Comparative study of leaching of silver nanoparticles from fabric and effective effluent treatment
Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechn...
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| Published in | Journal of environmental sciences (China) Vol. 24; no. 5; pp. 852 - 859 |
|---|---|
| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Netherlands
Elsevier B.V
01.05.2012
Delhi Public School, Dwarka, New Delh-110078i, India%Department of Bio & Nano Technology, Guru Jambheshwar University of Science & Technology, Hisar, Haryana-125001, India%CSIR-National Physical Laboratory, New Delhi-110012, India |
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| Abstract | Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Agn for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Agn leached into the effluent for reutilization, thus preventing environmental repercussions. |
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| AbstractList | X703; Nano silver (Agn) is employed as an active antimicrobial agent,but the environmental impact of Agn released from commercial products is unknown.The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology.This work investigated the amount of silver released from three different types of fabric into water during washing.Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions.Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants.In an attempt to recover the Agn for reutilizatlon and to save it from polluting water,the effluents from the wash were efficiently treated with bacterial strains.This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water.The process ensured the recovery of the Agn leached into the effluent for reutilization,thus preventing environmental repercussions. Nano silver (Ag(n)) is employed as an active antimicrobial agent, but the environmental impact of Ag(n) released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Ag(n) for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Ag(n) leached into the effluent for reutilization, thus preventing environmental repercussions.Nano silver (Ag(n)) is employed as an active antimicrobial agent, but the environmental impact of Ag(n) released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Ag(n) for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Ag(n) leached into the effluent for reutilization, thus preventing environmental repercussions. Nano silver (Agₙ) is employed as an active antimicrobial agent, but the environmental impact of Agₙ released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Agₙ for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Agₙ leached into the effluent for reutilization, thus preventing environmental repercussions. Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Agn for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Agn leached into the effluent for reutilization, thus preventing environmental repercussions. Nano silver (Ag(n)) is employed as an active antimicrobial agent, but the environmental impact of Ag(n) released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Ag(n) for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Ag(n) leached into the effluent for reutilization, thus preventing environmental repercussions. Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Agn for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Agn leached into the effluent for reutilization, thus preventing environmental repercussions. |
| Author | Aneesh Pasricha Sant Lal Jangra Nahar Singh Neeraj Dilbaghi K. N. Sood Kanupriya Arora Renu Pasricha |
| AuthorAffiliation | Delhi Public School, Dwarka, New Delh-110078i, India;Department of Bio & Nano Technology, Guru Jambheshwar University of Science & Technology, Hisar, Haryana-125001, India;CSIR-National Physical Laboratory |
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| Keywords | AAS silver nanoparticles effluent eco-environment SEM leaching TEM silver nanopartlcles |
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| Notes | silver nanoparticles leaching eco-environment effluent SEM TEM AAS Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity of nanomaterial released from consumer products during use should be determined to assess the environmental risks of advancement of nanotechnology. This work investigated the amount of silver released from three different types of fabric into water during washing. Three different types of fabric were loaded with chemically synthesized Ag nanoparticles and washed repeatedly under simulated washing conditions. Variable leaching rates among fabric types suggest that the manufacturing process may control the release of silver reaching the waste water treatment plants. In an attempt to recover the Agn for reutilization and to save it from polluting water, the effluents from the wash were efficiently treated with bacterial strains. This treatment was based on biosorption and was very efficient for the elimination of silver nanoparticles in the wash water. The process ensured the recovery of the Agn leached into the effluent for reutilization, thus preventing environmental repercussions. 11-2629/X ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-1 content type line 23 ObjectType-Article-1 ObjectType-Feature-2 |
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| Snippet | Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity... Nano silver (Agn) is employed as an active antimicrobial agent, but the environmental impact of Agn released from commercial products is unknown. The quantity... Nano silver (Ag(n)) is employed as an active antimicrobial agent, but the environmental impact of Ag(n) released from commercial products is unknown. The... Nano silver (Agₙ) is employed as an active antimicrobial agent, but the environmental impact of Agₙ released from commercial products is unknown. The quantity... X703; Nano silver (Agn) is employed as an active antimicrobial agent,but the environmental impact of Agn released from commercial products is unknown.The... |
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| SubjectTerms | AAS Animals anti-infective agents Bacillus subtilis - ultrastructure Bacteria Biodegradation, Environmental biosorption Colloids Cotton Fiber eco-environment effluent Effluents environmental impact Fabrics Leaching manufacturing Metal Nanoparticles - chemistry Metal Nanoparticles - ultrastructure Nanomaterials Nanoparticles nanosilver Nanostructure risk SEM Silver Silver - isolation & purification silver nanoparticles Spectrometry, X-Ray Emission Spectrophotometry, Ultraviolet TEM Textiles washing Waste Disposal, Fluid wastewater treatment Water Pollutants, Chemical - isolation & purification Water Purification - methods Wool 产品发布 污水再利用 污水处理厂 浸出率 环境风险评估 织物类型 银纳米粒子 面料 |
| Title | Comparative study of leaching of silver nanoparticles from fabric and effective effluent treatment |
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