Enhancing electric-field control of ferromagnetism through nanoscale engineering of high-Tc MnxGe1−x nanomesh

Nie, Tianxiao; Tang, Jianshi; Kou, Xufeng; Yin, Gen; Lee, Shengwei; Zhu, Xiaodan; Chang, Li Te; Murata, Koichi; Fan, Yabin; Wang, Kang L.

doi:10.1038/ncomms12866

Cited by 35 publications

(33 citation statements)

References 49 publications

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“…Geometric-enhanced MR is another specific case of the orbital MR associated with the material shape [24,28]. Knudsen cells.…”

Section: Geometric-enhanced Mr Effectmentioning

confidence: 99%

“…Therefore, we pay our attention to the pattern-assistant growth of Mn x Ge 1−x nanostructures and disclose their MR property. In this section, Mn x Ge 1−x nanomesh is demonstrated, which could simultaneously provide the nanostructure benefit [55] and large-scale uniform fabrication [28]. The growth of Mn x Ge 1−x nanomesh is also proceeded in the MBE chamber.…”

Section: Geometric-enhanced and Electric-field Controlled Mr In Mn X mentioning

confidence: 99%

“…As the demand for the sensors with higher integration density and lower manufacturing cost is continuously growing, it calls for not only innovative sensor configuration but also novel material candidate with much higher sensitivity to magnetic field, higher compatibility with CMOS technology, and lower power consumption. Mn x Ge 1−x [26] as the silicon-compatible material appears to be an appealing candidate for application in MR sensors through the combined use of GMR [27] and geometric-enhanced MR [28]. In light of that, we give a review xbased MR sensors may set a new stage for the next-generation sensors with improved sensitivity, higher scalability, and higher compatibility with current CMOS technology.…”

Section: Introductionmentioning

confidence: 99%

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Engineering Magnetoresistance in MnxGe1−x System for Magnetic Sensor Application

Nie¹,

Zhao²,

Wang³

2017

Magnetic Sensors - Development Trends and Applications

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In 2007, a Nobel Prize is awarded to Dr. Albert Fert and Peter Grünberg for their contribution in giant magnetoresistance (GMR) effect. The magnetic head based on GMR effect has significantly increased the storage density in the hard disk drive (HDD) and brought the coming of the digital age. Besides, the rapid development of GMR sensor has opened a wide and promising range of applications, including the aspects in automobile, traffic monitor, biomedicine, and space, etc. As continuously extending the market, it needs GMR sensor with much lower cost, smaller size, higher sensitivity, and compatibility with the CMOS technology. In light of that, we give a review about the recent progress of the MR effect in Mn x Ge 1−x system, which refers to the material growth and magnetic and MR property. Through engineering the Mn x Ge 1−x structure, it could realize the transition from negative to positive MR, geometric-enhanced giant MR, and electricfield controlled MR. The fact of well-designed MR effect and high compatibility with Si technology brings a high potential and advantage for fabricating Mn x Ge 1−x-based MR sensors, which could be widely used in magnetic head and biomedical sensors, among others, with the superiority of much lower manufacturing cost, lower power dissipation, higher integration density, and higher sensitivity.

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“…Geometric-enhanced MR is another specific case of the orbital MR associated with the material shape [24,28]. Knudsen cells.…”

Section: Geometric-enhanced Mr Effectmentioning

confidence: 99%

Section: Geometric-enhanced and Electric-field Controlled Mr In Mn X mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Engineering Magnetoresistance in MnxGe1−x System for Magnetic Sensor Application

Nie¹,

Zhao²,

Wang³

2017

Magnetic Sensors - Development Trends and Applications

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“…Also, the tunability of the spin degrees of freedom in semiconducting materials offers a great potential for future spintronic applications. However, to achieve a reliable injection and detection of spin-polarized electrons in spintronic devices, appropriate heterostructures between semiconductors and magnetic alloys [9,10] need to be formed. Hence, a tailored growth process that preserves the injection efficiency and high Curie temperature is necessary.…”

Section: Introductionmentioning

confidence: 99%

Spontaneous shape transition of Mn_xGe₁₋_x islands to long nanowires

Rezvani¹,

Favre²,

Giuli³

et al. 2021

Beilstein J. Nanotechnol.

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We report experimental evidence for a spontaneous shape transition, from regular islands to elongated nanowires, upon high-temperature annealing of a thin Mn wetting layer evaporated on Ge(111). We demonstrate that 4.5 monolayers is the critical thickness of the Mn layer, governing the shape transition to wires. A small change around this value modulates the geometry of the nanostructures. The Mn–Ge alloy nanowires are single-crystalline structures with homogeneous composition and uniform width along their length. The shape evolution towards nanowires occurs for islands with a mean size of ≃170 nm. The wires, up to ≃1.1 μm long, asymptotically tend to ≃80 nm of width. We found that tuning the annealing process allows one to extend the wire length up to ≃1.5 μm with a minor rise of the lateral size to ≃100 nm. The elongation process of the nanostructures is in agreement with a strain-driven shape transition mechanism proposed in the literature for other heteroepitaxial systems. Our study gives experimental evidence for the spontaneous formation of spatially uniform and compositionally homogeneous Mn-rich GeMn nanowires on Ge(111). The reliable and simple synthesis approach allows one to exploit the room-temperature ferromagnetic properties of the Mn–Ge alloy to design and fabricate novel nanodevices.

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“…Si and Ge, have great potential as dilute magnetic semiconductors (DMS) for spintronic applications with complementary metaloxide-semiconductor (CMOS) compatibility [1][2][3] . Structural engineering is being intensively explored as a method to enhance the Curie temperature (T c ) of group IV based DMSs 4,5 . However, compared to III-V and II-VI semiconductors, e.g.…”

Section: Introductionmentioning

confidence: 99%

Atomic layer doping of Mn magnetic impurities from surface chains at a Ge/Si hetero-interface

et al. 2018

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We realize Mn δ -doping into Si and Si/Ge interfaces using Mn atomic chains on Si(001). Highly sensitive X-ray absorption fine structure techniques reveal that encapsulation at room temperature prevents the formation of silicides / germanides whilst maintaining one dimensional anisotropic structures. This is revealed by studying both the incident X-ray polarization dependence and post-annealing effects. Density functional theory calculations suggest that Mn atoms are located at substitutional sites, and show good agreement with experiment. A comprehensive magnetotransport study reveals magnetic ordering within the Mn δ -doped layer, which is present at around 120 K. We demonstrate that doping methods based on the burial of surface nanostructures allows for the realization of systems for which conventional doping methods fail.

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Enhancing electric-field control of ferromagnetism through nanoscale engineering of high-Tc MnxGe1−x nanomesh

Cited by 35 publications

References 49 publications

Engineering Magnetoresistance in MnxGe1−x System for Magnetic Sensor Application

Engineering Magnetoresistance in MnxGe1−x System for Magnetic Sensor Application

Spontaneous shape transition of Mn_xGe₁₋_x islands to long nanowires

Atomic layer doping of Mn magnetic impurities from surface chains at a Ge/Si hetero-interface

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Enhancing electric-field control of ferromagnetism through nanoscale engineering of high-Tc MnxGe1−x nanomesh

Cited by 35 publications

References 49 publications

Engineering Magnetoresistance in MnxGe1−x System for Magnetic Sensor Application

Engineering Magnetoresistance in MnxGe1−x System for Magnetic Sensor Application

Spontaneous shape transition of MnxGe1−x islands to long nanowires

Atomic layer doping of Mn magnetic impurities from surface chains at a Ge/Si hetero-interface

Contact Info

Product

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Spontaneous shape transition of Mn_xGe₁₋_x islands to long nanowires