Abstract: The MPX3 family of magnetic van-der-Waals materials (M denotes a first row transition metal and X either S or Se) are currently the subject of broad and intense attention for low-dimensional magnetism and transport and also for novel device and technological applications, but the vanadium compounds have until this point not been studied beyond their basic properties. We present the observation of an isostructural Mott insulator–metal transition in van-der-Waals honeycomb antiferromagnet V0.9PS3 through high-pressure x-ray diffraction and transport measurements. We observe insulating variable-range-hopping type resistivity in V0.9PS3, with a gradual increase in effective dimensionality with increasing pressure, followed by a transition to a metallic resistivity temperature dependence between 112 and 124 kbar. The metallic state additionally shows a low-temperature upturn we tentatively attribute to the Kondo effect. A gradual structural distortion is seen between 26 and 80 kbar, but no structural change at higher pressures corresponding to the insulator–metal transition. We conclude that the insulator–metal transition occurs in the absence of any distortions to the lattice—an isostructural Mott transition in a new class of two-dimensional material, and in strong contrast to the behavior of the other MPX3 compounds

Alireza, Patricia L.

Coak, Matthew J.

Daisenberger, Dominik

Haines, Charles R. S.

Hamidov, Hayrullo

Liu, Cheng

Park, Je-Geun

Saxena, Siddharth S.

Son, Suhan

Wildes, Andrew R.

npj Quantum Materials

English

arXiv

© 2019, The Author(s).The MPX3 family of magnetic van-der-Waals materials (M denotes a first row transition metal and X either S or Se) are currently the subject of broad and intense attention for low-dimensional magnetism and transport and also for novel device and technological applications, but the vanadium compounds have until this point not been studied beyond their basic properties. We present the observation of an isostructural Mott insulator–metal transition in van-der-Waals honeycomb antiferromagnet V0.9PS3 through high-pressure x-ray diffraction and transport measurements. We observe insulating variable-range-hopping type resistivity in V0.9PS3, with a gradual increase in effective dimensionality with increasing pressure, followed by a transition to a metallic resistivity temperature dependence between 112 and 124 kbar. The metallic state additionally shows a low-temperature upturn we tentatively attribute to the Kondo effect. A gradual structural distortion is seen between 26 and 80 kbar, but no structural change at higher pressures corresponding to the insulator–metal transition. We conclude that the insulator–metal transition occurs in the absence of any distortions to the lattice—an isostructural Mott transition in a new class of two-dimensional material, and in strong contrast to the behavior of the other MPX3 compounds11sciescopu

Matthew J. Coak

Suhan Son

Dominik Daisenberger

Hayrullo Hamidov

Charles R. S. Haines

Patricia L. Alireza

Andrew R. Wildes

Cheng Liu

Siddharth S. Saxena

Je-Geun Park

IBS Publications Repository

Undetermined

Isostructural Mott transition in 2D honeycomb antiferromagnet V0.9PS3

University of Birmingham Research Portal

Isostructural Mott transition in 2D honeycomb antiferromagnet V$_0.9$PS$_3$

Apollo (Cambridge)

1ISOSTRUCTURAL MOTT TRANSITION IN 2D HONEYCOMB ANTIFERROMAGNET V0.9PS3 -SUPPLEMENTARY INFORMATIONFigure 1. Integrated powder diffraction patterns for V0.9PS3 at room temperature. A diffuse background has been subtractedand the y-axis offset of each curve has been set to the value of its pressure in kbar.5 10 15 202050150180IntensityDataCalculatedDifferencedata4LP - 11 kbarFigure 2. Rietveld refinement of the integrated powder x-ray patterns, after subtraction of a diffuse background, for V0.9PS3at 11 kbar (the lowest pressure measured), in the LP phase.25 10 15 2020100250380IntensityDataCalculatedDifferencedata4HP-I - 177 kbarHe  HeFigure 3. Rietveld refinement of the integrated powder x-ray patterns, after subtraction of a diffuse background, for V0.9PS3 at177 kbar, in the HP-I phase. The peaks marked ‘He’ in are due to the solid helium pressure medium and were included in therefinement as an additional phase or impurity. These appear at 150 kbar - the freezing point of helium at room temperature,and the change of their positions with pressure were found to match the data of Mao et.al. [1].LP (11 kbar) C2/m R = 7% wR = 9% χ2 = 3.01 GOF = 4%a = 5.8436(15) Å b = 10.0876(8) Å c = 6.5237(18) Å β = 107.098(5) º V = 367.56(6) Å3 ρ = 3.060(1) g.cm−3x y z Occ UisoV(4g) 0 0.331(1) 0 0.86(4) 0.079(4)P(4i) 0.043(4) 0 0.122(3) 1 0.091(6)S(4i) 0.758(2) 0 0.249(4) 1 0.071(6)S(8j) 0.260(2) 0.1738(7) 0.234(2) 1 0.070(3)HP-I (177 kbar) C2/m R = 7% wR = 10% χ2 = 3.56 GOF = 4%a = 5.5469(3) Å b = 9.5892(6) Å c = 5.4788(9) Å β = 90.136(8) º V = 291.42(7) Å3 ρ = 3.813(1) g.cm−3x y z Occ UisoV(4g) 0 0.3431(4) 0 0.86(4) 0.090(3)P(4i) 0.0076(7) 0 0.8492(20) 1 0.061(3)S(4i) 0.3257(11) 0 0.7214(7) 1 0.025(4)S(8j) 0.8441(3) 0.1649(3) 0.7510(5) 1 0.039(3)Table I. Refinement parameters for the LP low-pressure phase at 11 kbar and the HP-I high-pressure phase at 177 kbar.30 50 100 150 200Pressure (kbar)5.55.555.65.655.75.755.85.855.9a (Å)0 50 100 150 200Pressure (kbar)9.59.69.79.89.91010.110.2b (Å)0 50 100 150 200Pressure (kbar)5.45.65.866.26.46.66.8c (Å)Figure 4. Lattice parameters extracted from powder x-ray refinements for V0.9PS3 at room temperature as a function ofpressure. Blue circles denote the LP phase and red crosses the HP-I phase. Note that while there is a jump in the c axis valuebetween the two phases, this is due to a change in β and does not correspond to a change in inter-planar spacing or cell volume.4Figure 5. Photograph of the diamond anvil cell sample region and gasket, installed on the lower anvil prior to loading of thepressure medium and pressurization. The four gold wires connected to the single-crystal V0.9PS3 crystal can be seen runningalong insulated epoxy tracks dug into the Be-Cu gasket. Two ruby chips are visible above and to the right of the sample.5a)0 0.05 0.1 0.15 0.21 / T (K-1)468101214161820ln(/T)0 kbar 63 kbar77 kbar80 kbar90 kbar 97 kbar112 kbarVPS3b)0 10 20 30 40 50 60 70 80Pressure (kbar)012345T 0 (K)1040 50 100 150Pressure (kbar)102104106(300 K) (cm)Figure 6. a) - ln(ρ/T ) vs 1/T plotted to extract the α power law dependence in the generalized variable range hoppingexpression discussed in the main text ρ = ρ0Te(T0/T )α. Fits of type 1/Tα are shown as black lines, allowing the exponent α tobe extracted. b) - extracted values of the T0 characteristic temperature. Inset shows values of the room-temperature resistivityas pressure is increased, on a logarithmic axis. Arrows denote a kink or change of slope at 80 kbar and the insulator-metaltransition between 112-124 kbar.Unlike in other MPX3 materials such as FePS3 [2], the resistivity cannot be well described by a simple Arrhenius-type insulating temperature dependence - Fig. 6.a illustrates this by plotting ln(ρ/T ) against 1/T - the resultingplots are far from straight lines and can be fitted with a simple power law dependence. The simpler form ln(ρ)against 1/T for an equivalent plot gives an extremely similar result and is the standard test for Arrhenius eEa/kbTresistivity. Fig. 6.b shows the extracted characteristic temperature T0 and the room temperature resistivity. If the6data follows variable-range-hopping expression ρ = ρ0Te(T0/T )α, plotting ln(ρ/T ) against 1/T as in Fig. 6.a thenyields an expression ln(ρ/T ) = ln(ρ0) + Tα0 (1/T )α and so the exponent α can easily be found from a non-linearleast-squares fit. Such fits are shown overlayed onto the data curves - good fits are seen up to pressures around80 kbar, but then the quality of fits starts to decrease as the data move away from the VRH form, particularly atlower temperatures, as the insulator-metal transition is approached.As the transition is approached, the To characteristic temperature is continuously suppressed - again, no clearabrupt changes - until the VRH expression breaks down in the close proximity of metallization above 80 kbar. Aselectron overlap is increased by pressure, the hopping energies are gradually decreasing. The decrease in the room-temperature resistivity - a metric which is of course independent of any fitting methodology - is once again smoothand continuous, except for the insulator-metal transition at 112-124 kbar and a slight kink or change of slope around80 kbar. 80 kbar corresponds to the maximum pressure of the LP - HP-I structural crossover, so a change in ρ(p) canbe expected here as phase ratios are no longer changing and affecting the resistivity.[1] H. Mao, R. Hemley, Y. Wu, A. Jephcoat, L. Finger, C. Zha, and W. Bassett, Physical Review Letters 60, 2649 (1988).[2] C. Haines, M. Coak, A. Wildes, G. Lampronti, C. Liu, P. Nahai-Williamson, H. Hamidov, D. Daisenberger, and S. Saxena,Physical Review Letters 121 (2018), 10.1103/physrevlett.121.266801.

Isostructural Mott transition in 2D honeycomb antiferromagnet V 0.9 PS 3

The MPX3 family of magnetic van-der-Waals materials (M denotes a first row transition metal and X either S or Se) are currently the subject of broad and intense attention for low-dimensional magnetism and transport and also for novel device and technological applications, but the vanadium compounds have until this point not been studied beyond their basic properties. We present the observation of an isostructural Mott insulator–metal transition in van-der-Waals honeycomb antiferromagnet V0.9PS3 through high-pressure x-ray diffraction and transport measurements. We observe insulating variable-range-hopping type resistivity in V0.9PS3, with a gradual increase in effective dimensionality with increasing pressure, followed by a transition to a metallic resistivity temperature dependence between 112 and 124 kbar. The metallic state additionally shows a low-temperature upturn we tentatively attribute to the Kondo effect. A gradual structural distortion is seen between 26 and 80 kbar, but no structural change at higher pressures corresponding to the insulator–metal transition. We conclude that the insulator–metal transition occurs in the absence of any distortions to the lattice—an isostructural Mott transition in a new class of two-dimensional material, and in strong contrast to the behavior of the other MPX3 compounds

Haines, Sebastian

University of East Anglia digital repository

https://pr.ibs.re.kr/bitstream/8788114/6527/1/Isostructural%20Mott%20transition%20in%202D%20honeycomb%20antiferromagnet%20V0.9PS3.pdf

Isostructural Mott transition in 2D honeycomb antiferromagnet V 0.9 PS 3

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University of Birmingham Research Portal

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