Phonon and Thermal Properties of Quasi-Two-Dimensional FePS<sub>3</sub> and MnPS<sub>3</sub> Antiferromagnetic Semiconductors

Kargar, Fariborz; Coleman, Ece Aytan; Ghosh, Suchismita; Lee, Jonathan; Gomez, Michael J.; Liu, Yuhang; Magana, Andres Sanchez; Barani, Zahra; Mohammadzadeh, Amirmahdi; Debnath, Bishwajit; Wilson, R. B.; Lake, Roger K.; Balandin, Alexander A.

doi:10.1021/acsnano.9b09839

Cited by 72 publications

(66 citation statements)

References 69 publications

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“…MnPS 3 belongs to a class of layered antiferromagnetic insulators with chemical composition as XPS y ( X = Fe, Cr, Mn, Ni; y = 3, 4) 20 – 22 . It has an energy bandgap of ~3.0 eV for bulk crystals 23 with an easy axis mostly perpendicular to the sample plane 22 . Within each layer, the manganese atoms form a hexagonal structure and the localized spin of ~5.9 μ B on each manganese atom has antiferromagnetic exchange interaction with its nearest neighboring manganese atoms 22 , 24 , as shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

Electrically switchable van der Waals magnon valves

Chen

Liu

et al. 2021

Nat Commun

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Van der Waals magnets have emerged as a fertile ground for the exploration of highly tunable spin physics and spin-related technology. Two-dimensional (2D) magnons in van der Waals magnets are collective excitation of spins under strong confinement. Although considerable progress has been made in understanding 2D magnons, a crucial magnon device called the van der Waals magnon valve, in which the magnon signal can be completely and repeatedly turned on and off electrically, has yet to be realized. Here we demonstrate such magnon valves based on van der Waals antiferromagnetic insulator MnPS3. By applying DC electric current through the gate electrode, we show that the second harmonic thermal magnon (SHM) signal can be tuned from positive to negative. The guaranteed zero crossing during this tuning demonstrates a complete blocking of SHM transmission, arising from the nonlinear gate dependence of the non-equilibrium magnon density in the 2D spin channel. Using the switchable magnon valves we demonstrate a magnon-based inverter. These results illustrate the potential of van der Waals anti-ferromagnets for studying highly tunable spin-wave physics and for application in magnon-base circuitry in future information technology.

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Section: Resultsmentioning

confidence: 99%

Electrically switchable van der Waals magnon valves

Chen

Liu

et al. 2021

Nat Commun

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“…The obtained Raman data are in line with the literature reports attesting to the quality of the crystals. [6,20,[53][54][55][56][57] The test structures were prepared by mechanically exfoliating bulk crystals onto a Si/SiO 2 substrate with the oxide thickness of 300 nm. The uniform and relatively thick layers (200-400 nm) of the exfoliated layers were chosen in order to compensate for the high resistivity of the material and increase the current level in the device channels.…”

Section: Methodsmentioning

confidence: 99%

Low‐Frequency Electronic Noise in Quasi‐2D van der Waals Antiferromagnetic Semiconductor FePS₃—Signatures of Phase Transitions

Ghosh

Kargar

Mohammadzadeh

et al. 2021

Adv Elect Materials

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These layered quasi-2D van der Waals (vdW) compounds have interesting electronic, optical, and magnetic properties that can offer new device functionalities. [7][8][9][10][11][12][13][14][15][16][17][18][19] It has been demonstrated that some MPX 3 thin films are one of the rare few-layer vdW materials, which can have stable intrinsic antiferomagnetism (AF) even at mono-and few layer thicknesses. [20][21][22] The existence of weak vdW bonds between the MPX 3 layers makes them potential candidates for the 2D spintronic devices. The metal element of the MPX 3 materials modifies the bandgap from a medium bandgap of ≈1.3 eV to a wide bandgap of ≈3.5 eV. [1][2][3] The diverse properties of these materials tunable by proper selection and combination of the M and X elements make the MPX 3 materials an interesting platform for fundamental science and practical applications. [1][2][3][4][23][24][25][26][27][28][29][30] Among MPX 3 materials, FePS 3 is particularly promising. Its Ising-type ordering allows it to maintain the bulk-like magnetic behavior down to a single monolayer, which explains its moniker -"magnetic graphene." [31] The cleavage energy of FePSe 3 is slightly higher than that of graphite, while that for all other combinations of the M and X elements is lower than that of graphite. [32] The Néel temperature, T N , for FePS 3 is reported to be around 118 K. [1,2,20] It shows strong magnetic anisotropy. [15,33,34] In the crystal, each Fe atom is ferromagnetically coupled with two of its neighbors but the layer is antiferromagnetically coupled with nearest layers making it a zigzag-AF (z-AF) material. [1] The semiconducting nature of FePS 3 , with the energy bandgap of 1.5 eV, and a possibility of the strain engineering of electron and phonon band-structure create additional means for the control of both electron and spin transport. [9,17,35] The quantized spin waves, i.e., magnons in FePS 3 , have frequencies in the terahertz (THz) frequency range, [36,37] which makes this material interesting for THz magnonic devices. However, the electron and spin transport properties of FePS 3 have not been studied in sufficient details yet to assess the potential of such materials for THz applications.Here, we report the results of investigation of low-frequency current fluctuations, i.e., electronic noise, in thin films of FePS 3. The current-voltage (I-V) and noise characteristics

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“…Many theoretical calculations have verified that layered materials, such as arsenene [27], MnSb 2 S 4 [28], MXene [29], phosphorene [8], WS 2 [30], and C 3 N 4 [31], can be promising anode materials for MIBs. Furthermore, 2D layered transition metal phosphorous trichalcogenides (MPX 3 , where M = Mn, Fe, Ni, etc., and X = S, Se) have been widely explored because of their interesting physicochemical features, including electronic, magnetic, and superconductive properties [32,33]. Hitherto, materials from the MPX 3 family serve as good candidates for LIBs because of their reversible lithium storage capacity and fast lithium ion/electron conduction [34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Density Functional Theory Calculations for the Evaluation of FePS3 as a Promising Anode for Mg Ion Batteries

Cao

Pan

Wang

et al. 2020

Trans. Tianjin Univ.

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FePS 3 , a classical 2D layered material with transition metal phosphorous trichalcogenides, was investigated as an anode material for Mg ion batteries. We used density functional theory to calculate the Mg storage properties of FePS 3 , such as Mg adsorption energy, theoretical specific capacity, average voltage, diffusion energy barriers, volume change, and electronic conductivity. The theoretical specific capacity of the FePS 3 monolayer is 585.6 mA h/g with a relatively low average voltage of 0.483 V (vs. Mg/Mg 2+), which is favorable to a high energy density. The slight change in volume and good electronic conductivity of bulk FePS 3 are beneficial to electrode stability during cycling.

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Phonon and Thermal Properties of Quasi-Two-Dimensional FePS₃ and MnPS₃ Antiferromagnetic Semiconductors

Cited by 72 publications

References 69 publications

Electrically switchable van der Waals magnon valves

Electrically switchable van der Waals magnon valves

Low‐Frequency Electronic Noise in Quasi‐2D van der Waals Antiferromagnetic Semiconductor FePS₃—Signatures of Phase Transitions

Density Functional Theory Calculations for the Evaluation of FePS3 as a Promising Anode for Mg Ion Batteries

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Phonon and Thermal Properties of Quasi-Two-Dimensional FePS3 and MnPS3 Antiferromagnetic Semiconductors

Cited by 72 publications

References 69 publications

Electrically switchable van der Waals magnon valves

Electrically switchable van der Waals magnon valves

Low‐Frequency Electronic Noise in Quasi‐2D van der Waals Antiferromagnetic Semiconductor FePS3—Signatures of Phase Transitions

Density Functional Theory Calculations for the Evaluation of FePS3 as a Promising Anode for Mg Ion Batteries

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Phonon and Thermal Properties of Quasi-Two-Dimensional FePS₃ and MnPS₃ Antiferromagnetic Semiconductors

Low‐Frequency Electronic Noise in Quasi‐2D van der Waals Antiferromagnetic Semiconductor FePS₃—Signatures of Phase Transitions