Details

Autor(en) / Beteiligte

• Imran, Ahmad
• López-Rayo, Sandra
• Magid, Jakob
• Hansen, Hans Christian Bruun

Titel

Dissolution kinetics of pyroaurite-type layered double hydroxide doped with Zn: Perspectives for pH controlled micronutrient release

Ist Teil von

• Applied clay science, 2016-04, Vol.123, p.56-63

Ort / Verlag

Elsevier B.V

Erscheinungsjahr

2016

Link zum Volltext

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Layered double hydroxides (LDH) have a high potential for use as a source of micronutrients for plants since their dissolution rates may be controlled within the pH range observed in rhizospheres of plants in need of nutrients. Here the Zn2+ release from a pyroaurite-type LDH host at different pH was investigated. Zinc doped Mg–Fe(III) LDH intercalated with nitrate (PY(Zn)NO3) was synthesized by co-precipitation. For reference, both the nitrate and carbonate forms without Zn doping (PYNO3 and PYCO3) were also synthesized. The LDH with a Mg:Fe(III) molar ratio of 2 were found to be pure. LDH dissolution was monitored at a constant pH (4–8) to study the release of framework metal cations, dissolution stoichiometry and release kinetics. The LDH dissolved incongruently, releasing Mg2+ and Zn2+, and leaving an Fe(III)-enriched residue. The stoichiometry of metal release at a particular pH remained the same throughout the dissolution. Release kinetics of Zn2+ and Mg2+ from PY LDH was ‘first order’ with respect to the metal cations in the LDH, providing rate constants in the range of 0.16×10−3 to 10.1×10−3min−1, with the highest rate constants at low pH. Metal ion (M) release had a fractional order with respect to [H+], resulting in overall release kinetics according to: rate=kH×[M][H+]n with n in the range 0.25–0.43. The type of interlayer anion did not affect the overall release kinetics. Lower amounts of Zn2+ were released with respect to Mg2+ as pH increased, indicating that Zn2+ was increasingly retained in the residual Fe(III)-enriched phase. The present study demonstrates not only the pH-controlled release of micronutrient metal cations doped into the LDH framework but also points to resorption as critical parameters for optimizing the release profile. Furthermore, the present study indicates how the incorporation of the desired metal cation within the structure of the LDH may be adapted for other micronutrient/s such as Mn or Cu with the intention of using them as fertilizer. •Kinetics of LDH dissolution — a proton-promoted phenomenon•‘First order kinetic model’ predicted dissolution data with good accuracy.•Incorporation of Zn in matrix provided extra stability to LDH.•A full rate equation for dissolution that incorporates pH-dependence.