Use of Nanoparticles in Soil-Water Bioremediation Processes

Revista De La Ciencia Del Suelo Y Nutricion Vegetal Pub Date : 2008-01-01 DOI:10.4067/S0718-27912008000400007

N. Durán

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引用次数: 19

Abstract

As a general definition, nanotechnology is involved with objects on the nano scale, or materials measuring between 1 and 100 nm. It was found a good definition that is practical and unconstrained by any arbitrary size limitations: The design, characterization, production, and application of structures, devices, and systems by controlled manipulation of size and shape at the nanometer scale that produces structures, devices, and systems with at least one novel/superior characteristic or property (Bawa et al., 2005). Nanotechnology has contributed to the development of a great diversity of materials as those used in electronic, optoelectronic, biomedical, pharmaceutical, cosmetic, energy, catalytic, and materials applications. In the manufacturing community, the most profitable trail for nanoscale particles and materials have been in the areas of sunscreen, magnetic recording tape, automotive catalyst supports, biolabeling, chemical-mechanical polishing, electroconductive coatings, and optical fibers. However, the emergence of nanotechnology presents a number of potential environmental benefits. This potential impact area could be divided into three categories: treatment and remediation, sensing and detection, and pollution prevention. Some nanoparticles destroy contaminants, for instance, while others sequester them. The specific nanotechnologies that it will be discussed hereafter focus on site remediation and waste water treatment. Besides the applications for soil, groundwater, and wastewater, a number of nanotechnologies for air remediation are also in development. Carbon nanotubes, for example, have been recognized for their ability to adsorb dioxin much more strongly than traditional activated carbon. Smaller particle size enables the development of smaller sensors, which can be deployed more easily into remote locations. The ability of nanotechnology to abate pollution production is in progress and could potentially catalyze the most revolutionary changes in the environmental field (Watlington, 2005).

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纳米颗粒在土壤-水生物修复过程中的应用

作为一个一般的定义，纳米技术涉及纳米尺度上的物体，或尺寸在1到100纳米之间的材料。我们发现了一个实用且不受任何任意尺寸限制约束的好定义:通过在纳米尺度上控制尺寸和形状来设计、表征、生产和应用结构、设备和系统，从而生产出至少具有一种新颖/优越特征或特性的结构、设备和系统(Bawa等人，2005)。纳米技术为电子、光电、生物医学、制药、化妆品、能源、催化和材料等领域的材料发展做出了巨大贡献。在制造业中，纳米级颗粒和材料最有利可图的应用领域是防晒霜、磁带、汽车催化剂支架、生物标签、化学机械抛光、导电涂层和光纤。然而，纳米技术的出现带来了许多潜在的环境效益。这一潜在影响区域可分为三类:处理和补救、感知和检测以及污染预防。例如，一些纳米颗粒可以破坏污染物，而另一些则可以隔离污染物。具体的纳米技术将着重于场地修复和废水处理。除了土壤、地下水和废水的应用之外，一些用于空气修复的纳米技术也在开发中。例如，碳纳米管因其吸附二恶英的能力比传统活性炭强得多而得到认可。更小的颗粒尺寸可以开发更小的传感器，这可以更容易地部署到偏远地区。纳米技术减少污染生产的能力正在取得进展，并可能催化环境领域最具革命性的变化(Watlington, 2005)。

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Revista De La Ciencia Del Suelo Y Nutricion Vegetal

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