Your search keyword '"Phelps, Tommy J"' showing total 33 results

1. The Evolution Pathway of Ammonia-Oxidizing Archaea Shaped by Major Geological Events.

Author

Yang, Yiyan, Zhang, Chuanlun, Lenton, Timothy M, Yan, Xinmiao, Zhu, Maoyan, Zhou, Mengdi, Tao, Jianchang, Phelps, Tommy J, and Cao, Zhiwei

Subjects

NITRIFICATION, AMMONIA-oxidizing archaebacteria, OXYGENATION (Chemistry), ANALYTICAL geochemistry, GLACIATION, MAGMATISM

Abstract

Primordial nitrification processes have been studied extensively using geochemical approaches, but the biological origination of nitrification remains unclear. Ammonia-oxidizing archaea (AOA) are widely distributed nitrifiers and implement the rate-limiting step in nitrification. They are hypothesized to have been important players in the global nitrogen cycle in Earth's early history. We performed systematic phylogenomic and marker gene analyses to elucidate the diversification timeline of AOA evolution. Our results suggested that the AOA ancestor experienced terrestrial geothermal environments at ∼1,165 Ma (1,928–880 Ma), and gradually evolved into mesophilic soil at ∼652 Ma (767–554 Ma) before diversifying into marine settings at ∼509 Ma (629–412 Ma) and later into shallow and deep oceans, respectively. Corroborated by geochemical evidence and modeling, the timing of key diversification nodes can be linked to the global magmatism and glaciation associated with the assembly and breakup of the supercontinent Rodinia, and the later oxygenation of the deep ocean. Results of this integrated study shed light on the geological forces that may have shaped the evolutionary pathways of the AOA, which played an important role in the ancient global nitrogen cycle. [ABSTRACT FROM AUTHOR]

Published

2021

2. Active Anaerobic Archaeal Methanotrophs in Recently Emerged Cold Seeps of Northern South China Sea.

Author

Zhang, Tingting, Xiao, Xi, Chen, Songze, Zhao, Jing, Chen, Zongheng, Feng, Junxi, Liang, Qianyong, Phelps, Tommy J., and Zhang, Chuanlun

Subjects

METHANOTROPHS, SULFATE-reducing bacteria, RNA analysis, CONTINENTAL slopes, NUCLEOTIDE sequence, BACTERIAL communities, MICROORGANISM populations, METHANE as fuel

Abstract

Cold seep ecosystems are developed from methane-rich fluids in organic rich continental slopes, which are the source of various dense microbial and faunal populations. Extensive studies have been conducted on microbial populations in this unique environment; most of them were based on DNA, which could not resolve the activity of extant organisms. In this study, RNA and DNA analyses were performed to evaluate the active archaeal and bacterial communities and their network correlations, particularly those participating in the methane cycle at three sites of newly developed cold seeps in the northern South China Sea (nSCS). The results showed that both archaeal and bacterial communities were significantly different at the RNA and DNA levels, revealing a higher abundance of methane-metabolizing archaea and sulfate-reducing bacteria in RNA sequencing libraries. Site ROV07-01, which exhibited extensive accumulation of deceased Calyptogena clam shells, was highly developed, and showed diverse and active anaerobic archaeal methanotrophs (ANME)-2a/b and sulfate-reducing bacteria from RNA libraries. Site ROV07-02, located near carbonate crusts with few clam shell debris, appeared to be poorly developed, less anaerobic and less active. Site ROV05-02, colonized by living Calyptogena clams, could likely be intermediary between ROV07-01 and ROV07-02, showing abundant ANME-2dI and sulfate-reducing bacteria in RNA libraries. The high-proportions of ANME-2dI, with respect to ANME-2dII in the site ROV07-01 was the first report from nSCS, which could be associated with recently developed cold seeps. Both ANME-2dI and ANME-2a/b showed close networked relationships with sulfate-reducing bacteria; however, they were not associated with the same microbial operational taxonomic units (OTUs). Based on the geochemical gradients and the megafaunal settlements as well as the niche specificities and syntrophic relationships, ANMEs appeared to change in community structure with the evolution of cold seeps, which may be associated with the heterogeneity of their geochemical processes. This study enriched our understanding of more active sulfate-dependent anaerobic oxidation of methane (AOM) in poorly developed and active cold seep sediments by contrasting DNA- and RNA-derived community structure and activity indicators. [ABSTRACT FROM AUTHOR]

Published

2020

3. Impact of Terrestrial Input on Deep-Sea Benthic Archaeal Community Structure in South China Sea Sediments.

Author

Lai, Dengxun, Hedlund, Brian P., Xie, Wei, Liu, Jingjing, Phelps, Tommy J., Zhang, Chuanlun, and Wang, Peng

Subjects

MARINE sediments, SEDIMENTS, CLIMATE change, INTERGLACIALS, GLACIATION, MICROBIAL communities

Abstract

Archaea are widespread in marine sediments and play important roles in the cycling of sedimentary organic carbon. However, factors controlling the distribution of archaea in marine sediments are not well understood. Here we investigated benthic archaeal communities over glacial-interglacial cycles in the northern South China Sea and evaluated their responses to sediment organic matter sources and inter-species interactions. Archaea in sediments deposited during the interglacial period Marine Isotope Stage (MIS) 1 (Holocene) were significantly different from those in sediments deposited in MIS 2 and MIS 3 of the Last Glacial Period when terrestrial input to the South China Sea was enhanced based on analysis of the long-chain n-alkane C31. The absolute archaeal 16S rRNA gene abundance in subsurface sediments was highest in MIS 2, coincident with high sedimentation rates and high concentrations of total organic carbon. Soil Crenarchaeotic Group (SCG; Nitrososphaerales) species, the most abundant ammonia-oxidizing archaea in soils, increased dramatically during MIS 2, likely reflecting transport of terrestrial archaea during glacial periods with high sedimentation rates. Co-occurrence network analyses indicated significant association of SCG archaea with benthic deep-sea microbes such as Bathyarchaeota and Thermoprofundales in MIS 2 and MIS 3, suggesting potential interactions among these archaeal groups. Meanwhile, Thermoprofundales abundance was positively correlated with total organic carbon (TOC), along with n-alkane C31 and sedimentation rate, indicating that Thermoprofundales may be particularly important in processing of organic carbon in deep-sea sediments. Collectively, these results demonstrate that the composition of heterotrophic benthic archaea in the South China Sea may be influenced by terrestrial organic input in tune with glacial-interglacial cycles, suggesting a plausible link between global climate change and microbial population dynamics in deep-sea marine sediments. [ABSTRACT FROM AUTHOR]

Published

2020

4. Population dynamics of methanogens and methanotrophs along the salinity gradient in Pearl River Estuary: implications for methane metabolism.

Author

Chen, Songze, Wang, Peng, Liu, Haodong, Xie, Wei, Wan, Xianhui Sean, Kao, Shuh-Ji, Phelps, Tommy J., and Zhang, Chuanlun

Subjects

POPULATION dynamics, METHANOTROPHS, CARBON cycle, ESTUARINE ecology, METHANE, ESTUARIES, ATMOSPHERIC methane, NITROGEN cycle

Abstract

Methane, a major greenhouse gas, plays an important role in global carbon cycling and climate change. Methanogenesis is identified as an important process for methane formation in estuarine sediments. However, the metabolism of methane in the water columns of estuaries is not well understood. The goal of this research was to examine the dynamics in abundance and community composition of methanogens and methanotrophs, and to examine whether and how they take part in methane metabolism in the water columns from the lower Pearl River (freshwater) to the coastal South China Sea (seawater). Quantitative PCR (qPCR) and high-throughput sequencing results showed that the abundance of methanogens decreased with increasing salinity, suggesting that growth of these methanogens in the Pearl River Estuary may be influenced by high salinity. Also, the methane concentration in surface waters was lower than that in near-bottom waters at most sites, suggesting sediment methanogens are a likely source of methane. In the estuarine mixing zone, significantly high methane concentrations existed with the presence of salt-tolerant methanogens (e.g., Methanomicrobiaceae, Methanocella, Methanosaeta and Methanobacterium) and methanotrophs (e.g., Methylocystis and Methylococcaceae), which were found in brackish habitats. Furthermore, a number of methanotrophic OTUs (from pmoA gene sequence data) had specific positive correlations with methanogenic OTUs (from mcrA gene sequence data), and some of these methanogenic OTUs were correlated with concentrations of particulate organic carbon (POC). The results indicate that methanotrophs and methanogens may be intimately linked in methane metabolism attached with particles in estuarine waters. [ABSTRACT FROM AUTHOR]

Published

2020

5. Improved ZnS nanoparticle properties through sequential NanoFermentation.

Author

Moon, Ji-Won, Eskelsen, Jeremy R., Ivanov, Ilia N., Jacobs, Christopher B., Jang, Gyoung Gug, Kidder, Michelle K., Joshi, Pooran C., Armstrong, Beth L., Pierce, Eric M., Oremland, Ronald S., Phelps, Tommy J., and Graham, David E.

Subjects

NANOPARTICLES, HEAVY metals, PARTICLE size determination, SURFACE coatings, CHEMICAL synthesis, ALKALOID synthesis

Abstract

Sequential NanoFermentation (SNF) is a novel process which entails sparging microbially produced gas containing H2S from a primary reactor through a concentrated metal-acetate solution contained in a secondary reactor, thereby precipitating metallic sulfide nanoparticles (e.g., ZnS, CuS, or SnS). SNF holds an advantage over single reactor nanoparticle synthesis strategies, because it avoids exposing the microorganisms to high concentrations of toxic metal and sulfide ions. Also, by segregating the nanoparticle products from biological materials, SNF avoids coating nanoparticles with bioproducts that alter their desired properties. Herein, we report the properties of ZnS nanoparticles formed from SNF as compared with ones produced directly in a primary reactor (i.e., conventional NanoFermentation, or “CNF”), commercially available ZnS, and ZnS chemically synthesized by bubbling H2S gas through a Zn-acetate solution. The ZnS nanoparticles produced by SNF provided improved optical properties due to their smaller crystallite size, smaller overall particle sizes, reduced biotic surface coatings, and reduced structural defects. SNF still maintained the advantages of NanoFermentation technology over chemical synthesis including scalability, reproducibility, and lower hazardous waste burden. [ABSTRACT FROM AUTHOR]

Published

2018

6. Impacts of Methane on Carbon Dioxide Storage in Brine Formations.

Author

Soltanian, Mohamad R., Amooie, Mohammad A., Cole, David R., Darrah, Thomas H., Graham, David E., Pfiffner, Susan M., Phelps, Tommy J., and Moortgat, Joachim

Subjects

CARBON dioxide, CARBON sequestration, SALT, METHANE, GAS leakage

Abstract

Abstract: In the context of geological carbon sequestration (GCS), carbon dioxide (CO2) is often injected into deep formations saturated with a brine that may contain dissolved light hydrocarbons, such as methane (CH4). In this multicomponent multiphase displacement process, CO2 competes with CH4 in terms of dissolution, and CH4 tends to exsolve from the aqueous into a gaseous phase. Because CH4 has a lower viscosity than injected CO2, CH4 is swept up into a ‘bank’ of CH4‐rich gas ahead of the CO2 displacement front. On the one hand, this may provide a useful tracer signal of an approaching CO2 front. On the other hand, the emergence of gaseous CH4 is undesirable because it poses a leakage risk of a far more potent greenhouse gas than CO2 if the cap rock is compromised. Open fractures or faults and wells could result in CH4 contamination of overlying groundwater aquifers as well as surface emissions. We investigate this process through detailed numerical simulations for a large‐scale GCS pilot project (near Cranfield, Mississippi) for which a rich set of field data is available. An accurate cubic‐plus‐association equation‐of‐state is used to describe the non‐linear phase behavior of multiphase brine‐CH4‐CO2 mixtures, and breakthrough curves in two observation wells are used to constrain transport processes. Both field data and simulations indeed show the development of an extensive plume of CH4‐rich (up to 90 mol%) gas as a consequence of CO2 injection, with important implications for the risk assessment of future GCS projects. [ABSTRACT FROM AUTHOR]

Published

2018

7. A microbial functional group-based module for simulating methane production and consumption: Application to an incubated permafrost soil.

Author

Xu, Xiaofeng, Elias, Dwayne A., Graham, David E., Phelps, Tommy J., Carroll, Sue L., Wullschleger, Stan D., and Thornton, Peter E.

Published

2015

8. Insights into the structure of mixed CO2/CH4 in gas hydrates.

Author

Everett, S. Michelle, Rawn, Claudia J., Chakoumakos, Bryan C., Keffer, David J., Huq, Ashfia, and Phelps, Tommy J.

Subjects

METHANE hydrates, CARBON dioxide, NEUTRON diffraction, GAS hydrates, SCATTERING (Physics)

Abstract

The exchange of carbon dioxide for methane in natural gas hydrates is an attractive approach to harvesting CH4 for energy production while simultaneously sequestering CO2. In addition to the energy and environmental implications, the solid solution of clathrate hydrate (CH4)1-x(CO2)x·5.75H2O provides a model system to study how the distinct bonding and shapes of CH4 and CO2 influence the structure and properties of the compound. High-resolution neutron diffraction was used to examine mixed CO2/CH4 gas hydrates. CO2-rich hydrates had smaller lattice parameters, which were attributed to the higher affinity of the CO2 molecule interacting with H2O molecules that form the surrounding cages, and resulted in a reduction in the unit-cell volume. Experimental nuclear scattering densities illustrate how the cage occupants and energy landscape change with composition. These results provide important insights on the impact and mechanisms for the structure of mixed CH4/CO2 gas hydrate. [ABSTRACT FROM AUTHOR]

Published

2015

9. Stoichiometry and temperature sensitivity of methanogenesis and CO2 production from saturated polygonal tundra in Barrow, Alaska.

Author

Roy Chowdhury, Taniya, Herndon, Elizabeth M., Phelps, Tommy J., Elias, Dwayne A., Gu, Baohua, Liang, Liyuan, Wullschleger, Stan D., and Graham, David E.

Subjects

TUNDRA ecology, PERMAFROST, MICROBIAL growth, ATMOSPHERIC carbon dioxide, TEMPERATURE effect, STOICHIOMETRY

Abstract

Arctic permafrost ecosystems store ~50% of global belowground carbon (C) that is vulnerable to increased microbial degradation with warmer active layer temperatures and thawing of the near surface permafrost. We used anoxic laboratory incubations to estimate anaerobic CO2 production and methanogenesis in active layer (organic and mineral soil horizons) and permafrost samples from center, ridge and trough positions of water-saturated low-centered polygon in Barrow Environmental Observatory, Barrow AK, USA. Methane ( CH4) and CO2 production rates and concentrations were determined at −2, +4, or +8 °C for 60 day incubation period. Temporal dynamics of CO2 production and methanogenesis at −2 °C showed evidence of fundamentally different mechanisms of substrate limitation and inhibited microbial growth at soil water freezing points compared to warmer temperatures. Nonlinear regression better modeled the initial rates and estimates of Q10 values for CO2 that showed higher sensitivity in the organic-rich soils of polygon center and trough than the relatively drier ridge soils. Methanogenesis generally exhibited a lag phase in the mineral soils that was significantly longer at −2 °C in all horizons. Such discontinuity in CH4 production between −2 °C and the elevated temperatures (+4 and +8 °C) indicated the insufficient representation of methanogenesis on the basis of Q10 values estimated from both linear and nonlinear models. Production rates for both CH4 and CO2 were substantially higher in organic horizons (20% to 40% wt. C) at all temperatures relative to mineral horizons (<20% wt. C). Permafrost horizon (~12% wt. C) produced ~5-fold less CO2 than the active layer and negligible CH4. High concentrations of initial exchangeable Fe( II) and increasing accumulation rates signified the role of iron as terminal electron acceptors for anaerobic C degradation in the mineral horizons. [ABSTRACT FROM AUTHOR]

Published

2015

10. Size tunable elemental copper nanoparticles: extracellular synthesis by thermoanaerobic bacteria and capping molecules.

Author

Gyoung Gug Jang, Jacobs, Christopher B., Gresback, Ryan G., Ivanov, Ilia N., Meyer, Harry M., Kidder, Michelle, Joshi, Pooran C., Jellison, Jr., Gerald E., Phelps, Tommy J., Graham, David E., and Ji-Won Moon

Abstract

Bimodal sized elemental copper (Cu) nanoparticles (NPs) were synthesized from inexpensive oxidized copper salts by an extracellular metal-reduction process using anaerobic Thermoanaerobacter sp. X513 bacteria in aqueous solution. The bacteria nucleate NPs outside of the cell, and they control the Cu2+ reduction rate to form uniform crystallites with an average diameter of 1.75 ± 0.46 mm after 3 days incubation. To control the size and enhance the air stability of Cu NPs, the reaction mixtures were supplemented with nitrilotriacetic acid as a chelator, and the surfactant capping agents oleic acid, oleylamine, ascorbic acid, or L-cysteine. Time-dependent UV-visible absorption measurements and XPS studies indicated well-suspended, bimodal colloidal Cu NPs (70-150 and 5-10 nm) with extended airstability up to 300 min and stable Cu NP film surfaces with 14% oxidation after 20 days. FTIR spectroscopy suggested that these capping agents were effectively adsorbed on the NP surface providing oxidation resistance under aqueous and dry conditions. Compared to previously reported Cu NP syntheses, this biological process substantially reduced the requirement for hazardous organic solvents and chemical reducing agents, while reducing the levels of Cu oxide impurities in the product. This process was highly reproducible and scalable from 0.01 to 1 L batches. [ABSTRACT FROM AUTHOR]

Published

2015

11. VI: SUBSURFACE AND LANDFILLS: Chapter 66: Drilling, Coring, and Sampling Subsurface Environments.

Author

KIEFT, THOMAS L., PHELPS, TOMMY J., and FREDRICKSON, JAMES K.

Published

2007

12. Trends and future challenges in sampling the deep terrestrial biosphere.

Author

Cole, David R., Wilkins, Michael J., Peterson, Lee, Pfiffner, Susan M., Phelps, Tommy J., Schrenk, Matthew O., Daly, Rebecca A., Wrighton, Kelly C., Mouser, Paula J., Trexler, Ryan, Sharma, Shihka, Biddle, Jennifer F., Denis, Elizabeth H., Fredrickson, Jim K., Kieft, Thomas L., and Onstott, Tullis C.

Subjects

BIOSPHERE, SUBSURFACE bacteria, DRILLING & boring, SHALE, MICROBIAL contamination

Abstract

Research in the deep terrestrial biosphere is driven by interest in novel biodiversity and metabolisms, biogeochemical cycling, and the impact of human activities on this ecosystem. As this interest continues to grow, it is important to ensure that when subsurface investigations are proposed, materials recovered from the subsurface are sampled and preserved in an appropriate manner to limit contamination and ensure preservation of accurate microbial, geochemical, and mineralogical signatures. On February 20th, 2014, a workshop on "Trends and Future Challenges in Sampling The Deep Subsurface" was coordinated in Columbus, Ohio by The Ohio State University and West Virginia University faculty, and sponsored by The Ohio State University and the Sloan Foundation's Deep Carbon Observatory. The workshop aims were to identify and develop best practices for the collection, preservation, and analysis of terrestrial deep rock samples. This document summarizes the information shared during this workshop. [ABSTRACT FROM AUTHOR]

Published

2014

13. Commercial DNA extraction kits impact observed microbial community composition in permafrost samples.

Author

Vishnivetskaya, Tatiana A., Layton, Alice C., Lau, Maggie C. Y., Chauhan, Archana, Cheng, Karen R., Meyers, Arthur J., Murphy, Jasity R., Rogers, Alexandra W., Saarunya, Geetha S., Williams, Daniel E., Pfiffner, Susan M., Biggerstaff, John P., Stackhouse, Brandon T., Phelps, Tommy J., Whyte, Lyle, Sayler, Gary S., and Onstott, Tullis C.

Subjects

NUCLEIC acid isolation methods, PERMAFROST, POLYMERASE chain reaction, BACTERIAL diversity, GENE targeting, RIBOSOMAL RNA, NUCLEOTIDE sequence

Abstract

The total community genomic DNA (g DNA) from permafrost was extracted using four commercial DNA extraction kits. The g DNAs were compared using quantitative real-time PCR (q PCR) targeting 16 S r RNA genes and bacterial diversity analyses obtained via 454 pyrosequencing of the 16 S r RNA ( V3 region) amplified in single or nested PCR. The Fast DNA® SPIN ( FDS) Kit provided the highest g DNA yields and 16 S r RNA gene concentrations, followed by Mo Bio Power Soil® ( PS) and Mo Bio Power Lyzer™ ( PL) kits. The lowest g DNA yields and 16 S r RNA gene concentrations were from the Meta- G- Nome™ ( MGN) DNA Isolation Kit. Bacterial phyla identified in all DNA extracts were similar to that found in other soils and were dominated by Actinobacteria, Firmicutes, Gemmatimonadetes, Proteobacteria, and Acidobacteria. Weighted Uni Frac and statistical analyses indicated that bacterial community compositions derived from FDS, PS, and PL extracts were similar to each other. However, the bacterial community structure from the MGN extracts differed from other kits exhibiting higher proportions of easily lysed β- and γ- Proteobacteria and lower proportions of Actinobacteria and Methylocystaceae important in carbon cycling. These results indicate that g DNA yields differ between the extraction kits, but reproducible bacterial community structure analysis may be accomplished using g DNAs from the three bead-beating lysis extraction kits. [ABSTRACT FROM AUTHOR]

Published

2014

14. Hexavalent Chromium Reduction under Fermentative Conditions with Lactate Stimulated Native Microbial Communities.

Author

Somenahally, Anil C., Mosher, Jennifer J., Yuan, Tong, Podar, Mircea, Phelps, Tommy J., Brown, Steven D., Yang, Zamin K., Hazen, Terry C., Arkin, Adam P., Palumbo, Anthony V., Van Nostrand, Joy D., Zhou, Jizhong, and Elias, Dwayne A.

Subjects

CHROMIUM removal (Water purification), FERMENTATION, LACTATES, GROUNDWATER microbiology, BIOREMEDIATION, ELECTRON donor-acceptor complexes, NUCLEOTIDE sequence, BIOREACTORS

Abstract

Microbial reduction of toxic hexavalent chromium (Cr(VI)) in-situ is a plausible bioremediation strategy in electron-acceptor limited environments. However, higher [Cr(VI)] may impose stress on syntrophic communities and impact community structure and function. The study objectives were to understand the impacts of Cr(VI) concentrations on community structure and on the Cr(VI)-reduction potential of groundwater communities at Hanford, WA. Steady state continuous flow bioreactors were used to grow native communities enriched with lactate (30 mM) and continuously amended with Cr(VI) at 0.0 (No-Cr), 0.1 (Low-Cr) and 3.0 (High-Cr) mg/L. Microbial growth, metabolites, Cr(VI), 16S rRNA gene sequences and GeoChip based functional gene composition were monitored for 15 weeks. Temporal trends and differences in growth, metabolite profiles, and community composition were observed, largely between Low-Cr and High-Cr bioreactors. In both High-Cr and Low-Cr bioreactors, Cr(VI) levels were below detection from week 1 until week 15. With lactate enrichment, native bacterial diversity substantially decreased as Pelosinus spp., and Sporotalea spp., became the dominant groups, but did not significantly differ between Cr concentrations. The Archaea diversity also substantially decreased after lactate enrichment from Methanosaeta (35%), Methanosarcina (17%) and others, to mostly Methanosarcina spp. (95%). Methane production was lower in High-Cr reactors suggesting some inhibition of methanogens. Several key functional genes were distinct in Low-Cr bioreactors compared to High-Cr. Among the Cr resistant microbes, Burkholderia vietnamiensis, Comamonas testosterone and Ralstonia pickettii proliferated in Cr amended bioreactors. In-situ fermentative conditions facilitated Cr(VI) reduction, and as a result 3.0 mg/L Cr(VI) did not impact the overall bacterial community structure. [ABSTRACT FROM AUTHOR]

Published

2013

15. Long-term solid-phase fate of co-precipitated U(VI)-Fe(III) following biological iron reduction by Thermoanaerobacter.

Author

MADDEN, ANDREW S., SWINDLE, ANDREW L., BEAZLEY, MELANIE J., JI-WON MOON, RAVEL, BRUCE, and PHELPS, TOMMY J.

Subjects

URANIUM, IRON, BIOGEOCHEMISTRY, SLURRY, FERRIC hydroxides, CRYSTALLIZATION

Abstract

The texture and mineralogy of solid phases resulting from biogeochemical metal reduction of U(VI)-FeOOH slurries was investigated over a period of four years. Solid-phase reaction products were analyzed with EXAFS, TEM, and XRD following fermentative reduction of uranium-loaded ferric hydroxide precursors with 0.01 and 0.05 cation mole fraction (CMF) U by cultures of Thermoanaerobacter sp. strain TOR-39. Only minor changes could be distinguished between 3 and 51 months for most slurries. Magnetite, goethite, uraninite, and minor akaganéite were present after 3 months at both U-CMFs. Akaganéite was not detected by XRD after 3 months, but was still observed by TEM after 50 months. Increasing uranium in the starting slurries led to a greater proportion of oxidized iron in the solid-phase products. Euhedral goethite and subhedral to euhedral magnetite were observed at all times. Uraninite was observed in clusters of <10 nm particles without any particular relationship to the iron minerals. HRTEM imaging indicated that even the smallest uraninite particles were well crystallized, with textures that remained consistent throughout the duration of experiments. X-ray absorption spectra after 3 months indicated 100% and 96.4% U(IV) in 0.01 and 0.05 CMF U slurries, respectively. EXAFS spectra were consistent with uraninite at both uranium levels, plus additional non-uraninite U(IV) for 0.05 CMF U. One 0.05 CMF U culture slurry was found to have a lower pH and a more oxidized final iron mineral assemblage; in this case uraninite was not observed by XRD, but large (101 nm average diameter) rounded uraninite grains were observed by TEM. These grains were observed in chains or aggregates often connected by necks, in textures suggestive of biological influence. HRTEM demonstrated each grain was composed of poorly oriented, primary, 2-5 nm uraninite crystallites. Uraninite crystal growth occurred by nanoparticle aggregation, but ripening was not observed even though incubation temperatures were held at 65 °C for 20 days. Thus, previous studies of biogenic nanoparticulate uraninite short-term reactivity are likely to be representative of systems aged over a period of years. [ABSTRACT FROM AUTHOR]

Published

2012

16. Microbes in thawing permafrost: the unknown variable in the climate change equation.

Author

Graham, David E, Wallenstein, Matthew D, Vishnivetskaya, Tatiana A, Waldrop, Mark P, Phelps, Tommy J, Pfiffner, Susan M, Onstott, Tullis C, Whyte, Lyle G, Rivkina, Elizaveta M, Gilichinsky, David A, Elias, Dwayne A, Mackelprang, Rachel, VerBerkmoes, Nathan C, Hettich, Robert L, Wagner, Dirk, Wullschleger, Stan D, and Jansson, Janet K

Subjects

PERMAFROST microbiology, CLIMATE change, METHANOBACTERIACEAE, HUMUS, MICROBIOLOGICAL synthesis, THERMOKARST, HYDROLOGY

Published

2012

17. Deep gold mines of South Africa: windows into the subsurface biosphere.

Author

Onstott, Tullis C., Tobin, K., Dong, H., DeFlaun, M. F., Fredrickson, James K., Bailey, T., Brockman, Fred J., Kieft, Thomas L., Peacock, Amy, White, David C., Balkwill, David, Phelps, Tommy J., and Boone, D. R.

Published

1997

18. Formation of magnetite and iron-rich carbonates by thermophilic iron-reducing bacteria.

Author

Zhang, Chuanlun, Vali, Hojatollah, Liu, Shi, Roh, Yul, Cole, Dave, Kirschvink, Joseph L., Onstott, Tullis C., McKay, David S., and Phelps, Tommy J.

Published

1997

19. Large-scale production of magnetic nanoparticles using bacterial fermentation.

Author

Ji-Won Moon, Rawn, Claudia J., Rondinone, Adam J., Love, Lonnie J., Yul Roh, Everett, S. Michelle, Lauf, Robert J., and Phelps, Tommy J.

Subjects

NANOPARTICLES, MAGNETITE, FERMENTATION, MICROBIOLOGICAL synthesis, ELECTRON microscopy, MICROBIOLOGY

Abstract

Production of both nano-sized particles of crystalline pure phase magnetite and magnetite substituted with Co, Ni, Cr, Mn, Zn or the rare earths for some of the Fe has been demonstrated using microbial processes. This microbial production of magnetic nanoparticles can be achieved in large quantities and at low cost. In these experiments, over 1 kg (wet weight) of Zn-substituted magnetite (nominal composition of ZnFeO) was recovered from 30 l fermentations. Transmission electron microscopy (TEM) was used to confirm that the extracellular magnetites exhibited good mono-dispersity. TEM results also showed a highly reproducible particle size and corroborated average crystallite size (ACS) of 13.1 ± 0.8 nm determined through X-ray diffraction ( N = 7) at a 99% confidence level. Based on scale-up experiments performed using a 35-l reactor, the increase in ACS reproducibility may be attributed to a combination of factors including an increase of electron donor input, availability of divalent substitution metal ions and fewer ferrous ions in the case of substituted magnetite, and increased reactor volume overcoming differences in each batch. Commercial nanometer sized magnetite (25–50 nm) may cost $500/kg. However, microbial processes are potentially capable of producing 5–90 nm pure or substituted magnetites at a fraction of the cost of traditional chemical synthesis. While there are numerous approaches for the synthesis of nanoparticles, bacterial fermentation of magnetite or metal-substituted magnetite may represent an advantageous manufacturing technology with respect to yield, reproducibility and scalable synthesis with low costs at low energy input. [ABSTRACT FROM AUTHOR]

Published

2010

20. Establishment and metabolic analysis of a model microbial community for understanding trophic and electron accepting interactions of subsurface anaerobic environments.

Author

Miller, Lance D., Mosher, Jennifer J., Venkateswaran, Amudhan, Yang, Zamin K., Palumbo, Anthony V., Phelps, Tommy J., Podar, Mircea, Schadt, Christopher W., and Keller, Martin

Subjects

MICROORGANISMS, BIOGEOCHEMICAL cycles, BIOTECHNOLOGY, ANAEROBIC bacteria, DESULFOVIBRIO vulgaris genetics

Abstract

Background: Communities of microorganisms control the rates of key biogeochemical cycles, and are important for biotechnology, bioremediation, and industrial microbiological processes. For this reason, we constructed a model microbial community comprised of three species dependent on trophic interactions. The three species microbial community was comprised of Clostridium cellulolyticum, Desulfovibrio vulgaris Hildenborough, and Geobacter sulfurreducens and was grown under continuous culture conditions. Cellobiose served as the carbon and energy source for C. cellulolyticum, whereas D. vulgaris and G. sulfurreducens derived carbon and energy from the metabolic products of cellobiose fermentation and were provided with sulfate and fumarate respectively as electron acceptors. Results: qPCR monitoring of the culture revealed C. cellulolyticum to be dominant as expected and confirmed the presence of D. vulgaris and G. sulfurreducens. Proposed metabolic modeling of carbon and electron flow of the threespecies community indicated that the growth of C. cellulolyticum and D. vulgaris were electron donor limited whereas G. sulfurreducens was electron acceptor limited. Conclusions: The results demonstrate that C. cellulolyticum, D. vulgaris, and G. sulfurreducens can be grown in coculture in a continuous culture system in which D. vulgaris and G. sulfurreducens are dependent upon the metabolic byproducts of C. cellulolyticum for nutrients. This represents a step towards developing a tractable model ecosystem comprised of members representing the functional groups of a trophic network. [ABSTRACT FROM AUTHOR]

Published

2010

21. Microbial formation of lanthanide-substituted magnetites by Thermoanaerobacter sp. TOR-39.

Author

Ji-Won Moon, Roh, Yul, Yeary, Lucas W., Lauf, Robert J., Rawn, Claudia J., Love, Lonnie J., and Phelps, Tommy J.

Subjects

IONS, POISONS, BIOTECHNOLOGY, BIOTECHNOLOGY research, RARE earth metals, SOLUTION (Chemistry), OXIDE minerals, MAGNETITE

Abstract

The potentially toxic effects of soluble lanthanide (L) ions, although microbially induced mineralization can facilitate the formation of tractable materials, has been one factor preventing the more widespread use of L-ions in biotechnology. Here, we propose a new mixed-L precursor method as compared to the traditional direct addition technique. L (Nd, Gd, Tb, Ho and Er)-substituted magnetites, L y Fe3 − y O4 were microbially produced using L-mixed precursors, L x Fe1 − x OOH, where x = 0.01–0.2. By combining lanthanides into the akaganeite precursor phase, we were able to mitigate some of the toxicity, enabling the microbial formation of L-substituted magnetites using a metal reducing bacterium, Thermoanaerobacter sp. TOR-39. The employment of L-mixed precursors enabled the microbial formation of L-substituted magnetite, nominal composition up to L0.06Fe2.94O4, with at least tenfold higher L-concentration than could be obtained when the lanthanides were added as soluble salts. This mixed-precursor method can be used to extend the application of microbially produced L-substituted magnetite, while also mitigating their toxicity. [ABSTRACT FROM AUTHOR]

Published

2007

22. Microbial uranium immobilization independent of nitrate reduction.

Author

Madden, Andrew S., Smith, April C., Balkwill, David L., Fagan, Lisa A., and Phelps, Tommy J.

Subjects

MICROBIAL ecology, URANIUM, NITRATES, BIOREMEDIATION, INDUSTRIAL contamination, BIOLOGICAL treatment of water

Abstract

At many uranium processing and handling facilities, including sites in the US Department of Energy (DOE) complex, high levels of nitrate are present as co-contamination with uranium in groundwater. The daunting prospect of complete nitrate removal prior to the reduction of uranium provides a strong incentive to explore bioremediation strategies that allow for uranium bioreduction and stabilization in the presence of nitrate. Typical in situ strategies involving the stimulation of metal-reducing bacteria are hindered by low-pH environments and require that the persistent nitrate must first and continuously be removed or transformed prior to uranium being a preferred electron acceptor. This work investigated the possibility of stimulating nitrate-indifferent, pH-tolerant microorganisms to achieve bioreduction of U(VI) despite nitrate persistence. Enrichments from U-contaminated sediments demonstrated nearly complete reduction of uranium with very little loss of nitrate from pH 5.7–6.2 using methanol or glycerol as a carbon source. Bacterial 16S rRNA genes were amplified from uranium-reducing enrichments (pH 5.7–6.2) and sequenced. Phylogenetic analyses classified the clone sequences into four distinct clusters. Data from sequencing and terminal-restriction fragment length polymorphism (T-RFLP) profiles indicated that the majority of the microorganisms stimulated by these enrichment conditions consisted of low G+C Gram-positive bacteria most closely related to Clostridium and Clostridium-like organisms. This research demonstrates that the stimulation of a natural microbial community to immobilize U through bioreduction is possible without the removal of nitrate. [ABSTRACT FROM AUTHOR]

Published

2007

23. Magnetic Properties of Biosynthesized Magnetite Nanoparticles.

Author

Yeary, Lucas W., Ji-Won Moon, Love, Lonnie J., Thompson, James R., Rawn, Claudia J., and Phelps, Tommy J.

Subjects

IRON ores, OXIDE minerals, NANOPARTICLES, MAGNETIC properties, TRANSMISSION electron microscopy, SOLUTION (Chemistry)

Abstract

Magnetic nanoparticles, which are unique because of both structural and functional elements, have various novel applications. The popularity and practicality of nanoparticle materials create a need for a synthesis method that produces quality particles in sizable quantities. This paper describes such a method, one that uses bacterial synthesis to create nanoparticles of magnetite. The thermophilic bacterial strain Thermoanaerobacter ethanolicus TOR-39 was incubated under anaerobic conditions at 65 °C for two weeks in aqueous solution containing Fe ions from a magnetite precursor (akaganeite). Magnetite particles formed outside of bacterial cells. We verified particle size and morphology by using dynamic light scattering, X-ray diffraction, and transmission electron microscopy. Average crystallite size was 45 nm. We characterized the magnetic properties by using a superconducting quantum interference device magnetometer; a saturation magnetization of 77 emu/g was observed at 5 K. These results are comparable to those for chemically synthesized magnetite nanoparticles. [ABSTRACT FROM AUTHOR]

Published

2005

24. The U-tube: A novel system for acquiring borehole fluid samples from a deep geologic CO2 sequestration experiment.

Author

Freifeld, Barry M., Trautz, Robert C., Kharaka, Yousif K., Phelps, Tommy J., Myer, Larry R., Hovorka, Susan D., and Collins, Daniel J.

Published

2005

25. A Modular Injection System, Multilevel Sampler, and Manifold for Tracer Tests.

Author

Mailloux, Brian J., Fuller, Mark E., Rose, George F., Onstott, Tullis C., DeFlaun, Mary F., Alvarez, Enrique, Hemingway, Chris, Hallet, R. Bruce, Phelps, Tommy J., and Griffin, Timothy

Subjects

GROUNDWATER, AQUIFERS, WATER temperature, GROUNDWATER monitoring, HYDROGEN-ion concentration

Abstract

Ground water injection and sampling systems were developed for bacterial transport experiments in both homogenous and heterogeneous unconsolidated, surficial aquifers. Two types of injection systems, a large single tank and a dynamic mixing tank, were designed to deliver more than 800 L of amended ground water to the aquifer over 12 hours, without altering the ground water temperature, pH, Eh, or dissolved gas composition. Two types of multilevel samplers (MLSs) were designed and installed. Permanent MLSs performed well for the homogenous surficial aquifer, but their installation procedure promoted vertical mixing, which could obfuscate experimental data obtained from vertically stratified, heterogeneous aquifers. A novel, removable MLS was designed to fit in 2- and 4-inch wells. Expandable O-rings between each sampling port hydraulically isolated each port for sample collection when a nut was tightened at the land surface. A low-cost vacuum manifold system designed to work with both MLS designs used 50 mL centrifuge tubes to efficiently sample 12 MLS ports with one peristaltic pump head. The integrated system was developed and used during four field campaigns over a period of three years. During each campaign, more than 3000 ground water samples were collected in less than one week. This system should prove particularly useful for ground water tracer, injection, and push-pull experiments that require high-frequency and/or high-density sampling. [ABSTRACT FROM AUTHOR]

Published

2003

26. A new experimental facility for investigating the formation and properties of gas hydrates under simulated seafloor conditions.

Author

Phelps, Tommy J., Peters, David J., Marshall, Simon L., West, Olivia R., Liang, Liyuan, Blencoe, James G., Alexiades, Vasilios, Jacobs, Gary K., Naney, Michael T., and Heck, Jack L.

Subjects

SIMULATION methods & models, PRESSURE vessels

Abstract

A seafloor process simulator (SPS) has been developed for experimental investigations of the physical, geochemical, and microbiological processes affecting the formation and stability of methane and carbon dioxide hydrates at temperatures and pressures corresponding to ocean depths of 2 km. The SPS is a corrosion-resistant pressure vessel whose salient characteristics are: (i) an operating range suitable for study of methane and carbon dioxide hydrates; (ii) numerous access and observation ports, and (iii) a large (0.0722 m3) internal volume. Initial experiments have shown that the SPS can be used to produce large amounts of high-purity methane hydrate over a wide range of experimental conditions. © 2001 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2001

27. Low-Substrate Regulated Microaerophilic Behavior as a Stress Response of Aquatic and Soil Bacteria.

Author

Mazumder, Raja, Pinkart, Holly C., Alban, Patrick S., Phelps, Tommy J., and Benoit, Robert B.

Subjects

BACTERIAL ecology, BIOMOLECULES, MICROBIOLOGY, LIPIDS, PSEUDOMONAS, FRESH water

Abstract

Low-substrate regulated microaerophilic behavior (LSRMB) was observed in 10–54% of the bacteria isolated from several fresh-water lakes or ponds, subsurface soils, activated sludge, and Antarctic dry valley soils. Five Pseudomonas and two Bacillus type species showed LSRMB. A subsurface Pseudomonas jessenii strain was used as a model to show the metabolic interaction between substrate and oxygen concentrations, cell band movement, and the appearance of unique stress lipids and proteins. When the oxygen in the P. jessenii culture medium was increased from 11% to 100% saturation under atmospheric condition, the concentration of 17:0 cyclopropane fatty acid, a stress indicator, increased five-fold, and four unique proteins were also detected. This stress response occurred only in low-substrate media. It is our hypothesis that LSRMB is a common but under-appreciated trait of many aquatic and soil bacteria. [ABSTRACT FROM AUTHOR]

Published

2000

28. Iron reduction by psychrotrophic enrichment cultures.

Author

Zhang, Chuanlun, Stapleton, Raymond D., Zhou, Jizhong, Palumbo, Anthony V., and Phelps, Tommy J.

Published

1999

29. Procedures for Sampling Deep Subsurface Microbial Communities in Unconsolidated Sediments.

Author

Russell, Brent F., Phelps, Tommy J., Griffin, William T., and Sargent, Kenneth A.

Published

1992

30. Grain size and depth constraints on microbial variability in coastal plain subsurface sediments.

Author

Zhang, Chuanlun, Palumbo, Anthony V., Phelps, Tommy J., Beauchamp, John J., Brockman, Fred J., Murray, Chris J., Parsons, Brian S., and Swift, Donald J. P.

Published

1998

31. Corrigendum: Active Anaerobic Archaeal Methanotrophs in Recently Emerged Cold Seeps of Northern South China Sea.

Author

Zhang, Tingting, Xiao, Xi, Chen, Songze, Zhao, Jing, Chen, Zongheng, Feng, Junxi, Liang, Qianyong, Phelps, Tommy J., and Zhang, Chuanlun

Subjects

METHANOTROPHS, SEEPAGE, MARINE engineers, ENGINEERING laboratories

Abstract

Keywords: anaerobic methanotrophs; methane; anaerobic oxidation of methane; cold seeps; calyptogena EN anaerobic methanotrophs methane anaerobic oxidation of methane cold seeps calyptogena N.PAG N.PAG 1 02/15/21 20210211 NES 210211 In the published article, there was an error in affiliation 3. Instead of "Southern Marine Science and Engineering Guangdong Laboratory, Guangzhou, China", it should be "Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou), Guangzhou, China." Anaerobic methanotrophs, methane, anaerobic oxidation of methane, cold seeps, calyptogena. [Extracted from the article]

Published

2021

32. Filtration of Bioaerosols Using a Granular Metallic Filter with Micrometer-Sized Collectors.

Author

Damit, Brian, Bischoff, Brian L., Phelps, Tommy J., Wu, Chang-Yu, and Cheng, Meng-Dawn

Subjects

GRANULAR materials, MICROBIOLOGICAL aerosols, MEMBRANE filters, MICROMETERS, MICROORGANISMS

Abstract

Experimental studies with granular bed filters composed of sized metallic granules have demonstrated their use in aerosol filtration. However, the effectiveness of metallic membrane filters against bioaerosols has not been established. In this work, the filtration efficiency and filter quality of these filters against airborne B. subtilis endospore and MS2 virus were determined as a function of face velocity and loading time. In experiments, a physical removal efficiency greater than 99.9% and a viable removal efficiency greater than 99.999% were observed for both bacterial spore and viral aerosols. A lower face velocity produced both higher collection efficiency and filter quality for virus but was not a statistically significant factor for spore filtration. Although the filter had high filtration efficiency of the test bioaerosols, its high pressure drop resulted in a low filter quality (). Overall, filters with micrometer-sized collectors capture bioaerosols effectively but their applications in aerosol filtration may be limited by their high pressure drop. [ABSTRACT FROM AUTHOR]

Published

2014

33. ChemInform Abstract: Drilling, Coring, and Sampling Subsurface Environments.

Author

Kieft, Thomas L., Phelps, Tommy J., and Fredrickson, James K.

Published

2008