Role of surface on magnetic properties of La1−xSrxΜn03+δ nanocrystallites

2015 IEEE Magnetics Conference (INTERMAG) Pub Date : 2015-05-11 DOI:10.1109/INTMAG.2015.7156774

Z. Jirák, M. Kačenka, O. Kaman, M. Maryško, N. Belozerova, S. Kichanov, D. Kozlenko

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引用次数: 5

Abstract

The ferromagnetic La1-xSrxMnO3+δ particles have recently been prepared from the flux of sodium nitrite at ≈500°C [1,2]. The advantage of this facile method is the high yield of cubic-shape nanocrystals without a very fine matter that is common for an alternative preparation via sol-gel route. The size of the as-prepared nanoparticles is ≈50 nm. A detailed magnetic study, including the neutron diffraction at zero and high pressures, has been performed on as-prepared particles of compositions x=0 .28 and 0 .37. Based on these experiments we conclude that as-prepared manganite particles show certain oxygen excess δ>0 that can be ascribed mainly to the surface oxygen chemisorption [3]. As a consequence the valence of Mn ions is shifted toward a higher oxidation state and this shift has probably a pronounced radial distribution in the particles, reaching possibly pure Mn4+ at the uppermost surface layers. We suggest that such overdoping is the true reason for “magnetically dead” shell in the manganite nanoparticles and is also the source of surface stress that compresses the particle core and modifies its physical properties. Such compressive stress drives the magnetic ground state of x=0 .37 particles towards a mixture of FM and A-type AFM ordering. In the x=0 .28 particles, only the FM phase is observed (M1000kA/m(4.5 K)=59.7 Am2/kg, TC=319 K), but an A-type AFM component can be induced by application of high external pressures. Our observations are interpreted based on so-called t-J hamiltonian that takes into account the superexchange between localized t2g spins (S=3/2) and the double exchange mediated by itinerant eg carriers (s=1/2) of Mn3+/Mn4+ perovskite lattice [4].

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表面对La1−xSrxΜn03+δ纳米晶磁性能的影响

最近，用亚硝酸钠在≈500℃的温度下制备了铁磁性La1-xSrxMnO3+δ颗粒[1,2]。这种简单的方法的优点是高产量的立方形状的纳米晶体没有非常细的物质，是常见的替代制备通过溶胶-凝胶途径。制备的纳米颗粒尺寸约为50 nm。对制备的成分x= 0.28和0.37的粒子进行了详细的磁性研究，包括零压和高压下的中子衍射。根据这些实验，我们得出结论，制备的锰矿颗粒表现出一定的氧过量δ>0，这主要归因于表面氧化学吸附[3]。结果，Mn离子的价向更高的氧化态移动，这种移动可能在颗粒中具有明显的径向分布，可能在最上层的表层达到纯Mn4+。我们认为，这种过度掺杂是锰酸盐纳米颗粒中“磁死”壳的真正原因，也是表面应力的来源，从而压缩颗粒核心并改变其物理性质。这种压应力驱动x= 0.37粒子的磁基态向FM和a型AFM有序的混合方向发展。在x= 0.28的粒子中，只观察到FM相(M1000kA/m(4.5 K)=59.7 Am2/kg, TC=319 K)，但高外部压力可以诱导出a型AFM组分。我们的观察结果是基于所谓的t-J哈密顿量来解释的，该哈密顿量考虑了局部t2g自旋(S=3/2)和Mn3+/Mn4+钙钛矿晶格中流动eg载流子(S= 1/2)之间的超交换[4]。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 IEEE Magnetics Conference (INTERMAG)

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