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Electromagnetic Functionalization of Wide-Bandgap Dielectric Oxides by Boron Interstitial Doping.

Dae-Sung ParkGregory J ReesHaiyuan WangDiana RataAndrew J MorrisIgor V MaznichenkoSergey OstaninAkash BhatnagarChel-Jong ChoiRagnar D B JónssonKai KaufmannReza KashtibanMarc WalkerCheng-Tien ChiangEinar B ThorsteinssonZhengdong LuoIn-Sung ParkJohn V HannaIngrid MertigKathrin DörrHafliði P GíslasonChris F McConville
Published in: Advanced materials (Deerfield Beach, Fla.) (2018)
A surge in interest of oxide-based materials is testimony for their potential utility in a wide array of device applications and offers a fascinating landscape for tuning the functional properties through a variety of physical and chemical parameters. In particular, selective electronic/defect doping has been demonstrated to be vital in tailoring novel functionalities, not existing in the bulk host oxides. Here, an extraordinary interstitial doping effect is demonstrated centered around a light element, boron (B). The host matrix is a novel composite system, made from discrete bulk LaAlO3 :LaBO3 compounds. The findings show a spontaneous ordering of the interstitial B cations within the host LaAlO3 lattices, and subsequent spin-polarized charge injection into the neighboring cations. This leads to a series of remarkable cation-dominated electrical switching and high-temperature ferromagnetism. Hence, the induced interstitial doping serves to transform a nonmagnetic insulating bulk oxide into a ferromagnetic ionic-electronic conductor. This unique interstitial B doping effect upon its control is proposed to be as a general route for extracting/modifying multifunctional properties in bulk oxides utilized in energy and spin-based applications.
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