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Your search keyword '"Anastasia Piliouras"' showing total 9 results
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9 results on '"Anastasia Piliouras"'

1. The effects of storms and a transient sandy veneer on the interannual planform evolution of a low-relief coastal cliff and shore platform at Sargent Beach, Texas, USA

Author

R. Palermo, Travis Swanson, David Mohrig, Andrew D. Ashton, and Anastasia Piliouras

Subjects
Shore, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Sediment, Storm, QE500-639.5, Sinuosity, 010502 geochemistry & geophysics, 01 natural sciences, Current (stream), Dynamic and structural geology, Geophysics, 13. Climate action, Erosion, Cliff, Spatial variability, 14. Life underwater, Physical geography, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Coastal cliff erosion is alongshore-variable and episodic, with retreat rates that depend upon sediment as either tools of abrasion or protective cover. However, the feedbacks between coastal cliff planform morphology, retreat rate, and sediment cover are poorly quantified. This study investigates Sargent Beach, Texas, USA, at the annual to interannual scale to explore (1) the relationship between temporal and spatial variability in cliff retreat rate, roughness, and sinuosity and (2) the response of retreat rate and roughness to changes in sand and shell hash cover of the underlying mud substrate as well as the impact of major storms using field measurements of sediment cover, erosion, and aerial images to measure shore platform morphology and retreat. A storm event in 2009 increased the planform roughness and sinuosity of the coastal cliff at Sargent Beach. Following the storm, aerial-image-derived shorelines with annual resolution show a decrease in average alongshore erosion rates from 12 to 4 m yr−1, coincident with a decrease in shoreline roughness and sinuosity (smoothing). Like the previous storm, a storm event in 2017 increased the planform roughness and sinuosity of the cliff. Over shorter timescales, monthly retreat of the sea cliff occurred only when the platform was sparsely covered with sediment cover on the shore platform, indicating that the tools and cover effects can significantly affect short-term erosion rates. The timescale to return to a smooth shoreline following a storm or roughening event, given a steady-state erosion rate, is approximately 24 years, with the long-term rate suggesting a maximum of ∼107 years until Sargent Beach breaches, compromising the Gulf Intracoastal Waterway (GIWW) under current conditions and assuming no future storms or intervention. The observed retreat rate varies, both spatially and temporally, with cliff face morphology, demonstrating the importance of multi-scale measurements and analysis for interpretation of coastal processes and patterns of cliff retreat.

Published
2021

2. Organic carbon burial by river meandering partially offsets bank-erosion carbon fluxes in a discontinuous permafrost floodplain

Author

Anastasia Piliouras, Woodward W. Fischer, P. C. Kemeny, A. Joshua West, A. J. Chadwick, M. Douglas, Gen Li, Michael P. Lamb, Jon Schwenk, and Joel C. Rowland

Subjects
Hydrology, Total organic carbon, geography, geography.geographical_feature_category, Floodplain, Erosion, Environmental science, Sediment, Silt, Permafrost, Bank erosion, Deposition (geology)
Abstract

Arctic river systems erode permafrost in their banks and mobilize particulate organic carbon (OC). Meandering rivers can entrain particulate OC from permafrost many meters below the depth of annual thaw, potentially enabling OC oxidation and the production of greenhouse gases. However, the amount and fate of permafrost OC that is mobilized by river erosion is uncertain. To constrain OC fluxes due to riverbank erosion and deposition, we collected riverbank and floodplain sediment samples along the Koyukuk River, which meanders through discontinuous permafrost in central Alaska. We measured sediment total OC (TOC), radiocarbon content, water content, bulk density, grain size, and floodplain stratigraphy. Radiocarbon abundance and TOC were higher in samples dominated by silt as compared to sand, which we used to map OC content onto floodplain stratigraphy and estimate carbon fluxes due to river meandering. Results showed that sediment being eroded from cutbanks and deposited as point bars had similar OC stocks (mean ± 1SD of 125.3 ± 13.1 kgOC m−2 in cutbanks versus 114.0 ± 15.7 kgOC m−2 in point bars) whether or not the banks contained permafrost. We also observed radiocarbon-depleted biospheric OC in both cutbanks and permafrost-free point bars. These results indicate that a significant fraction of aged biospheric OC that is liberated from floodplains by bank erosion is subsequently re-deposited in point bars, rather than being oxidized. The process of aging, erosion, and re-deposition of floodplain organic material may be intrinsic to river-floodplain dynamics, regardless of permafrost content.

Published
2021
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3. Impact of River Channel Lateral Migration on Microbial Communities across a Discontinuous Permafrost Floodplain

Author

Anastasia Piliouras, P. C. Kemeny, A. J. Chadwick, Jon Schwenk, Usha F. Lingappa, Michael P. Lamb, Joel C. Rowland, A. Joshua West, M. Douglas, Woodward W. Fischer, and Gen Li

Subjects
Hydrology, geography, geography.geographical_feature_category, Ecology, Floodplain, River channel migration, Microbiota, Permafrost, Sediment, Applied Microbiology and Biotechnology, Carbon Cycle, Rivers, Microbial population biology, Arctic, Tributary, Water Movements, Environmental Microbiology, Environmental science, Alaska, Channel (geography), Food Science, Biotechnology
Abstract

Permafrost soils store approximately twice the amount of carbon currently present in Earth’s atmosphere and are acutely impacted by climate change due to the polar amplification of increasing global temperature. Many organic-rich permafrost sediments are located on large river floodplains, where river channel migration periodically erodes and redeposits the upper tens of meters of sediment. Channel migration exerts a first-order control on the geographic distribution of permafrost and floodplain stratigraphy and thus may affect microbial habitats. To examine how river channel migration in discontinuous permafrost environments affects microbial community composition, we used amplicon sequencing of the 16S rRNA gene on sediment samples from floodplain cores and exposed riverbanks along the Koyukuk River, a large tributary of the Yukon River in west-central Alaska. Microbial communities are sensitive to permafrost thaw: communities found in deep samples thawed by the river closely resembled near-surface active-layer communities in nonmetric multidimensional scaling analyses but did not resemble floodplain permafrost communities at the same depth. Microbial communities also displayed lower diversity and evenness in permafrost than in both the active layer and permafrost-free point bars recently deposited by river channel migration. Taxonomic assignments based on 16S and quantitative PCR for the methyl coenzyme M reductase functional gene demonstrated that methanogens and methanotrophs are abundant in older permafrost-bearing deposits but not in younger, nonpermafrost point bar deposits. The results suggested that river migration, which regulates the distribution of permafrost, also modulates the distribution of microbes potentially capable of producing and consuming methane on the Koyukuk River floodplain. IMPORTANCE Arctic lowlands contain large quantities of soil organic carbon that is currently sequestered in permafrost. With rising temperatures, permafrost thaw may allow this carbon to be consumed by microbial communities and released to the atmosphere as carbon dioxide or methane. We used gene sequencing to determine the microbial communities present in the floodplain of a river running through discontinuous permafrost. We found that the river’s lateral movement across its floodplain influences the occurrence of certain microbial communities—in particular, methane-cycling microbes were present on the older, permafrost-bearing eroding riverbank but absent on the newly deposited river bars. Riverbank sediment had microbial communities more similar to those of the floodplain active-layer samples than permafrost samples from the same depth. Therefore, spatial patterns of river migration influence the distribution of microbial taxa relevant to the warming Arctic climate.

Published
2021

6. Modeling Functional Organic Chemistry in Arctic Rivers: An Idealized Siberian System

Author

Oliver W. Wingenter, Scott Elliott, Anastasia Piliouras, Georgina A. Gibson, Amadini Jayasinghe, Jitendra Kumar, Forrest M. Hoffman, Jaclyn Clement Kinney, Nicole Jeffery, Naval Postgraduate School (U.S.), and Oceanography

Subjects
Atmospheric Science, dissolved carbon, 010504 meteorology & atmospheric sciences, aqueous organic chemistry, aerosol, Flux, light penetration, lcsh:QC851-999, 010501 environmental sciences, Environmental Science (miscellaneous), Permafrost, 01 natural sciences, polar coastlines, arctic rivers, Box modeling, functional groups, trace gases, Tributary, Dissolved organic carbon, Organic chemistry, macromolecules, surface activity, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Taiga, biophysical influence, Tundra, Arctic, adsorption, Environmental science, lcsh:Meteorology. Climatology
Abstract

17 USC 105 interim-entered record; under review. The article of record as published may be found at https://doi.org/10.3390/atmos11101090 Rivers of the Arctic will become ever more important for the global climate, since they carry a majority of continental dissolved organic carbon flux into the rapidly changing polar ocean. Aqueous organics comprise a wide array of functional groups, several of which are likely to impact coastal and open water biophysical properties. Light attenuation, interfacial films, aerosol formation, gas release and momentum exchange can all be cited. We performed Lagrangian kinetic modeling for the evolution of riverine organic chemistry as the molecules in question make their way from the highlands to Arctic outlets. Classes as diverse as the proteins, sugars, lipids, re-condensates, humics, bio-tracers and small volatiles are all included. Our reduced framework constitutes an idealized northward flow driving a major hydrological discharge rate and primarily representing the Russian Lena. Mountainous, high solute and tundra sources are all simulated, and they meet up at several points between soil and delta process reactors. Turnover rates are parameterized beginning with extrapolated coastal values imposed along a limited tributary network, with connections between different terrestrial sub-ecologies. Temporal variation of our total dissolved matter most closely resembles the observations when we focus on the restricted removal and low initial carbon loads, suggesting relatively slow transformation along the water course. Thus, channel combinations and mixing must play a dominant role. Nevertheless, microbial and photochemical losses help determine the final concentrations for most species. Chemical evolution is distinct for the various functionalities, with special contributions from pre- and post-reactivity in soil and delta waters. Several functions are combined linearly to represent the collective chromophoric dissolved matter, characterized here by its absorption. Tributaries carry the signature of lignin phenols to segregate tundra versus taiga sources, and special attention is paid to the early then marine behaviors of low molecular weight volatiles. Heteropolycondensates comprise the largest percentage of reactive carbon in our simulations due to recombination/accumulation, and they tend to be preeminent at the mouth. Outlet concentrations of individual structures such as amino acids and absorbers lie above threshold values for biophysical influence, on the monolayer and light attenuation. The extent of coastal spreading is examined through targeted regional box modeling, relying on salinity and color for calibration. In some cases, plumes reach the scale of peripheral arctic seas, and amplification is expected during upcoming decades. Conclusions are mapped from the Lena to other boreal discharges, and future research questions are outlined regarding the bonding type versus mass release as permafrost degrades. Dynamic aqueous organic coupling is recommended for polar system models, from headwaters to coastal diluent. This research was supported by the Regional and Global Model Analysis (RGMA) component of the Earth and Environmental System Modeling (EESM) program, within the U.S. Department of Energy’s Office of Science. It is a direct contribution to the HiLAT-RASM project. Funds were also provided by the closely related RUBISCO biogeochemistry validation effort, home to ILAMB and IOMB (International Land and Ocean Model Benchmarking). This research was funded by U.S. Department of Energy: OBER RGMA.

Published
2020
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