Metal-insulator transition induced by oxygen isotope exchange in the magnetoresistive perovskite manganites

Perovskite manganites derived from LaMnO3 have recently become the subject of intensive study following the discovery of 'colossal' magnetoresistance (a magnetically induced change in electrical resistance of up to several orders of magnitude) in several members of this family of compounds...

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Veröffentlicht in:Nature (London) 1998-01, Vol.391 (6663), p.159-161
Hauptverfasser: Gorbenko, O. Yu, Babushkina, N. A, Belova, L. M, Kaul, A. R, Bosak, A. A, Ozhogin, V. I, Kugel, K. I
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container_issue 6663
container_start_page 159
container_title Nature (London)
container_volume 391
creator Gorbenko, O. Yu
Babushkina, N. A
Belova, L. M
Kaul, A. R
Bosak, A. A
Ozhogin, V. I
Kugel, K. I
description Perovskite manganites derived from LaMnO3 have recently become the subject of intensive study following the discovery of 'colossal' magnetoresistance (a magnetically induced change in electrical resistance of up to several orders of magnitude) in several members of this family of compounds. The manganites exhibit a broad range of electronic and magnetic phases, ranging from low-resistance ferromagnetic metals to high-resistance insulators, which are extremely sensitive to variation of composition, temperature and pressure. A recent study showed that such sensitivity also extends to oxygen isotope exchange: replacing 16O with 18O in La0.8Ca0.2MnO3 produces an unusually large change in the magnetic properties (a 21-kelvin decrease in the Curie temperature). The magnitude of this isotope shift is evidence for the essential role played by electron-phonon coupling in determining the transport properties of these materials. Here we show that this sensitivity to oxygen isotope exchange can be even more extreme. In its normal state, the compound La0.175Pr0.525Ca0.3MnO3 undergoes an insulator-to-metal transition as it is cooled below ∼95 K. But we find that, after substituting 18O for 16O, the compound remains an insulator down to 4.2 K, so providing a vivid demonstration of the importance of lattice vibrations in these materials.
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Yu ; Babushkina, N. A ; Belova, L. M ; Kaul, A. R ; Bosak, A. A ; Ozhogin, V. I ; Kugel, K. I</creator><creatorcontrib>Gorbenko, O. Yu ; Babushkina, N. A ; Belova, L. M ; Kaul, A. R ; Bosak, A. A ; Ozhogin, V. I ; Kugel, K. I</creatorcontrib><description>Perovskite manganites derived from LaMnO3 have recently become the subject of intensive study following the discovery of 'colossal' magnetoresistance (a magnetically induced change in electrical resistance of up to several orders of magnitude) in several members of this family of compounds. The manganites exhibit a broad range of electronic and magnetic phases, ranging from low-resistance ferromagnetic metals to high-resistance insulators, which are extremely sensitive to variation of composition, temperature and pressure. A recent study showed that such sensitivity also extends to oxygen isotope exchange: replacing 16O with 18O in La0.8Ca0.2MnO3 produces an unusually large change in the magnetic properties (a 21-kelvin decrease in the Curie temperature). The magnitude of this isotope shift is evidence for the essential role played by electron-phonon coupling in determining the transport properties of these materials. Here we show that this sensitivity to oxygen isotope exchange can be even more extreme. In its normal state, the compound La0.175Pr0.525Ca0.3MnO3 undergoes an insulator-to-metal transition as it is cooled below ∼95 K. 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The manganites exhibit a broad range of electronic and magnetic phases, ranging from low-resistance ferromagnetic metals to high-resistance insulators, which are extremely sensitive to variation of composition, temperature and pressure. A recent study showed that such sensitivity also extends to oxygen isotope exchange: replacing 16O with 18O in La0.8Ca0.2MnO3 produces an unusually large change in the magnetic properties (a 21-kelvin decrease in the Curie temperature). The magnitude of this isotope shift is evidence for the essential role played by electron-phonon coupling in determining the transport properties of these materials. Here we show that this sensitivity to oxygen isotope exchange can be even more extreme. In its normal state, the compound La0.175Pr0.525Ca0.3MnO3 undergoes an insulator-to-metal transition as it is cooled below ∼95 K. But we find that, after substituting 18O for 16O, the compound remains an insulator down to 4.2 K, so providing a vivid demonstration of the importance of lattice vibrations in these materials.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><doi>10.1038/34380</doi><tpages>3</tpages></addata></record>
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subjects Chemistry
Curie temperature
Humanities and Social Sciences
Insulators
Isotopes
letter
Magnetic properties
Magnetoresistivity
Manganites
Metals
multidisciplinary
Oxygen
Oxygen isotopes
Perovskites
Phases
Science
Science (multidisciplinary)
title Metal-insulator transition induced by oxygen isotope exchange in the magnetoresistive perovskite manganites
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