Temperature-programmed reduction study on calcination of nano-palladium

Effects of calcination treatment on samples of mono-metallic Pd and Pd-77-A g-23 alloy with primary particles around 8 nm were studied with the tempera ture-programmed reduction technique. Temperature profiles of hydrogen consu mption for calcined samples from a stream of 10% H-2 in N-2 were monitored by a thermal conductivity detector. Two distinct peaks, i.e., a consumption of hydrogen for PdO reduction and a subsequent desorption of hydrogen from bulk palladium hydride, were observed. The extent of palladium oxidation u pon calcinations increased with the temperature of calcination (T-o): i.e., chemisorption of oxygen on particle surface upon calcination at T-o < 373 K, reconstruction into a surface PdO structure at 473 K and incorporation i nto sublayers to form bulk PdO structure at high T-o. Minimum temperature ( T-r) required for reduction of oxidized palladium by the hydrogen stream wa s generally low (150 K < T-r < 320 K) and increased with the extent of oxid ation. A quantitative measurement of hydrogen desorbed from reduced samples suggested a formation of alloy phase in freshly prepared Ag-77-Pd-23 prima ry particles. The freshly prepared alloy was inhomogeneous in composition b ut became homogeneous upon calcination at T-o < 673 K.