Uptake of heavy metal ions in layered double hydroxides and Applications in cementitious materials

Experimental evidence and first-principle study

Conference Paper (2018)
Author(s)

Bo Li (Wuhan University of Technology)

Shizhe Zhang (TU Delft - Civil Engineering & Geosciences)

Qiu Li (Wuhan University of Technology)

Neng Li (Eindhoven University of Technology, Wuhan University of Technology)

Bo Yuan (Wuhan University of Technology)

HJH Brouwers (Eindhoven University of Technology)

Qingliang Yu (Eindhoven University of Technology)

Wei Chen (Wuhan University of Technology)

Research Group
Materials and Environment
More Info
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Publication Year
2018
Language
English
Research Group
Materials and Environment
Pages (from-to)
283-297
ISBN (electronic)
978-2-35158-213-8
Event
4th International Conference on Service<br/>Life Design for Infrastructures (2018-08-27 - 2018-08-30), Delft, Netherlands
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Abstract

The uptake mechanism of heavy metal ions in Layered double hydroxides (LDHs) is investigated in this paper via solid-solution exchange experiments and first principle study. The structures of heavy metal doped LDHs are revealed with XRD, TEM and solid state NMR analysis combined with first principle calculations. The experimental results show that Cu2+ or Cr3+ ions are immobilized in the form of isomorphic substitution during reconstruction of calcined LDHs, forming a non-stoichiometric structure. The Cu2+ or Cr3+ ions are immobilized via isomorphic substitution for Mg2+ and Al3+ in the plate of the layered structure, respectively. The structure of Cu2+ doped LDHs is identified as as [Mg2+ (1-x)(1- z)Cu2+ (1-x)zAl3+ x(OH)2] Anx/ n·yH2O, where z is the Cu2+/Mg2+ molar ratio. The structure of Cr3+ doped LDHs is identified as [Mg2+ 1-x Cr3+ xzAl3+
x(1-z)(OH)2] An- (x+z)/n·yH2O, where z is the Cr3+/Al3+ molar ratio. The Cu2+ or Cr3+ ions from mixing water can be efficiently immobilized with Mg-Al LDHs in cement.

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