论文题目:

In situ growth of Prussian blue nanocrystal within Fe3+ crosslinking PAA resin for radiocesium highly efficient and rapid separation from water

英文论文题目:

In situ growth of Prussian blue nanocrystal within Fe3+ crosslinking PAA resin for radiocesium highly efficient and rapid separation from water

第一作者:

杨红军

英文第一作者:

Yang, H. J.

联系作者:

于洪文

英文联系作者:

Yu, H. W.

发表年度:

2015

卷:

277

页码:

40-47

摘要:

A new nanocomposite, called FPPB, was prepared by the in situ synthesis of a Prussian blue (PB) nanocrystal within Fe3+ crosslinking poly(acrylic acid) (PM) resin for the highly efficient and rapid separation of radiocesium from water. The adsorption of Cs+ by FPPB follows the Langmuir and Freundlich isotherm model with distribution coefficients touched 1.15 x 10(5) mL/g and a good adsorption capacity of 72.47 mg/g (pH approximate to 7). FPPB displays high adsorption capacity for Cs+ capture under a wide pH range (4.0-10). The kinetics of Cs+ uptake by FPPB is fast (>90% elimination capacity of relatively low Cs+ concentrations during only 20 min of Cs+/FPPB contact) and fit well with the pseudo-second-order kinetic model. This should be attributed to the high dispersion of PB nanoparticles. The adsorption Cs+ from complex solutions containing various competitive cations in large excess was also effective. FPPB is a cost-effective sorbent and could be developed by only stirring using environmental friendly and inexpensive materials at room temperature. Furthermore, the FPPB-Cs+ can be easily retrieved from water with sieve. It is expected that the as-prepared FPPB has extensive applicability in the elimination of radiocesium from nuclear wastewater.

英文摘要:

A new nanocomposite, called FPPB, was prepared by the in situ synthesis of a Prussian blue (PB) nanocrystal within Fe3+ crosslinking poly(acrylic acid) (PM) resin for the highly efficient and rapid separation of radiocesium from water. The adsorption of Cs+ by FPPB follows the Langmuir and Freundlich isotherm model with distribution coefficients touched 1.15 x 10(5) mL/g and a good adsorption capacity of 72.47 mg/g (pH approximate to 7). FPPB displays high adsorption capacity for Cs+ capture under a wide pH range (4.0-10). The kinetics of Cs+ uptake by FPPB is fast (>90% elimination capacity of relatively low Cs+ concentrations during only 20 min of Cs+/FPPB contact) and fit well with the pseudo-second-order kinetic model. This should be attributed to the high dispersion of PB nanoparticles. The adsorption Cs+ from complex solutions containing various competitive cations in large excess was also effective. FPPB is a cost-effective sorbent and could be developed by only stirring using environmental friendly and inexpensive materials at room temperature. Furthermore, the FPPB-Cs+ can be easily retrieved from water with sieve. It is expected that the as-prepared FPPB has extensive applicability in the elimination of radiocesium from nuclear wastewater.

刊物名称:

Chemical Engineering Journal

英文刊物名称:

Chemical Engineering Journal

英文参与作者:

Li, H. Y., Zhai, J. L., Yu, H. W.