Nano-aluminum: Transport through sand columns and environmental effects on plants and soil communities

Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental...

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Bibliographic Details
Published in:Environmental research Vol. 106; no. 3; pp. 296 - 303
Main Authors: Doshi, Reeti, Braida, Washington, Christodoulatos, Christos, Wazne, Mahmoud, O’Connor, Gregory
Format: Journal Article
Language:English
Published: Netherlands Elsevier Inc 01.03.2008
Subjects:
Aliivibrio fischeri - drug effects
Aliivibrio fischeri - metabolism
Aluminum Oxide - chemistry
Aluminum Oxide - pharmacokinetics
Aluminum Oxide - toxicity
Ecotoxicology
Fabaceae - drug effects
Fabaceae - growth & development
Fabaceae - metabolism
Glucose - metabolism
Hydrogen-Ion Concentration
Lolium - drug effects
Lolium - metabolism
Lolium perenne
Metal Nanoparticles - chemistry
Metal Nanoparticles - toxicity
Microtox
Nano-aluminum
Phaseolus vulgaris
Plant uptake
Soil Microbiology
Soil Pollutants - chemistry
Soil Pollutants - pharmacokinetics
Soil Pollutants - toxicity
Soil respiration
Solubility
Transport
Vibrio fischeri
USA, California
Nano-aluminum
Microtox
Transport
Soil respiration
Plant uptake
ISSN:0013-9351, 1096-0953
Online Access:Get full text
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Abstract Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental impacts on soil systems. Surface phenomena and pH are variables controlling the transport of nano-aluminum particles through porous media. pH environment controls solubility and electrostatic interactions between nano-aluminum particles and porous media. (i.e., changes in point of zero charge, agglomeration, etc.). Concentrations (up to 17 mg/L) far greater than the World Health Organization guideline for Al in drinking water (0.2 mg/L) were measured in columns’ leachates. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. It appears that the presence of nano-aluminum particles did not have an adverse effect on the growth of California red kidney bean ( Phaseolus vulgaris) and rye grass ( Lolium perenne) plants in the concentration range tested. California red beans did not show uptake of aluminum, while the situation was different for rye grass where a 2.5-fold increase in Al concentration in the leaves was observed as compared with control tests. Nano-aluminum particles in suspension do not appear to have an impact on the metabolic activity of Vibrio fischeri. However, when the nano-aluminum particles were amended to the soil, Alex aluminum resulted in a 50% reduction of light output at concentrations below 5000 mg/L soil suspension concentration while L-Alex showed a similar effect at around 17,500 mg/L and the control soil at 37,500 mg/L. Soil respiration studies show that there are not statistical differences between the time and sizes of peaks in CO 2 production and the total mineralization of glucose.
AbstractList Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental impacts on soil systems. Surface phenomena and pH are variables controlling the transport of nano-aluminum particles through porous media. pH environment controls solubility and electrostatic interactions between nano-aluminum particles and porous media. (i.e., changes in point of zero charge, agglomeration, etc.). Concentrations (up to 17mg/L) far greater than the World Health Organization guideline for Al in drinking water (0.2mg/L) were measured in columns' leachates. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. It appears that the presence of nano-aluminum particles did not have an adverse effect on the growth of California red kidney bean (Phaseolus vulgaris) and rye grass (Lolium perenne) plants in the concentration range tested. California red beans did not show uptake of aluminum, while the situation was different for rye grass where a 2.5-fold increase in Al concentration in the leaves was observed as compared with control tests. Nano-aluminum particles in suspension do not appear to have an impact on the metabolic activity of Vibrio fischeri. However, when the nano-aluminum particles were amended to the soil, Alex aluminum resulted in a 50% reduction of light output at concentrations below 5000mg/L soil suspension concentration while L-Alex showed a similar effect at around 17,500mg/L and the control soil at 37,500mg/L. Soil respiration studies show that there are not statistical differences between the time and sizes of peaks in CO sub(2) production and the total mineralization of glucose.
The fate and transport of two types of nano-aluminum particles in subsurface environments as well as potential environmental impacts of these particles were explored. The nano-aluminum particles used were 100 nm in size. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. The results showed that nano-aluminum particles coated with Al sub(2)O sub(3) leached out larger amounts of Al than L-Alex particles. No differences in plant growth between aluminum amended and non-amended control soils were observed. The results concluded that a complete evaluation of plant growth required a very large number of replicates and measurements of dry and humid biomass over time.
Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental impacts on soil systems. Surface phenomena and pH are variables controlling the transport of nano-aluminum particles through porous media. pH environment controls solubility and electrostatic interactions between nano-aluminum particles and porous media. (i.e., changes in point of zero charge, agglomeration, etc.). Concentrations (up to 17 mg/L) far greater than the World Health Organization guideline for Al in drinking water (0.2 mg/L) were measured in columns' leachates. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. It appears that the presence of nano-aluminum particles did not have an adverse effect on the growth of California red kidney bean (Phaseolus vulgaris) and rye grass (Lolium perenne) plants in the concentration range tested. California red beans did not show uptake of aluminum, while the situation was different for rye grass where a 2.5-fold increase in Al concentration in the leaves was observed as compared with control tests. Nano-aluminum particles in suspension do not appear to have an impact on the metabolic activity of Vibrio fischeri. However, when the nano-aluminum particles were amended to the soil, Alex aluminum resulted in a 50% reduction of light output at concentrations below 5000 mg/L soil suspension concentration while L-Alex showed a similar effect at around 17,500 mg/L and the control soil at 37,500 mg/L. Soil respiration studies show that there are not statistical differences between the time and sizes of peaks in CO(2) production and the total mineralization of glucose.
Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental impacts on soil systems. Surface phenomena and pH are variables controlling the transport of nano-aluminum particles through porous media. pH environment controls solubility and electrostatic interactions between nano-aluminum particles and porous media. (i.e., changes in point of zero charge, agglomeration, etc.). Concentrations (up to 17 mg/L) far greater than the World Health Organization guideline for Al in drinking water (0.2 mg/L) were measured in columns’ leachates. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. It appears that the presence of nano-aluminum particles did not have an adverse effect on the growth of California red kidney bean ( Phaseolus vulgaris) and rye grass ( Lolium perenne) plants in the concentration range tested. California red beans did not show uptake of aluminum, while the situation was different for rye grass where a 2.5-fold increase in Al concentration in the leaves was observed as compared with control tests. Nano-aluminum particles in suspension do not appear to have an impact on the metabolic activity of Vibrio fischeri. However, when the nano-aluminum particles were amended to the soil, Alex aluminum resulted in a 50% reduction of light output at concentrations below 5000 mg/L soil suspension concentration while L-Alex showed a similar effect at around 17,500 mg/L and the control soil at 37,500 mg/L. Soil respiration studies show that there are not statistical differences between the time and sizes of peaks in CO 2 production and the total mineralization of glucose.
Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental impacts on soil systems. Surface phenomena and pH are variables controlling the transport of nano-aluminum particles through porous media. pH environment controls solubility and electrostatic interactions between nano-aluminum particles and porous media. (i.e., changes in point of zero charge, agglomeration, etc.). Concentrations (up to 17 mg/L) far greater than the World Health Organization guideline for Al in drinking water (0.2 mg/L) were measured in columns' leachates. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. It appears that the presence of nano-aluminum particles did not have an adverse effect on the growth of California red kidney bean (Phaseolus vulgaris) and rye grass (Lolium perenne) plants in the concentration range tested. California red beans did not show uptake of aluminum, while the situation was different for rye grass where a 2.5-fold increase in Al concentration in the leaves was observed as compared with control tests. Nano-aluminum particles in suspension do not appear to have an impact on the metabolic activity of Vibrio fischeri. However, when the nano-aluminum particles were amended to the soil, Alex aluminum resulted in a 50% reduction of light output at concentrations below 5000 mg/L soil suspension concentration while L-Alex showed a similar effect at around 17,500 mg/L and the control soil at 37,500 mg/L. Soil respiration studies show that there are not statistical differences between the time and sizes of peaks in CO(2) production and the total mineralization of glucose.Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles (with aluminum oxide, or carboxylate ligand coating, Alex and L-Alex, respectively) through sand columns along with associated environmental impacts on soil systems. Surface phenomena and pH are variables controlling the transport of nano-aluminum particles through porous media. pH environment controls solubility and electrostatic interactions between nano-aluminum particles and porous media. (i.e., changes in point of zero charge, agglomeration, etc.). Concentrations (up to 17 mg/L) far greater than the World Health Organization guideline for Al in drinking water (0.2 mg/L) were measured in columns' leachates. Plant uptake studies, mineralization of radiolabeled glucose test and Microtox test were used to investigate the environmental impacts of nano-aluminum on soil communities and plants. It appears that the presence of nano-aluminum particles did not have an adverse effect on the growth of California red kidney bean (Phaseolus vulgaris) and rye grass (Lolium perenne) plants in the concentration range tested. California red beans did not show uptake of aluminum, while the situation was different for rye grass where a 2.5-fold increase in Al concentration in the leaves was observed as compared with control tests. Nano-aluminum particles in suspension do not appear to have an impact on the metabolic activity of Vibrio fischeri. However, when the nano-aluminum particles were amended to the soil, Alex aluminum resulted in a 50% reduction of light output at concentrations below 5000 mg/L soil suspension concentration while L-Alex showed a similar effect at around 17,500 mg/L and the control soil at 37,500 mg/L. Soil respiration studies show that there are not statistical differences between the time and sizes of peaks in CO(2) production and the total mineralization of glucose.
Author Braida, Washington
O’Connor, Gregory
Doshi, Reeti
Wazne, Mahmoud
Christodoulatos, Christos
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  surname: Doshi
  fullname: Doshi, Reeti
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  organization: Center for Environmental System, Stevens Institute of Technology, Hoboken, NJ 07030, USA
– sequence: 2
  givenname: Washington
  surname: Braida
  fullname: Braida, Washington
  email: wbraida@stevens.edu
  organization: Center for Environmental System, Stevens Institute of Technology, Hoboken, NJ 07030, USA
– sequence: 3
  givenname: Christos
  surname: Christodoulatos
  fullname: Christodoulatos, Christos
  email: christod@stevens.edu
  organization: Center for Environmental System, Stevens Institute of Technology, Hoboken, NJ 07030, USA
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  givenname: Mahmoud
  surname: Wazne
  fullname: Wazne, Mahmoud
  email: mwazne@stevens.edu
  organization: Center for Environmental System, Stevens Institute of Technology, Hoboken, NJ 07030, USA
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  givenname: Gregory
  surname: O’Connor
  fullname: O’Connor, Gregory
  email: goconnor@pica.army.mil
  organization: US Army, Environmental Technology Division, Picatinny, NJ 07806, USA
BackLink https://www.ncbi.nlm.nih.gov/pubmed/17537426$$D View this record in MEDLINE/PubMed
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IsPeerReviewed true
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Issue 3
Keywords Nano-aluminum
Microtox
Transport
Soil respiration
Plant uptake
Language English
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Zeng (10.1016/j.envres.2007.04.006_bib13) 2006; 63
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Snippet Nano-aluminum is being used in increasing quantities as energetic material. This research addresses the transport of two types of nanosized aluminum particles...
The fate and transport of two types of nano-aluminum particles in subsurface environments as well as potential environmental impacts of these particles were...
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SubjectTerms Aliivibrio fischeri - drug effects
Aliivibrio fischeri - metabolism
Aluminum Oxide - chemistry
Aluminum Oxide - pharmacokinetics
Aluminum Oxide - toxicity
Ecotoxicology
Fabaceae - drug effects
Fabaceae - growth & development
Fabaceae - metabolism
Glucose - metabolism
Hydrogen-Ion Concentration
Lolium - drug effects
Lolium - metabolism
Lolium perenne
Metal Nanoparticles - chemistry
Metal Nanoparticles - toxicity
Microtox
Nano-aluminum
Phaseolus vulgaris
Plant uptake
Soil Microbiology
Soil Pollutants - chemistry
Soil Pollutants - pharmacokinetics
Soil Pollutants - toxicity
Soil respiration
Solubility
Transport
Vibrio fischeri
Title Nano-aluminum: Transport through sand columns and environmental effects on plants and soil communities
URI https://dx.doi.org/10.1016/j.envres.2007.04.006
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