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Климин, С. А.; Popova, M. N.; Маврин, Б. Н.; Loosdrecht, P.H.M. van; Svistov, L. E.; Smirnov, Alex I.; Prozorova, L. A.; Nidda, H Von; Seidov, Z.; Loidl, A.; Shapiro, A. B.; Demianets, L. A.

doi:10.1103/physrevb.68.174408

Cited by 38 publications

(46 citation statements)

References 11 publications

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“…[8][9][10] Therefore it remains an interesting challenge for preparative chemists to identify new classes of model materials. Experimentally studied examples of the frustrated 2D cases are scarce with prominent, intriguing compounds such as NiGa 2 S 4 , 11 RbFe[MoO 4 ] 2 , [12][13][14] CuFeO 2 , 15 or AM 3 (OH) 6 (SO 4 ) 2 -the jarosite type of compounds. [16][17][18] Here, we present a class of materials where a reduction of the dimensionality of a system can be achieved by using "chemical scissors," such as nonmagnetic large counter ions (e.g., A 2+ = Sr or Ba), see Fig.…”

Section: Introductionmentioning

confidence: 99%

AAg2M[VO4]2
Möller
¹
,
Amuneke
²
,
Daniel
³

et al. 2012
Phys. Rev. B
36
1
48
0
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AAg 2 M[VO 4 ] 2 with A = Sr 2+ or Ba 2+ present a series of layered compounds featuring a triangular lattice of transition metal cations, M = Co 2+ or Ni 2+ , connected via nonmagnetic ortho-vanadates, which provide the magnetic superexchange within the layers. For this series of insulating compounds, ferromagnetic long-range order below 10 K is suggested by magnetization and specific heat measurements and confirmed by neutron diffraction experiments. We have investigated the impact of the spacer size of A 2+ separating the layers leading to a tilting of the vanadates and consequently inducing a change in the effective magnetic correlations. Magnetization and specific heat measurements corroborate the important dependence of the magnetic superexchange on the orientation of the vanadates and the respective spin system. Furthermore, the ground state properties of the spin systems, S = 1 (Ni 2+ ) and S = 3/2 (Co 2+ ) in their respective octahedral coordination of oxygen, are evaluated. Calculated magnetic moments of the single ion complexes agree well with the magnetic structure. We, furthermore, report the dependence of T c on applied isotropic pressure suggestive of a pressure effect on the effective ferromagnetic exchange coupling constants. In addition spectroscopic investigations probing the electronic structure of the [MO 6 ] complexes and the vibrational structure of the [VO 4 ] units are given.

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Section: Introductionmentioning

confidence: 99%

AAg2M[VO4]2
Möller
¹
,
Amuneke
²
,
Daniel
³

et al. 2012
Phys. Rev. B
36
1
48
0
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“…It undergoes a structural phase transition at Tc ~195 K with octahedra (tetrahedra) rotating counterclockwise (clockwise) about the c axis for domain type I and vice versa for domain type II. The point group of the room temperature phase of RbFe(MoO4)2 is known to be 3 ̅ , while that for the low temperature structural phase is likely to be 3 ̅ but with a couple of other options including 3 and 32 16,28,30 (see sample growth details in Methods).…”

mentioning

confidence: 99%

“…x-ray diffraction 30 to distinguish the subtle differences between point groups 3 , 32, and 3 ̅ . The 3 point group is immediately disqualified because the departure of the RA patterns from the mirror planes at room temperature indicates the absence of mirror symmetries below Tc.…”

mentioning

confidence: 99%

Observation of a ferro-rotational order coupled with second-order nonlinear optical fields

Jin

Drueke

et al. 2019

Nat. Phys.

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The ferro-rotational order 1-3 , whose order parameter (OP) is an axial vector invariant under both time reversal (TR) and spatial inversion (SI) operations, is the last remaining category of ferroics to be observed after the ferroelectric, ferromagnetic, and ferro-toroidal orders. This order has become increasingly popular in many new quantum materials, especially in complex oxides 1,3 , and is considered responsible for a number of novel phenomena such as polar vortices 4 , giant magnetoelectric coupling 5 , and type-II multiferroics 6 . However, physical properties of the ferrorotational order have been rarely studied either theoretically or experimentally. Here, using high sensitivity rotational anisotropy second harmonic generation (RA SHG), we have, for the first time, exploited the electric quadrupole (EQ) contribution to the SHG to directly couple to this centrosymmetric ferro-rotational order in an archetype of type-II multiferroics, RbFe(MoO4)2. Surprisingly, we have found that two types of domains with opposite ferro-rotational vectors emerge with distinct populations at the critical temperature Tc ~195 K and gradually evolve to reach an even ratio at lower temperatures. Moreover, we have identified the ferro-rotational order phase transition as weak first order, and have revealed its conjugate coupling field as a unique combination of the induced EQ SHG and the incident fundamental electric fields. Our results on physical properties of a ferro-rotational order provide crucial knowledge for understanding and searching for novel phases of matter built upon the ferro-rotational order. Further, these results open the possibility of revealing unconventional centrosymmetric orders and identifying their conjugate coupling fields with second order nonlinear optics.

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“…Double molybdates MFe(MoO 4 ) 2 (M=Na, K, Rb) exhibit interesting ferroelastic and antiferromagnetic properties [10][11][12][13][14], and Li 3 Fe(MoO 4 ) 3 is considered as a possible positive electrode in lithium cells [16,17]. However, despite detail characterization and attractive functional properties of some double iron(III) molybdates, none T-x diagrams have been constructed for the systems M 2 MoO 4 -Fe 2 (MoO 4 ) 3 (M=Li, Na, K, Rb, Cs) and only lithium and sodium containing systems were studied using X-ray diffraction [7].…”

Section: Introductionmentioning

confidence: 99%

“…Double molybdates MFe(MoO 4 ) 2 (M= Li-Cs), M 3 Fe(MoO 4 ) 3 (M =Li, K), M 5 Fe(MoO 4 ) 4 (M= K, Rb, Cs) [7][8][9][10][11][12][13][14][15][16][17][18][19] were described in literature; the crystal structures of MFe(MoO 4 ) 2 (M= Li, Na, K, Rb) [20][21][22][23][24][25], Li 3 Fe(MoO 4 ) 3 [26] and Rb 5 Fe(MoO 4 ) 4 [20] were determined. In the structures, the molybdenum atoms are tetrahedrally coordinated while the Fe 3 + cations usually have the octahedral coordination excluding the structure of the low-temperature Rb 5 Fe(MoO 4 ) 4 [20] where the iron atoms are located in square pyramids.…”

Section: Introductionmentioning

confidence: 99%

Phase formation features in the systems M2MoO4–Fe2(MoO4)3 (M=Rb, Cs) and crystal structures of new double polymolybdates M3FeMo4O15

Khal'baeva

Солодовников

Хайкина

et al. 2010

Journal of Solid State Chemistry

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Structural phase transition in the two-dimensional triangular lattice antiferromagnetRbFe(MoO4)2

Cited by 38 publications

References 11 publications

AAg2M[VO4]2
Möller
¹
,
Amuneke
²
,
Daniel
³

et al. 2012
Phys. Rev. B
36
1
48
0
View full text Add to dashboard Cite

AAg2M[VO4]2
Möller
¹
,
Amuneke
²
,
Daniel
³

et al. 2012
Phys. Rev. B
36
1
48
0
View full text Add to dashboard Cite

Observation of a ferro-rotational order coupled with second-order nonlinear optical fields

Phase formation features in the systems M2MoO4–Fe2(MoO4)3 (M=Rb, Cs) and crystal structures of new double polymolybdates M3FeMo4O15

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Structural phase transition in the two-dimensional triangular lattice antiferromagnetRbFe(MoO4)2

Cited by 38 publications

References 11 publications

AAg2M[VO4]2Möller1, Amuneke2, Daniel3 et al. 2012Phys. Rev. B361480View full textAdd to dashboardCite

AAg2M[VO4]2Möller1, Amuneke2, Daniel3 et al. 2012Phys. Rev. B361480View full textAdd to dashboardCite

Observation of a ferro-rotational order coupled with second-order nonlinear optical fields

Phase formation features in the systems M2MoO4–Fe2(MoO4)3 (M=Rb, Cs) and crystal structures of new double polymolybdates M3FeMo4O15

Contact Info

Product

Resources

About

AAg2M[VO4]2
Möller
¹
,
Amuneke
²
,
Daniel
³

et al. 2012
Phys. Rev. B
36
1
48
0
View full text Add to dashboard Cite

AAg2M[VO4]2
Möller
¹
,
Amuneke
²
,
Daniel
³

et al. 2012
Phys. Rev. B
36
1
48
0
View full text Add to dashboard Cite