Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/springer-journals/interplay-of-transport-processes-and-interfacial-chemistry-affecting-Ehjr1VAClD
References (75)
-
E. Nakayama, Hiroyuki Tokoro, T. Kuwamoto, T. Fujinaga (1981)
Dissolved state of chromium in seawaterNature, 290
-
A. Gröhlich, M. Langer, M. Mitrakas, A. Zouboulis, I. Katsoyiannis, M. Ernst (2017)
Effect of organic matter on Cr(VI) removal from groundwaters by Fe(II) reductive precipitation for groundwater treatmentWater, 9
-
F. Richard, A. Bourg (1991)
Aqueous geochemistry of chromium: A reviewWater Research, 25
-
Yuanyuan Liu, Fen Xu, Chongxuan Liu (2017)
Coupled Hydro-Biogeochemical Processes Controlling Cr Reductive Immobilization in Columbia River Hyporheic Zone.Environmental science & technology, 51 3
-
D. Dzombak, F. Morel (1990)
Surface Complexation Modeling: Hydrous Ferric Oxide -
J. Zachara, D. Girvin, R. Schmidt, C. Resch (1987)
Chromate adsorption on amorphous iron oxyhydroxide in the presence of major groundwater ions.Environmental science & technology, 21 6
-
G. Dönmez, Z. Aksu (2002)
Removal of chromium(VI) from saline wastewaters by Dunaliella speciesProcess Biochemistry, 38
-
C. Pan, L. Troyer, J. Catalano, D. Giammar (2016)
Dynamics of Chromium(VI) Removal from Drinking Water by Iron Electrocoagulation.Environmental science & technology, 50 24
-
C. McClain, S. Fendorf, Shane Johnson, A. Menendez, K. Maher (2019)
Lithologic and redox controls on hexavalent chromium in vadose zone sediments of California’s Central ValleyGeochimica et Cosmochimica Acta
-
M. Mullet, Sophie Boursiquot, J. Ehrhardt (2004)
Removal of hexavalent chromium from solutions by mackinawite, tetragonal FeSColloids and Surfaces A: Physicochemical and Engineering Aspects, 244
-
R. Wilkin, C. Su, R. Ford, C. Paul (2005)
Chromium-removal processes during groundwater remediation by a zerovalent iron permeable reactive barrier.Environmental science & technology, 39 12
-
Jennylynn Balmer (2018)
Hexavalent ChromiumWorkplace Health & Safety, 66
-
Peng Liao, C. Pan, Wenyu Ding, Wenlu Li, S. Yuan, J. Fortner, D. Giammar (2020)
Formation and Transport of Cr(III)-NOM-Fe Colloids upon Reaction of Cr(VI) with NOM-Fe(II) Colloids at Anoxic-Oxic Interfaces.Environmental science & technology
-
L. Palma, N. Verdone, G. Vilardi (2018)
Kinetic Modeling of Cr(VI) Reduction by nZVI in Soil: The Influence of Organic Matter and Manganese OxideBulletin of Environmental Contamination and Toxicology, 101
-
T. Harif, M. Khai, A. Adin (2012)
Electrocoagulation versus chemical coagulation: coagulation/flocculation mechanisms and resulting floc characteristics.Water research, 46 10
-
M Mullet, S Boursiquot, J J Ehrhardt (2004)
Removal of hexavalent chromium from solutions by mackinawite, tetragonal FeS. Colloids and SurfacesA, Physicochemical and Engineering Aspects, 244
-
Xiaohong Guan, Haoran Dong, Jun Ma, I. Lo, Xiaomin Dou (2011)
Performance and mechanism of simultaneous removal of chromium and arsenate by Fe(II) from contaminated groundwaterSeparation and Purification Technology, 80
-
P. Nico, R. Zasoski (2000)
Importance of Mn(III) Availability on the Rate of Cr(III) Oxidation on δ-MnO2Environmental Science & Technology, 34
-
L. Eary, D. Rai (1988)
Chromate removal from aqueous wastes by reduction with ferrous ion.Environmental science & technology, 22 8
-
Yan Xiong, Jie Chen, M. Duan, Xiang Li, Jun Li, Can Zhang, Shenwen Fang, Ruihua Liu, Run Zhang (2019)
Insight into adsorption-interaction mechanism of Cr(VI) at silica adsorbent surface by evanescent wave measurement.Langmuir : the ACS journal of surfaces and colloids
-
Karen Murray, B. Tebo (2007)
Cr(III) is indirectly oxidized by the Mn(II)-oxidizing bacterium Bacillus sp. strain SG-1.Environmental science & technology, 41 2
-
S. Loyaux-Lawniczak, P. Refait, J. Ehrhardt, P. Lecomte, J. Génin (2000)
Trapping of Cr by Formation of Ferrihydrite during the Reduction of Chromate Ions by Fe(II)-Fe(III) Hydroxysalt Green RustsEnvironmental Science & Technology, 34
-
A. González, K. Ndungu, A. Flegal (2005)
Natural occurrence of hexavalent chromium in the Aromas Red Sands Aquifer, California.Environmental science & technology, 39 15
-
David Hastings, S. Emerson (1986)
Oxidation of manganese by spores of a marine bacillus: Kinetic and thermodynamic considerationsGeochimica et Cosmochimica Acta, 50
-
Jing Hu, Guohua Chen, I. Lo (2006)
Selective removal of heavy metals from industrial wastewater using maghemite nanoparticle: Performance and mechanismsJournal of Environmental Engineering, 132
-
Dennis Kraemer, R. Frei, S. Viehmann, M. Bau (2019)
Mobilization and isotope fractionation of chromium during water-rock interaction in presence of siderophoresApplied Geochemistry
-
Zimeng Wang, D. Giammar (2015)
Metal Contaminant Oxidation Mediated by Manganese Redox Cycling in Subsurface Environment -
B. Sass, D. Rai (1987)
Solubility of amorphous chromium(III)-iron(III) hydroxide solid solutionsInorganic Chemistry, 26
-
Z. Pan, Xiaomin Zhu, Anshuman Satpathy, Wenlu Li, J. Fortner, D. Giammar (2019)
Cr(VI) Adsorption on Engineered Iron Oxide Nanoparticles: Exploring Complexation Processes and Water Chemistry.Environmental science & technology
-
N. Bompoti, M. Chrysochoou, M. Machesky (2016)
Advances in Surface Complexation Modeling for Chromium Adsorption on Iron OxideGeotechnical special publication
-
I. Yoon, Sunbaek Bang, Jin-Soo Chang, Min Kim, Kyoung-Woong Kim (2011)
Effects of pH and dissolved oxygen on Cr(VI) removal in Fe(0)/H2O systems.Journal of hazardous materials, 186 1
-
E. Saad, Jingying Sun, Shuo Chen, O. Borkiewicz, M. Zhu, O. Duckworth, Yuanzhi Tang (2017)
Siderophore and Organic Acid Promoted Dissolution and Transformation of Cr(III)-Fe(III)-(oxy)hydroxides.Environmental science & technology, 51 6
-
Ji‐Zheng He, Y. Meng, Yuan-ming Zheng, Li‐Mei Zhang (2010)
Cr(III) oxidation coupled with Mn(II) bacterial oxidation in the environmentJournal of Soils and Sediments, 10
-
N Bompoti, M Chrysochoou, M Machesky (2016)
Advances in surface complexation modeling for chromium adsorption on iron oxideIn Geo-Chicago 2016: Sustainable Waste Management and Remediation
-
(2014)
California regulations related to drinking water -
L. Palma, M. Gueye, E. Petrucci (2015)
Hexavalent chromium reduction in contaminated soil: A comparison between ferrous sulphate and nanoscale zero-valent iron.Journal of hazardous materials, 281
-
N. Bompoti, M. Chrysochoou, M. Machesky (2019)
A Unified Surface Complexation Modeling Approach for Chromate Adsorption on Iron Oxides.Environmental science & technology, 53 11
-
Sarika Singh, K. Barick, D. Bahadur (2011)
Surface engineered magnetic nanoparticles for removal of toxic metal ions and bacterial pathogens.Journal of hazardous materials, 192 3
-
Dieter Diem, W. Stumm (1984)
Is dissolved Mn2+ being oxidized by O2 in absence of Mn-bacteria or surface catalysts?Geochimica et Cosmochimica Acta, 48
-
Karen Murray, Mylene Mozafarzadeh, B. Tebo (2005)
Cr(III) Oxidation and Cr Toxicity in Cultures of the Manganese(II)-Oxidizing Pseudomonas putida Strain GB-1Geomicrobiology Journal, 22
-
Wenjun Jiang, Quan Cai, W. Xu, Mingwei Yang, Yong Cai, D. Dionysiou, K. O’Shea (2014)
Cr(VI) adsorption and reduction by humic acid coated on magnetite.Environmental science & technology, 48 14
-
Youxiang Wu, B. Deng, Huifang Xu, Hiromi Kornishi (2005)
Chromium(III) Oxidation Coupled with Microbially Mediated Mn(II) OxidationGeomicrobiology Journal, 22
-
Debra Hausladen, Annika Alexander-Ozinskas, C. McClain, S. Fendorf (2018)
Hexavalent Chromium Sources and Distribution in California Groundwater.Environmental science & technology, 52 15
-
Claudia Rosales-Landeros, C. Barrera-Díaz, B. Bilyeu, V. Guerrero, Fernando Núñez (2013)
A Review on Cr(VI) Adsorption Using Inorganic MaterialsAmerican Journal of Analytical Chemistry, 4
-
K. Johnson (2006)
Manganese Redox Chemistry RevisitedScience, 313
-
S. Namgung, M. Kwon, N. Qafoku, Giehyeon Lee (2014)
Cr(OH)3(s) oxidation induced by surface catalyzed Mn(II) oxidation.Environmental science & technology, 48 18
-
Xiaolei Liu, Hailiang Dong, Xuewei Yang, L. Kovarik, Yu Chen, Q. Zeng (2018)
Effects of citrate on hexavalent chromium reduction by structural Fe(II) in nontronite.Journal of hazardous materials, 343
-
F. Battaglia-Brunet, S. Foucher, D. Morin, I. Ignatiadis (2004)
Chromate (CrO2−4) Reduction in Groundwaters by Using Reductive Bacteria in Fixed-Bed BioreactorsWater, Air and Soil Pollution: Focus, 4
-
C. Pan, Huan Liu, J. Catalano, Zimeng Wang, Ao Qian, D. Giammar (2019)
Understanding the Roles of Dissolution and Diffusion in Cr(OH)3 Oxidation by δ-MnO2ACS Earth and Space Chemistry
-
C. Dai, X. Zuo, Bo Cao, Yandi Hu (2016)
Homogeneous and Heterogeneous (Fex, Cr1-x)(OH)3 Precipitation: Implications for Cr Sequestration.Environmental science & technology, 50 4
-
B. Manning, J. Kiser, Hancheol Kwon, S. Kanel (2007)
Spectroscopic investigation of Cr(III)- and Cr(VI)-treated nanoscale zerovalent iron.Environmental science & technology, 41 2
-
Yu Jiang, B. Xi, Rui Li, Mingxiao Li, Zheng Xu, Yuning Yang, Shaobo Gao (2019)
Advances in Fe(III) bioreduction and its application prospect for groundwater remediation: A reviewFrontiers of Environmental Science & Engineering, 13
-
Weifan Liu, Bo Sun, Junlian Qiao, Xiaohong Guan (2019)
Influence of pyrophosphate on the generation of soluble Mn(III) from reactions involving Mn oxides and Mn(VII).Environmental science & technology
-
C. Pan, Huan Liu, J. Catalano, Ao Qian, Zimeng Wang, D. Giammar (2017)
Rates of Cr(VI) Generation from CrxFe1-x(OH)3 Solids upon Reaction with Manganese Oxide.Environmental science & technology, 51 21
-
Debra Hausladen, S. Fendorf (2017)
Hexavalent Chromium Generation within Naturally Structured Soils and Sediments.Environmental science & technology, 51 4
-
C. McClain, S. Fendorf, S. Webb, K. Maher (2017)
Quantifying Cr(VI) Production and Export from Serpentine Soil of the California Coast Range.Environmental science & technology, 51 1
-
M. Schlautman, I. Han (2001)
Effects of pH and dissolved oxygen on the reduction of hexavalent chromium by dissolved ferrous iron in poorly buffered aqueous systems.Water research, 35 6
-
D. Parkhurst, S. Christenson, G. Breit (1993)
Ground-water-quality assessment of the central Oklahoma Aquifer, Oklahoma: Geochemical and geohydrologic investigations -
E. Butler, Lixia Chen, C. Hansel, L. Krumholz, A. Madden, Ying Lan (2015)
Biological versus mineralogical chromium reduction: potential for reoxidation by manganese oxide.Environmental science. Processes & impacts, 17 11
-
M. Mullet, F. Demoisson, B. Humbert, L. Michot, D. Vantelon (2007)
Aqueous Cr(VI) reduction by pyrite: Speciation and characterisation of the solid phases by X-ray photoelectron, Raman and X-ray absorption spectroscopiesGeochimica et Cosmochimica Acta, 71
-
G. Icopini, D. Long (2002)
Speciation of aqueous chromium by use of solid-phase extractions in the field.Environmental science & technology, 36 13
-
K. Lai, I. Lo (2008)
Removal of chromium (VI) by acid-washed zero-valent iron under various groundwater geochemistry conditions.Environmental science & technology, 42 4
-
C. Barrera-Díaz, V. Lugo-Lugo, B. Bilyeu (2012)
A review of chemical, electrochemical and biological methods for aqueous Cr(VI) reduction.Journal of hazardous materials, 223-224
-
P. Yuan, Dong Liu, Mingde Fan, Dan Yang, Runliang Zhu, Fei Ge, Jianxi Zhu, Hongping He (2010)
Removal of hexavalent chromium [Cr(VI)] from aqueous solutions by the diatomite-supported/unsupported magnetite nanoparticles.Journal of hazardous materials, 173 1-3
-
Xiaopeng Huang, X. Hou, Fahui Song, Jincai Zhao, Lizhi Zhang (2016)
Facet-Dependent Cr(VI) Adsorption of Hematite Nanocrystals.Environmental science & technology, 50 4
-
Yingying Xie, X. Yi, K. Shah, J. Reinfelder, Han Ye, P. Chiang, Zhenqing Shi, Z. Dang, G. Lu (2019)
Elucidation of desferrioxamine B on the liberation of chromium from schwertmanniteChemical Geology
-
C. Varadharajan, H. Beller, M. Bill, Eoin Brodie, M. Conrad, R. Han, Courtney Irwin, Joern Larsen, H. Lim, S. Molins, C. Steefel, April Hise, Li Yang, P. Nico (2017)
Reoxidation of Chromium(III) Products Formed under Different Biogeochemical Regimes.Environmental science & technology, 51 9
-
C. Pan, L. Troyer, Peng Liao, J. Catalano, Wenlu Li, D. Giammar (2017)
Effect of Humic Acid on the Removal of Chromium(VI) and the Production of Solids in Iron Electrocoagulation.Environmental science & technology, 51 11
-
Kai-yue Chen, Y. Tzou, Y. Chan, Jeng-Jzung Wu, H. Teah, Yu-Ting Liu (2019)
Removal and simultaneous reduction of Cr(VI) by organo-Fe(III) composites produced during coprecipitation and coagulation processes.Journal of hazardous materials, 376
-
Ao Qian, W. Zhang, Chengming Shi, C. Pan, D. Giammar, S. Yuan, Hongliang Zhang, Zimeng Wang (2019)
Geochemical Stability of Dissolved Mn(III) in the Presence of Pyrophosphate as a Model Ligand: Complexation and Disproportionation.Environmental science & technology, 53 10
-
M. Bishop, Paul Glasser, Hailiang Dong, B. Arey, L. Kovarik (2014)
Reduction and immobilization of hexavalent chromium by microbially reduced Fe-bearing clay mineralsGeochimica et Cosmochimica Acta, 133
-
Debra Hausladen, S. Fakhreddine, S. Fendorf (2019)
Governing Constraints of Chromium(VI) Formation from Chromium(III)-Bearing Minerals in Soils and SedimentsSoil Systems
-
M. Pettine, Luca D'Ottone, L. Campanella, F. Millero, R. Passino (1998)
The reduction of chromium (VI) by iron (II) in aqueous solutionsGeochimica et Cosmochimica Acta, 62
-
Edmond Eary, D. Rai (1987)
Kinetics of chromium(III) oxidation to chromium(VI) by reaction with manganese dioxideEnvironmental Science & Technology, 21
-
C. Oze, D. Bird, S. Fendorf (2007)
Genesis of hexavalent chromium from natural sources in soil and groundwaterProceedings of the National Academy of Sciences, 104
- Publisher
- Springer Journals
- Copyright
- Copyright © Higher Education Press 2020
- ISSN
- 2095-2201
- eISSN
- 2095-221X
- DOI
- 10.1007/s11783-020-1260-y
- Publisher site
- See Article on Publisher Site
Abstract
Hexavalent chromium (Cr(VI)) is a water-soluble pollutant in soil and groundwater, the mobility, bioavailability, and toxicity of which can be controlled by transforming to less mobile and more environmentally benign Cr(III) by ways of reduction. This review focused on recent advances in identifying the reaction pathways, kinetics, and products of iron-based techniques for Cr(VI) removal. It also examines new information regarding remobilization of Cr(III) in the existence of complexing ligands and manganese (Mn) of different oxidation states. A range of iron-based techniques can remove Cr(VI) from water by adsorption or reduction-coprecipitation processes. However, the success of a chromium treatment or remediation strategy requires the stability of the Cr(III)-containing solids with respect to solubilization or reoxidation in the settings they are generated. Manganese is ubiquitous in aquatic and terrestrial environments, and the redox cycling of manganese may greatly influence the fate, transport, and distribution of chromium. Coupling of redox reactions of chromium, iron, and manganese involves reaction pathways not only in the aqueous phase but also at solid-aqueous interfaces. To provide a quantitative understanding of these processes, it is essential to develop mechanistically based kinetic and transport models. Continued research should be made on iron-based treatment of Cr(VI)-contaminated water and soils and the stability of the subsequently produced Cr (III)-containing solids at environmentally relevant conditions, which will support improved predictions of chromium’s environmental fate and transport and aid in decision-making for remediation and treatment of Cr contamination.[graphic not available: see fulltext]
Journal
Frontiers of Environmental Science & Engineering – Springer Journals
Published: Oct 1, 2020
Keywords: Chromium(VI) contamination; Redox reaction; Iron oxide; Manganese oxide; Modeling