Antiferromagnetic ordering in van der Waals 2D magnetic material MnPS
                    <sub>3</sub>
                    probed by Raman spectroscopy

Kim, Kangwon; Lim, Soo Yeon; Kim, Jungcheol; Lee, Jae-Ung; Lee, Sung-Min; Kim, Pilkwang; Park, Kisoo; Son, Sangyoung; Park, Cheol-Hwan; Park, Je‐Geun; Cheong, Hyeonsik

doi:10.1088/2053-1583/ab27d5

Cited by 159 publications

(123 citation statements)

References 39 publications

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“…This is also the case of Mn-based compounds, 2H-MnS 2 , 2H-MnSe 2 , MnPS 3 , MnPSe 3 ( Fig. 1d, e), which agreed with magnetometry measurements [20][21][22] . It is noteworthy that CuBr 3 and 2H-FeS 2 have substantially larger magnitudes of BQ exchange (Table 1) comparable to more complex materials, i.e., ferropnictides, where spin and electronic correlations are known to play a key role in the determination of their superconducting and strongly-correlated properties 23 .…”

Section: Biquadratic Exchange Interactionssupporting

confidence: 88%

Biquadratic exchange interactions in two-dimensional magnets

et al. 2020

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Magnetism in recently discovered van der Waals materials has opened several avenues in the study of fundamental spin interactions in truly two-dimensions. A paramount question is what effect higher-order interactions beyond bilinear Heisenberg exchange have on the magnetic properties of few-atom thick compounds. Here we demonstrate that biquadratic exchange interactions, which is the simplest and most natural form of non-Heisenberg coupling, assume a key role in the magnetic properties of layered magnets. Using a combination of nonperturbative analytical techniques, non-collinear first-principles methods and classical Monte Carlo calculations that incorporate higher-order exchange, we show that several quantities including magnetic anisotropies, spin-wave gaps and topological spin-excitations are intrinsically renormalized leading to further thermal stability of the layers. We develop a spin Hamiltonian that also contains antisymmetric exchanges (e.g., Dzyaloshinskii–Moriya interactions) to successfully rationalize numerous observations, such as the non-Ising character of several compounds despite a strong magnetic anisotropy, peculiarities of the magnon spectrum of 2D magnets, and the discrepancy between measured and calculated Curie temperatures. Our results provide a theoretical framework for the exploration of different physical phenomena in 2D magnets where biquadratic exchange interactions have an important contribution.

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Section: Biquadratic Exchange Interactionssupporting

confidence: 88%

Biquadratic exchange interactions in two-dimensional magnets

et al. 2020

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“…However spin Hall based measurements of D 2 in MnPS 3 put its value at merely 0.3 meV [35]. Since it is unlikely that D 2 is several times larger in ultrathin flakes compared to bulk crystals, especially given that Raman spectroscopy studies show no drastic changes in T AF or the phonon spectrum as a function of thickness [19], we rule out a non-collinear spin texture as the cause for ac mirror breaking. Instead, it is possible that the substrate induced strain tilts the easyaxis, causing the Néel ordered moments to rigidly cant out of the ac plane.…”

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confidence: 89%

Linear Magnetoelectric Phase in Ultrathin MnPS3 Probed by Optical Second Harmonic Generation

et al. 2020

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The transition metal thiophosphates M PS3 (M = Mn, Fe, Ni) are a class of van der Waals stacked insulating antiferromagnets that can be exfoliated down to the ultrathin limit. MnPS3 is particularly interesting because its Néel ordered state breaks both spatial-inversion and timereversal symmetries, allowing for a linear magneto-electric phase that is rare among van der Waals materials. However, it is unknown whether this unique magnetic structure of bulk MnPS3 remains stable in the ultrathin limit. Using optical second harmonic generation rotational anisotropy, we show that long-range linear magneto-electric type Néel order in MnPS3 persists down to at least 5.3 nm thickness. However an unusual mirror symmetry breaking develops in ultrathin samples on SiO2 substrates that is absent in bulk materials, which is likely related to substrate induced strain.

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“…Chromium triiodide (CrI 3 ) stands out among the large family of van der Waals (VDW) ferromagnets (FMs) investigated so far, because its isolated atomic crystal is one of the first two to realize two-dimensional (2D) ferromagnetic long-range order [1,2] in the monolayer limit, and more importantly, it is the first-ever interlayer antiferromagnetic (AFM) semiconductor [3][4][5][6] in its multilayer form. This phenomenon also makes CrI 3 distinct from the 2D intralayer AFMs [7][8][9]. From an application perspective, such unique magnetic properties of CrI 3 have already drawn enormous interest in developing novel device functionalities that are tunable by either magnetic [3][4][5][6] or electric [10][11][12] fields.…”

Section: Introductionmentioning

confidence: 99%

Magnetic-Field-Induced Quantum Phase Transitions in a van der Waals Magnet

Luo

et al. 2020

Phys. Rev. X

106

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Exploring new parameter regimes to realize and control novel phases of matter has been a main theme in modern condensed matter physics research. The recent discovery of two-dimensional (2D) magnetism in nearly freestanding monolayer atomic crystals has already led to observations of a number of novel magnetic phenomena absent in bulk counterparts. Such intricate interplays between magnetism and crystalline structures provide ample opportunities for exploring quantum phase transitions in this new 2D parameter regime. Here, using magnetic field-and temperature-dependent circularly polarized Raman spectroscopy of phonons and magnons, we map out the phase diagram of chromium triiodide (CrI 3) that has been known to be a layered antiferromagnet (AFM) in its 2D films and a ferromagnet (FM) in its threedimensional (3D) bulk. However, we reveal a novel mixed state of layered AFM and FM in 3D CrI 3 bulk crystals where the layered AFM survives in the surface layers, and the FM appears in deeper bulk layers. We then show that the surface-layered AFM transits into the FM at a critical magnetic field of 2 T, similar to what was found in the few-layer case. Interestingly, concurrent with this magnetic phase transition, we discover a first-order structural phase transition that alters the crystallographic point group from C 3i (rhombohedral) to C 2h (monoclinic). Our result not only unveils the complex single-magnon behavior in 3D CrI 3 , but it also settles the puzzle of how CrI 3 transits from a bulk FM to a thin-layered AFM semiconductor, despite recent efforts in understanding the origin of layered AFM in CrI 3 thin layers, and reveals the intimate relationship between the layered AFM-to-FM and the crystalline rhombohedral-tomonoclinic phase transitions. These findings further open opportunities for future 2D magnet-based magnetomechanical devices.

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Antiferromagnetic ordering in van der Waals 2D magnetic material MnPS ₃ probed by Raman spectroscopy

Cited by 159 publications

References 39 publications

Biquadratic exchange interactions in two-dimensional magnets

Biquadratic exchange interactions in two-dimensional magnets

Linear Magnetoelectric Phase in Ultrathin MnPS3 Probed by Optical Second Harmonic Generation

Magnetic-Field-Induced Quantum Phase Transitions in a van der Waals Magnet

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Antiferromagnetic ordering in van der Waals 2D magnetic material MnPS 3 probed by Raman spectroscopy

Cited by 159 publications

References 39 publications

Biquadratic exchange interactions in two-dimensional magnets

Biquadratic exchange interactions in two-dimensional magnets

Linear Magnetoelectric Phase in Ultrathin MnPS3 Probed by Optical Second Harmonic Generation

Magnetic-Field-Induced Quantum Phase Transitions in a van der Waals Magnet

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Antiferromagnetic ordering in van der Waals 2D magnetic material MnPS ₃ probed by Raman spectroscopy