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2023 |
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Co-deployment of Passive Samplers and Mussels Reveals Major Source of Ongoing PCB Inputs to the Anacostia River in Washington, DC. NJ Lombard, M Bokare, R Harrison, L Yonkos, A Pinkney, D Murali, U. Ghosh. Environ. Sci. Technol. 57, 3, 1320–1331, 2023. |
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Seasonal trends of PCBs in air over Washington DC reveal localized urban sources and the influence of Anacostia River. M Bokare, N Lombard, S Magee, D Murali, U Ghosh. Environmental Pollution 316, 120490, 2023. |
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2022 |
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Equilibrium Porewater Measurement of PCBs and PAHs Using Direct Water Extraction and Comparison with Passive Sampling. Yan, S.; Bokare, M; Ghosh, U. Environ. Sci. Technol. Environmental Science & Technology 56 (14), 10020-10029, 2022. |
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Interlaboratory Study of Polyethylene and Polydimethylsiloxane Polymeric Samplers for Ex Situ Measurement of Freely-Dissolved Hydrophobic Organic Compounds in Sediment Porewater. Lotufo, G.; Michalsen, M.; Reible, D.D.; Gschwend, P.M.; Ghosh, U.; Kennedy, A.J.; Kerns, K.M.; Rakowska, M.I.; Odetayo, A.; MacFarlane, J.K; Yan, S.; Bokare, M. Environ. Toxicol. Chem. 41 (8), 1885-1902, 2022. |
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Evaluation of Methylmercury Uptake Mechanisms of a Novel Activated Carbon-Based Equilibrium Passive Sampler for Prediction of Porewater Methylmercury. Washburn, S.J.; Damond, J.; Sanders, J.P.; Gilmour, C.C.; Ghosh, U. Environ. Toxicol. Chem. 41 (9), 2052-2064, 2022. |
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Comparative study on polychlorinated biphenyl sorption to activated carbon and biochar and the influence of natural organic matter. Zhou, Y.; Miao, D.; Gomez-Eyles, J.L.; Ghosh, U.; Bi, M.; Li, J.; Ren, F. Chemosphere, 287 132239, 2022. |
2021 |
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Deconvoluting Thermodynamics from Biology in the Aquatic Food Web Model. U. Ghosh, M. Bokare, F.A.P.C. Gobas. Environ. Toxicol. Chem. 40, 2145-2155. 2021. |
2020 |
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Development of a novel equilibrium passive sampling device for methylmercury in sediment and soil porewaters. Sanders, J.P.; Alyssa McBurney. A.; Gilmourc, C.C.; Schwartz, G.E.; Kane Driscoll, S.B.; Brown, S.S.; Ghosh, U. Environ. Toxicol. Chem. 39, 323–334. 2020. |
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Full Scale Application of Activated Carbon to Reduce Pollutant Bioavailability in a 5-Acre Lake. Patmont, E.; Jalalizadeh, M.; Needham, T.; Vance, J.; Greene, R.; Cargill, J.; Ghosh, U. ASCE J. Env. Engr. 146(5): 04020024. 2020. |
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Passive sampling protocol for ex situ determination of freely dissolved concentrations of hydrophobic organic chemicals in sediments and soils: Basis for interpreting toxicity and assessing bioavailability, risks, and remediation necessity. M.T.O. Jonker, R. M. Burgess, U. Ghosh, P.M. Gschwend, S.E. Hale, R. Lohmann, M.J. Lydy, K.A. Maruya, D. Reible, F. Smedes. Nature Protocols. Published online 20 April 2020. DOI: https://doi.org/10.1038/S41596-020-0311-Y |
2019 |
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A Pilot-Scale Field Study: In Situ Treatment of PCB-Impacted Sediments with Bioamended Activated Carbon. Payne, R.B.; Ghosh, U.; May, H.D.; Marshall, C.W.; Sowers, K.R. Environ. Sci. Technol., 53, 2626-2634. 2019. |
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Bioaccumulation in Functionally Different Species: Ongoing Input of PCBs with Sediment Deposition to Activated Carbon Remediated Beds. Gidley, P.T.; Kennedy, A.J.; Lotufo, G.R.; Wooley, A.H.; Melby. N.L.; Ghosh, U.; Burgess, R.M.; Mayer, P.; Fernandez, L.A.; Schmidt, S.N.; Wang, A.P.; Ruiz, C.E.; and Bridges, T.S. Environ. Toxicol. Chem. 38(10):2326-2336. 2019. |
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Response to “Comment on ‘A Pilot-Scale Field Study: In Situ Treatment of PCB-Impacted Sediments with Bioamended Activated Carbon’ Rayford B. Payne, Upal Ghosh, Harold D. May, Christopher W. Marshall, and Kevin R. Sowers. Environ. Sci. Technol., 53, 6104-6105, 2019. |
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Kinetics of PCB Microbial Dechlorination Explained by Freely Dissolved Concentration in Sediment Microcosms. Needham, T.P.; Payne, R.B.; Sowers, K.R.; Ghosh, U. Environ. Sci. Technol. 53, 13, 7432-7441. 2019 |
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Four decades since the ban, old urban wastewater treatment plant remains a dominant source of PCBs to the environment. Needham, T.P. and Ghosh, U. Environmental Pollution 246, 390-397. 2019. |
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Impact of Dissolved Organic Matter on Mercury and Methylmercury Sorption to Activated Carbon in Soils: Implications for Remediation. Grace E. Schwartz, James P. Sanders, Alyssa McBurney, Upal Ghosh, Cynthia C. Gilmour. Environ. Sci: Proc. Impacts. 21, 485-496, 2019 |
2018 |
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Evaluation of passive sampling polymers and non-equilibrium adjustment methods in a multi-year surveillance of sediment porewater PCBs. James P. Sanders, Natasha A. Andrade, Upal Ghosh. Environ. Toxicol. Chem. 37, 2496–2505, 2018. |
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Persistent reductions in the bioavailability of PCBs at a tidally inundated Phragmites australis marsh amended with activated carbon. James P. Sanders, Natasha A. Andrade, Charles A. Menzie, C. Bennett Amos, Cynthia C. Gilmour, Elizabeth A. Henry, Steven S. Brown, Upal Ghosh. Environ. Toxicol. Chem. 37, 2487–2495, 2018. |
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Enhanced biochars can match activated carbon performance in sediments with high native bioavailability of PCBs. J.L. Gomez-Eyles and U. Ghosh. Chemosphere, 203, 179-187, 2018. |
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Advancing the use of passive sampling in risk assessment and management of contaminated sediments: Results of an international passive sampling inter-laboratory comparison. Michiel T.O. Jonker, Stephan A. van der Heijden, Dave Adelman, Jennifer N. Apell, Robert M. Burgess, Yongju Choi, Loretta A. Fernandez, Geanna M. Flavetta, Upal Ghosh, Philip M. Gschwend, Sarah E. Hale, Mehregan Jalalizadeh, Mohammed Khairy, Mark A. Lampi, Wenjian Lao, Rainer Lohmann, Michael J. Lydy, Keith A. Maruya, Samuel A. Nutile, Amy M.P. Oen, Magdalena I. Rakowska, Danny Reible, Tatsiana P. Rusina, Foppe Smedes, and Yanwen Wu. Environ. Sci. Technol. 52(6):3574-3582. 2018 |
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Activated carbon thin-layer placement as an in situ mercury remediation tool in a Penobscot River salt marsh Cynthia Gilmour, Tyler Bell, Ally Soren, Georgia Riedel, Gerhardt Riedel, Dianne Kopec, Drew Bodaly, Upal Ghosh. Science of the Total Environment 621, 839–848. 2018. |
2017 |
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Cross Validation of Two Partitioning-Based Sampling Approaches in Mesocosms Containing PCB Contaminated Field Sediment, Biota, and Activated Carbon Amendment. Stine N. Schmidt, Alice P. Wang, Philip T. Gidley, Allyson H. Wooley, Guilherme R. Lotufo, Robert M. Burgess, Upal Ghosh, Loretta A. Fernandez, and Philipp Mayer. Environ. Sci. Technol. 51, 9996-10004, 2017. |
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Assimilation Efficiency of Sediment-Bound PCBs Ingested by Fish Impacted by Strong Sorption. Hilda Fadaei, Ernest Williams, Allen Place, John Connolly, and Upal Ghosh. Environ. Toxicol. Chem. 36, 3480-3488, 2017. |
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Mesocosm Studies on the Efficacy of Bioamended Activated Carbon for Treating PCB-Impacted Sediment. Rayford B Payne, Upal Ghosh, Harold D May, Christopher W. Marshall, and Kevin R Sowers. Environ. Sci. Technol. 51, 18, 10691-10699, 2017. |
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Analysis of Measurement Errors in Passive Sampling of Porewater PCB Concentrations under Static and Periodically Vibrated Conditions. M. Jalalizadeh and Upal Ghosh. Environ. Sci. Technol. 51, 7018-7027, 2017. |
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Differential bioavailability of polychlorinated biphenyls associated with environmental particles: Microplastic in comparison to wood, coal and biochar. Beckingham B, Ghosh, U. Environmental Pollution, 2017, 220, 150-158. |
2016 |
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In situ passive sampling of sediment porewater enhanced by periodic vibration. Jalalizadeh, M. and Ghosh, U. Environ. Sci. Technol. 2016, 50, 8741–8749. |
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Effect of PAH source materials and soil components on partitioning and dermal uptake. Xia, H., Gomez-Eyles, J.L., Ghosh, U. Environ. Sci. Technol. Dec 2016, 50, 3444–3452. |
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Oral bioavailability and dermal absorption of PAHs from soil – state of the science. Ruby, M.V., Gomez-Eyles, J.L., Ghosh, U., Roberts, S.M., Tomlinson, P., Menzie, C., Kissel, J.C., Bunge, A.L., Lowney, Y.W. Environ. Sci. Technol. 2016, 50, 2151–2164. |
2015 |
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Measuring and modeling the effect of PCB bioavailability changes in sediments on bioaccumulation in fish. Fadaei H., Watson, A., Place, A., Connolly, J., and Ghosh, U. Environ. Sci. Technol. 2015, 49, 12405–12413. |
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Oral bioavailability and dermal absorption of PAHs from soil – state of the science. Ruby, M.V., Gomez-Eyles, J.L., Ghosh, U., Roberts, S.M., Tomlinson, P., Menzie, C., Kissel, J.C., Bunge, A.L., Lowney, Y.W. Submitted to Environ. Sci. Technol. In press 2015. |
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In-Situ Sediment Treatment Using Activated Carbon: A Demonstrated Sediment Cleanup Technology. In Press, Integr. ENvir. Assmnt. Manage. 2014.
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2014 |
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Nathalie J. Lombard, Upal Ghosh, Birthe Kjellerup, Kevin Sowers. Kinetics and threshold level of dechlorination activity by the anaerobic
ultramicrobacterium Dehalobium Chlorocoercia DF-1. Environ. Sci. Technol. 48, 4353-4360, 2014. |
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Passive Sampling Methods for Contaminated Sediments: Practical Guidance for Selection, Calibration and Implementation. Ghosh U, Kane Driscoll S, Burgess R, Gobas
FAPC, Maruya, K, Jonker C, Gala W, Choi Y, Beegan C, Apitz S, Mortimer M, Reible D. Integr Environ Assess Manage. 10, 210-223, 2014. |
2013 |
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Evaluation of biochars and activated carbons for in situ remediation of sediments impacted with organics, mercury and methylmercury. Jose L. Gomez-Eyles**, Carmen Yupanqui*, Barbara Beckingham*, Georgia Riedel, Cynthia Gilmour, and Upal Ghosh. Environ. Sci. Technol. 47, 13721-13729, 2013.
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Activated carbon mitigates mercury and methylmercury bioavailability in
contaminated sediments. Cynthia C. Gilmour, Georgia S. Riedel,
Gerhardt Riedel, Seokjoon Kwon**, Richard Landis, Steven S. Brown,
Charles A. Menzie, Elizabeth A. Henry, and Upal Ghosh. Environ. Sci. Technol. 47, 13001-13010,
2013.
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Observations of limited secondary effects with activated carbon amendment
in river sediments. Beckingham, Barbara*, Ghosh, Upal, Buys, David,
and VanDewalker, Heather. Environ. Toxicol. Chem. 32, 1504-1515,
2013.
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Polyoxymethylene passive samplers to monitor changes in bioavailability
and diffusive flux of PCBs after activated carbon amendment to
sediment in the field. Barbara Beckingham*, and Upal Ghosh. Chemosphere.
91, 1401-1407.
2013.
|
2012 |
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Spatial distribution of PCB dechlorinating bacteria and activities in
contaminated soil. Birthe Kjellerup, Piuly Paul, Upal Ghosh, Harold May
and Kevin Sowers. Applied and Environmental Soil Science. Article ID 584970,
2012.
|
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Transport of Polycyclic Aromatic Hydrocarbons in Amended Sediment Caps.
Philip Gidley*, Seokjoon Kwon**, Alexander Yakirevich, Victor Magar, Upal
Ghosh. Environ. Sci. Technol., 46, 5032-5039, 2012.
|
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Investigating differential binding of chlorinated dioxins and furans in
soil and soil components using selective supercritical fluid extraction.
Steve Hawthorne, Yunzhou Chai, John W. Davis, Michael Wilken, and Upal Ghosh.
Chemosphere. 88, 261-269, 2012.
|
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Sorption of organic compounds to fresh and field-aged activated carbons in soils and sediments. Amy M.P. Oen, Marie Elmquist Kruså,
Barbara Beckingham*, Upal Ghosh, Richard G. Luthy, Thomas Hartnik, Thomas
Henriksen, Gerard Cornelissen. Environ. Sci. Technol., 46, 810–817,
2012.
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2011 |
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Effectiveness of Activated Carbon and Biochar in Reducing the Availability
of Polychlorinated Dibenzo-p-dioxins/dibenzofurans in Soils. Yunzhou Chai,
Rebecca J. Currie, John W. Davis, Michael Wilken, Greg D. Martin, Vyacheslav
N. Fishman, and Upal Ghosh. Environ. Sci. Technol., 46, 1035-1043, 2011.
|
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Field scale reduction of PCB bioavailability with activated carbon amendment
to river sediments. Barbara Beckingham* and Upal Ghosh. Environ. Sci. Technol.,
45, 10567–10574, 2011.
|
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Influence of Activated Carbon Amendment on the Accumulation and Elimination of PCBs in the Earthworm Eisenia fetida. P. Paul*, and U. Ghosh. Environmental Pollution, 159, 3763-3768, 2011.
|
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In-situ sorbent amendments: A new direction in contaminated sediment management. Upal Ghosh, Richard G. Luthy, Gerard Cornelissen, David Werner, Charles A. Menzie. Environ. Sci. Technol. Feature Article, 45, 1163–1168. 2011.
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Study of the biouptake of labeled single walled carbon nanotubes using fluorescence based method. Minghui Yang, Seokjoon Kwon, Yordan Kostov, Avraham Rasooly, Govind Rao, and Upal Ghosh. Environ. Chem. Letters. 9, 235-241, 2011.
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2010 |
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Comparison of field vs. laboratory exposures of L. variegatus to PCB impacted river sediments. Barbara Beckingham and Upal Ghosh. Environ. Toxicol. Chem., 29, 2851-2858, 2010.
|
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Polychlorinated biphenyl sorption and availability in field-contaminated
sediments. Sarah E. Hale, Seokjoon Kwon**, Upal Ghosh, Richard
G. Luthy, David Werner. Environ. Sci. Technol. 44, 2809-2815, 2010.
|
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Bioaccumulation of polychlorinated dibenzo-p-dioxins/dibenzofurans in E. foetida from floodplain soils and the effect of activated carbon amendment. Sonja K. Fagervold, Yunzhou Chai, John W. Davis, Michael Wilken, and Upal Ghosh. Environ. Sci. Technol. 44, 5546-5552, 2010
|
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Role of Black Carbon in the Distribution of Polychlorinated Dibenzo-p-dioxins/dibenzofurans in Aged Field-contaminated Soils. Yunzhou Chai, John W. Davis, Michael Wilken, Greg D Martin, Daniel M. Mowery, and Upal Ghosh. Chemosphere., 82, 639-647, 2010.
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Particle-Scale measurement of PAH aqueous equilibrium partitioning in Impacted Sediments. Upal Ghosh and Steve Hawthorne, Environ. Sci. Technol. 44, 1204-1210, 2010.
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Polychlorinated biphenyl sorption to activated carbon and the attenuation caused by sediment. Sarah Hale, Seokjoon Kwon, Upal Ghosh, and David Werner. Global NEST Journal, Global NEST Journal, 12, 318-326, 2010.
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Evaluation of sorbent amendments for in situ remediation of metal contaminated sediments. Seokjoon Kwon, Jeff Thomas, Brian E. Reed, Laura Levine, Victor S. Magar, and Upal Ghosh. Environ. Toxicol. Chem., 29, 1883-1892, 2010.
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2009 |
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Removal and Fate of Polycyclic Aromatic Hydrocarbon Pollutants in an Urban
Stormwater Bioretention Facility, C. DiBlasi, C., H. Li, A.P. Davis,
U. Ghosh. Environmental Science and Technology. 43, 494-502, 2009.
|
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Quantification of activated carbon contents in soils and sediments
using chemothermal and wet oxidation methods. Braendli, Rahel;
Bergsli, Anders; Ghosh, Upal; Hartnik, Thomas; Breedveld, Gijsbert;
Cornelissen, Gerard. Environmental Pollution. 157, 3465-3470, 2009. |
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Field application of activated carbon amendment for in-situ stabilization
of polychlorinated biphenyls in marine sediment. Cho, Y., Ghosh,
U., Kennedy, A. J., Grossman, A., Ray, G.; Tomaszewski, J. E.,
Smithenry, D., Bridges,
T. S., Luthy, R. G. Environ. Sci. Technol. 43, 3815-3823,
2009. |
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Modeling PCB Mass Transfer and Bioaccumulation in a Freshwater Oligochaete
Before and After Amendment of Sediment with Activated Carbon, X.
Sun, D. Werner, Ghosh, U. Environmental Science
and Technology. 43, 1115-1121, 2009. |
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Pilot plant experiences using physical and biological treatment steps for the remediation of groundwater from a former MGP site. T. Wirthensohn1, P. Schoeberl, U. Ghosh, and W. Fuchs. In press, Journal of Hazardous Materials, 163, 43-52, 2009.
|
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Measurement of Activated Carbon and Other Black Carbons in Sediments. Adam Grossman, and Upal Ghosh. Chemosphere, 75, 469-475, 2009. |
2008 |
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Site specific microbial communities in three PCB-impacted sediments are associated with different in situ dechlorinating activities. B.V. Kjellerup, X. Sun, U. Ghosh, H.D. May, K.R. Sowers. Environ. Microbiol., 10, 1296-1309, 2008. |
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The effect of activated carbon on partitioning, desorption, and biouptake
of native PCBs in four freshwater sediments, X. Sun, U. Ghosh.
Environ. Toxicol. Chem. 27, 2287-2295, 2008 |
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|
2007 |
 |
PCB Bioavailability Control in Lumbriculus variegatus Through Different
Modes of Activated Carbon Addition to Sediments. Xueli SUn and
Upal Ghosh. Environ. Sci. Technol. 41, 4774-4780, 2007. |
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The Role of Black Carbon in Influencing Availability of PAHs in Sediments.
U. Ghosh. Human and Ecological Risk Assessment. 13: 276–285, 2007. |
|
 | Field methods for amending marine sediment with activated carbon and assessing treatment effectiveness. Y-M. Cho, D.W. Smithenry, U. Ghosh, A.J. Kennedy, R.N. Milward, T.S. Bridges, R.G. Luthy. Marine Environment Research. 64, 541–555, 2007. |
2006 |
 |
Modeling Polychlorinated Biphenyl Mass Transfer after Amendment of Contaminated
Sediment with Activated Carbon. D. Werner, U. Ghosh, and R. G.
Luthy. Environ. Sci. Technol. 40, 4211-4218., 2006. |
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Role of Weathered Coal Tar Pitch in the Partitioning of Polycyclic Aromatic Hydrocarbons in Manufactured Gas Plant Site Sediments. M.F. Khalil,
U. Ghosh, J.P. Kreitinger. Environ. Sci. Technol. 40, 5681-5687, 2006. |
2005 |
 | The Effects of Dose and Particle Size on Activated Carbon Treatment to Sequester polychlorinated biphenyls and polyaromatic hydrocarbons in Marine Sediments. J.R. Zimmerman, D. Werner, U. Ghosh, R.N. Millward, T.S. Bridges, R.G. Luthy. Environmental Toxicology and Chemistry, 24, 1594-1601, 2005. |
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Addition
of Activated Carbon to Sediments to Reduce PCB Bioaccumulation
by a Polychaete (Neanthes arenaceodentata) and an Amphipod (Leptocheirus
plumulosus).
R.N. Millward, T.S. Bridges, U. Ghosh, J.R. Zimmerman, R.G. Luthy.
Environ Sci. Technol. 39, 2880-2887, 2005. |
 | Effect of Oil and Grease on PCB Phase Partitioning During Land Biotreatment of PCB-Impacted Sediment. S.W. McNamara, U. Ghosh, D.A. Dzombak, A.S. Weber, J.S. Smith, and R.G. Luthy. Accepted for publication in ASCE Journal of Environmental Engineering, 278-286, Feb, 2005. |
 | Response to comment on: "Addition of carbon sorbents to reduce PCB and PAH bioavailability in marine sediments. Physicochemical tests. J.R. Zimmerman, U. Ghosh, R.G. Luthy, R.N. Millward, T.S. Bridges. J.R. Zimmerman, U. Ghosh, R.G. Luthy, R.N. Millward, T.S. Bridges. Environ Sci. & Technol, 39, 1199-1200, 2005. |
2004 |
 | Addition of carbon sorbents to reduce PCB and PAH bioavailability in marine sediments. Physicochemical tests. J.R. Zimmerman, U. Ghosh, R.G. Luthy, R.N. Millward, T.S. Bridges. Accepted for publication in Environ Sci. & Technol, 38, 5458-5664, 2004 |
 | Thermal Programmed Desorption (TPD) of PAHs From Mineral and Organic Surfaces. Talley, J.W., Ghosh, U., Tucker, S., Furey, J., and Luthy, R.G. Environmental Engineering Science. 21, 647-660, 2004. |
2003 |
 | PAH Sorption Mechanism and Partitioning Behavior in Lampblack-Impacted Soils from Former Oil-Gas Plant Sites. Lei Hong, Upal Ghosh, Tania Mahajan, Richard N. Zare, and Richard G. Luthy. Environ Sc. & Technol., 37, 3625-3634, 2003. |
 | PCB and PAH Speciation Among Particle Types in Contaminated Sediments and Effects on PAH Bioavailability. U. Ghosh, J. Zimmerman, R. G. Luthy. Environ. Sci. & Technol., 37, 2209-2217, 2003. |
2002 |
 | Particle-Scale Understanding of the Bioavailability of PAHs in Sediment. J.W. Talley, U. Ghosh, S.G. Tucker, J.S. Furey, R.G. Luthy, Environ. Sci. & Technol., Special issue in honor of James J. Morgan, 36, 477-483, 2002. |
 | Contaminated Aquatic Sediments: A literature Review. U. Ghosh. Water Environment Research Literature Review, September/October 2002, (64). |
2001 |
 | Particle-scale Investigation of PAH Desorption Kinetics and Thermodynamics from Sediments. U. Ghosh, J.W. Talley, R.G. Luthy, Environ. Sci. & Technol., 35, 3468-3475, 2001. |
 | Microscale Detection of Polychlorinated Biphenyls Using Two-Step Laser Mass Spectrometry. T.B. Mahajan, U. Ghosh, R.N. Zare, R.G. Luthy. International Journal of Mass Spec. 212, 41-48, 2001. |
 | Microprobe Laser Mass Spectrometry Studies of Polycyclic Aromatic Hydrocarbon Distributions on Harbor Sediments and Coals. J.S. Gillette, U. Ghosh, T. Mahajan, R.G. Luthy, and R.N. Zare. Israel Journal of Chemistry, 41, 105-110, 2001. |
2000 |
 | Microscale Location, Characterization, and Association of Polycyclic Aromatic Hydrocarbons on Harbor Sediment Particles. U. Ghosh, R.G. Luthy, J.S. Gillette and R.N. Zare. Environ. Sci. & Technol., 34, 1729-1736, 2000. |
 | Relationship Between PCB Desorption Equilibrium, Kinetics, and Availability During Land Biotreatment. U. Ghosh, A.S. Weber, J.N. Jensen, J.R. Smith. Environ. Sci. & Technol., 34, 2542-2548, 2000. |
1999 |
 | Congener Level PCB Desorption Kinetics of Field Contaminated Sediments. U. Ghosh, A.S. Weber, J.N. Jensen, J.R. Smith. Journal of Soil Contamination, vol. 8, no. 5, 1999. |
 | Granular Activated Carbon (GAC) and Biological Activated Carbon (BAC) Treatment of Waters Containing PCBs and Particulates. U. Ghosh, A.S. Weber, J.N. Jensen, J.R. Smith. Water Environment Research, vol. 71, no. 2, 1999. |
1995-1998 |
 | PCB Congener Distribution in Aqueous Solution Prepared by Glass Bead Generator Column. U. Ghosh, A.S. Weber, J.N. Jensen, J.R. Smith. Water Research, vol. 32, no. 5, 1998. |
 | Surface Aeration. J. Atkinson, S. Blair, S. Taylor, U. Ghosh. ASCE Journal of Environmental Engineering, vol. 12, no. 1, 1995. |
 | Economic Analysis and Ecological Impacts of Fish and Shellfish Industry in India. V.K. Sharma, U. Ghosh, G. S. Haripriya. Encology, vol. 11, no. 10, 1997. |
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