is the first to deploy uranium comminution age for Tibetan dust source tracing, and the results are important to elucidate the multiple origins and dynamics of dust in the Tibetan Plateau.

Published

2022

2. The physical and chemical limnology of Yukon’s largest lake, Lhù’ààn Mân’ (Kluane Lake), prior to the 2016 ‘A’ą̈y Chù’ diversion

Author

Ellorie A. McKnight, Heidi Swanson, Janice Brahney, and David S. Hik

Subjects

lhù’ààn mân’ (kluane lake), ‘a’ą̈y chù’ (slims river), physical limnology, climate change, large northern lakes, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

Despite increasing evidence that large northern lakes are rapidly changing due to climate change, descriptive baseline studies of their physicochemical properties are largely lacking, limiting our ability to detect or predict change. This study represents a comprehensive scientific assessment of the limnology of Yukon’s largest lake: Lhù’ààn Mân’ (Kluane Lake), an important waterbody for local and First Nation communities, and key habitat for trout and salmon. Water sample and instrument data generated throughout 2015 describe distinct regions within the lake and their respective seasonal variability. A deep, glacially-influenced southern basin was characterized by cold, turbid, poorly stratified, unproductive, and nutrient-poor conditions; a shallower northwestern region (Tthe Kaala Daagur (Brooks/Little Arm)) was warmer, fully mixed, and more productive; a northeast region (’Ùha K’ènji (Talbot/Big Arm)) was clear and stratified with intermediate depth, temperature, productivity, and nutrient concentrations; and a central region had intermediate physicochemical conditions relative to the other three. This variability demonstrates the need for adequate spatial (within lake) and temporal (between seasons) monitoring of large northern lakes. In 2016, glacier recession within the watershed resulted in diversion of the lake’s primary inflow (‘A’ą̈y Chù’ (Slims River)). Our results, when used together with Indigenous knowledge, form a historical reference that enables assessments of the potential ecological consequences to Lhù’ààn Mân’.

Published

2021

3. Heavy metal levels and sources in suspended particulate matters of the glacier watersheds in Northeast Tibetan Plateau

Author

Rui Wu, Zhiwen Dong, Xiping Cheng, Janice Brahney, Xiaoyu Jiao, and Lihua Wu

Subjects

trace metals level, SPM, glacier watershed, Northeast Tibetan Plateau, source appointments, Environmental sciences, GE1-350

Abstract

This study collected summer meltwater runoff samples from several glacier watersheds of the northeast Tibetan Plateau during June-July 2017, and measured the concentrations of 17 trace elements (Li, Be, Sc, V, Cr, Co, Ni, Cu, Zn, Ga, Rb, Mo, Cd, In, Sb, Cs, Ba) in meltwater suspended particulate matter (SPM), in order to reveal the elemental concentration, spatial distribution, and water quality in remote glacier watershed under regional anthropogenic activities. Results showed that, the concentration of heavy metal elements was relatively high in Yuzhufeng Glacier basin, ranging from 0.57 μg/L (In) to 1,551.6 μg/L (Ba), whereas in Qiyi Glacier basin it was the lowest, ranging from 0.02 to 85.05 μg/L; and relatively medium in other glacier watersheds, with total elemental concentration varying from 1,503.9 to 1726.2 μg/L. Moreover, enrichment factors (EFs) of SPM heavy metals showed significantly higher value in the downstream than that of upper glacier region of the watershed. Most heavy metals with low EFs mainly originated from crust dust, while others with higher EFs (e.g., Cd, Sb) probably originated from anthropogenic sources. Spatially, the EFs of heavy metals were higher in Yuzhufeng and Laohugou Glacier basins; while in other regions the EFs were relatively low, which may be caused by regional land-surface and atmospheric environmental differences surrounding the various glacier watersheds. Compared with other remote locations in global range, heavy metals level (e.g., Cu, Ni, and Zn) in this region is relatively higher. Meanwhile, we find that, though the water quality of the glacier basin in northeast Tibetan Plateau was relatively clean and pollution-free, it is still obviously affected by regional anthropogenic activities. Mining activities, transportation and natural weathering and erosion processes in the study areas have important effects on the content of heavy metal pollutants of river-water SPM in the glacier watershed. Moreover, backward air-mass trajectories demonstrated the potential atmospheric pollutants transport from the surrounding cities and suburbs, to deposit in the snowpack and glaciers, and then melted out and released into meltwater runoff. This study provides a new perspective on more complete view of heavy metals distribution in glacier watershed, and new understanding for the cryosphere water environment evaluation in the Tibetan Plateau region.

Published

2022

4. Protecting endangered species in the USA requires both public and private land conservation

Author

Niall G. Clancy, John P. Draper, J. Marshall Wolf, Umarfarooq A. Abdulwahab, Maya C. Pendleton, Soren Brothers, Janice Brahney, Jennifer Weathered, Edd Hammill, and Trisha B. Atwood

Subjects

Medicine, Science

Abstract

Abstract Crucial to the successful conservation of endangered species is the overlap of their ranges with protected areas. We analyzed protected areas in the continental USA to assess the extent to which they covered the ranges of endangered tetrapods. We show that in 80% of ecoregions, protected areas offer equal (25%) or worse (55%) protection for species than if their locations were chosen at random. Additionally, we demonstrate that it is possible to achieve sufficient protection for 100% of the USA’s endangered tetrapods through targeted protection of undeveloped public and private lands. Our results highlight that the USA is likely to fall short of its commitments to halting biodiversity loss unless more considerable investments in both public and private land conservation are made.

Published

2020

5. Limited progress in nutrient pollution in the U.S. caused by spatially persistent nutrient sources.

Author

Rebecca J Frei, Gabriella M Lawson, Adam J Norris, Gabriel Cano, Maria Camila Vargas, Elizabeth Kujanpää, Austin Hopkins, Brian Brown, Robert Sabo, Janice Brahney, and Benjamin W Abbott

Subjects

Medicine, Science

Abstract

Human agriculture, wastewater, and use of fossil fuels have saturated ecosystems with nitrogen and phosphorus, threatening biodiversity and human water security at a global scale. Despite efforts to reduce nutrient pollution, carbon and nutrient concentrations have increased or remained high in many regions. Here, we applied a new ecohydrological framework to ~12,000 water samples collected by the U.S. Environmental Protection Agency from streams and lakes across the contiguous U.S. to identify spatial and temporal patterns in nutrient concentrations and leverage (an indicator of flux). For the contiguous U.S. and within ecoregions, we quantified trends for sites sampled repeatedly from 2000 to 2019, the persistence of spatial patterns over that period, and the patch size of nutrient sources and sinks. While we observed various temporal trends across ecoregions, the spatial patterns of nutrient and carbon concentrations in streams were persistent across and within ecoregions, potentially because of historical nutrient legacies, consistent nutrient sources, and inherent differences in nutrient removal capacity for various ecosystems. Watersheds showed strong critical source area dynamics in that 2-8% of the land area accounted for 75% of the estimated flux. Variability in nutrient contribution was greatest in catchments smaller than 250 km2 for most parameters. An ensemble of four machine learning models confirmed previously observed relationships between nutrient concentrations and a combination of land use and land cover, demonstrating how human activity and inherent nutrient removal capacity interactively determine nutrient balance. These findings suggest that targeted nutrient interventions in a small portion of the landscape could substantially improve water quality at continental scales. We recommend a dual approach of first prioritizing the reduction of nutrient inputs in catchments that exert disproportionate influence on downstream water chemistry, and second, enhancing nutrient removal capacity by restoring hydrological connectivity both laterally and vertically in stream networks.

Published

2021

6. Relationships between borders, management agencies, and the likelihood of watershed impairment.

Author

Josh Epperly, Andrew Witt, Jeffrey Haight, Susan Washko, Trisha B Atwood, Janice Brahney, Soren Brothers, and Edd Hammill

Subjects

Medicine, Science

Abstract

In the United States, the Clean Water Act (CWA) establishes water quality standards important for maintaining healthy freshwater ecosystems. Within the CWA framework, states define their own water quality criteria, leading to a potential fragmentation of standards between states. This fragmentation can influence the management of shared water resources and produce spillover effects of pollutants crossing state lines and other political boundaries. We used numerical simulations to test the null prediction of no difference in impairment between watersheds that cross political boundaries (i.e. state lines, national or coastal borders, hereafter termed "transboundary") and watersheds that cross no boundaries (hereafter "internal"). We found that transboundary watersheds are more likely to be impaired than internal watersheds. Further, we examined possible causes for this relationship based on both geographic and sociopolitical drivers. Though geographic variables such as human-modified land cover and the amount of upstream catchment area are associated with watershed impairment, the number and type of agencies managing land within a watershed better explained the different impairment levels between transboundary and internal watersheds. Watersheds primarily consisting of public lands are less impaired than watersheds consisting of private lands. Similarly, watersheds primarily managed by federal agencies are less impaired than state-managed watersheds. Our results highlight the importance of considering Integrated Watershed Management strategies for water resources within a fragmented policy framework.

Published

2018

7. Evidence for accelerated weathering and sulfate export in high alpine environments

Author

John T Crawford, Eve-Lyn S Hinckley, M Iggy Litaor, Janice Brahney, and Jason C Neff

Subjects

sulfur, cations, calcium, weathering, climate, mountains, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

High elevation alpine ecosystems—the ‘water towers of the world’—provide water for human populations around the globe. Active geomorphic features such as glaciers and permafrost leave alpine ecosystems susceptible to changes in climate which could also lead to changing biogeochemistry and water quality. Here, we synthesize recent changes in high-elevation stream chemistry from multiple sites that demonstrate a consistent and widespread pattern of increasing sulfate and base cation concentrations or fluxes. This trend has occurred over the past 30 years and is consistent across multiple sites in the Rocky Mountains of the United States, western Canada, the European Alps, the Icelandic Shield, and the Himalayas in Asia. To better understand these recent changes and to examine the potential causes of increased sulfur and base cation concentrations in surface waters, we present a synthesis of global records as well as a high resolution 33 year record of atmospheric deposition and river export data from a long-term ecological research site in Colorado, USA. We evaluate which factors may be driving global shifts in stream chemistry including atmospheric deposition trends and broad climatic patterns. Our analysis suggests that recent changes in climate may be stimulating changes to hydrology and/or geomorphic processes, which in turn lead to accelerated weathering of bedrock. This cascade of effects has broad implications for the chemistry and quality of important surface water resources.

Published

2019

8. Primary production modeling identifies restoration targets for shifting shallow, eutrophic lakes to clear-water regimes

Author

Leighton King, Janice Brahney, Scott Daly, Michael J. Paul, Kateri R. Salk, and Soren Brothers

Subjects

Ecology, Aquatic Science, Ecology, Evolution, Behavior and Systematics

Published

2023

9. The scaling of leaf nitrogen and phosphorus along a phosphorus availability gradient in a subtropical forest

Author

Jiahao Wen, Janice Brahney, Yaoben Lin, Zhiliang Ma, Ningxiao Sun, Ji Zheng, Huawei Ji, Hongzhang Kang, Baoming Du, Guopeng Liang, Muhammad Umair, and Chunjiang Liu

Subjects

Ecology, Plant Science

Published

2022

10. Beaver Pond Geomorphology Influences Pond Nitrogen Retention and Denitrification

Author

Desneiges Murray, Bethany T. Neilson, and Janice Brahney

Subjects

Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Water Science and Technology

Published

2023

11. Metal concentrations in wetland plant tissues influences transfer to terrestrial food webs

Author

Edd Hammill, Maya Pendleton, Janice Brahney, Karin M. Kettenring, and Trisha B. Atwood

Subjects

Food Chain, Lead, Metals, Heavy, Wetlands, Health, Toxicology and Mutagenesis, General Medicine, Plants, Management, Monitoring, Policy and Law, Poaceae, Toxicology, Copper, Arsenic

Abstract

Wetland plants tolerate potentially hazardous metals through a variety of strategies, including exclusion or accumulation. Whether plants sequester metals and where they store them in their tissues is important for understanding the potential role of plants as remediators or vectors of metals to terrestrial food webs. Here we evaluate metal sequestration in Great Salt Lake wetlands for one invasive (Phragmites australis; phragmites) and three native plant species, i.e. threesquare bulrush (Schoenoplectus americanus), hardstem bulrush (Schoenoplectus acutus), alkali bulrush (Bolboschoenus maritimus), and their terrestrial invertebrates. We observed higher concentrations of arsenic and copper than other metals in plant tissues, although high lead concentrations were observed in phragmites. All plants acted as excluders of arsenic and selenium, retaining the bulk of the metal mass in belowground tissues. In contrast, lead, copper, and cadmium were transferred to above ground tissues of hardstem bulrush and phragmites. The aboveground translocation facilitated the movement of these metals into invertebrates, with the highest concentrations in most cases found in predators. Though our results highlight the potential for metal remediation via wetland plant growth and removal, care should be taken to ensure that remediation efforts do not lead to bioaccumulation.

Published

2022

12. Long-distance atmospheric transport of microplastic fibers depends on their shapes

Author

Shuolin Xiao, Yuanfeng Cui, Janice Brahney, Natalie Mahowald, and Qi Li

Abstract

Recent studies have highlighted the importance of the atmosphere in the long-range transport of microplastic fibers (MPFs). However, both dry deposition processes and sources of MPFs are poorly understood due to their complexity in size and shape, which can be 100s $\mu m$ long, possessing round or flat cross-sections with dimensions of $O(1)\,\mu m$ thickness, and $O(10)\,\mu m$ width. Here, we develop a theory-based settling velocity model for MPFs in the atmosphere, predicting a much smaller aerodynamic size than a volumetrically equivalent spherical particle. Incorrect identification of flat fibers as cylindrical ones due to uncertainty in the thickness of sampled MPFs overestimates their dry deposition rate. Accounting for fiber thickness in sampled MPFs leads to a mean residence-time enhancement above $450\%$ compared to spherical-shaped particles, suggesting a much more efficient long-range transport of flat fibers than previously thought and that the ocean might be a major source of atmospheric plastics.

Published

2023

13. The physical and chemical limnology of Yukon’s largest lake, Lhù’ààn Mân’ (Kluane Lake), prior to the 2016 ‘A’ą̈y Chù’ diversion

Author

Janice Brahney, David S. Hik, Ellorie A. McKnight, and Heidi K. Swanson

Subjects

010504 meteorology & atmospheric sciences, lhù’ààn mân’ (kluane lake), Limnology, Climate change, Environmental engineering, Limiting, ‘a’ą̈y chù’ (slims river), 010501 environmental sciences, TA170-171, 01 natural sciences, Environmental sciences, physical limnology, climate change, General Earth and Planetary Sciences, Environmental science, large northern lakes, GE1-350, Physical geography, General Agricultural and Biological Sciences, Baseline (configuration management), 0105 earth and related environmental sciences, General Environmental Science

Abstract

Despite increasing evidence that large northern lakes are rapidly changing due to climate change, descriptive baseline studies of their physicochemical properties are largely lacking, limiting our ability to detect or predict change. This study represents a comprehensive scientific assessment of the limnology of Yukon’s largest lake: Lhù’ààn Mân’ (Kluane Lake), an important waterbody for local and First Nation communities, and key habitat for trout and salmon. Water sample and instrument data generated throughout 2015 describe distinct regions within the lake and their respective seasonal variability. A deep, glacially-influenced southern basin was characterized by cold, turbid, poorly stratified, unproductive, and nutrient-poor conditions; a shallower northwestern region (Tthe Kaala Daagur (Brooks/Little Arm)) was warmer, fully mixed, and more productive; a northeast region (’Ùha K’ènji (Talbot/Big Arm)) was clear and stratified with intermediate depth, temperature, productivity, and nutrient concentrations; and a central region had intermediate physicochemical conditions relative to the other three. This variability demonstrates the need for adequate spatial (within lake) and temporal (between seasons) monitoring of large northern lakes. In 2016, glacier recession within the watershed resulted in diversion of the lake’s primary inflow (‘A’ą̈y Chù’ (Slims River)). Our results, when used together with Indigenous knowledge, form a historical reference that enables assessments of the potential ecological consequences to Lhù’ààn Mân’.

Published

2021

14. Evaluation of hydrograph separation techniques with uncertain end‐member composition

Author

Eileen Lukens, Bethany T. Neilson, Kenneth H. Williams, Janice Brahney, and John Wiley & Sons Ltd.

Subjects

hydrograph separation, solutes, data-limited, insteam chemistry, end-member mixing, Environmental Health, mass balance, Water Science and Technology

Abstract

Hydrograph separation is one of many approaches used to analyse shifts in source water contributions to stream flow resulting from climate change in remote watersheds. Understanding these shifts is vital, as shifts in source water contributions to a stream can shape water management decisions. Because remote watersheds are often inaccessible and have poorly characterized contributing water sources, or end-members, it is critical to understand the implications of using different hydrograph separation techniques in these data-limited environments. To explore the uncertainty associated with different techniques, results from two hydrograph separation techniques, mass balance and principle component analysis, were compared using 3 years of aqueous geochemical data from the East River watershed located in the Elk Mountains of Central Colorado. Solute concentrations of the end-members were characterized by both a limited set of direct chemical measurements of different sources and detailed seasonal instream chemistry to examine the influences of uncertain end-member compositions in a data-limited environment. Annual volumetric end-member contributions to stream flow had relatively good agreement across separation techniques. Large variations in time were observed in the hydrograph separations, depending on the end-member type, and estimated flow contributions varied between the selected solutes. End-member concentrations characterized by stream chemistry showed several limitations including a reduced number of distinguishable end-members and differences in timing of flow contributions. Results highlight the benefits of using multiple hydrograph separation techniques by providing a ‘weight-of-evidence’ approach to environments with limited end-member concentration data.

Published

2022

15. Constraining Physical Understanding of Aerosol Loading, Biogeochemistry, and Snowmelt Hydrology from Hillslope to Watershed Scale in the East River Scientific Focus Area

Author

McKenzie Skiles, Janice Brahney, and David Gochis

Published

2022

16. Sediment source fingerprinting as an aid to large-scale landscape conservation and restoration: A review for the Mississippi River Basin

Author

Zhen Xu, Patrick Belmont, Janice Brahney, and Allen C. Gellis

Subjects

Geologic Sediments, Environmental Engineering, Mississippi, Rivers, Reproducibility of Results, General Medicine, Management, Monitoring, Policy and Law, Waste Management and Disposal, Environmental Monitoring

Abstract

Reliable quantitative information on sediment sources to rivers is critical to mitigate contamination and target conservation and restoration actions. However, for large-scale river basins, determination of the relative importance of sediment sources is complicated by spatiotemporal variability in erosional processes and sediment sources, heterogeneity in sediment transport and deposition, and a paucity of sediment monitoring data. Sediment source fingerprinting is an increasingly adopted field-based technique that identifies the nature and relative source contribution of sediment transported in waterways. Notably, sediment source fingerprinting provides information that is independent of other field, modeling, or remotely sensed techniques. However, the diversity in sampling, analytical, and interpretive methods for sediment fingerprinting has been recognized as a problem in terms of developing standardized procedures for its application at the scale of large river basins. Accordingly, this review focuses on sediment source fingerprinting studies conducted within the Mississippi River Basin (MRB), summarizes unique information provided by sediment source fingerprinting that is distinct from traditional monitoring techniques, evaluates consistency and reliability of methodological approaches among MRB studies, and provides prospects for the use of sediment source fingerprinting as an aid to large-scale landscape conservation and restoration under current management frameworks. Most MRB studies reported credible fingerprinting results and found near-channel sources to be the dominant sediment sources in most cases, and yet a lack of standardization in procedural steps makes results difficult to compare. Findings from MRB studies demonstrated that sediment source fingerprinting is a highly valuable and reliable sediment source assessment approach to assist land and water resource management under current management frameworks, but efforts are needed to make this technique applicable in large-scale landscape conservation and restoration efforts. We summarize research needs and discuss sediment fingerprinting use for basin-scale management efforts with the aim of encouraging that this technique is robust and reliable as it moves forward.

Published

2022

17. Microplastics and nanoplastics in the marine-atmosphere environment

Author

Deonie Allen, Steve Allen, Sajjad Abbasi, Alex Baker, Melanie Bergmann, Janice Brahney, Tim Butler, Robert A. Duce, Sabine Eckhardt, Nikolaos Evangeliou, Tim Jickells, Maria Kanakidou, Peter Kershaw, Paolo Laj, Joseph Levermore, Daoji Li, Peter Liss, Kai Liu, Natalie Mahowald, Pere Masque, Dušan Materić, Andrew G. Mayes, Paul McGinnity, Iolanda Osvath, Kimberly A. Prather, Joseph M. Prospero, Laura E. Revell, Sylvia G. Sander, Won Joon Shim, Jonathan Slade, Ariel Stein, Oksana Tarasova, Stephanie Wright, and Institute for Atmospheric and Earth System Research (INAR)

Subjects

Ocean, Atmospheric Science, Air, Human health, Transport, Pollution, 114 Physical sciences, Particles, TA, Abundance, South china sea, Deposition, Aerosol, Global analysis, Nature and Landscape Conservation, Earth-Surface Processes

Abstract

The discovery of atmospheric micro(nano)plastic transport and ocean-atmosphere exchange points to a highly complex marine plastic cycle, with negative implications for human and ecosystem health. Yet, observations are currently limited. In this Perspective, we quantify the processes and fluxes of the marine-atmospheric micro(nano)plastic cycle, with the aim of highlighting the remaining unknowns in atmospheric micro(nano)plastic transport. Between 0.013 and 25 million metric tons per year of micro(nano)plastics are potentially being transported within the marine atmosphere and deposited in the oceans. However, the high uncertainty in these marine-atmospheric fluxes is related to data limitations and a lack of study intercomparability. To address the uncertainties and remaining knowledge gaps in the marine-atmospheric micro(nano)plastic cycle, we propose a future global marine-atmospheric micro(nano)plastic observation strategy, incorporating novel sampling methods and the creation of a comparable, harmonized and global data set. Together with long-term observations and intensive investigations, this strategy will help to define the trends in marine-atmospheric pollution and any responses to future policy and management actions. Atmospheric transport of microplastics could be a major source of plastic pollution to the ocean, yet observations currently remain limited. This Perspective quantifies the known budgets of the marine-atmospheric micro(nano)plastic cycle and proposes a future global observation strategy.

Published

2022

18. Growth of grasses and forbs, nutrient concentration, and microbial activity in soil treated with microbeads

Author

Jingfeng Wang, Xiao Guo, Janice Brahney, Zhenwei Xu, Yi Hu, Wenyi Sheng, Yanni Chen, Mingyan Li, and Weihua Guo

Subjects

Health, Toxicology and Mutagenesis, General Medicine, Toxicology, Pollution

Published

2023

19. Effects of a diatom ecosystem engineer (Didymosphenia geminata) on stream food webs: implications for native fishes

Author

Niall G. Clancy, Phaedra Budy, James Dunnigan, and Janice Brahney

Subjects

0106 biological sciences, biology, Consumer, Ecology, 010604 marine biology & hydrobiology, Aquatic Science, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Ecosystem engineer, Didymosphenia geminata, Diatom, Habitat, Environmental science, Ecology, Evolution, Behavior and Systematics, Benthic algae

Abstract

Stream habitat changes affecting primary consumers often indirectly impact secondary consumers such as fishes. Blooms of the benthic algae Didymosphenia geminata (Didymo) are known to affect stream macroinvertebrates, but the potential indirect trophic impacts on fish consumers are poorly understood. In streams of the Kootenai River basin, we quantified the diet, condition, and growth rate of species of trout, char, and sculpin. In 2018, macroinvertebrate taxa composition was different between a stream with Didymo and a stream without, but trout diets, energy demand, and growth rates were similar. Trout abundance was higher in the stream with Didymo, but the amount of drifting invertebrates was higher in the stream without. In 2019, we surveyed 28 streams with a gradient of coverage. Didymo abundance was correlated only with the percentage of aquatic invertebrates in trout diets and was not related to diets of char or sculpin or condition of any species. Thus, we found no evidence for a trophic link between Didymo blooms and the condition or growth of trout, char, or sculpin in mountainous headwater streams.

Published

2021

20. Uranium Isotopic Composition and Constraints on the Provenance of the Qinghai‐Tibet Plateau's Surface Dust

Author

Xiaoyu Jiao, Zhiwen Dong, Eric J. R. Parteli, Janice Brahney, Ting Wei, Marcelli Augusto, Junsheng Nie, Jiawen Ren, and Xiang Qin

Subjects

Geophysics, Physik (inkl. Astronomie), Earth-Surface Processes

Published

2022

21. Plastic rain in protected areas of the United States

Author

Margaret Hallerud, Suja Sukumaran, Eric Heim, Janice Brahney, Maura Hahnenberger, and American Association for the Advancement of Science (AAAS)

Subjects

wind entrainment, Conservation of Natural Resources, 010504 meteorology & atmospheric sciences, Rain, Environmental pollution, Wind, 010501 environmental sciences, 01 natural sciences, Square meter, plastic, Soil Pollutants, 0105 earth and related environmental sciences, Hydrology, Multidisciplinary, Water pollutants, Entrainment (meteorology), United States, Deposition (aerosol physics), Soil water, Environmental science, Environmental Pollution, Tonne, environment, Plastics, Environmental Sciences, Water Pollutants, Chemical

Abstract

Here, there, and everywhere No place is safe from plastic pollution. Brahney et al. show that even the most isolated areas in the United States—national parks and national wilderness areas—accumulate microplastic particles after they are transported there by wind and rain (see the Perspective by Rochman and Hoellein). They estimate that more than 1000 metric tons per year fall within south and central western U.S. protected areas. Most of these plastic particles are synthetic microfibers used for making clothing. These findings should underline the importance of reducing pollution from such materials. Science , this issue p. 1257 ; see also p. 1184

Published

2020

22. Limited progress in nutrient pollution in the U.S. caused by spatially persistent nutrient sources

Author

Adam J. Norris, Brian Brown, Robert D. Sabo, Janice Brahney, Gabriel Cano, Gabriella M. Lawson, Rebecca J. Frei, Elizabeth Kujanpaa, Benjamin W. Abbott, Austin Hopkins, and Maria Camila Vargas

Subjects

Computer and Information Sciences, Nitrogen, Science, Climate, Biodiversity, Marine and Aquatic Sciences, Social Sciences, Land cover, Human Geography, Water Chemistry, Machine Learning, Nutrient, Rivers, Surface Water, Artificial Intelligence, Water Quality, Land Use, Environmental Chemistry, Ecosystem, Hydrology, Multidisciplinary, Land use, Geography, Ecology and Environmental Sciences, Water Pollution, Aquatic Environments, Biology and Life Sciences, Agriculture, Phosphorus, Bodies of Water, Pollution, United States, Lakes, Chemistry, Nutrient pollution, Physical Sciences, Spatial ecology, Earth Sciences, Environmental science, Medicine, Water quality, Research Article, Freshwater Environments

Abstract

Human agriculture, wastewater, and use of fossil fuels have saturated ecosystems with nitrogen and phosphorus, threatening biodiversity and human water security at a global scale. Despite efforts to reduce nutrient pollution, carbon and nutrient concentrations have increased or remained high in many regions. Here, we applied a new ecohydrological framework to ~12,000 water samples collected by the U.S. Environmental Protection Agency from streams and lakes across the contiguous U.S. to identify spatial and temporal patterns in nutrient concentrations and leverage (an indicator of flux). For the contiguous U.S. and within ecoregions, we quantified trends for sites sampled repeatedly from 2000 to 2019, the persistence of spatial patterns over that period, and the patch size of nutrient sources and sinks. While we observed various temporal trends across ecoregions, the spatial patterns of nutrient and carbon concentrations in streams were persistent across and within ecoregions, potentially because of historical nutrient legacies, consistent nutrient sources, and inherent differences in nutrient removal capacity for various ecosystems. Watersheds showed strong critical source area dynamics in that 2–8% of the land area accounted for 75% of the estimated flux. Variability in nutrient contribution was greatest in catchments smaller than 250 km2for most parameters. An ensemble of four machine learning models confirmed previously observed relationships between nutrient concentrations and a combination of land use and land cover, demonstrating how human activity and inherent nutrient removal capacity interactively determine nutrient balance. These findings suggest that targeted nutrient interventions in a small portion of the landscape could substantially improve water quality at continental scales. We recommend a dual approach of first prioritizing the reduction of nutrient inputs in catchments that exert disproportionate influence on downstream water chemistry, and second, enhancing nutrient removal capacity by restoring hydrological connectivity both laterally and vertically in stream networks.

Published

2021

23. Hf-Nd-Sr Isotopic Composition of the Tibetan Plateau Dust as a Fingerprint for Regional to Hemispherical Transport

Author

Ting Wei, Shichang Kang, Zhiwen Dong, Ling Yang, Junming Guo, Xiang Qin, Chunlei Zong, and Janice Brahney

Subjects

Aerosols, geography, geography.geographical_feature_category, Plateau, Asian Dust, media_common.quotation_subject, Northern Hemisphere, Glacier, Dust, General Chemistry, Tibet, Arid, Sink (geography), Desertification, Environmental Chemistry, Environmental science, Aeolian processes, Ice Cover, Physical geography, media_common, Environmental Monitoring

Abstract

Large areas of arid regions in the Tibetan Plateau (TP) are undergoing desertification and subsequent aeolian emission and transport. The contribution of TP soils to the atmospheric aerosol burden in Asia and elsewhere is not known. Here, we use Hf, Nd, and Sr isotopes to distinguish the TP from other Asian dust-producing regions and compare the signatures to sediments in major dust sink regions. We found that the Hf-Nd-Sr isotopes of TP soils showed unique spatial signatures. From north to south, 87Sr/86Sr ratios gradually increased, while eNd and eHf values gradually decreased; from west to east, 87Sr/86Sr and eHf gradually increased, while eNd changed indistinctly. The Hf-Nd-Sr isotopic compositions of TP soils were controlled by four geographic isotope regions: the northern, southern, western, and eastern TP. Compared with Asian large deserts, the TP showed a unique isotopic composition, which together exhibited a significant spatial change across Asia. Compared to dust isotopes in prominent sink areas, we found that the TP is an important dust source to eastern TP glaciers, the Chinese Loess Plateau, South China Sea, Japan, and Greenland. This study provides clear isotopic evidence that the TP is a major aeolian contributor in the Northern Hemisphere and may have important implications for the global aeolian cycle.

Published

2021

24. Mountain lakes: Eyes on global environmental change

Author

Sudeep Chandra, Ruben Sommaruga, Steve Sadro, Jill S. Baron, David M. Walters, Isabella A. Oleksy, Martin J. Kainz, Sarah A. Spaulding, Kyle R. Christianson, Elizabeth J. Hundey, Katrina A. Moser, Daniel L. Preston, Neal Michelutti, Fabio Lepori, Jasmine E. Saros, John M. Melack, John P. Smol, Jiří Kopáček, Janice Brahney, and Angela L. Strecker

Subjects

Global and Planetary Change, Biogeochemical cycle, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Environmental change, Lake ecosystem, Climate change, Glacier, 010501 environmental sciences, Oceanography, 01 natural sciences, Paleolimnology, Earth system science, Environmental science, Physical geography, Transect, 0105 earth and related environmental sciences

Abstract

Mountain lakes are often situated in protected natural areas, a feature that leads to their role as sentinels of global environmental change. Despite variations in latitude, mountain lakes share many features, including their location in catchments with steep topographic gradients, cold temperatures, high incident solar and ultraviolet radiation (UVR), and prolonged ice and snow cover. These characteristics, in turn, affect mountain lake ecosystem structure, diversity, and productivity. The lakes themselves are mostly small, and up until recently, have been characterized as oligotrophic. This paper provides a review and update of the growing body of research that shows that sediments in remote mountain lakes archive regional and global environmental changes, including those linked to climate change, altered biogeochemical cycles, and changes in dust composition and deposition, atmospheric fertilization, and biological manipulations. These archives provide an important record of global environmental change that pre-dates typical monitoring windows. Paleolimnological research at strategically selected lakes has increased our knowledge of interactions among multiple stressors and their synergistic effects on lake systems. Lakes from transects across steep climate (i.e., temperature and effective moisture) gradients in mountain regions show how environmental change alters lakes in close proximity, but at differing climate starting points. Such research in particular highlights the impacts of melting glaciers on mountain lakes. The addition of new proxies, including DNA-based techniques and advanced stable isotopic analyses, provides a gateway to addressing novel research questions about global environmental change. Recent advances in remote sensing and continuous, high-frequency, limnological measurements will improve spatial and temporal resolution and help to add records to spatial gaps including tropical and southern latitudes. Mountain lake records provide a unique opportunity for global scale assessments that provide knowledge necessary to protect the Earth system.

Published

2019

25. Guidelines for reporting and archiving 210Pb sediment chronologies to improve fidelity and extend data lifecycle

Author

Janice Brahney, Sarah Paton, Colin J. Courtney Mustaphi, Marco A. Aquino-López, John Czaplewski, Simon Goring, Quinn Asena, Johnny Panga Brushworth, Alexandra L. Noronha, and Kiersten Orton

Subjects

010506 paleontology, Environmental change, Data curation, Stratigraphy, media_common.quotation_subject, Fidelity, Geology, 010502 geochemistry & geophysics, 01 natural sciences, Data science, Metadata, Earth and Planetary Sciences (miscellaneous), Relevance (information retrieval), Quality (business), Data reporting, Empirical evidence, 0105 earth and related environmental sciences, media_common

Abstract

Radiometric dating methods are essential for developing geochronologies to study Late Quaternary environmental change and 210Pb dating is commonly used to produce age-depth models from recent (within 150 years) sediments and other geoarchives. The past two centuries are marked by rapid environmental socio-ecological changes frequently attributed to anthropogenic land-use activities, modified biogeochemical cycles, and climate change. Consequently, historical reconstructions over this recent time interval have high societal value because analyses of these datasets provide understanding of the consequences of environmental modifications, critical ecosystem thresholds, and to define desirable ranges of variation for management, restoration, and conservation. For this information to be used more broadly, for example to support land management decisions or to contribute data to regional analyses of ecosystem change, authors must report all of the useful age-depth model information. However, at present there are no guidelines for researchers on what information should be reported to ensure 210Pb data are fully disclosed, reproducible, and reusable; leading to a plethora of reporting styles, including inadequate reporting that reduces potential reusability and shortening the data lifecycle. For example, 64% of the publications in a literature review of 210Pb dated geoarchives did not include any presentation of age uncertainty estimates in modeled calendar ages used in age-depth models. Insufficient reporting of methods and results used in 210Pb dating geoarchives severely hampers reproducibility and data reusability, especially in analyses that make use of databased palaeoenvironmental data. Reproducibility of data is fundamental to further analyses of the number of palaeoenvironmental data and the spatial coverage of published geoarchives sites. We suggest, and justify, a set of minimum reporting guidelines for metadata and data reporting for 210Pb dates, including an IEDA (Interdisciplinary Earth Data Alliance), LiPD (Linked Paleo Data) and generic format data presentation templates, to contribute to improvements in data archiving standards and to facilitate the data requirements of researchers analyzing datasets of several palaeoenvironmental study sites. We analyse practices of methods, results and first order interpretation of 210Pb data and make recommendations to authors on effective data reporting and archiving to maximize the value of datasets. We provide empirical evidence from publications and practitioners to support our suggested reporting guidelines. These guidelines increase the scientific value of 210Pb by expanding its relevance in the data lifecycle. Improving quality and fidelity of environmental datasets broadens interdisciplinary use, lengthens the potential lifecycle of data products, and achieves requirements applicable for evidenced-based policy support.

Published

2019

26. Identifying factors that affect mountain lake sensitivity to atmospheric nitrogen deposition across multiple scales

Author

Andi Heard, Jason J. Williams, Jiří Kopáček, Koren R. Nydick, Janice Brahney, Karin A. Koinig, Leora Nanus, Ruben Sommaruga, Katrina A. Moser, Isabella A. Oleksy, Steven Sadro, Jasmine E. Saros, Jill S. Baron, Beth J Hundey, Benjamin T. Burpee, Kyle R. Christianson, Taylor Ganz, and Rolf D. Vinebrooke

Subjects

0106 biological sciences, Environmental Engineering, Watershed, 010504 meteorology & atmospheric sciences, Context (language use), 01 natural sciences, parasitic diseases, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, geography, geography.geographical_feature_category, 010604 marine biology & hydrobiology, Ecological Modeling, Generalized additive model, Northern Hemisphere, Lake ecosystem, 15. Life on land, Pollution, 6. Clean water, 13. Climate action, Environmental science, Spatial variability, Physical geography, Deposition (chemistry), Mountain range

Abstract

Increased nitrogen (N) deposition rates over the past century have affected both North American and European mountain lake ecosystems. Ecological sensitivity of mountain lakes to N deposition varies, however, because chemical and biological responses are modulated by local watershed and lake properties. We evaluated predictors of mountain lake sensitivity to atmospheric N deposition across North American and European mountain ranges and included as response variables dissolved inorganic N (DIN = N-NH4+ + N-NO3–) concentrations and phytoplankton biomass. Predictors of these responses were evaluated at three different spatial scales (hemispheric, regional, subregional) using regression tree, random forest, and generalized additive model (GAM) analysis. Analyses agreed that Northern Hemisphere mountain lake DIN was related to N deposition rates and smaller scale spatial variability (e.g., regional variability between North American and European lakes, and subregional variability between mountain ranges). Analyses suggested that DIN, N deposition, and subregional variability were important for Northern Hemisphere mountain lake phytoplankton biomass. Together, these findings highlight the need for finer-scale, subregional analyses (by mountain range) of lake sensitivity to N deposition. Subregional analyses revealed differences in predictor variables of lake sensitivity. In addition to N deposition rates, lake and watershed features such as land cover, bedrock geology, maximum lake depth (Zmax), and elevation were common modulators of lake DIN. Subregional phytoplankton biomass was consistently positively related with total phosphorus (TP) in Europe, while North American locations showed variable relationships with N or P. This study reveals scale-dependent watershed and lake characteristics modulate mountain lake ecological responses to atmospheric N deposition and provides important context to inform empirically based management strategies.

Published

2021

27. Constraining the atmospheric limb of the plastic cycle

Author

Zbigniew Klimont, Kim Prather, G. Cornwell, Natalie M. Mahowald, Hitoshi Matsui, Marje Prank, Janice Brahney, and National Academy of Sciences

Subjects

Pollution, Biogeochemical cycle, Microplastics, 010504 meteorology & atmospheric sciences, Polymers, media_common.quotation_subject, Earth science, Transport pathways, 010501 environmental sciences, 01 natural sciences, Atmosphere, Soil, Extant taxon, Life Below Water, 0105 earth and related environmental sciences, media_common, Multidisciplinary, plastic deposition, plastic cycle, Dust, atmospheric microplastics, plastic aerosols, Deposition (aerosol physics), 13. Climate action, microplastic pollution, Other Life Sciences, Physical Sciences, Environmental science, Particulate Matter, Environmental Pollution, Plastic pollution, Plastics, Environmental Monitoring

Abstract

Plastic pollution is one of the most pressing environmental and social issues of the 21st century. Recent work has highlighted the atmosphere’s role in transporting microplastics to remote locations [S. Allen et al., Nat. Geosci. 12, 339 (2019) and J. Brahney, M. Hallerud, E. Heim, M. Hahnenberger, S. Sukumaran, Science 368, 1257–1260 (2020)]. Here, we use in situ observations of microplastic deposition combined with an atmospheric transport model and optimal estimation techniques to test hypotheses of the most likely sources of atmospheric plastic. Results suggest that atmospheric microplastics in the western United States are primarily derived from secondary re-emission sources including roads (84%), the ocean (11%), and agricultural soil dust (5%). Using our best estimate of plastic sources and modeled transport pathways, most continents were net importers of plastics from the marine environment, underscoring the cumulative role of legacy pollution in the atmospheric burden of plastic. This effort uses high-resolution spatial and temporal deposition data along with several hypothesized emission sources to constrain atmospheric plastic. Akin to global biogeochemical cycles, plastics now spiral around the globe with distinct atmospheric, oceanic, cryospheric, and terrestrial residence times. Though advancements have been made in the manufacture of biodegradable polymers, our data suggest that extant nonbiodegradable polymers will continue to cycle through the earth’s systems. Due to limited observations and understanding of the source processes, there remain large uncertainties in the transport, deposition, and source attribution of microplastics. Thus, we prioritize future research directions for understanding the plastic cycle.

Published

2021

28. The DUST^2 Project: A source-to-sink investigation of the modern dust system in southwestern North America

Author

Janice Brahney, Jeffrey S. Munroe, Maura Hahnenberger, S. McKenzie Skiles, Greg Carling, and Kevin D. Perry

Subjects

Earth science, Environmental science, Source to sink

Abstract

The DUST^2 project is a new Critical Zone Thematic Cluster funded by the US National Science Foundation. DUST^2, an abbreviation for Dust across a Desert-Urban-Summit Transect, will study the modern dust system in southwestern North America, from source to sink using a combination of methods. Previous work has demonstrated that arid lands in the southwestern US are significant sources of mineral dust. The amount of dust emitted increased notably following European settlement, and climate models predict future increases in dust emission in response to climate warming. This dust is transported to the north and east by the wind, particularly during the springtime and coincident with the passage of strong frontal systems. The properties of this natural dust are altered as it mixes with anthropogenic aerosols sourced from industry and other activities along the densely populated Wasatch Front in northern Utah. Eventually, this dust is delivered to mountain ranges at the eastern border of the Basin and Range as well as in the Rocky Mountains. There, dust impacts the albedo of snowpack, triggering changes in snowmelt timing and magnitude. Dust also influences the developmental trajectories of mountain soils and alters the nutrient status of mountain ecosystems. The six primary investigators of the DUST^2 project, along with an array of additional staff and students, will study this dust system with field and lab-based methods focused on dust emitting landscapes, dust transport modeling, dust collection in urban and mountain settings, snow monitoring and snowmelt modeling, and investigation of dust-influenced soils coupled with analysis and modeling of the cycling of dust-derived nutrients. A major goal of this project is to incorporate researchers beyond those responsible for establishing the overall project framework. Anyone interested in learning about ways to collaborate or become involved with the DUST^2 effort should contact a member of the project leadership team listed as authors on this abstract.

Published

2021

29. Wet and dry plastic deposition in the western United States

Author

Maura Hahnenberger, Margaret Hallerud, Suja Sukumaran, Janice Brahney, and Eric Heim

Subjects

Materials science, Metallurgy, Deposition (chemistry)

Abstract

Eleven billion tons of plastic are projected to accumulate in the environment by 2025. Because plastics are persistent, they fragment into pieces that are susceptible to wind entrainment. Using high resolution spatial and temporal data we tested whether plastics deposited wet versus dry have unique atmospheric life histories. Further, we report on the rates and sources of deposition to remote U.S. conservation areas. We show that urban centers and resuspension from soils or water are important sources for wet deposition. In contrast, plastics deposited dry were smaller in size and rates were related to indices that suggest longer range or global transport. Deposition rates averaged 132 plastics m-2 day-1 amounting to > 1000 tons of plastic deposition to western U.S. protected lands annually.

Published

2021

30. Microplastics are raining down from the sky

Author

Janice Brahney

Subjects

Microplastics, Oceanography, Sky, media_common.quotation_subject, Environmental science, media_common

Published

2021

31. Glacier recession alters stream water quality characteristics facilitating bloom formation in the benthic diatom Didymosphenia geminata

Author

Janice Brahney, Brian Menounos, Sarah E. Null, Curtis A. Gray, L. Capito, M. Bothwell, and Paul Jefferson Curtis

Subjects

Canada, Environmental Engineering, 010504 meteorology & atmospheric sciences, STREAMS, 010501 environmental sciences, 01 natural sciences, Rivers, Water Quality, Environmental Chemistry, Ecosystem, Ice Cover, Glacial period, Meltwater, Waste Management and Disposal, 0105 earth and related environmental sciences, Diatoms, geography, geography.geographical_feature_category, biology, Glacier, 15. Life on land, biology.organism_classification, Pollution, 6. Clean water, Didymosphenia geminata, Diatom, Oceanography, 13. Climate action, Environmental science, Bloom

Abstract

Glaciers provide cold, turbid runoff to many mountain streams in the late summer and buffer against years with low snowfall. The input of glacial meltwater to streams maintains unique habitats and support a diversity of stream flora and fauna. In western Canada, glaciers are anticipated to retreat by 60–80% by the end of the century, and this retreat will invoke widespread changes in mountain ecosystems. We used a space-for-time substitution along a gradient of glacierization in western Canada to develop insights into changes that may occur in glaciated regions over the coming decades. Here we report on observed changes in physical (temperature, turbidity), and chemical (dissolved and total nutrients) characteristics of mountain streams and the associated shifts in their diatom communities during de-glacierization. Shifts in habitat characteristics across gradients include changes in nutrient concentrations, light penetration, temperatures, and flow, all of which have led to distinct changes in diatom community composition. Importantly, glacial-fed rivers were 3–5 °C cooler than rivers without glacial contributions. Declines in glacial meltwater contribution to streams resulted in shifts in the timing of nutrient fluxes and lower concentrations of total phosphorus (TP), soluble reactive phosphorus (SRP), and higher dissolved inorganic nitrogen (DIN) and light penetration. The above set of conditions were linked to the overgrowth of the benthic diatom Didymosphenia geminata. These changes in stream condition and D. geminata colony development primarily occurred in streams with marginal (2–5%) to no glacier cover. Our data support a hypothesis that climate-induced changes in river hydrochemistry and physical condition lead to a phenological mismatch that favors D. geminata bloom development.

Published

2020

32. A New Sampler for the Collection and Retrieval of Dry Dust Deposition

Author

Janice Brahney, Gregory A. Wetherbee, P. Strong, Ruth C. Heindel, Cody Youngbull, Graham A. Sexstone, and Elsevier Ltd

Subjects

Aerosols, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Dust particles, fungi, Sampling (statistics), Geology, Dust, Atmospheric dust, 010502 geochemistry & geophysics, Atmospheric sciences, Dry deposition, 01 natural sciences, complex mixtures, Grain size, Deposition (aerosol physics), Snowmelt, Environmental science, Water quality, Sterile sampling, NADP, Environmental Sciences, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Atmospheric dust can influence biogeochemical cycles, accelerate snowmelt, and affect air, water quality, and human health. Yet, the bulk of atmospherically transported material remains poorly quantified in terms of total mass fluxes and composition. This lack of information stems in part from the challenges associated with measuring dust deposition. Here we report on the design and efficacy of a new dry deposition sampler (Dry Deposition Sampling Unit (DSU)) and method that quantifies the gravitational flux of dust particles. The sampler can be used alone or within existing networks such as those employed by the National Atmospheric Deposition Program (NADP). Because the samplers are deployed sterile and the use of water to remove trapped dust is not required, this method allows for the recovery of unaltered dry material suitable for subsequent chemical and microbiological analyses. The samplers were tested in the laboratory and at 15 field sites in the western United States. With respect to material retention, sampler performance far exceeded commonly used methods. Retrieval efficiency was >97% in all trials and the sampler effectively preserved grain size distributions during wind exposure experiments. Field tests indicated favorable comparisons to dust-on-snow measurement across sites (r2 0.70, p < 0.05) and within sites to co-located aerosol data (r2 0.57–0.99, p < 0.05). The inclusion of dust deposition and composition monitoring into existing networks increases spatial and temporal understanding of the atmospheric transport on materials and substantively furthers knowledge of the effects of dust on terrestrial ecosystems and human exposure to dust and associated deleterious compounds.

Published

2020

33. Corrigendum to Identifying factors that affect mountain lake sensitivity to atmospheric nitrogen deposition across multiple scales

Author

Benjamin T. Burpee, Jasmine E. Saros, Leora Nanus, Jill Baron, Janice Brahney, Kyle R. Christianson, Taylor Ganz, Andi Heard, Beth Hundey, Karin A. Koinig, Jiˇrí Kop´aˇcek, Katrina Moser, Koren Nydick, Isabella Oleksy, Steven Sadro, Ruben Sommaruga, Rolf Vinebrooke, and Jason Williams

Subjects

Environmental Engineering, Ecological Modeling, Pollution, Waste Management and Disposal, Water Science and Technology, Civil and Structural Engineering

Published

2022

34. Determining annual cryosphere storage contributions to streamflow using historical hydrometric records

Author

Brian Menounos, Janice Brahney, Paul Jefferson Curtis, and Xiaohua Wei

Subjects

Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Glacier, 02 engineering and technology, Snow field, Snow, 01 natural sciences, Double mass analysis, 6. Clean water, 020801 environmental engineering, Glacier mass balance, 13. Climate action, Streamflow, Environmental science, Cryosphere, Surface runoff, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Alpine glaciers and perennial snow fields are important hydrologic elements in many mountain environments providing runoff during the late summer and during periods of drought. Because relatively long records of glacier mass-balance data are absent from many glacierized catchments, it remains unclear to what extent shrinking perennial snow and glaciers have affected runoff trends from these watersheds. Here we employ a hydrograph separation technique that uses a double mass curve in an attempt to isolate changes in runoff due to glacier retreat and disappearance of perennial snow. The method is tested using hydrometric data from 20 glacierized and 16 non-glacierized catchments in the Columbia Basin of Canada. The resulting estimates on cryosphere storage contribution to streamflow were well correlated to other regional estimates based on measurements as well as empirical and mechanistic models. Annual cryosphere runoff changed from +19 to -55% during the period 1975-2012, with an average decline of 26%. For August runoff, these changes ranged from +17 to -66%, with an average decrease of 24%. Reduction of cryosphere contributions to annual and late summer flows are expected to continue in coming decades as glaciers and the perennial snow patches shrink. Our method to isolate changes in late summer cryospheric storage contributions can be used as a first order estimate on changes in glacier contributions to flow and may help researchers and water managers target watersheds for further analysis.

Published

2017

35. Evidence for Large Holocene Earthquakes Along the Denali Fault in Southwest Yukon, Canada

Author

Panya Lipovsky, Peter J. Haeussler, Andrée Blais-Stevens, John J. Clague, Brian Menounos, Janice Brahney, and Geological Society of America

Subjects

010506 paleontology, geography, Environmental Engineering, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Strike-Slip Fault, Fault (geology), Geotechnical Engineering and Engineering Geology, Strike-slip tectonics, 01 natural sciences, Late Holocene, Positive Flower Structure, Paleoseismic, Denali Fault, Earth and Planetary Sciences (miscellaneous), Seismology, Holocene, Geology, Environmental Sciences, 0105 earth and related environmental sciences

Abstract

The Yukon–Alaska Highway corridor in southern Yukon is subject to geohazards ranging from landslides to floods and earthquakes on faults in the St. Elias Mountains and Shakwak Valley. Here we discuss the late Holocene seismic history of the Denali fault, located at the eastern front of the St. Elias Mountains and one of only a few known seismically active terrestrial faults in Canada. Holocene faulting is indicated by scarps and mounds on late Pleistocene drift and by tectonically deformed Pleistocene and Holocene sediments. Previous work on trenches excavated against the fault scarp near the Duke River reveals paleoseismic sediment disturbance dated to ∼300–1,200, 1,200–1,900, and 3,000 years ago. Re-excavation of the trenches indicates a fourth event dated to 6,000 years ago. The trenches are interpreted to show a negative flower structure produced by extension of sediments by dextral strike-slip fault movement. Nearby Crescent Lake is ponded against the fault scarp. Sediment cores reveal four abrupt sediment and diatom changes reflecting seismic shaking at ∼1,200–1,900, 1,900–5,900, 5,900–6,200, and 6,500–6,800 years ago. At the Duke River, the fault offsets sediments, including two White River tephra layers (∼1,900 and 1,200 years old). Late Pleistocene outwash gravel and overlying Holocene aeolian sediments show in cross section a positive flower structure indicative of post-glacial contraction of the sediments by dextral strike-slip movement. Based on the number of events reflecting ∼M6, we estimate the average recurrence of large earthquakes on the Yukon part of the Denali fault to be about 1,300 years in the past 6,500–6,800 years.

Published

2019

36. Climate change accelerates recovery of the Tatra Mountain lakes from acidification and increases their nutrient and chlorophyll a concentrations

Author

Stephen A. Norton, Jiří Kopáček, Petr Porcal, Janice Brahney, Jiří Kaňa, Svetlana Bičárová, Evžen Stuchlík, and Tomáš Navrátil

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Ecology, 010604 marine biology & hydrobiology, Phosphorus, chemistry.chemical_element, Weathering, Aquatic Science, 01 natural sciences, chemistry.chemical_compound, Nutrient, Nitrate, chemistry, Environmental chemistry, Soil pH, Dissolved organic carbon, Soil water, Leaching (agriculture), Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

We evaluated changes in the concentration of cations, anions, nutrients (dissolved organic carbon, DOC; phosphorus, P; and nitrogen forms including nitrate, NO3− and total organic nitrogen, TON), and chlorophyll a (Chl-a) in 31 Tatra Mountain lakes in Slovakia and Poland during their recovery from acidic deposition (1992–2018). Typical effects of decreasing acidic deposition on the lakes’ water composition, such as decreasing base cation concentrations, were confounded by climate change and catchment characteristics, including areal proportions of well-developed soils and scree. A climate-related increase in physical erosion provided freshly exposed unweathered granodiorite (the dominant bedrock) to chemical weathering. Dissolution of accessory calcite in the granodiorite increased the in-lake Ca2+ and HCO3− concentrations and reversed the Ca2+ trends, which originally decreased in parallel with strong acid anions. These changes were most pronounced in steep, scree-rich areas, which are most sensitive to physical weathering. Fresh apatite [Ca5(PO4)3(F, Cl, OH)] in the crushed granodiorite acts as a P source at soil pH’s between 4 and 5 and in the presence of chelating organic acids within soils. These conditions enhance apatite solubility, which in part explains increasing P in lakes with scree-dominated catchments. Soil recovery from acidification due to decreasing acidic deposition and the neutralizing effect of weathering of erosion-derived accessory calcite were the most likely causes of elevated DOC and P export from soils. Their elevated leaching was accompanied by increasing in-lake concentrations of Chl-a and TON. The increasing TON concentrations were, as for Ca2+, most pronounced in the scree-rich catchments, and represented the most sensitive indicator of the changes in the lake water nutrient composition.

Published

2019

37. Source or sink? Quantifying beaver pond influence on non-point source pollutant transport in the Intermountain West

Author

Bethany T. Neilson, Janice Brahney, and Desneiges Murray

Subjects

Pollution, Geologic Sediments, Beaver, Environmental Engineering, Riffle, media_common.quotation_subject, 0208 environmental biotechnology, Rodentia, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, biology.animal, parasitic diseases, Animals, Ponds, Waste Management and Disposal, Nonpoint source pollution, 0105 earth and related environmental sciences, media_common, Pollutant, Castor canadensis, biology, Biogeochemistry, Phosphorus, Beaver dam, General Medicine, biology.organism_classification, 020801 environmental engineering, Environmental chemistry, Environmental science, Water Pollutants, Chemical, Environmental Monitoring

Abstract

Non-point source (NPS) pollution remains high in many watersheds despite strategies aimed at reducing such pollution. Beaver (Castor canadensis) activity converts lotic systems to semi-lentic by impounding stream flow and trapping sediments, which have a high affinity for NPS pollutants such as nitrogen (N), phosphorus (P), and heavy metals. This study aimed to identify environmental conditions under which beaver ponds influence the fate and cycling of NPS pollutants. Dissolved and particulate nutrients were sampled upstream and downstream of three headwater beaver ponds differing in age and character through the summer season. Sedimentation rates and sediment concentrations of nutrients and metals were also determined. Results from this study suggest that beaver ponds can attenuate heavy metals at a rate 2 to 4 times greater than a riffle reach (p 0.05). Metal sequestration scaled with pond age and sediment organic matter content. The oldest and youngest ponds had no significant effect on dissolved nutrients (NO

Published

2021

38. Aeolian dust transport, cycle and influences in high-elevation cryosphere of the Tibetan Plateau region: New evidences from alpine snow and ice

Author

Ting Wei, Shichang Kang, James J. Elser, Xiaoyu Jiao, Janice Brahney, Yaping Shao, and Zhiwen Dong

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Asian Dust, Glacier, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Ice core, Dust storm, General Earth and Planetary Sciences, Aeolian processes, Environmental science, Cryosphere, Glacial period, Meltwater, 0105 earth and related environmental sciences

Abstract

Aeolian dust has a great influence on mountain hydrology, climate, and biogeochemical cycles. Dust deposited on glaciers and snowpack of the high alpine mountains in Tibetan Plateau (TP) and its surrounding regions can provide a unique method of determining the high-elevation transport and deposition of Asian dust in the middle and upper troposphere. Long-range-transported (LRT) Asian dust is often transmitted through the high troposphere, thus studies on dust deposition in the high-elevation cryosphere can reflect the LRT information of aeolian dust, and provide an unparalleled record to understand the regional climate and environment change in the “Third Pole” region. This paper comprehensively reviews the current status of the major factors that determine aeolian dust transport, settling, and cycling, and the key components of this dust cycles in high-elevation cryosphere regions, revealed by glacial snowpack and ice-core dust geochemistry recorded in the mountain glacier areas of TP and western China. Research on glacial dust concentrations indicated that much higher amounts of aeolian dust were found to transport and cycle in the high-elevation troposphere over TP and surroundings, compared to other locations of the globe. Dust concentrations and fluxes in high elevation regions of the TP were closely related to the transport distance of the nearby dust sources (e.g. large deserts and Gobi in western China, and arid deserts on the plateau surface). Isotopes tracers (e.g. 87Sr/86Sr, and eHf, eNd) and dust size distributions revealed that aeolian dust transported over TP mainly originated from the arid and semi-arid deserts and surface crust soils on TP; Aeolian dust from the large deserts of central Asia (e.g. the Taklimakan Desert with small ratio) have not been easily transported to the hinterland of TP under the current climatic conditions. An End-Member Mixing Analysis model was also used to calculate the relative contributions of northern hemisphere dust sources to the TP glacier dust sinks. The marked spatial differences in LRT dust sources of TP glaciers were caused by the large-scale atmospheric circulation strength and interactions in the Asian region. In addition, Asian dust has a large influence on the radiative forcing of glacier and snow melt in which the iron oxide composition constitute an important driving factor. Biogeochemical cycles in cryospheric regions were significantly affected by aeolian dust cycles, influencing glacial ecosystems, meltwater geochemistry (e.g. dFe release) and nutrients supply for downstream aquatic ecosystems. Ice core records for the past hundred years revealed a general decreasing trend of dust storm frequency and atmospheric concentration over the TP region. This work provides new insights and perspectives on aeolian dust transport and cycling in high regions of the troposphere and cryosphere of the TP, identifying critical uncertainties and priorities for future research.

Published

2020

39. Continental-Scale Increase in Lake and Stream Phosphorus: Are Oligotrophic Systems Disappearing in the United States?

Author

Steven G. Paulsen, Alan T. Herlihy, Richard M. Mitchell, David V. Peck, John L. Stoddard, John Van Sickle, Janice Brahney, and Amina I. Pollard

Subjects

Hydrology, 010504 meteorology & atmospheric sciences, Phosphorus, chemistry.chemical_element, General Chemistry, 010501 environmental sciences, 01 natural sciences, United States, Lakes, Animal science, Rivers, chemistry, Environmental Chemistry, Environmental science, Total phosphorus, Environmental Monitoring, 0105 earth and related environmental sciences

Abstract

We describe continental-scale increases in lake and stream total phosphorus (TP) concentrations, identified through periodic probability surveys of thousands of water bodies in the conterminous U.S. The increases, observed over the period 2000-2014 were most notable in sites in relatively undisturbed catchments and where TP was initially low (e.g., less than 10 μg L(-1)). Nationally, the percentage of stream length in the U.S. with TP ≤ 10 μg L(-1) decreased from 24.5 to 10.4 to 1.6% from 2004 to 2009 to 2014; the percentage of lakes with TP ≤ 10 μg L(-1) decreased from 24.9 to 6.7% between 2007 and 2012. Increasing TP concentrations appear to be ubiquitous, but their presence in undeveloped catchments suggests that they cannot be entirely attributed to either point or common non-point sources of TP.

Published

2016

40. Evidence for accelerated weathering and sulfate export in high alpine environments

Author

Jason C. Neff, Eve-Lyn S. Hinckley, John Crawford, Janice Brahney, M. Iggy Litaor, and Institute of Physics Publishing Ltd.

Subjects

geography, calcium, geography.geographical_feature_category, Renewable Energy, Sustainability and the Environment, Earth science, Bedrock, alpine, Public Health, Environmental and Occupational Health, Biogeochemistry, Weathering, Glacier, mountains, Permafrost, cations, Deposition (aerosol physics), sulfur, weathering, Ecosystem, sense organs, Water quality, climate, Environmental Sciences, General Environmental Science

Abstract

High elevation alpine ecosystems—the ‘water towers of the world’—provide water for human populations around the globe. Active geomorphic features such as glaciers and permafrost leave alpine ecosystems susceptible to changes in climate which could also lead to changing biogeochemistry and water quality. Here, we synthesize recent changes in high-elevation stream chemistry from multiple sites that demonstrate a consistent and widespread pattern of increasing sulfate and base cation concentrations or fluxes. This trend has occurred over the past 30 years and is consistent across multiple sites in the Rocky Mountains of the United States, western Canada, the European Alps, the Icelandic Shield, and the Himalayas in Asia. To better understand these recent changes and to examine the potential causes of increased sulfur and base cation concentrations in surface waters, we present a synthesis of global records as well as a high resolution 33 year record of atmospheric deposition and river export data from a long-term ecological research site in Colorado, USA. We evaluate which factors may be driving global shifts in stream chemistry including atmospheric deposition trends and broad climatic patterns. Our analysis suggests that recent changes in climate may be stimulating changes to hydrology and/or geomorphic processes, which in turn lead to accelerated weathering of bedrock. This cascade of effects has broad implications for the chemistry and quality of important surface water resources.

Published

2019

41. Is atmospheric phosphorus pollution altering global alpine Lake stoichiometry?

Author

Jason C. Neff, D. S. Ward, Ashley P. Ballantyne, Natalie M. Mahowald, Janice Brahney, and Wiley-Blackwell Publishing, Inc.

Subjects

biomass burning, Pollution, Atmospheric Science, media_common.quotation_subject, chemistry.chemical_element, Nutrient, Physical Sciences and Mathematics, Environmental Chemistry, phosphorus, General Environmental Science, Trophic level, media_common, Global and Planetary Change, Phosphorus, stoichiometry, eutrophication, Deposition (aerosol physics), chemistry, Atmospheric chemistry, Environmental chemistry, alpine Lakes, Earth Sciences, Environmental science, dust, Water quality, Eutrophication

Abstract

Anthropogenic activities have significantly altered atmospheric chemistry and changed the global mobility of key macronutrients. Here we show that contemporary global patterns in nitrogen (N) and phosphorus (P) emissions drive large hemispheric variation in precipitation chemistry. These global patterns of nutrient emission and deposition (N:P) are in turn closely reflected in the water chemistry of naturally oligotrophic lakes (r2 = 0.81, p

Published

2015

42. Ecological changes in two contrasting lakes associated with human activity and dust transport in western Wyoming

Author

Janice Brahney, Ashley P. Ballantyne, Jason C. Neff, G. L. Farmer, Peter R. Leavitt, and P. Kociolek

Subjects

Cyanobacteria, 010504 meteorology & atmospheric sciences, biology, Chemistry, Ecology, Aquatic ecosystem, Sediment, chemistry.chemical_element, Fold (geology), 15. Life on land, 010501 environmental sciences, Aquatic Science, Oceanography, biology.organism_classification, 01 natural sciences, Nitrogen, Diatom, 13. Climate action, Aquatic plant, Ecosystem, 0105 earth and related environmental sciences

Abstract

The atmospheric transport and deposition of aerosols has the potential to influence the chemistry and biology of oligotrophic alpine lakes. In recent decades, dust and nitrogen emissions to alpine ecosystems have increased across large areas of the western U.S., including Wyoming. Here, we use sediment geochemistry and 87Sr/86Sr and 143Nd/144Nd isotopes to examine historical dust deposition rates to alpine lakes in the southwestern region of the Wind River Range, Wyoming. We evaluate the biological response using diatom fossil assemblages and sediment pigment concentrations. Sediment core analyses indicated that prior to a recent rise in dust flux, phosphorus concentrations and species composition were similar to those found in other alpine lakes in the region. Concomitant with a ∼50 fold increase in dust flux to the sediments circa 1940, sediment proxies revealed a two- to threefold increase in normalized sediment phosphorus content, an increase in the diatom-inferred total dissolved phosphorus concentration from ∼ 4 to 9-12 μg L−1, a tenfold increase in diatom production, and a relative increase in cyanobacteria abundance. The increase in dust influx during the 20th century appears to be due in part to human factors and demonstrates the potential for dust and other atmospheric pollutants to significantly alter remote aquatic ecosystems.

Published

2015

43. Dust mediated transfer of phosphorus to alpine lake ecosystems of the Wind River Range, Wyoming, USA

Author

Megan Otu, Ashley P. Ballantyne, Janice Brahney, T. Porwoll, Jason C. Neff, Sarah A. Spaulding, and P. Kociolek

Subjects

Hydrology, geography, geography.geographical_feature_category, biology, Phosphorus, Drainage basin, Lake ecosystem, Sediment, chemistry.chemical_element, biology.organism_classification, Deposition (aerosol physics), Diatom, chemistry, Dissolved organic carbon, Phytoplankton, Environmental Chemistry, Geology, Earth-Surface Processes, Water Science and Technology

Abstract

Alpine lakes receive a large fraction of their nutrients from atmospheric sources and are consequently sensitive to variations in both the amount and chemistry of atmospheric deposition. In this study we explored the spatial changes in lake water chemistry and biology along a gradient of dust deposition in the Wind River Range, Wyoming. Regional differences were explored using the variation in bulk deposition, lake water, sediment, and bedrock geochemistry and catchment characteristics. Dust deposition rates in the Southwestern region averaged 3.34 g m -2 year -1 , approximately three times higher than deposition rates in the North- western region (average 1.06 g m -2 year -1 ). Dust-P deposition rates ranged from 87 l gPm 2 day -1 in the Northwestern region to 276 l gP m 2 day -1 in the Southwestern region. Subalpine and alpine lakes in the Southwestern region had greater total phosphorus (TP) concentrations (5-13 l gL -1 ) and greater sediment phosphorus (SP) concentrations (2-5 mg g -1 ) than similar lakes elsewhere in the region (1-8 l gL -1 TP, 0.5-2 mg g -1 SP). Lake phosphorus concentrations were related to dissolved organic carbon (DOC) across vegetation gradients, but related to the percent of bare rock, catchment area to lake area, and catchment steepness across dust deposition gradients. Modern phytoplankton and zooplankton biomasses were two orders of magnitude greater in the Southwest than in the Northwest, and alpine lakes in the Southwest had a unique diatom species assemblage with relatively higher concentrations of Asterionella formosa, Pseudostauros

Published

2014

44. Biogeochemical response of alpine lakes to a recent increase in dust deposition in the Southwestern, US

Author

Ashley P. Ballantyne, Jason C. Neff, Jasmine E. Saros, C. L. Lawrence, Janice Brahney, and D. Fernandez

Subjects

Biogeochemical cycle, Watershed, 010504 meteorology & atmospheric sciences, Watershed area, lcsh:Life, chemistry.chemical_element, Atmospheric sciences, 01 natural sciences, 03 medical and health sciences, lcsh:QH540-549.5, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0105 earth and related environmental sciences, Earth-Surface Processes, Hydrology, 0303 health sciences, geography, geography.geographical_feature_category, Bedrock, lcsh:QE1-996.5, Biogeochemistry, 15. Life on land, lcsh:Geology, lcsh:QH501-531, Deposition (aerosol physics), chemistry, 13. Climate action, Nitrogen fixation, lcsh:Ecology, Carbon, Geology

Abstract

The deposition of dust has recently increased significantly over some regions of the western US. Here we explore how changes in dust deposition have affected the biogeochemistry of two alpine watersheds in Colorado, US. We first reconstruct recent changes in the mass accumulation rate of sediments and then we use isotopic measurements in conjunction with a Bayesian mixing model to infer that approximately 95% of the inorganic fraction of lake sediments is derived from dust. Elemental analyses of modern dust indicate that dust is enriched in Ca, Cr, Cu, Mg, Ni, and in one watershed, Fe and P relative to bedrock. The increase in dust deposition combined with its enrichment in certain elements has altered the biogeochemisty of these systems. Both lakes showed an increase in primary productivity as evidenced by a decrease in carbon isotopic discrimination; however, the cause of increased primary productivity varies due to differences in watershed characteristic. The lake in the larger watershed experienced greater atmospheric N loading and less P loading from the bedrock leading to a greater N:P flux ratio. In contrast, the lake in the smaller watershed experienced less atmospheric N loading and greater P loading from the bedrock, leading to a reduced N:P flux ratio. As a result, primary productivity was more constrained by N availability in the smaller watershed. N-limited primary productivity in the smaller watershed was partly ameliorated by an increase in nitrogen fixation as indicated by reduced nitrogen isotopic values in more contemporary sediments. This study illustrates that alpine watersheds are excellent integrators of changes in atmospheric deposition, but that the biogeochemical response of these watersheds may be mediated by their physical (i.e. watershed area) and chemical (i.e. underlying geology) properties.

Published

2011

45. Late Holocene paleohydrology of Kluane Lake, Yukon Territory, Canada

Author

Brian Menounos, Thomas W. D. Edwards, Janice Brahney, and John J. Clague

Subjects

Hydrology, geography, geography.geographical_feature_category, Drainage basin, Glacier, Aquatic Science, Paleolimnology, Isotope hydrology, Glacial period, Meltwater, Geology, Channel (geography), Holocene, Earth-Surface Processes

Abstract

We have gained new insight into the dynamic late Holocene paleohydrology and paleolimnology of Kluane Lake by reconstructing lakewater δ18O using sediment cellulose as an oxygen-isotope archive. Our data suggest that the lake was regularly open hydrologically between 5000 and 1000 cal year BP, although with substantially lower water levels and with greater evaporative loss in relation to inflow than under contemporary conditions. During part of this period the lake was meromictic and may have undergone intermittent hydrologic closure, but southward drainage to the Pacific Ocean via the Alsek River system was generally maintained. Isotopic evidence confirms that Kluane Lake underwent complete hydrologic closure 430–300 cal year BP (AD 1520–1650) after a major advance of Kaskawulsh Glacier blocked southward drainage. Closure persisted as the lake overtopped the Duke River fan, initiating northward drainage to the Bering Sea via the Yukon River system. Although incision of the new outlet channel led to a rapid decline in lake level, northward discharge via the Kluane River has been maintained for the past three centuries because of abundant inflow from the Slims River. Substantial quantities of glacial meltwater and seasonal runoff continue to drain via the Slims River from Kaskawulsh Glacier and its catchment in the St. Elias Mountains. During this period Kluane River has also become an important route for migrating anadromous salmon. The modern isotope hydrology of Kluane Lake confirms that its current positive water balance is highly dependent on discharge from Slims River. Declining glacial meltwater contributions to Slims River will likely lead to lower water levels in Kluane Lake over the coming decades and possible re-establishment of intermittent or perennial hydrologic closure.

Published

2010

46. Changes to the Productivity and Trophic Structure of a Sockeye Salmon Rearing Lake in British Columbia

Author

Janice Brahney, Marlow G. Pellatt, Richard Routledge, and Darren G. Bos

Subjects

geography, education.field_of_study, geography.geographical_feature_category, Ecology, biology, Population, Climate change, Glacier, δ15N, Management, Monitoring, Policy and Law, Aquatic Science, biology.organism_classification, Commercial fishing, Fishery, Productivity (ecology), Oncorhynchus, Environmental science, education, Ecology, Evolution, Behavior and Systematics, Trophic level

Abstract

In the 1990s, the returns of sockeye salmon Oncorhynchus nerka to Long Lake in Smith Inlet, British Columbia, declined substantially. In 1997 the commercial fishery was closed, and it will not be reopened until the population shows signs of sustained recovery. We examined paleolimnological and geochemical variables from a sediment core extracted from Long Lake in 2002. The nitrogen isotope concentration (δ15N), which is associated with salmon production, declined to unprecedented levels in the 20th century. Sodium and other alkali elements have also decreased at a generally accelerating pace since the mid-19th century, and there are indications that the headwater glacier has receded apace. Accompanying these trends were notable changes in proxies for lake ecology, including the size and abundance of planktonic invertebrates. The timing and behavior of these unprecedented changes in the sedimentary record point to potential impacts from both commercial fishing and climate change.

Published

2010

47. Timing and cause of water level fluctuations in Kluane Lake, Yukon Territory, over the past 5000 years

Author

John J. Clague, Janice Brahney, W.D. Edwards Thomas, Brian Menounos, and Cambridge University Press

Subjects

010506 paleontology, 010504 meteorology & atmospheric sciences, Magnetic Susceptibility, 01 natural sciences, Paleolimnology, Arts and Humanities (miscellaneous), Yukon Territory, Kluane Lake, Drainage, Sedimentology, Holocene, 0105 earth and related environmental sciences, Earth-Surface Processes, Carbon Isotopes, geography, geography.geographical_feature_category, Nitrogen Isotopes, Sediment, Glacier, Water level, Oceanography, Period (geology), General Earth and Planetary Sciences, Environmental Sciences, Geology

Abstract

We reconstructed late Holocene fluctuations of Kluane Lake in Yukon Territory from variations in bulk physical properties and carbon and nitrogen elemental and isotopic abundances in nine sediment cores. Fluctuations of Kluane Lake in the past were controlled by changes in climate and glaciers, which affected inflow of Slims and Duke rivers, the two largest sources of water flowing into the lake. Kluane Lake fluctuated within a narrow range, at levels about 25 m below the present datum, from about 5000 to 1300 cal yr BP. Low lake levels during this interval are probably due to southerly drainage of Kluane Lake to the Pacific Ocean, opposite the present northerly drainage to Bering Sea. Slims River, which today is the largest contributor of water to Kluane Lake, only rarely flowed into the lake during the period 5000 to 1300 cal yr BP. The lake rose 7–12 m between 1300 and 900 cal yr BP, reached its present level around AD 1650, and within a few decades had risen an additional 12 m. Shortly thereafter, the lake established a northern outlet and fell to near its present level.

Published

2008

48. The influence of nitrogen limitation on d15N and carbon : nitrogen ratios in sediments from sockeye salmon nursery lakes in British Columbia, Canada

Author

Darren G. Bos, Thomas W. D. Edwards, Marlow G. Pellatt, Janice Brahney, and Richard Routledge

Subjects

chemistry.chemical_classification, biology, Ecology, Stable isotope ratio, Nitrogen deficiency, chemistry.chemical_element, Sediment, Aquatic Science, Oceanography, biology.organism_classification, Nitrogen, Nutrient, chemistry, Bosmina, Environmental science, Organic matter, Ecosystem

Abstract

Carbon (C) and nitrogen (N) elemental and nitrogen isotopic ratios were determined for bulk organic matter in surface sediments of 11 sockeye salmon (Onchorynchus nerka) nursery lakes in British Columbia, Canada. Chitinous exoskeletons of Bosmina spp. were also picked from the sediments and analyzed for d 15 N. The correlation between salmon escapement (spawner abundance) and bulk organic d 15 N confirms the importance of marine-derived nitrogen to the study lakes. The relation between sediment d15N and escapement, however, suggests that simple mixing models may significantly underestimate spawner abundance in nitrogen-limited lakes. In addition, the use of sediment and chitin d15N and C : N data to characterize lake-specific differences demonstrates that sediment isotope signatures are dependent on attendant nitrogen deficiency. The sediment C : N ratio, on its own, provides a sensitive measure of nutrient status in these lakes. This finding provides an alternate additional interpretation of C : N ratios that may be more appropriate in large lakes where terrestrial contributions to the central basin are insignificant.

Published

2006

49. Separating the Influences of Diagenesis, Productivity and Anthropogenic Nitrogen Deposition on Sedimentary δ15N Variations

Author

Ashley P. Ballantyne, Janice Brahney, Megan Otu, Jason C. Neff, Sarah A. Spaulding, Ben L. Turner, and Elsevier BV

Subjects

Diatoms, Environmental change, Nitrogen isotopes, Geochemistry, Sediment, Sedimentation, C/N ratio, Lake sediments, Diagenesis, Atmospheric nitrogen deposition, Productivity (ecology), Geochemistry and Petrology, Benthic zone, Sedimentary organic matter, Sedimentary rock, Geomorphology, Geology

Abstract

The stable isotopic composition of nitrogen (δ15N) in organic lake sediments is frequently used to infer changes in the source or cycling of N prior to sedimentation. However, diagenetic processes that occur after sedimentation can systematically alter the primary isotopic signal recorded in sedimentary organic matter and must be accounted for in order to detect changes in the δ15N of nitrogen inputs to the sediment surface. Here we present a null model that estimates the diagenetic effect on sedimentary lake δ15N records. The model was tested using lake sediment cores from relatively pristine alpine lakes in the Wind River and Teton Ranges of Wyoming, USA. Model-inferred increases in productivity were tested against independent productivity proxies (diatom accumulation rates and the planktonic to benthic ratio), and inferred changes in anthropogenic nitrogen contribution were validated with records of atmospheric nitrogen deposition from the nearby Fremont Glacier, Wyoming. Diagenetic overprinting significantly altered sediment δ15N profiles, and the degree of alteration was not constant through time. Of the cores analyzed, ∼30–70% of the variability can be explained by diagenesis alone, with the remainder explained by either a change in productivity or a change in the isotopic composition of the source material. Our null model of isotopic fractionation proved to be successful at separating the diagenetic overprinting from other causes of isotopic shifts, thereby providing environmental scientists with an analytical tool to partition the effects of diagenesis and environmental change on sedimentary δ15N values.

Published

2014

50. Biogeochemical response of alpine lakes to recent changes in dust deposition

Author

C. L. Lawrence, Jason C. Neff, Ashley P. Ballantyne, Jasmine E. Saros, Janice Brahney, and D. Fernandez

Subjects

Biogeochemical cycle, Environmental chemistry, Environmental science, Soil science, Deposition (chemistry)

Abstract

The deposition of dust has recently increased significantly over some regions of the western US. Here we explore how changes in dust deposition have affected the biogeochemistry of two alpine watersheds in Colorado, US. We first reconstruct recent changes in the mass accumulation rate of sediments and then we use isotopic measurements in conjunction with a Bayesian mixing model to infer that approximately 95% of the inorganic fraction of lake sediments is derived from dust. Elemental analyses of modern dust indicate that dust is enriched in Ca, Cr, Cu, Mg, Ni, and in one watershed, Fe and P relative to bedrock. The increase in dust deposition combined with its enrichment in certain elements has altered the biogeochemisty of these systems. Both lakes showed an increase in primary productivity as evidenced by a decrease in carbon isotopic discrimination; however, the cause of increased primary productivity varies due to differences in watershed characteristic. The lake in the larger watershed experienced greater atmospheric N loading and less P loading from the bedrock leading to a greater N:P flux ratio. In contrast, the lake in the smaller watershed experienced less atmospheric N loading and greater P loading from the bedrock, leading to a reduced N:P flux ratio. As a result, primary productivity was more constrained by N availability in the smaller watershed. N-limited primary productivity in the smaller watershed was partly ameliorated by an increase in nitrogen fixation as indicated by reduced nitrogen isotopic values in more contemporary sediments. This study illustrates that alpine watersheds are excellent integrators of changes in atmospheric deposition, but that the biogeochemical response of these watersheds may be mediated by their physical (i.e. watershed area) and chemical (i.e. underlying geology) properties.

Published

2010