Exploring PtSO4 and PdSO4 phases: an evolutionary algorithm based investigation

Abstract

Metal sulfate formation is one of the major challenges to the emissions aftertreatment catalysts. Unlike the incredibly sulfation prone nature of Pd to form PdSO4, no experimental evidence exits for the PtSO4 formation. Given the mystery of nonexistence of the PtSO4, we explore the PtSO4 using a combined approach of evolutionary algorithm based search technique and quantum mechanical computations. Experimentally known PdSO4 is considered for the comparison and validation of our results. We predict many possible low-energy phases of the PtSO4 and PdSO4 at 0K, which are further investigated under wide range of temperature-pressure conditions. An entirely new low-energy (tetragonal P42/m) structure of the PtSO4 and PdSO4 is predicted, which appears to be the most stable phase of the PtSO4 and a competing phase of the experimentally known monoclinic C2/c phase of PdSO4. Phase stability at finite temperature is further examined and verified by free energy calculations of sulfates towards their possible decomposition products. Finally, temperature-pressure phase diagrams are computationally established for both PtSO4 and PdSO4.