Air‐Stable 2D Cr<sub>5</sub>Te<sub>8</sub> Nanosheets with Thickness‐Tunable Ferromagnetism

Chen, Chao; Chen, Xiaodie; Wu, Chenjun; Wang, Xiao; Yue, Ping; Wei, Xin; Zhou, Xing; Lu, Jiangbo; Zhu, Lujun; Zhou, Jiadong; Zhai, Tianrui; Han, Junbo; Xu, Hua

doi:10.1002/adma.202107512

Cited by 83 publications

(106 citation statements)

References 47 publications

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“…The lattice spacing of the diffraction spots marked by yellow circles is 2.88 Å, which is consistent with the measured (100) lattice spacing of monolayer WSe2. The diffraction spots marked with red circles show identical orientation with that of the WSe2, with a lattice spacing of 3.36 Å in accordance with the Cr5Te8 (200) planes, which reduces by ~2% from the value of freestanding Cr5Te8 [20] . The inner, red-circled diffraction spots with a larger periodicity (6.72 Å) representing those ordered, self-intercalated Cr atoms An atomic model of the Cr5Te8/WSe2 heterostructure based on iterative refinements from HAADF-STEM image analysis and first principles calculations is shown in Figure 2e, where a 3 × 3 Cr5Te8 supercell is commensurate with the 7 × 7 WSe2 supercell.…”

Section: Resultsmentioning

confidence: 89%

“…The diffraction spots marked with red circles show identical orientation with that of the WSe 2 , with a lattice spacing of 3.36 Å in accordance with the Cr 5 Te 8 (200) planes, which reduces by ≈2% from the value of freestanding Cr 5 Te 8 . [20] The inner, redcircled diffrac tion spots with a larger periodicity (6.72 Å) representing those ordered, selfintercalated Cr atoms is a structural fingerprint of trigonal Cr 5 Te 8 . Interestingly, the innermost diffraction spots highlighted by blue circles indicate a lattice spacing of 11.6 Å, which belongs to neither WSe 2 nor Cr 5 Te 8 alone, of interfacial Cr atoms to be reduced to 3 per supercell from 9 selfintercalated in the interior of Cr 5 Te 8 , suggesting inter facial reconstruction.…”

Section: Resultsmentioning

confidence: 98%

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Dative Epitaxy of Commensurate Monocrystalline Covalent van der Waals Moiré Supercrystal

et al. 2022

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Realizing van der Waals (vdW) epitaxy in the 80's represents a breakthrough that circumvents the stringent lattice matching and processing compatibility requirements in conventional covalent heteroepitaxy. However, due to the weak vdW interactions, there is little control over film qualities by the substrate. Typically, discrete domains with a spread of misorientation angles are formed, limiting the applicability of vdW epitaxy. Here we report the epitaxial growth of monocrystalline, covalent Cr5Te8 2D crystals on monolayer vdW WSe2 by chemical vapor deposition, driven by interfacial dative bond formation. The lattice of Cr5Te8, with a lateral dimension of a few ten microns, is fully commensurate with that of WSe2 via 3 × 3 (Cr5Te8)/7 × 7 (WSe2) supercell matching, forming a single-crystalline moiré superlattice. Our work has established a conceptually distinct paradigm of thin film epitaxy termed "dative epitaxy", which takes full advantage of covalent epitaxy with chemical bonding for fixing the atomic registry and crystal orientation, while circumventing its stringent lattice matching and processing compatibility requirements; conversely, it ensures the full flexibility of vdW epitaxy, while avoiding its poor orientation control. Cr5Te8 2D crystals grown by dative epitaxy exhibit square magnetic hysteresis, suggesting minimized interfacial defects that can serve as pinning sites.

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Section: Resultsmentioning

confidence: 89%

Section: Resultsmentioning

confidence: 98%

Dative Epitaxy of Commensurate Monocrystalline Covalent van der Waals Moiré Supercrystal

et al. 2022

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“…[1][2][4][5][6][7][8][9][10] Based on first-principles calculations, hundreds of 2D vdW magnets have been predicted for breakthroughs to realize controlled synthesis of 1 and 2 unit-cell CrSe and Cr 2 Te 3 by CVD growth and found these 2D ultrathin films show obvious thickness-dependent Curie temperature, the highest value is 280 K. Xu et al [36] reported that hexagonal CrTe 2 monolayer grown on bilayer graphene substrates by MBE with T C = 200 K. Zhang et al [37] reported that trigonal ultrathin Cr 2 Te 3 films are FM with T C = 195 K and exhibit strong perpendicular magnetic anisotropy with 5 × 10 6 J m −3 , and Li et al [38] prepared 2D nanosheets of α-MnSe 2 with nonstoichiometric surfaces via soft chemical etching, which were found to be a FM semiconductor with T C = 320 K. In addition, the robust FM/AFM order have also been found in 2D non-vdW CrSe 2 , Fe 7 Se 8 , Cr 5 Te 8 , FeTe, CrTe, α-MnSe 2 , and FeSe ultrathin films, their T C is up to 110, 300, 160, 220, 367, 160, and 553 K, respectively. [27,28,31,[38][39][40][41] Compared to 2D vdW magnets, 2D non-vdW ultrathin films have strong interlayer chemical bonding. Intuitively, the Curie temperature in the 2D non-vdW magnetic materials could be significantly elevated by the enhanced interlayer magnetic coupling.…”

Section: Introductionmentioning

confidence: 99%

“…[39] The CVD-grown 2D Cr 5 Te 8 is an air-stable FM material, the signal of magnetooptical Kerr effect is well maintained after aging in air for 3 months. [28] As shown in the X-ray diffraction pattern and M-H hysteresis measurement, the structures of 2D CrTe ultrathin crystals are stable even after 1-month exposure in ambient air and their strong intrinsic ferromagnetism still remained. [22] Moreover, the 2D hexagonal AFM semiconductor FeSe with few unit-cell thicknesses are also quite stable, and it could remain without phase transformation after exposure to air for a month or being heat treated at 600 K for 1 h under a N 2 atmosphere.…”

Section: Introductionmentioning

confidence: 99%

“…[17] Experimentally, 2D sheets of FM semiconductors α-Fe 2 O 3 and FeTiO 3 have been obtained from liquid-phase exfoliation, [20,21] and ultrathin films of transition-metal chalcogenides, such as CrTe (Se), Cr 2 X 3 (X = S, Se, Te), CrTe 2 , Cr 4 Te 5 , Cr 5 Te 8 , α-MnSe 2 , and FeTe, have been fabricated by CVD methods. [22][23][24][25][26][27][28][29][30][31] Some other 2D non-vdW materials have been synthesized, such as AMX 2 chalcogenides (A = Ag, Cu) and transition-metal nitrides/ phosphides/oxides and their alloys. [32,33] Recent theoretical work has also demonstrated the experimental feasibility of unknown 2D non-vdW materials by evaluating the interface binding energies.…”

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confidence: 99%

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Composition‐Dependent Magnetic Ordering in Freestanding 2D Non‐van der Waals Cr₂Te_xSe₃₋_x Crystals

Liu

Wang

Zhao

et al. 2022

Adv Funct Materials

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Since the confirmation of long-range magnetic ordering in 2D materials, much effort has been devoted to finding more 2D magnetic materials with high Curie temperature (T C ) and tunable physical properties. Most of the 2D magnets realized to date are based on van der Waals (vdW) materials, but recently synthesized 2D non-vdW ultrathin materials have revealed an alternative direction for the discovery of novel 2D magnets. In this paper, a family of 2D non-vdW Cr 2 Te x Se 3−x compounds is proposed. All Cr 2 Te x Se 3−x compounds are predicted to be energetically favorable and air stable, suggesting experimental feasibility, and long-term stability. Compared to other non-vdW materials, Cr 2 Te x Se 3−x compounds have superior oxidation resistance. Moreover, they exhibit obvious composition-dependent magnetic ordering, which originates from the competition between interlayer direct antiferromagnetic exchange and ferromagnetic superexchange. Among them, half-metals Cr 2 Te 3 and Cr 2 TeSe 2 exhibit robust ferromagnetism with high T C values of 396 and 261 K, respectively. Additionally, 2D Cr 2 TeSe 2 shows a sizable anomalous Hall conductivity of 6237 Ω cm −1 . The present results enrich the database of 2D non-vdW magnets and provide fundamental understanding about the composition-induced magnetic phase transition, which may be of use in spintronic applications.

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Preparation of 2D Materials

Tang,

2023

Two‐Dimensional Materials for Nonlinear Optics

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Air‐Stable 2D Cr₅Te₈ Nanosheets with Thickness‐Tunable Ferromagnetism

Cited by 83 publications

References 47 publications

Dative Epitaxy of Commensurate Monocrystalline Covalent van der Waals Moiré Supercrystal

Dative Epitaxy of Commensurate Monocrystalline Covalent van der Waals Moiré Supercrystal

Composition‐Dependent Magnetic Ordering in Freestanding 2D Non‐van der Waals Cr₂Te_xSe₃₋_x Crystals

Preparation of 2D Materials

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Air‐Stable 2D Cr5Te8 Nanosheets with Thickness‐Tunable Ferromagnetism

Cited by 83 publications

References 47 publications

Dative Epitaxy of Commensurate Monocrystalline Covalent van der Waals Moiré Supercrystal

Dative Epitaxy of Commensurate Monocrystalline Covalent van der Waals Moiré Supercrystal

Composition‐Dependent Magnetic Ordering in Freestanding 2D Non‐van der Waals Cr2TexSe3−x Crystals

Preparation of 2D Materials

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Air‐Stable 2D Cr₅Te₈ Nanosheets with Thickness‐Tunable Ferromagnetism

Composition‐Dependent Magnetic Ordering in Freestanding 2D Non‐van der Waals Cr₂Te_xSe₃₋_x Crystals