Mg doping enhanced magnetoelectric effect in the polar magnet Fe2Mo3O8

Magnetoelectric (ME) effect has given rise to a new design principle for novel low-power electronic devices. The polar magnet Fe2Mo3O8 with linear ME effect is one of the promising candidates. Unfortunately, for this material, a large ME response only appears in the ferrimagnetic state, which needs a high magnetic field to be activated. In this work, we successfully synthesize single-crystal (Fe0.95Mg0.05)2Mo3O8 (FMMO), which achieves a linear ME effect in the antiferromagnetic ground state and shows a significantly improved ME coefficient in the ferrimagnetic state. Compared with the parent phase, six times linear ME coefficient and more than ten orders of magnitude second-order ME coefficient are accomplished in the FMMO. The spin-lattice coupling and the exchange-striction mechanism are believed to play a crucial role in creating the giant ME effect. The present study provides an idea for designing materials with strong ME coupling.

Automated summary

In this study, single-crystal (Fe0.95Mg0.05)2Mo3O8 was successfully synthesized, which exhibits a linear magnetoelectric effect in the antiferromagnetic ground state and shows a significantly improved magnetoelectric coefficient. The spin-lattice coupling and the exchange-striction mechanism are believed to play a crucial role in creating the giant magnetoelectric effect.