Transition metal lithium orthosilicates are promising cathode materials for lithium-ion batteries. Here we report a combined experimental (in situ X-ray diffraction) and computational (static lattice and molecular dynamics) study of the thermal behavior of the Li2Fe0.5Mn0.5SiO4 orthosilicate from room temperature to 950°C. Our X-ray results showed that Pmnb polymorph is the most stable all over the explored temperature range. A significant cation disorder up to 80%, based on the anti-site defect, was found. The defect concentration depends on the synthesis route and temperature, and is completely reversible after the thermal treatments. Moreover, a careful analysis of the impurity phases allowed us to identify Li2SiO3, Fe3O4 and Li3Fe5O8, the last one never reported before.The minimization of defects by opportunely tuning the synthetic parameters would be of great importance in view of potential applications of these materials in lithium batteries.
Insight into cation disorder of Li2Fe0.5Mn0.5SiO4
BINI, MARCELLA;FERRARI, STEFANIA;CAPSONI, DORETTA;TEALDI, CRISTINA;MUSTARELLI, PIERCARLO
2013-01-01
Abstract
Transition metal lithium orthosilicates are promising cathode materials for lithium-ion batteries. Here we report a combined experimental (in situ X-ray diffraction) and computational (static lattice and molecular dynamics) study of the thermal behavior of the Li2Fe0.5Mn0.5SiO4 orthosilicate from room temperature to 950°C. Our X-ray results showed that Pmnb polymorph is the most stable all over the explored temperature range. A significant cation disorder up to 80%, based on the anti-site defect, was found. The defect concentration depends on the synthesis route and temperature, and is completely reversible after the thermal treatments. Moreover, a careful analysis of the impurity phases allowed us to identify Li2SiO3, Fe3O4 and Li3Fe5O8, the last one never reported before.The minimization of defects by opportunely tuning the synthetic parameters would be of great importance in view of potential applications of these materials in lithium batteries.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
