Your search keyword '"Tyne RL"' showing total 5 results

1. Dissolved gases in the deep North Atlantic track ocean ventilation processes

Author

Seltzer, AM, Nicholson, DP, Smethie, WM, Tyne, RL, Le Roy, E, Stanley, RHR, Stute, M, Barry, PH, McPaul, K, Davidson, PW, Chang, BX, Rafter, PA, Lethaby, P, Johnson, RJ, Khatiwala, S, and Jenkins, WJ

Subjects

overturning circulation, Multidisciplinary, ddc:551, air-sea interaction, noble gases, nitrogen cycle, gas exchange

Abstract

Gas exchange between the atmosphere and ocean interior profoundly impacts global climate and biogeochemistry. However, our understanding of the relevant physical processes remains limited by a scarcity of direct observations. Dissolved noble gases in the deep ocean are powerful tracers of physical air-sea interaction due to their chemical and biological inertness, yet their isotope ratios have remained underexplored. Here, we present high-precision noble gas isotope and elemental ratios from the deep North Atlantic (~32°N, 64°W) to evaluate gas exchange parameterizations using an ocean circulation model. The unprecedented precision of these data reveal deep-ocean undersaturation of heavy noble gases and isotopes resulting from cooling-driven air-to-sea gas transport associated with deep convection in the northern high lati-tudes. Our data also imply an underappreciated and large role for bubble-mediated gas exchange in the global air-sea transfer of sparingly soluble gases, including O2, N2, and SF6. Using noble gases to validate the physical representation of air-sea gas exchange in a model also provides a unique opportunity to distinguish physical from biogeochemical signals. As a case study, we compare dissolved N2/Ar measurements in the deep North Atlantic to physics-only model predictions, revealing excess N2 from benthic denitrification in older deep waters (below 2.9 km). These data indicate that the rate of fixed N removal in the deep Northeastern Atlantic is at least three times higher than the global deep-ocean mean, suggesting tight coupling with organic carbon export and raising potential future implications for the marine N cycle., NSF, UK NERC, University of Oxford Advanced Research Computing facility, https://www.bco-dmo.org/project/887496, research

Published

2023

2. Identifying and Understanding Microbial Methanogenesis in CO 2 Storage.

Author

Tyne RL, Barry PH, Lawson M, Lloyd KG, Giovannelli D, Summers ZM, and Ballentine CJ

Subjects

Carbon, Carbon Dioxide, Groundwater

Abstract

Carbon capture and storage (CCS) is an important component in many national net-zero strategies. Ensuring that CO 2 can be safely and economically stored in geological systems is critical. To date, CCS research has focused on the physiochemical behavior of CO 2 , yet there has been little consideration of the subsurface microbial impact on CO 2 storage. However, recent discoveries have shown that microbial processes (e.g., methanogenesis) can be significant. Importantly, methanogenesis may modify the fluid composition and the fluid dynamics within the storage reservoir. Such changes may subsequently reduce the volume of CO 2 that can be stored and change the mobility and future trapping systematics of the evolved supercritical fluid. Here, we review the current knowledge of how microbial methanogenesis could impact CO 2 storage, including the potential scale of methanogenesis and the range of geologic settings under which this process operates. We find that methanogenesis is possible in all storage target types; however, the kinetics and energetics of methanogenesis will likely be limited by H 2 generation. We expect that the bioavailability of H 2 (and thus potential of microbial methanogenesis) will be greatest in depleted hydrocarbon fields and least within saline aquifers. We propose that additional integrated monitoring requirements are needed for CO 2 storage to trace any biogeochemical processes including baseline, temporal, and spatial studies. Finally, we suggest areas where further research should be targeted in order to fully understand microbial methanogenesis in CO 2 storage sites and its potential impact.

Published

2023

3. Dissolved gases in the deep North Atlantic track ocean ventilation processes.

Author

Seltzer AM, Nicholson DP, Smethie WM, Tyne RL, Le Roy E, Stanley RHR, Stute M, Barry PH, McPaul K, Davidson PW, Chang BX, Rafter PA, Lethaby P, Johnson RJ, Khatiwala S, and Jenkins WJ

Abstract

Gas exchange between the atmosphere and ocean interior profoundly impacts global climate and biogeochemistry. However, our understanding of the relevant physical processes remains limited by a scarcity of direct observations. Dissolved noble gases in the deep ocean are powerful tracers of physical air-sea interaction due to their chemical and biological inertness, yet their isotope ratios have remained underexplored. Here, we present high-precision noble gas isotope and elemental ratios from the deep North Atlantic (~32°N, 64°W) to evaluate gas exchange parameterizations using an ocean circulation model. The unprecedented precision of these data reveal deep-ocean undersaturation of heavy noble gases and isotopes resulting from cooling-driven air-to-sea gas transport associated with deep convection in the northern high latitudes. Our data also imply an underappreciated and large role for bubble-mediated gas exchange in the global air-sea transfer of sparingly soluble gases, including O 2 , N 2 , and SF 6 . Using noble gases to validate the physical representation of air-sea gas exchange in a model also provides a unique opportunity to distinguish physical from biogeochemical signals. As a case study, we compare dissolved N 2 /Ar measurements in the deep North Atlantic to physics-only model predictions, revealing excess N 2 from benthic denitrification in older deep waters (below 2.9 km). These data indicate that the rate of fixed N removal in the deep Northeastern Atlantic is at least three times higher than the global deep-ocean mean, suggesting tight coupling with organic carbon export and raising potential future implications for the marine N cycle.

Published

2023

4. Rapid microbial methanogenesis during CO 2 storage in hydrocarbon reservoirs.

Author

Tyne RL, Barry PH, Lawson M, Byrne DJ, Warr O, Xie H, Hillegonds DJ, Formolo M, Summers ZM, Skinner B, Eiler JM, and Ballentine CJ

Subjects

Bacteria metabolism, Geology, Temperature, Carbon Dioxide analysis, Groundwater, Methane metabolism

Abstract

Carbon capture and storage (CCS) is a key technology to mitigate the environmental impact of carbon dioxide (CO 2 ) emissions. An understanding of the potential trapping and storage mechanisms is required to provide confidence in safe and secure CO 2 geological sequestration 1,2 . Depleted hydrocarbon reservoirs have substantial CO 2 storage potential 1 , 3 , and numerous hydrocarbon reservoirs have undergone CO 2 injection as a means of enhanced oil recovery (CO 2 -EOR), providing an opportunity to evaluate the (bio)geochemical behaviour of injected carbon. Here we present noble gas, stable isotope, clumped isotope and gene-sequencing analyses from a CO 2 -EOR project in the Olla Field (Louisiana, USA). We show that microbial methanogenesis converted as much as 13-19% of the injected CO 2 to methane (CH 4 ) and up to an additional 74% of CO 2 was dissolved in the groundwater. We calculate an in situ microbial methanogenesis rate from within a natural system of 73-109 millimoles of CH 4 per cubic metre (standard temperature and pressure) per year for the Olla Field. Similar geochemical trends in both injected and natural CO 2 fields suggest that microbial methanogenesis may be an important subsurface sink of CO 2 globally. For CO 2 sequestration sites within the environmental window for microbial methanogenesis, conversion to CH 4 should be considered in site selection., (© 2021. The Author(s).)

Published

2021

5. Occurrence and Sources of Radium in Groundwater Associated with Oil Fields in the Southern San Joaquin Valley, California.

Author

McMahon PB, Vengosh A, Davis TA, Landon MK, Tyne RL, Wright MT, Kulongoski JT, Hunt AG, Barry PH, Kondash AJ, Wang Z, and Ballentine CJ

Subjects

California, Environmental Monitoring, Oil and Gas Fields, Water Supply, Groundwater, Radium, Water Pollutants, Chemical

Abstract

Geochemical data from 40 water wells were used to examine the occurrence and sources of radium (Ra) in groundwater associated with three oil fields in California (Fruitvale, Lost Hills, South Belridge). 226 Ra+ 228 Ra activities (range = 0.010-0.51 Bq/L) exceeded the 0.185 Bq/L drinking-water standard in 18% of the wells (not drinking-water wells). Radium activities were correlated with TDS concentrations ( p < 0.001, ρ = 0.90, range = 145-15,900 mg/L), Mn + Fe concentrations ( p < 0.001, ρ = 0.82, range = <0.005-18.5 mg/L), and pH ( p < 0.001, ρ = -0.67, range = 6.2-9.2), indicating Ra in groundwater was influenced by salinity, redox, and pH. Ra-rich groundwater was mixed with up to 45% oil-field water at some locations, primarily infiltrating through unlined disposal ponds, based on Cl, Li, noble-gas, and other data. Yet 228 Ra/ 226 Ra ratios in pond-impacted groundwater (median = 3.1) differed from those in oil-field water (median = 0.51). PHREEQC mixing calculations and spatial geochemical variations suggest that the Ra in the oil-field water was removed by coprecipitation with secondary barite and adsorption on Mn-Fe precipitates in the near-pond environment. The saline, organic-rich oil-field water subsequently mobilized Ra from downgradient aquifer sediments via Ra-desorption and Mn/Fe-reduction processes. This study demonstrates that infiltration of oil-field water may leach Ra into groundwater by changing salinity and redox conditions in the subsurface rather than by mixing with a high-Ra source.

Published

2019