Litcius/Paper detail

Reversible manipulation of the magnetic state in SrRuO3 through electric-field controlled proton evolution

Zhuolu Li, Shengchun Shen, Zijun Tian, Kyle Hwangbo, Meng Wang, Yujia Wang, F. Michael Bartram, Liqun He, Yingjie Lyu, Yongqi Dong, Gang Wan, Hao‐Bo Li, Nianpeng Lu, Jiadong Zang, Hua Zhou, Elke Arenholz, Qing He, Luyi Yang, Weidong Luo, Pu Yu

2020Nature Communications135 citationsDOIOpen Access PDF

Abstract

Abstract Ionic substitution forms an essential pathway to manipulate the structural phase, carrier density and crystalline symmetry of materials via ion-electron-lattice coupling, leading to a rich spectrum of electronic states in strongly correlated systems. Using the ferromagnetic metal SrRuO 3 as a model system, we demonstrate an efficient and reversible control of both structural and electronic phase transformations through the electric-field controlled proton evolution with ionic liquid gating. The insertion of protons results in a large structural expansion and increased carrier density, leading to an exotic ferromagnetic to paramagnetic phase transition. Importantly, we reveal a novel protonated compound of HSrRuO 3 with paramagnetic metallic as ground state. We observe a topological Hall effect at the boundary of the phase transition due to the proton concentration gradient across the film-depth. We envision that electric-field controlled protonation opens up a pathway to explore novel electronic states and material functionalities in protonated material systems.

Topics & Concepts

ProtonationIonic bondingParamagnetismPhase transitionChemical physicsCondensed matter physicsMaterials scienceElectric fieldPhase boundaryFerromagnetismElectronic structurePhase (matter)IonChemistryPhysicsOrganic chemistryQuantum mechanicsAdvanced Condensed Matter PhysicsMagnetic and transport properties of perovskites and related materialsElectronic and Structural Properties of Oxides