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Trace amounts of MgO were doped on Cu/ZnO/Al
2O
3 catalysts with the Cu/Zn/Al molar ratio of 45/45/10 and tested for the water–gas shift (WGS) reaction. A mixture of Zn(Cu)–Al hydrotalcite (HT) and Cu/Zn aurichalcite was prepared by co-precipitation (
cp) of the metal nitrates and calcined at 300 °C to form the catalyst precursor. When the precursor was dispersed in an aqueous solution of Mg(II) nitrate, HT was reconstituted by the “memory effect.” During this procedure, the catalyst particle surface was modified by MgO-doping, leading to a high sustainability. Contrarily,
cp-Mg/Cu/Zn/Al prepared by Mg
2+, Cu
2+, Zn
2+ and Al
3+ co-precipitation as a control exhibited high activity but low sustainability. Mg
2+ ions were enriched in the surface layer of
m-Mg–Cu/Zn/Al, whereas Mg
2+ ions were homogeneously distributed throughout the particles of
cp-Mg/Cu/Zn/Al. CuO particles were significantly sintered on the
m-catalyst during the dispersion, whereas CuO particles were highly dispersed on the
cp-catalyst. However, the
m-catalyst was more sustainable against sintering than the
cp-catalyst. Judging from TOF, the surface doping of MgO more efficiently enhanced an intrinsic activity of the
m-catalyst than the
cp-catalyst. Trace amounts of MgO on the catalyst surface were enough to enhance both activity and sustainability of the
m-catalyst by accelerating the reduction–oxidation between Cu
0 and Cu
+ and by suppressing Cu
0 (or Cu
+) oxidation to Cu
2+.