Reversible displacive transformation in MnTe polymorphic semiconductor

Mori, Shunsuke; Hatayama, Shogo; Yi, Shuang; Ando, Daisuke; Sutou, Yuji

doi:10.1038/s41467-019-13747-5

Cited by 48 publications

(43 citation statements)

References 28 publications

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“…In fact, utilizing the polymorphism for non-volatile memory application was reported recently for another telluride, MnTe. [24] Furthermore, the inverted structure may become a building block of currently unknown 2D vdW-bonded CdTe. The investigation of this issue is currently underway.…”

Section: Discussionmentioning

confidence: 99%

Polymorphism of CdTe in the Few‐Monolayer Limit

Kolobov

Кузнецов

Fons

et al. 2021

Physica Rapid Research Ltrs

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Decreasing the thickness of semiconductors to the few monolayer limit often results in structural relaxation and the appearance of new properties. Herein, the bistability of 2ML thick CdTe, where the zinc blende structure of the bulk phase is metastable and the stable (ground) state is represented by an inverted structure with Cd atoms sandwiched by Te planes, is demonstrated. The thermodynamic stability of both phases is demonstrated by the absence of imaginary modes in the phonon dispersion spectra of both phases fully relaxed at 0 K. Both phases are direct‐gap semiconductors and the transformation from the zinc blende phase to the inverted phase is accompanied by a marked increase of the bandgap from 0.13 to 1.03 eV. In combination with the stable α‐CdTe phase, results demonstrate the polymorphism of ultrathin CdTe. A pronounced property contrast between the phases suggests the possible use of few‐monolayer CdTe for memory applications.

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Section: Discussionmentioning

confidence: 99%

Polymorphism of CdTe in the Few‐Monolayer Limit

Kolobov

Кузнецов

Fons

et al. 2021

Physica Rapid Research Ltrs

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“…As a nonlayered p-type semiconductor with a multiphase, α-MnTe has an ordered antiparallel magnetic moment with a Néel temperature of 307 K. It has been explored in memristor, magnetism, , thermoelectric, and photocatalytic applications and has shown superior properties like an above room temperature Néel temperature, good stability, high thermal conductivity, high carrier concentration, and reversible phase change. Since the controllable preparation of the 2D α-MnTe crystal is hard to achieve, most research has remained on the thin film until now, while the growth of the high quality crystal is limited to molecular beam epitaxy which is hard to industrialize.…”

Section: Introductionmentioning

confidence: 99%

Chemical Vapor Deposition-Grown Nonlayered α-MnTe Nanosheet for Photodetectors with Ultrahigh Responsivity and External Quantum Efficiency

et al. 2020

Chem. Mater.

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Development of new two-dimensional (2D) materials with high performance photoelectronic properties is critical for the future multifunctional and miniaturized optoelectronic devices. α-MnTe is an room-temperature antiferromagnetic, direct band gap p-type semiconductor with unique energy band structure and may have high photoelectric conversion efficiency and excellent photoelectric properties. However, controlled synthesis of the 2D α-MnTe single crystal has rarely been achieved so far. In this paper, 2D α-MnTe nanosheets with a NiAs-type hexagonal structure, a stable 2D nonlayered p-type semiconductor, are prepared for the first time via van der Waals epitaxy chemical vapor deposition (CVD) on mica. The thickness of 2D α-MnTe can be well tuned by the reaction temperature and gas flow. The photoelectric performance of the photodetector based on the 2D α-MnTe nanosheet shows that the 2D α-MnTe nanosheet based photodetector has an ultrahigh photoresponsivity (2599 A/W), external quantum efficiency (EQE, 8.065 × 105%), and excellent photodetectivity (3.32 × 1012 jones) at an illumination of 400 nm @ 0.062 mW/cm2 at 3 V, which is one of best performances of 2D material based photodetectors. Our work provides a new avenue to high performance 2D optoelectronic devices.

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“…MnTe is a typical polymorphism and stabilizes in hexagonal NiAs-type α-phase [nickeline (NC), Figure S1a] under normal atmospheric conditions, showing a phase change from α-phase to β-phase [wurtzite, Figure S1b], and then to γ-phase [zinc-blende, Figure S1c], and finally to δ-phase [salt-rock, Figure S1d] with the increase of temperature in the phase diagram. − All of these MnTe phases exhibit antiferromagnetic (AFM) ground states. − Recently, anisotropic magnetoresistance memory and magnetic anisotropy of α-MnTe have been reported to show the availability in AFM spintronic and memristive devices. , Thanks to the polymorphism, reversible resistive switching correlated to the reversible displacive transformation, which is between the α-phase (nickeline) and the β-phase (wurtzite), is found in MnTe and demonstrates a stronger competition in nonvolatile memory than in conventional phase-change Ge–Sb–Te materials . Interestingly, Balan et al reported the magnetic ordering transfer from the antiferromagnetic state to the paramagnetic one and the bandgap broadening from 1.3 to 2.1 eV when α-MnTe is confined to 2D form .…”

Section: Introductionmentioning

confidence: 99%

Nanometer-Thick Metastable Zinc Blende γ-MnTe Single-Crystalline Films for High-Performance Ultraviolet and Broadband Photodetectors

Lian

Zhou

Zhang

et al. 2020

ACS Appl. Nano Mater.

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Van der Waals heteroepitaxial (vdWE) has been intensely developed and considered as the most promising heteroepitaxial technique for growth of high-quality nanoscale films, covalent-bonded semiconductor films, and heterostructures to create the next-generation flexible electronic/optoelectronic devices because of its nature of relief of the strict requirement of lattice matching and its elegant exfoliation and transfer to any substrates of interest. However, application of the vdWE route in growing metastable and artificial materials and structures is still absent. In this work, by using the molecular beam epitaxy (MBE), epitaxy of metastable γ-phase nanometer-thick MnTe thin films is achieved on two-dimensional mica substrates through attentive control of its growth kinetics. The good crystallinity of vdWE γ-MnTe thin films is shown by a low half peak width value of about 0.19° for 50 nm-thick epitaxial films. Moreover, a structure with perfect lattice, a wide E g opt of ∼3.26 eV with the direct electron transition structure, a broad absorption region from ultraviolet (UV) to near-infrared (NIR), and an ultrahigh absorption coefficient beyond 106 cm–1 in the UV region are found in vdWE nanometer-thick γ-MnTe thin films. The photodetectors with vdWE γ-MnTe/mica systems exhibit a highly sensitive broadband detecting from the UV to the NIR region. The detectors show an outstanding UV response with a high responsivity of 526 A W–1 and specific detectivity of 2.46 × 1012 Jones and show fast photoresponse speeds (τrising = 1.9 ms and τdecay = 1.7 ms) under a 375 nm laser illumination that indicate a great potential in flexible UV and broad spectrum detection of the photodetectors with vdWE nanometer-thick γ-MnTe/mica.

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Reversible displacive transformation in MnTe polymorphic semiconductor

Cited by 48 publications

References 28 publications

Polymorphism of CdTe in the Few‐Monolayer Limit

Polymorphism of CdTe in the Few‐Monolayer Limit

Chemical Vapor Deposition-Grown Nonlayered α-MnTe Nanosheet for Photodetectors with Ultrahigh Responsivity and External Quantum Efficiency

Nanometer-Thick Metastable Zinc Blende γ-MnTe Single-Crystalline Films for High-Performance Ultraviolet and Broadband Photodetectors

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