Dynamic Behavior of the Jahn−Teller Distorted Cu(H2O)62+ Ion in Cu2+ Doped Cs2[Zn(H2O)6](ZrF6)2 and the Crystal Structure of the Host Lattice

Hitchman, Michael A.; Yablokov, Yu. V.; Petrashen, V. E.; Augustyniak‐Jablokov, Maria A.; Stratemeier, Horst; Riley, Mark J.; Łukaszewicz, K.; Tomaszewski, Paweł E.; Pietraszko, A.

doi:10.1021/ic010464d

Cited by 38 publications

(48 citation statements)

References 21 publications

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“…The studied Ni 3+ centers in DPPH and PHZS crystals are different from other TM impurity (e.g., Mn 2+ , Cr 3+ , and Fe 3+ [46][47][48] ) centers in the same crystals, with the nondegenerated ground state in the absence of the Jahn-Teller effect. In addition, when the impurity Cu 2+ enters Tutton salts, [14,15,[49][50][51][52] it may also occupy the host Zn 2+ site, but usually presents elongated octahedra instead of the compressed octahedra in the studied systems.…”

Section: Discussionmentioning

confidence: 98%

Theoretical studies of the g factors and local structures of the Ni³⁺ centers in Na₂Zn(SO₄)₂·4H₂O and K₂Zn(SO₄)₂·6H₂O crystals

Chen

Feng

et al. 2020

Magnetic Reson in Chemistry

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The local structures and the g factors gi (i = x, y, z) for Ni3+ centers in Na2Zn(SO4)2·4H2O (DPPH) and K2Zn(SO4)2·6H2O (PHZS) crystals are theoretically studied by using the perturbation formulas of the g factors for a 3d7 ion with low spin (S = 1/2) in orthorhombically compressed octahedra. In these formulas, the contributions to g factors from both the spin‐orbit coupling interactions of the central ion and ligands are taken into account, and the required crystal‐field parameters are estimated from the superposition model and the local geometry of the systems. Based on the calculations, the Ni‐O bonds are found to suffer the axial compression δz (or Δz) of about 0.111 Å (or 0.036 Å) along the z‐axis for Ni3+ centers in DPPH (or PHZS) crystals. Meanwhile, the Ni‐O bonds may experience additional planar bond length variation δx (≈0.015 Å) along x‐ and y‐axes for the orthorhombic Ni3+ center in DPPH. The theoretical g factors agree well with the experimental data. The obtained local structural parameters for both Ni3+ centers are discussed.

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Section: Discussionmentioning

confidence: 98%

Theoretical studies of the g factors and local structures of the Ni³⁺ centers in Na₂Zn(SO₄)₂·4H₂O and K₂Zn(SO₄)₂·6H₂O crystals

Chen

Feng

et al. 2020

Magnetic Reson in Chemistry

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“…(2011). E67, i6-i7 9Zr-F3 = 1.968 5Zr-F3 = 1.9727 3Zr-F3 = 1.962 (5) Zr-F5 = 2.0006 8Zr-F1 = 2.004 (5) Zr-F1 = 2.0018 3Zr-F6 = 1.977 (5) Zr-F3 = 2.0293 9Zr-F5 = 2.029 (4) Zr-F5 = 2.0277 (3) Zr-F5 = 2.037 (5) Distances Zr-F (Å ) Zr-F2 = 2.0554 (8) Zr-F6 = 2.059 (4) Zr-F6 = 2.0570 (3) Zr-F4 = 2.067 (4) Zr-F1 = 2.0708 8Zr-F2 = 2.063 (4) Zr-F2 = 2.0668 (4) Zr-F2 = 2.069 (4) Zr-F4 = 2.1468 9Zr-F4 = 2.156 5 2Cs-F3 = 3.065 (5) K-F1 = 2.7895 9K-F2 = 2.799 (5) K-F3 = 2.8094 2Cs-F3 = 3.102 (5) K-O2 = 2.8927 10K-O3 = 2.942 (5) K-O1 = 2.8968 3Cs-O2 = 3.218 (5) K-O1 = 3.1012 10K-O1 = 2.980 (5) K-O2 = 3.0873 5Cs-O1 = 3.236 (5) K-F6 = 3.1684 12K-F3 = 3.1307 7K-F3 = 3.1707 7Cs-F5 = 3.228 6 Data collection: APEX2 (Bruker, 2008); cell refinement: SAINT (Bruker, 2008); data reduction: SAINT; program(s) used to solve structure: SHELXS97 (Sheldrick, 2008); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: DIAMOND (Brandenburg, 1999) and ORTEP-3 for Windows (Farrugia, 1997); software used to prepare material for publication: SHELXTL (Sheldrick, 2008 (Bukvetskii et al, 1993) (Hitchman et al, 2002). In the title structure the Ni 2+ cation (site symmetry 1) is coordinated by six water molecules with two Ni-O distances slightly longer (2.0781 (9) Å) than the four others (2x 2.0548 (10) Å and 2x 2.0570 (11) Å).…”

Section: Inorganic Compounds I6mentioning

confidence: 99%

Dipotassium hexaaquanickel(II) bis[hexafluoridozirconate(IV)]

et al. 2010

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Single crystals of the title compound, K 2 [Ni(H 2 O) 6 ][ZrF 6 ] 2 , were grown by slow evaporation of a 40% aqueous HF solution in which a stoichiometric mixture of NiCl 2 Á6H 2 O, ZrF 4 and KCl was dissolved. The monoclinic structure is isotypic with its K 2 Cu, K 2 Zn, Cs 2 Zn and Cs 2 Cu analogues. The structure is built up from isolated, slightly elongated octahedral [Ni(H 2 O) 6 ] 2+ complex cations (symmetry 1) and dimeric [Zr 2 F 12 ] 4À complex anions (symmetry 1) that are also isolated from each other. The [Zr 2 F 12 ] 4À anion results from the association of two distorted pentagonal-bipyramidal [ZrF 7 ] coordination polyhedra by sharing an equatorial edge passing through an inversion center of the unit cell. Both isolated [Ni(H 2 O) 6 ] 2+ and [Zr 2 F 12 ] 4À complex ions are situated in planes parallel to (010). They are connected by the eightcoordinated K + ions into a three-dimensional structure. An intricate O-HÁ Á ÁF hydrogen-bonding network consolidates the structure. Related literature For isotypic structures, see: Fischer & Weiss (1973); Bukvetskii et al. (1993); Hitchman et al. (2002). For a review on the stereochemistry of zirconium and hafnium fluorido complexes, see: Davidovich (1998). For background to distortion indices, see: Momma & Izumi (2008). Experimental Crystal data K 2 [Ni(H 2 O) 6 ][ZrF 6 ] 2 M r = 655.45 Monoclinic, P2 1 =n a = 6.6090 (1) Å b = 10.0398 (1) Å c = 11.7843 (1) Å = 95.897 (1) V = 777.79 (2) Å 3 Z = 2 Mo K radiation = 3.20 mm À1 T = 296 K 0.28 Â 0.14 Â 0.09 mm Data collection Bruker APEXII CCD diffractometer Absorption correction: multi-scan (SADABS; Bruker, 2008) T min = 0.613, T max = 0.748 17267 measured reflections 4436 independent reflections 3858 reflections with I > 2(I) R int = 0.028 Refinement R[F 2 > 2(F 2)] = 0.023 wR(F 2) = 0.052 S = 1.06 4436 reflections 131 parameters All H-atom parameters refined Á max = 0.63 e Å À3 Á min = À0.57 e Å À3 inorganic compounds Acta Cryst. (2011). E67, i6-i7 Oudahmane et al. K 2 [Ni(H 2 O) 6 ][ZrF 6 ] 2 i7 supporting information sup-5 Acta Cryst. (2011). E67, i6-i7 supporting information sup-6

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“…Several of these EPR studies revealed limitations of the SG model, the most apparent being that 12 is not constant over the entire temperature range 2,4,9,[12][13][14][15] . In other systems, the tensor variations that were not fully predicted, 4,11,18 which was initially suggested as due to a non-Boltzmann thermal equilibrium at low temperatures, but later also from temperature dependent changes in the lattice strains. In a few other cases, gmin was observed to vary with temperature 4,9 and therefore a three-state SG model was applied 1,9,10 .…”

Section: Introductionmentioning

confidence: 99%

“…The inclusion of lattice strain parameters generally led to better agreements to the g-tensor variations, but also found good comparisons with the 12 values that were estimated from the SG model 3,15,19 . However, three systems; the Magnesium Ammonium Tutton salt (abbreviated MgNH4S) 4 , the Zinc Ammonium Tutton salt (abbreviated ZnNH4S) 11 and the Tutton analog, Cs2Zn(H2O)6(ZrF6)2 18 exhibited behaviors inconsistent with either the SG or vibronic models. These failures were attributed to host dynamics of the NH4 groups and/or fluxations in the hydrogen bonding interactions, leading to temperature dependent deformations of the potential energy surfaces 11,18,21 .…”

Section: Introductionmentioning

confidence: 99%

“…However, three systems; the Magnesium Ammonium Tutton salt (abbreviated MgNH4S) 4 , the Zinc Ammonium Tutton salt (abbreviated ZnNH4S) 11 and the Tutton analog, Cs2Zn(H2O)6(ZrF6)2 18 exhibited behaviors inconsistent with either the SG or vibronic models. These failures were attributed to host dynamics of the NH4 groups and/or fluxations in the hydrogen bonding interactions, leading to temperature dependent deformations of the potential energy surfaces 11,18,21 . Keeping in mind the restricted temperature validity of the SG model in most of these systems, the 12 values used in discussions below were those reported in ranges where they remained relatively constant, i.e., usually when T>120 K.…”

Section: Introductionmentioning

confidence: 99%

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Electron Paramagnetic Resonance Characteristics and Crystal Structure of a Tutton Salt Analogue: Copper-Doped Cadmium Creatininium Sulfate

2020

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Electron Paramagnetic Resonance and crystallographic studies on copper-doped cadmium creatininium sulfate (CdCrnS) were undertaken to study the characteristics of a copperhexahydrate complex in an organic analog of Tutton's salt. X-ray diffraction experiments determined the crystal structure of CdCrnS at both 100 K and 298 K. CdCrnS, like Tutton salt, crystallizes in the monoclinic space group P21/n. The unit cell contains two cadmium hexahydrate complexes, four creatininium ions, four sulfates and four additional solvation waters. Both crystallography and EPR find the doped copper replaces the cadmium in the structure. Single crystal EPR measurements at room temperature determined the g and copper hyperfine (A Cu ) tensors (principal values: g; 2.437, 2.134, 2.080, A Cu ; -327, -84.8, 7.33 MHz).EPR spectra of the powder at room temperature gave g; 2.448, 2.125, 2.085 and A Cu ; -315, -75.0, 35.0 MHz, and at 110 K gave g; 2.462, 2.116, 2.077 and A Cu ; -340, -30.0, 35.0 MHz. The room temperature tensors are close to the "rigid lattice limit" values found in copper doped Tutton salts but having a higher gmin and weaker A Cux coupling than average. A small but measureable temperature dependency of the tensors indicated the presence of a dynamic Jahn-Teller (JT) effect. In addition, the EPR linewidth changed dramatically with temperature which is like that found in all copper doped Tutton crystals. Utilizing the model of Silver-Getz for the g-value variation gave an estimate for the energy difference (δ12 = 640 cm -1 ) between the ground and next highest JT configuration. An empirical correlation appears to exist between δ12 and gmin and A Cu x for the copper hexahydrates studied in similar crystals. This suggests a relationship between the amount of unpaired spin in the copper d orbital x-lobe and the gap between wells of the adiabatic potential surface.

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Dynamic Behavior of the Jahn−Teller Distorted Cu(H₂O)₆²⁺ Ion in Cu²⁺ Doped Cs₂[Zn(H₂O)₆](ZrF₆)₂ and the Crystal Structure of the Host Lattice

Cited by 38 publications

References 21 publications

Theoretical studies of the g factors and local structures of the Ni³⁺ centers in Na₂Zn(SO₄)₂·4H₂O and K₂Zn(SO₄)₂·6H₂O crystals

Theoretical studies of the g factors and local structures of the Ni³⁺ centers in Na₂Zn(SO₄)₂·4H₂O and K₂Zn(SO₄)₂·6H₂O crystals

Dipotassium hexaaquanickel(II) bis[hexafluoridozirconate(IV)]

Electron Paramagnetic Resonance Characteristics and Crystal Structure of a Tutton Salt Analogue: Copper-Doped Cadmium Creatininium Sulfate

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Dynamic Behavior of the Jahn−Teller Distorted Cu(H2O)62+ Ion in Cu2+ Doped Cs2[Zn(H2O)6](ZrF6)2 and the Crystal Structure of the Host Lattice

Cited by 38 publications

References 21 publications

Theoretical studies of the g factors and local structures of the Ni3+ centers in Na2Zn(SO4)2·4H2O and K2Zn(SO4)2·6H2O crystals

Theoretical studies of the g factors and local structures of the Ni3+ centers in Na2Zn(SO4)2·4H2O and K2Zn(SO4)2·6H2O crystals

Dipotassium hexaaquanickel(II) bis[hexafluoridozirconate(IV)]

Electron Paramagnetic Resonance Characteristics and Crystal Structure of a Tutton Salt Analogue: Copper-Doped Cadmium Creatininium Sulfate

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Product

Resources

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Dynamic Behavior of the Jahn−Teller Distorted Cu(H₂O)₆²⁺ Ion in Cu²⁺ Doped Cs₂[Zn(H₂O)₆](ZrF₆)₂ and the Crystal Structure of the Host Lattice

Theoretical studies of the g factors and local structures of the Ni³⁺ centers in Na₂Zn(SO₄)₂·4H₂O and K₂Zn(SO₄)₂·6H₂O crystals

Theoretical studies of the g factors and local structures of the Ni³⁺ centers in Na₂Zn(SO₄)₂·4H₂O and K₂Zn(SO₄)₂·6H₂O crystals