Ab-initio study of paramagnetic defects in Mn and Cr doped transparent polycrystalline Al2O3 ceramics

Mubashir Mansoor, Mehya Mansoor, M. Mansoor, Zuhal Er, Filiz Çinar Şahin
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引用次数: 6

Abstract

Birefringence is a major source of difficulty in sintering of transparent polycrystalline alumina ceramics, especially as the grain size exceeds a few hundred nanometers, which ultimately leads to complete opacity, mainly due to scattering of light. Recent studies have made it clear that by application of a strong magnetic field, alumina grains can be aligned along a particular crystallographic orientation, which minimizes scattering due to birefringence, and enhances transparency. Defects that cause spin delocalization are known to induce a paramagnetic behavior in alumina ceramics. Therefore, such defects have become a focal point of research for magnetic field assisted sintering of transparent polycrystalline alumina, in order to reduce the necessary magnetic field strength during production process. In light of recent studies on paramagnetic potentials of transition metal doped alumina, we have applied Spin Polarized Density Functional Theory (SP-DFT) calculations on manganese and chromium doped and co-doped alumina to calculate the magnetic moments, density of states and defect formation energies, which should be expected from this system of dopants, along with their interactions with oxygen vacancies. The results clearly indicate that formation of a point defect comprised of chromium and manganese positioned substitutionally at adjacent aluminum sites, in vicinity of an oxygen vacancy can induce a magnetic moment equivalent to 5 Bohr magnetons (μβ), outperforming previously reported defects. Based on this study we find it likely that chromium and manganese co-doping in alumina can further reduce the required magnetic field strength for production of transparent polycrystalline alumina.
Mn和Cr掺杂透明多晶Al2O3陶瓷顺磁缺陷的Ab-initio研究
双折射是透明多晶氧化铝陶瓷烧结困难的主要来源,特别是当晶粒尺寸超过几百纳米时,这最终导致完全不透明,主要是由于光的散射。最近的研究表明,通过施加强磁场,氧化铝颗粒可以沿着特定的晶体取向排列,从而最大限度地减少由于双折射引起的散射,并提高透明度。引起自旋离域的缺陷已知会在氧化铝陶瓷中诱发顺磁性行为。因此,这类缺陷已成为磁场辅助烧结透明多晶氧化铝的研究热点,以降低生产过程中所需的磁场强度。鉴于最近对过渡金属掺杂氧化铝的顺磁势的研究,我们应用自旋极化密度泛函理论(SP-DFT)计算了锰和铬掺杂和共掺杂氧化铝的磁矩、态密度和缺陷形成能,以及它们与氧空位的相互作用。结果清楚地表明,在氧空位附近的相邻铝位上形成由铬和锰取代组成的点缺陷,可以产生相当于5玻尔磁子(μβ)的磁矩,优于先前报道的缺陷。基于本研究,我们发现在氧化铝中铬锰共掺杂可能会进一步降低生产透明多晶氧化铝所需的磁场强度。
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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