Magnetism in quasi-two-dimensional tri-layer La2.1Sr1.9Mn3O10 manganite

Abstract

The tri-layer La3-3xSr1+3xMn3O10 manganites of Ruddlesden-Popper (RP) series are naturally arranged layered structure with alternate stacking of m-MnO2 (m = 3) planes and rock-salt type block layers (La, Sr)2O2 along c-axis. The dimensionality of the RP series manganites depends on the number of perovskite layers and significantly affects the magnetic and transport properties of the system. The tri-layer La2.1Sr1.9Mn3O10 shows second-order magnetic phase transition. The critical behavior of phase transition has been studied around the transition temperature (TC) to understand the low dimensional magnetism in tri-layer La2.1Sr1.9Mn3O10 of the Ruddlesden-Popper series manganites. We have determined the critical exponents for tri-layer La2.1Sr1.9Mn3O10, which belong to the short-range two-dimensional (2D)-Ising universality class. The low dimensional magnetism in tri-layer La2.1Sr1.9Mn3O10 manganite is also explained with the help of renormalization group theoretical approach for short-range 2D-Ising systems. It has been shown that the layered structure of tri-layer La2.1Sr1.9Mn3O10 results in three different type of interactions intra-planer ( Jab ), intra-tri-layer ( Jc ) and inter-tri-layer ( J' ) such that Jab > Jc >> J' and competition among these give rise to the canted antiferromagnetic spin structure above T C . Based on the similar magnetic interaction in bi-layer manganite, we propose that the tri-layer La2.1Sr1.9Mn3O10 should be able to host the skyrmion below T C due to its strong anisotropy and layered structure.