Impact of evolution of structural defects on the ferromagnetic and electrical properties of laser deposited Indium-doped SnO2 thin films

IF 2.1 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Solid State Communications Pub Date : 2024-08-15 DOI:10.1016/j.ssc.2024.115658

Shyamsundar Ghosh

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Abstract

Impact of non-magnetic cationic-substitution on the evolution of structural defects and correlated ferromagnetic and electrical properties are investigated in series of pulsed laser deposited Sn_1-xIn_xO₂ (0.0 ≤ x ≤ 0.12) thin films. Beyond the nominal doping concentration of 2 at.% (i.e. x > 0.02), Indium (In)-doped SnO₂ film switches to exhibit from n-type to p-type electrical conductivity and simultaneously the magnetization (M_S) as well as the Curie temperature (T_C) of the films increase significantly. Estimated values of ‘M_S’ and ‘T_C’ are found to achieve as large as 15.21 emu/cm³ and 540 K respectively when In-doping concentration approaches towards x = 0.08 and afterwards tend to decrease abruptly. Various spectroscopic techniques including Positron Annihilation Lifetime Spectroscopy (PALS) have detected the existence of Sn vacancy (V_Sn) defects within Sn_1-xIn_xO₂ films arise as the effect of In-substitution at Sn site (In_Sn) under O-rich atmosphere. The estimated positron lifetimes and the increase of line-shape S-parameter confirm the rise of V_Sn defects which serve as the major source of magnetic moments in non-magnetic host SnO₂. Besides, In_Sn defects introduce excess holes within SnO₂ lattice and thereby the magnetic spin-spin RKKY interaction between near-by V_Sn defects are mediated ferromagetically through the localized holes. For x > 0.08, stabilization of various donor-type defects such as Sn interstitial (Sn_i), indium interstitial (In_i) actually compensates the acceptors that leads to reduce the effective hole density consequently diminishing the strength of ferromagnetism within SnO₂. Hence, tuning of such ferromagnetic and semiconducting properties through non-magnetic cationic substitution in transparent conducting oxides can be very promising in the field of next-generation spintronics.

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结构缺陷演变对激光沉积掺铟二氧化硒薄膜铁磁性和电学特性的影响

在一系列脉冲激光沉积的 Sn1-xInxO2 (0.0 ≤ x ≤ 0.12) 薄膜中，研究了非磁性阳离子替代对结构缺陷演变以及相关铁磁性和电特性的影响。当标称掺杂浓度超过 2 at.%（即 x >0.02）时，掺铟二氧化锡薄膜的导电性会从 n 型转变为 p 型，同时薄膜的磁化率（MS）和居里温度（TC）也会显著增加。当铟掺杂浓度接近 x = 0.08 时，"MS "和 "TC "的估计值分别达到 15.21 emu/cm3 和 540 K，之后则骤然下降。包括正电子湮没寿命光谱（PALS）在内的各种光谱技术检测到 Sn1-xInxO2 薄膜中存在 Sn 空位（VSn）缺陷，这是由于在富 O 气氛下 Sn 位点（InSn）的 In 取代效应造成的。估算的正电子寿命和线形 S 参数的增加证实了 VSn 缺陷的增加，它是非磁性主 SnO2 中磁矩的主要来源。此外，InSn 缺陷在 SnO2 晶格中引入了过剩的空穴，因此近邻 VSn 缺陷之间的磁性自旋-自旋 RKKY 相互作用通过局部空穴以铁磁方式介导。当 x > 0.08 时，各种供体型缺陷（如锡间隙（Sni）、铟间隙（Ini））的稳定实际上补偿了受体，导致有效空穴密度降低，从而减弱了二氧化锡内部的铁磁性强度。因此，通过透明导电氧化物中的非磁性阳离子取代来调整这种铁磁性和半导体特性，在下一代自旋电子学领域大有可为。

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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来源期刊

Solid State Communications 物理-物理：凝聚态物理

CiteScore

3.40

自引率

4.80%

发文量

287

审稿时长

51 days

期刊介绍： Solid State Communications is an international medium for the publication of short communications and original research articles on significant developments in condensed matter science, giving scientists immediate access to important, recently completed work. The journal publishes original experimental and theoretical research on the physical and chemical properties of solids and other condensed systems and also on their preparation. The submission of manuscripts reporting research on the basic physics of materials science and devices, as well as of state-of-the-art microstructures and nanostructures, is encouraged. A coherent quantitative treatment emphasizing new physics is expected rather than a simple accumulation of experimental data. Consistent with these aims, the short communications should be kept concise and short, usually not longer than six printed pages. The number of figures and tables should also be kept to a minimum. Solid State Communications now also welcomes original research articles without length restrictions. The Fast-Track section of Solid State Communications is the venue for very rapid publication of short communications on significant developments in condensed matter science. The goal is to offer the broad condensed matter community quick and immediate access to publish recently completed papers in research areas that are rapidly evolving and in which there are developments with great potential impact.