RUI: Collaborative Research: Spin-gapless semiconductivity and half-metallicity in Heusler alloys

RUI:合作研究:霍斯勒合金中的自旋无隙半导体性和半金属性

基本信息

  • 批准号:
    2003856
  • 负责人:
  • 金额:
    $ 15.99万
  • 依托单位:
  • 依托单位国家:
    美国
  • 项目类别:
    Standard Grant
  • 财政年份:
    2020
  • 资助国家:
    美国
  • 起止时间:
    2020-08-15 至 2024-07-31
  • 项目状态:
    已结题

项目摘要

Non-Technical Abstract:Current computing technology is based on the manipulation of the charge of electrons for the purpose of information processing. Hard disks, which are used in large-scale storage of data, function by exploiting the intrinsic magnetism of electrons. Spintronics is a fledging field that unites these two technologies to create a new computing paradigm that could result in substantial enhancements in computing speed and attendant energy efficiency. Spintronic devices such as magnetic random access memory (MRAM) have already been commercialized but the potential of spintronics is far greater. This project advances the field of spintronics through the systematic discovery of new materials that possess the necessary electronic and magnetic properties to undergird large-scale development of new spintronic devices. The project combines both theoretical and experimental approaches to maximize the effectiveness of the discovery process. In addition to its direct scientific impact, the project positively influences the development of the future science and technology workforce through the heavy involvement of undergraduate students in all aspects of the research. Outreach programs involving K-12 students and the general public further broadens the impact of the project via engaging activities that emphasize and elevate the importance of science to the well-being of humanity. This project is jointly funded by the Division of Materials Research (DMR) and the Established Program to Stimulate Competitive Research (EPSCoR).Technical Abstract:The main goal of this project is the identification and synthesis of new half-metallic (HM) and spin-gapless semiconducting (SGS) materials for applications in spintronics. In particular, this project investigates structural, magnetic, electronic, and spin-transport properties of HM and SGS Heusler alloys in bulk and thin-film geometry. This is achieved by performing comprehensive theoretical and experimental investigations of candidate materials, using state-of-the-art techniques, tools, and research methods, including X-ray diffraction, transmission electron microscopy, Quantum Design VersaLab magnetometer, Quantum Design Physical Property Measurement System, point-contact Andreev reflection, and first-principles density functional calculations. The project is motivated by recent discovery that certain Heusler compounds change their ground state from metallic to SGS and/or HM upon modification of their elemental compositions. This approach has a clear advantage over mechanical strain-induced half-metallic transitions reported in the literature, as it requires no external pressure. Second, this project provides experimental confirmation that certain half-metals retain a 100% spin-polarization in thin-film geometry, contrary to the conventional wisdom that reduced geometry destroys half-metallicity due to the emergence of surface states. This could open a new page in spintronic applications, e.g., in devices based on multilayer design, such as magnetoresistive tunnel junctions. This project is jointly funded by the Division of Materials Research (DMR) and the Established Program to Stimulate Competitive Research (EPSCoR).This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
非技术摘要:目前的计算技术是基于对电子电荷的操纵,以实现信息处理的目的。用于大规模数据存储的硬盘通过利用电子的固有磁性来工作。自旋电子学是一个新兴的领域,它将这两种技术结合起来,创造了一种新的计算模式,可以大大提高计算速度和随之而来的能源效率。自旋电子器件,如磁性随机存取存储器(MRAM)已经商业化,但自旋电子学的潜力要大得多。该项目通过系统地发现具有必要的电子和磁性的新材料来推进自旋电子学领域,以支持新自旋电子器件的大规模开发。该项目结合了理论和实验方法,以最大限度地提高发现过程的有效性。除了其直接的科学影响,该项目积极影响未来的科学和技术劳动力的发展,通过在研究的各个方面的本科生的大量参与。涉及K-12学生和公众的外联计划通过参与强调和提升科学对人类福祉重要性的活动进一步扩大了该项目的影响。该项目由材料研究部(DMR)和刺激竞争研究的既定计划(EPSCoR)共同资助。技术摘要:该项目的主要目标是识别和合成新的半金属(HM)和自旋无隙半导体(SGS)材料,用于自旋电子学。特别是,该项目研究HM和SGS Heusler合金在大块和薄膜几何结构中的结构,磁性,电子和自旋输运性质。这是通过对候选材料进行全面的理论和实验研究来实现的,使用最先进的技术,工具和研究方法,包括X射线衍射,透射电子显微镜,量子设计VersaLab磁力计,量子设计物理特性测量系统,点接触Andreev反射和第一原理密度泛函计算。该项目的动机是最近发现某些Heusler化合物在改变其元素组成后将其基态从金属变为SGS和/或HM。这种方法有一个明显的优势,在文献中报道的机械应变诱导的半金属化转变,因为它不需要外部压力。第二,该项目提供了实验证实,某些半金属保持100%的自旋极化薄膜几何形状,相反的传统智慧,减少几何破坏半金属由于表面状态的出现。这可能会在自旋电子学应用中打开新的一页,例如,在基于多层设计的器件中,例如磁阻隧道结。该项目由材料研究部(DMR)和促进竞争研究的既定计划(EPSCoR)共同资助。该奖项反映了NSF的法定使命,并通过使用基金会的知识价值和更广泛的影响审查标准进行评估,被认为值得支持。

项目成果

期刊论文数量(1)
专著数量(0)
科研奖励数量(0)
会议论文数量(0)
专利数量(0)

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Parashu Kharel其他文献

Synthesis, structure, morphology, magnetism, and magnetocaloric-effect studies of Lasub0.7/subSrsub0.3/subMnsub1−x/subFesubx/subOsub3/sub perovskite nanoparticles
镧锶锰铁氧体钙钛矿纳米粒子的合成、结构、形貌、磁性和磁热效应研究
  • DOI:
    10.1016/j.jallcom.2023.170454
  • 发表时间:
    2023-10-05
  • 期刊:
  • 影响因子:
    6.300
  • 作者:
    Turkiya M. Al-Shahumi;Imaddin A. Al-Omari;Salim H. Al-Harthi;Myo Tay Zar Myint;Parashu Kharel;Suvechhya Lamichhane;Sy-Hwang Liou
  • 通讯作者:
    Sy-Hwang Liou
Effect of atomic disorder on electronic, magnetic and electron-transport properties of Tisub2/subMnAl
原子无序对 Tisub2/subMnAl 的电子、磁和电子输运性质的影响
  • DOI:
    10.1016/j.jallcom.2021.162625
  • 发表时间:
    2022-02-25
  • 期刊:
  • 影响因子:
    6.300
  • 作者:
    Pavel V. Lukashev;Zachary Lehmann;Lukas Stuelke;Randall Filippone;Bishnu Dahal;Shah Valloppilly;Jace Waybright;Arjun K. Pathak;Yung Huh;Paul M. Shand;Parashu Kharel
  • 通讯作者:
    Parashu Kharel

Parashu Kharel的其他文献

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