Nanosheets-built flowerlike micro/nanostructured Bi2O2.33 and its highly efficient iodine removal performances
作者:Shengwen Liu, Shenghong Kang, Huimin Wang, Guozhong Wang, Huijun Zhao and Weiping Cai
期刊:Chemical Engineering Journal
卷(期)页:2016, 289, 219-230
全文链接:http://www.sciencedirect.com/science/article/pii/S1385894715017738
The flowerlike micro/nanostructured bismuth oxide is synthesized by the solvothermal reaction using ethylene glycol–ethanol solution of bismuth nitrate pentahydrate. The as-synthesized bismuth oxide powders consist of the flowerlike microscaled particles with the size mostly falling into the range of 2–5 μm. The particles are built with the cross-linked nanosheets of 5–10 nm in thickness. Such micro/nanostructured bismuth oxide particles are, stoichiometrically, Bi6O7 or Bi2O2.33. Importantly, this material has exhibited the highly efficient adsorption performances to both negatively univalent iodine ions I− and quinquevalent iodine ions I(V) (or IO3−) with fast kinetic processes and high capacities. The maximum adsorption capacities are up to 285 and 229 mg g−1 for I− and I(V), respectively, which are much higher than those for the most reported adsorbents. This highly efficient iodine removal performance is attributed to the adsorption-induced chemical reaction mechanism as well as the micro/nanostructure of the flower-like Bi2O2.33 particles. Further experiments have demonstrated that such material has a strong selectivity to both I− and I(V) in the solution with largely excessive competitive anions such as nitrate and sulfate, can work in a wide pH range from 3 to 11, and has exhibited good practicability for highly efficient iodine removal from the real iodine-contaminated waters. This work not only deepens understanding of iodine adsorption behaviors, but also provides a promising iodine adsorbent.
期刊:Chemical Engineering Journal
卷(期)页:2016, 289, 219-230
全文链接:http://www.sciencedirect.com/science/article/pii/S1385894715017738
The flowerlike micro/nanostructured bismuth oxide is synthesized by the solvothermal reaction using ethylene glycol–ethanol solution of bismuth nitrate pentahydrate. The as-synthesized bismuth oxide powders consist of the flowerlike microscaled particles with the size mostly falling into the range of 2–5 μm. The particles are built with the cross-linked nanosheets of 5–10 nm in thickness. Such micro/nanostructured bismuth oxide particles are, stoichiometrically, Bi6O7 or Bi2O2.33. Importantly, this material has exhibited the highly efficient adsorption performances to both negatively univalent iodine ions I− and quinquevalent iodine ions I(V) (or IO3−) with fast kinetic processes and high capacities. The maximum adsorption capacities are up to 285 and 229 mg g−1 for I− and I(V), respectively, which are much higher than those for the most reported adsorbents. This highly efficient iodine removal performance is attributed to the adsorption-induced chemical reaction mechanism as well as the micro/nanostructure of the flower-like Bi2O2.33 particles. Further experiments have demonstrated that such material has a strong selectivity to both I− and I(V) in the solution with largely excessive competitive anions such as nitrate and sulfate, can work in a wide pH range from 3 to 11, and has exhibited good practicability for highly efficient iodine removal from the real iodine-contaminated waters. This work not only deepens understanding of iodine adsorption behaviors, but also provides a promising iodine adsorbent.