Magnetic Frustration in a Quantum Spin Chain: The Case of Linarite<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:msub><mml:mi>PbCuSO</mml:mi><mml:mn>4</mml:mn></mml:msub><mml:mo stretchy="false">(</mml:mo><mml:mi>OH</mml:mi><mml:msub><mml:mo stretchy="false">)</mml:mo><mml:mn>2</mml:mn></mml:msub></mml:math>

Willenberg, Benjamin; Schäpers, M.; Rule, K. C.; Süllow, S.; Reehuis, M.; Ryll, H.; Klemke, Bastian; Kiefer, K.; Schottenhamel, W.; Büchner, B.; Ouladdiaf, B.; Uhlarz, M.; Beyer, R.; Wosnitza, J.; Wolter, A. U. B.

doi:10.1103/physrevlett.108.117202

Cited by 65 publications

(108 citation statements)

References 30 publications

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“…In such compounds it is frequently found that the spin exchange interactions between the Cu 2+ (S=1/2) ions are such that the next-nearest-neighbor (NNN) exchange is antiferromagnetic (AFM), the nearest-neighbor (NN) exchange is ferromagnetic (FM), and the NNN spin exchange is often considerably stronger than the NN spin exchange. Due to the inherent competition of the NN and NNN spin exchange interactions, the CuX 2 ribbon chains tend to develop unusual AFM incommensurate spiral spin structures [1][2][3][4][5][6][7][8][9] and sometimes concomitantly multiferroic behavior. [10][11][12][13] These CuX 2 ribbon chains are formed by linking CuX 4 basal-square-planes of axially elongated CuX 6 (X = O, Cl, Br,...) octahedra together via their trans-edges.…”

Section: Low Dimensional Magnetic Cumentioning

confidence: 99%

“…Some systems, such as Li 2 ZrCuO 4 and PbCuSO 4 (OH) 2 (linarite), prevent long-range FM ordering since they exhibit an AFM incommensurate spin-spiral structure along the ribbon chains. 8,9,19,20 Other systems, such as Ca 2 Y 2 Cu 5 O 10 and Li 2 CuO 2 , do contain FM ribbon chains, however, weak interchain interactions force the FM-ribbon chains to align antiparallel, resulting in long-range AFM ordering. [21][22][23][24][25][26] In the case of Li 2 CuO 2 , the absence of a spiral magnetic order in the ribbon chains is understood to be a consequence of order by disorder arising from interchain interactions.…”

Section: -18mentioning

confidence: 99%

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Characterization of the spin-12linear-chain ferromagnet CuAs2O4

et al. 2014

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The magnetic and lattice properties of the S=1/2 quantum-spin-chain ferromagnet, CuAs2O4, mineral name trippkeite, were investigated. The crystal structure of CuAs2O4 is characterized by the presence of corrugated CuO2 ribbon chains. Measurements of the magnetic susceptibility, heat capacity, electron paramagnetic resonance and Raman spectroscopy were performed. Our experiments conclusively show that a ferromagnetic transition occurs at ∼7.4 K. Ab initio DFT calculations reveal dominant ferromagnetic nearest-neighbor and weaker antiferromagnetic nextnearest-neighbor spin exchange interactions along the ribbon chains. The ratio of Jnn/Jnnn is near -4, placing CuAs2O4 in close proximity to a quantum critical point in the Jnn -Jnnn phase diagram. TMRG simulations used to analyze the magnetic susceptibility confirm this ratio. Single-crystal magnetization measurements indicate that a magnetic anisotropy forces the Cu 2+ spins to lie in an easy plane perpendicular to the c-axis. An analysis of the field and temperature dependent magnetization by modified Arrott plots reveals a 3d-XY critical behavior. Lattice perturbations induced by quasi-hydrostatic pressure and temperature were mapped via magnetization and Raman spectroscopy.

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Section: Low Dimensional Magnetic Cumentioning

confidence: 99%

Section: -18mentioning

confidence: 99%

Characterization of the spin-12linear-chain ferromagnet CuAs2O4

et al. 2014

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“…Below T N = 2.8 K linarite shows magnetic long range order at zero field. Neutron scattering experiments 31 have confirmed the spin structure of the ground state to be an elliptical helix with the propagation vector k = (0, 0.186, 0.5). From bulk magnetic measurements, we have estimated the magnetic exchange interactions, with FM-NN J 1 ≈ −100 K, AFM-NNN J 2 ≈ 36 K and J ic ∼ 5 K 30 .…”

mentioning

confidence: 99%

“…Unfortunately, for many of the candidates for exhibiting multipolar phases, the involved AFM magnetic couplings and thus the saturation field are quite large, making it difficult to probe the multipolar phases. In this respect, linarite, PbCuSO 4 (OH) 2 , is a promising spin-multipolar candidate as the Cu 2+ ions form a quasi-1D S = 1/2 spinchain along the crystallographic b-axis 17,[30][31][32][33] . The material crystallizes in a monoclinic space group P 2 1 /m with lattice parameters 31,32,34 (at 1.8 K) a = 9.682Å, b = 5.646Å, c = 4.683Å, and β = 102.65 • (Fig.…”

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confidence: 99%

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Dynamics of linarite: Observations of magnetic excitations

et al. 2017

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Here we present inelastic neutron scattering measurements from the frustrated, quantum spin-1/2 chain material linarite, PbCuSO4(OH)2. Time of flight data, taken at 0.5 K and zero applied magnetic field reveals low-energy dispersive spin wave excitations below 1.5 meV both parallel and perpendicular to the Cu-chain direction. From this we confirm that the interchain couplings within linarite are around 10 % of the nearest neighbour intrachain interactions. We analyse the data within both linear spin-wave theory and density matrix renormalisation group theories and establish the main magnetic exchange interactions and the simplest realistic Hamiltonian for this material.

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Stabilization of Short‐ and Long‐Range Magnetic Ordering through the Cooperative Effect of 1D [CuO₄]_∞ Chains and [CuO₂X₂] Quadrilateral in Quasi‐1D Spin‐1/2 Systems

Guo,

Si,

et al. 2024

Angewandte Chemie

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Quasi‐1D chain antiferromagnets with reduced structural dimensionality are a rich playground for investigating novel quantum phenomena. We report the synthesis, crystal structure, and magnetism of two novel quasi‐1D antiferromagnets, β‐PbCu2(TeO3)2Cl2 (I) and PbCu2(TeO3)2Br2 (II). Their magnetic frameworks are constructed via Cu‐based quasi‐1D [Cu(2)O4] zigzag chains with square‐planar [Cu(1)O2X2] (X = Cl or Br) separated among 1D chains. Specific heat measurements show l peaks at ~9 K and ~19 K for I and II, respectively. Moreover, both broad maximums (χmax = 90 K for I and 80 K for II) and small kinks (TN ≈ 9 K for I and 19 K for II) have been observed in magnetic susceptibility measurements of I and II. Bonner‐Fisher model fitting, and theoretical analyses were performed to evaluate the magnetic exchange interactions. Our experimental and theoretical results and structure‐properties relationship analysis reveal the coexistence of short‐ and long‐range magnetic ordering from the cooperative effect of 1D [CuO4] chains and [CuO2X2] quadrilateral.

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Magnetic Frustration in a Quantum Spin Chain: The Case of LinaritePbCuSO4(OH)2

Cited by 65 publications

References 30 publications

Characterization of the spin-12linear-chain ferromagnet CuAs2O4

Characterization of the spin-12linear-chain ferromagnet CuAs2O4

Dynamics of linarite: Observations of magnetic excitations

Stabilization of Short‐ and Long‐Range Magnetic Ordering through the Cooperative Effect of 1D [CuO₄]_∞ Chains and [CuO₂X₂] Quadrilateral in Quasi‐1D Spin‐1/2 Systems

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Magnetic Frustration in a Quantum Spin Chain: The Case of LinaritePbCuSO4(OH)2

Cited by 65 publications

References 30 publications

Characterization of the spin-12linear-chain ferromagnet CuAs2O4

Characterization of the spin-12linear-chain ferromagnet CuAs2O4

Dynamics of linarite: Observations of magnetic excitations

Stabilization of Short‐ and Long‐Range Magnetic Ordering through the Cooperative Effect of 1D [CuO4]∞ Chains and [CuO2X2] Quadrilateral in Quasi‐1D Spin‐1/2 Systems

Contact Info

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About

Stabilization of Short‐ and Long‐Range Magnetic Ordering through the Cooperative Effect of 1D [CuO₄]_∞ Chains and [CuO₂X₂] Quadrilateral in Quasi‐1D Spin‐1/2 Systems