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M Di Toro

Showing results (71-80 of 89) with videos related to

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Environmental Science & Technology|August 23, 2023
Linear Free Energy Relationship for Predicting the Rate Constants of Munition Compound Reduction by the Fe(II)-Hematite and Fe(II)-Goethite Redox CouplesPaula A Cárdenas-Hernández, Kevin Hickey, Dominic M Di Toro, et al.
Environmental Science & Technology|May 1, 2019
Experimental Validation of Hydrogen Atom Transfer Gibbs Free Energy as a Predictor of Nitroaromatic Reduction Rate ConstantsJimmy Murillo-Gelvez, Kevin P Hickey, Dominic M Di Toro, et al.
Environmental Science & Technology|February 4, 2012
Effects of nonreversibility, particle concentration, and ionic strength on heavy-metal sorptionD M Di Toro, J D Mahony, P R Kirchgraber, et al.
Environmental Science & Technology|March 29, 2022
Modeling the Reduction Kinetics of Munition Compounds by Humic AcidsKevin P Hickey, Jimmy Murillo-Gelvez, Dominic M Di Toro, et al.
Environmental Toxicology and Chemistry|September 14, 2022
Modeling Time-Dependent Aquatic Toxicity of Hydrocarbons: Role of Organism Weight, Temperature, and Substance HydrophobicityAaron D Redman, Thomas F Parkerton, Daniel J Letinski, et al.
Environmental Toxicology and Chemistry|October 13, 2001
Biotic ligand model of the acute toxicity of metals. 1. Technical basisD M Di Toro, H E Allen, H L Bergman, et al.
Environmental Science & Technology|December 31, 2005
Iron(II)-catalyzed oxidation of arsenic(III) in a sediment columnKevin J Bisceglia, Kevin J Rader, Richard F Carbonaro, et al.
Chemosphere|February 19, 2018
Technical basis for using passive sampling as a biomimetic extraction procedure to assess bioavailability and predict toxicity of petroleum substancesA D Redman, J D Butler, D J Letinski, et al.
Comparative Biochemistry and Physiology. Toxicology & Pharmacology : CBP|October 3, 2002
Extension of the biotic ligand model of acute toxicity to a physiologically-based model of the survival time of rainbow trout (Oncorhynchus mykiss) exposed to silverPaul R Paquin, Viktoria Zoltay, Richard P Winfield, et al.
Environmental Science & Technology|December 13, 2006
A terrestrial biotic ligand model. 1. Development and application to Cu and Ni toxicities to barley root elongation in soilsSagar Thakali, Herbert E Allen, Dominic M Di Toro, et al.
Pageof 9

Showing results (71-80 of 89) with videos related to

Sort By:
Pageof 9
Environmental Science & Technology|August 23, 2023
Linear Free Energy Relationship for Predicting the Rate Constants of Munition Compound Reduction by the Fe(II)-Hematite and Fe(II)-Goethite Redox CouplesPaula A Cárdenas-Hernández, Kevin Hickey, Dominic M Di Toro, et al.
Environmental Science & Technology|May 1, 2019
Experimental Validation of Hydrogen Atom Transfer Gibbs Free Energy as a Predictor of Nitroaromatic Reduction Rate ConstantsJimmy Murillo-Gelvez, Kevin P Hickey, Dominic M Di Toro, et al.
Environmental Science & Technology|February 4, 2012
Effects of nonreversibility, particle concentration, and ionic strength on heavy-metal sorptionD M Di Toro, J D Mahony, P R Kirchgraber, et al.
Environmental Science & Technology|March 29, 2022
Modeling the Reduction Kinetics of Munition Compounds by Humic AcidsKevin P Hickey, Jimmy Murillo-Gelvez, Dominic M Di Toro, et al.
Environmental Toxicology and Chemistry|September 14, 2022
Modeling Time-Dependent Aquatic Toxicity of Hydrocarbons: Role of Organism Weight, Temperature, and Substance HydrophobicityAaron D Redman, Thomas F Parkerton, Daniel J Letinski, et al.
Environmental Toxicology and Chemistry|October 13, 2001
Biotic ligand model of the acute toxicity of metals. 1. Technical basisD M Di Toro, H E Allen, H L Bergman, et al.
Environmental Science & Technology|December 31, 2005
Iron(II)-catalyzed oxidation of arsenic(III) in a sediment columnKevin J Bisceglia, Kevin J Rader, Richard F Carbonaro, et al.
Chemosphere|February 19, 2018
Technical basis for using passive sampling as a biomimetic extraction procedure to assess bioavailability and predict toxicity of petroleum substancesA D Redman, J D Butler, D J Letinski, et al.
Comparative Biochemistry and Physiology. Toxicology & Pharmacology : CBP|October 3, 2002
Extension of the biotic ligand model of acute toxicity to a physiologically-based model of the survival time of rainbow trout (Oncorhynchus mykiss) exposed to silverPaul R Paquin, Viktoria Zoltay, Richard P Winfield, et al.
Environmental Science & Technology|December 13, 2006
A terrestrial biotic ligand model. 1. Development and application to Cu and Ni toxicities to barley root elongation in soilsSagar Thakali, Herbert E Allen, Dominic M Di Toro, et al.
Pageof 9