Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations
Arsenic (V) uptake from groundwater by using Vallisneria gigantea plants was studied using batch experiments. Reflectance and fluorescence of intact plants were investigated and changes in photophysical properties following arsenic absorption were reported. Good correlations have been found between...
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Acceso en línea: | https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00456535_v138_n_p383_Iriel http://hdl.handle.net/20.500.12110/paper_00456535_v138_n_p383_Iriel |
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paper:paper_00456535_v138_n_p383_Iriel2023-06-08T15:05:16Z Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations Iriel, Analía Lagorio, María Gabriela Fernández Cirelli, Alicia Bioaccumulation Chlorophyll emission Equilibrium isotherms Kinetics Reflectance Bioaccumulation Biochemistry Biosorption Enzyme kinetics Fluorescence Groundwater Kinetics Reflection Arsenic concentration Biosorption process Dubinin-Radushkevich Equilibrium isotherms Fluorescence measurements Good correlations Photophysical properties Translocation factor Arsenic arsenic ground water arsenic ground water water pollutant absorption aquatic plant arsenic bioaccumulation biological uptake chlorophyll concentration (composition) correlation diffusion equilibrium fluorescence groundwater pollution kinetics monocotyledon phytoremediation reflectance translocation absorption Article bioaccumulation biosorption concentration (parameters) diffusion fluorescence nonhuman physical parameters plant plant root species Vallisneria gigantea adsorption chemistry Hydrocharitaceae isolation and purification kinetics pH physical phenomena theoretical model water pollutant Vallisneria Vallisneria gigantea Adsorption Arsenic Diffusion Groundwater Hydrocharitaceae Hydrogen-Ion Concentration Kinetics Models, Theoretical Physical Processes Water Pollutants, Chemical Arsenic (V) uptake from groundwater by using Vallisneria gigantea plants was studied using batch experiments. Reflectance and fluorescence of intact plants were investigated and changes in photophysical properties following arsenic absorption were reported. Good correlations have been found between arsenic concentration in groundwater and parameters derived from reflectance and fluorescence measurements. This system reached its equilibrium after seven days when the removal quantities were strongly dependent on the initial arsenic concentration. Interestingly, Vallisneria plants were able to accumulate from 100 to 600mg As kg-1 in roots and fronds although the translocation factors were low (0.6-1.6). Kinetic data for biosorption process followed a first-order law. At low arsenic concentrations the uptake in plants was governed by diffusion aspects. Langmuir, Freundlich and Dubinin-Radushkevich models were applied and results demonstrated that arsenic uptake was better described by the Langmuir model. As a final remark we concluded that a plant of this species should be able to remove 1mg As per week. © 2015 Elsevier Ltd. Fil:Iriel, A. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Lagorio, M.G. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Fernández Cirelli, A. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2015 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00456535_v138_n_p383_Iriel http://hdl.handle.net/20.500.12110/paper_00456535_v138_n_p383_Iriel |
institution |
Universidad de Buenos Aires |
institution_str |
I-28 |
repository_str |
R-134 |
collection |
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
topic |
Bioaccumulation Chlorophyll emission Equilibrium isotherms Kinetics Reflectance Bioaccumulation Biochemistry Biosorption Enzyme kinetics Fluorescence Groundwater Kinetics Reflection Arsenic concentration Biosorption process Dubinin-Radushkevich Equilibrium isotherms Fluorescence measurements Good correlations Photophysical properties Translocation factor Arsenic arsenic ground water arsenic ground water water pollutant absorption aquatic plant arsenic bioaccumulation biological uptake chlorophyll concentration (composition) correlation diffusion equilibrium fluorescence groundwater pollution kinetics monocotyledon phytoremediation reflectance translocation absorption Article bioaccumulation biosorption concentration (parameters) diffusion fluorescence nonhuman physical parameters plant plant root species Vallisneria gigantea adsorption chemistry Hydrocharitaceae isolation and purification kinetics pH physical phenomena theoretical model water pollutant Vallisneria Vallisneria gigantea Adsorption Arsenic Diffusion Groundwater Hydrocharitaceae Hydrogen-Ion Concentration Kinetics Models, Theoretical Physical Processes Water Pollutants, Chemical |
spellingShingle |
Bioaccumulation Chlorophyll emission Equilibrium isotherms Kinetics Reflectance Bioaccumulation Biochemistry Biosorption Enzyme kinetics Fluorescence Groundwater Kinetics Reflection Arsenic concentration Biosorption process Dubinin-Radushkevich Equilibrium isotherms Fluorescence measurements Good correlations Photophysical properties Translocation factor Arsenic arsenic ground water arsenic ground water water pollutant absorption aquatic plant arsenic bioaccumulation biological uptake chlorophyll concentration (composition) correlation diffusion equilibrium fluorescence groundwater pollution kinetics monocotyledon phytoremediation reflectance translocation absorption Article bioaccumulation biosorption concentration (parameters) diffusion fluorescence nonhuman physical parameters plant plant root species Vallisneria gigantea adsorption chemistry Hydrocharitaceae isolation and purification kinetics pH physical phenomena theoretical model water pollutant Vallisneria Vallisneria gigantea Adsorption Arsenic Diffusion Groundwater Hydrocharitaceae Hydrogen-Ion Concentration Kinetics Models, Theoretical Physical Processes Water Pollutants, Chemical Iriel, Analía Lagorio, María Gabriela Fernández Cirelli, Alicia Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations |
topic_facet |
Bioaccumulation Chlorophyll emission Equilibrium isotherms Kinetics Reflectance Bioaccumulation Biochemistry Biosorption Enzyme kinetics Fluorescence Groundwater Kinetics Reflection Arsenic concentration Biosorption process Dubinin-Radushkevich Equilibrium isotherms Fluorescence measurements Good correlations Photophysical properties Translocation factor Arsenic arsenic ground water arsenic ground water water pollutant absorption aquatic plant arsenic bioaccumulation biological uptake chlorophyll concentration (composition) correlation diffusion equilibrium fluorescence groundwater pollution kinetics monocotyledon phytoremediation reflectance translocation absorption Article bioaccumulation biosorption concentration (parameters) diffusion fluorescence nonhuman physical parameters plant plant root species Vallisneria gigantea adsorption chemistry Hydrocharitaceae isolation and purification kinetics pH physical phenomena theoretical model water pollutant Vallisneria Vallisneria gigantea Adsorption Arsenic Diffusion Groundwater Hydrocharitaceae Hydrogen-Ion Concentration Kinetics Models, Theoretical Physical Processes Water Pollutants, Chemical |
description |
Arsenic (V) uptake from groundwater by using Vallisneria gigantea plants was studied using batch experiments. Reflectance and fluorescence of intact plants were investigated and changes in photophysical properties following arsenic absorption were reported. Good correlations have been found between arsenic concentration in groundwater and parameters derived from reflectance and fluorescence measurements. This system reached its equilibrium after seven days when the removal quantities were strongly dependent on the initial arsenic concentration. Interestingly, Vallisneria plants were able to accumulate from 100 to 600mg As kg-1 in roots and fronds although the translocation factors were low (0.6-1.6). Kinetic data for biosorption process followed a first-order law. At low arsenic concentrations the uptake in plants was governed by diffusion aspects. Langmuir, Freundlich and Dubinin-Radushkevich models were applied and results demonstrated that arsenic uptake was better described by the Langmuir model. As a final remark we concluded that a plant of this species should be able to remove 1mg As per week. © 2015 Elsevier Ltd. |
author |
Iriel, Analía Lagorio, María Gabriela Fernández Cirelli, Alicia |
author_facet |
Iriel, Analía Lagorio, María Gabriela Fernández Cirelli, Alicia |
author_sort |
Iriel, Analía |
title |
Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations |
title_short |
Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations |
title_full |
Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations |
title_fullStr |
Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations |
title_full_unstemmed |
Biosorption of arsenic from groundwater using Vallisneria gigantea plants. Kinetics, equilibrium and photophysical considerations |
title_sort |
biosorption of arsenic from groundwater using vallisneria gigantea plants. kinetics, equilibrium and photophysical considerations |
publishDate |
2015 |
url |
https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00456535_v138_n_p383_Iriel http://hdl.handle.net/20.500.12110/paper_00456535_v138_n_p383_Iriel |
work_keys_str_mv |
AT irielanalia biosorptionofarsenicfromgroundwaterusingvallisneriagiganteaplantskineticsequilibriumandphotophysicalconsiderations AT lagoriomariagabriela biosorptionofarsenicfromgroundwaterusingvallisneriagiganteaplantskineticsequilibriumandphotophysicalconsiderations AT fernandezcirellialicia biosorptionofarsenicfromgroundwaterusingvallisneriagiganteaplantskineticsequilibriumandphotophysicalconsiderations |
_version_ |
1768546621140762624 |