4.6 Article

Highly efficient removal of methylene blue via hollow graphene-based magnesium silicate

Journal

JOURNAL OF MATERIALS SCIENCE
Volume 56, Issue 29, Pages 16351-16361

Publisher

SPRINGER
DOI: 10.1007/s10853-021-06299-x

Keywords

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Funding

  1. Scientific and Technological Innovation Project of Fujian Province [2012H6008]
  2. Scientific and Technological Innovation Project of Fuzhou City [2013-G-92]

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A composite adsorbent of hollow bubble-wrap-like reduced graphene oxide/magnesium silicate (HG@MS) with high efficiency for methylene blue (MB) removal was successfully synthesized using a template and hydrothermal method. The adsorbent showed a large surface area, abundant adsorption sites for MB, maximum adsorption capacity, and recyclability. The adsorption kinetics and isothermal model were also studied, confirming the effectiveness of HG@MS for MB removal.
Methylene blue (MB) has been a severe threat to the ecological environment and organismal health, and synthesizing effective adsorbents for MB adsorption becomes an urgent demand for environmental protection. Magnesium silicate (MgSi) has proven to be an efficient adsorbent for MB removal. A hollow bubble-wrap-like reduced graphene oxide/magnesium silicate (HG@MS) composite with high efficiency for MB removal was synthesized by template and hydrothermal method. Microsphere polystyrene was used as the template for fabricating bubble-wrap-like graphene oxide, while magnesium silicate is in situ growth on the surface of reduced graphene oxide. After removing the PS template, the hollow bubble-wrap-like HG@MS adsorbent was made, which was assigned to a large surface area (570 cm(2)/g). Such a high surface area provides abundant adsorption sites for MB, which resulted in the maximum adsorption capacity of 595.2 mg/g. Meanwhile, the adsorption of MB on the adsorbent follows the pseudo-second-order kinetic model and the Langmuir isothermal model. The desorption results reflected that HG@MS remains 86% adsorption capacities for 5 recycles, which confirms HG@MS is recyclable.

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