Charge-doped nickel oxide, Y1.90Ca0.10BaNiO5

Lannuzel, F.-X.; Boucher, F.; Payen, C.

doi:10.1107/S1600536801011667

Charge-doped nickel oxide, Y_1.90Ca_0.10BaNiO₅

The crystal structure of orthorhombic yttrium calcium barium nickel pentaoxide, Y_1.90Ca_0.10BaNiO₅, a charge-doped quasi-one-dimensional nickel oxide, has been determined from X-ray single-crystal data at room temperature. Ca²⁺ ions replace at random the Y³⁺ ions within the Immm crystal structure of the undoped compound, Y₂BaNiO₅.

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Supporting information

	Crystallographic Information File (CIF) https://doi.org/10.1107/S1600536801011667/br6025sup1.cif Contains datablocks global, I
	Structure factor file (CIF format) https://doi.org/10.1107/S1600536801011667/br6025Isup2.hkl Contains datablock I

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Key indicators

Single-crystal X-ray study
T = 293 K
Mean (Ni-O) = 0.001 Å
Disorder in main residue
R factor = 0.016
wR factor = 0.042
Data-to-parameter ratio = 18.6

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ADDSYM reports no extra symmetry


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Comment top

The crystal structure of the divalent nickel oxide Y₂BaNiO₅ was first determined from single-crystal diffraction data by Müller-Buschbaum & Schlüter (1990), Amador et al. (1990) and Buttrey et al. (1990). It has an orthorhombic crystal structure that contains infinite linear chains of flattened NiO₆ octahedra sharing corners along the crystallographic a direction. The magnetic properties of this charge-transfer insulator are those of an antiferromagnetic chain compound with a Haldane spin gap (Darriet & Regnault, 1993). Hole doping in Y₂BaNiO₅, which is achieved by substituting Ca²⁺ for Y³⁺, has attracted considerable attention in recent years, arising from quite interesting electronic and physical properties and possible connections to high-temperature superconductivity (Di Tusa et al., 1994; Janod et al., 2001). X-ray and neutron-powder diffraction data for Y_{2 -} _xCa_xBaNiO₅ have been analysed using the Rietveld method (Massarotti et al., 1999) but, as far as we know, no single-crystal structure determination has been published so far.

In this work, we have analyzed a single-crystal of Y_{2 -} _xCa_xBaNiO₅, prepared by a flux method. The refinement of the single-crystal data confirms that Ca²⁺ ions replace at random the Y³⁺ ions within the Immm crystal structure of the undoped compound without any sign of superstructure, in agreement with the results of a previous electron diffraction study (Xu et al., 2001). The refinement of the Ca,Y occupancy factors leads to the composition x = 0.10 (1), in agreement with the value determined from our energy-dispersive X-ray elemental analysis, x = 0.11 (2). Atomic parameters (positions, ADP's and occupation ratio) are obtained here with s.u.'s much smaller than those reported from powder data (Massarotti et al., 1999). Moreover, the z coordinate of the Y/Ca site is very close to those reported for the undoped compound by Müller-Buschbaum & Schlüter (1990) and Amador et al. (1990), but significantly different from that obtained by Buttrey et al. (1990). Our study seems to highlight the unreliability of the refinement of Buttrey et al. (1990) concerning not only the lattice parameters, as already suggested by these authors, but also the z coordinate of the Y site.

We thus confirm that substitution of Y³⁺ by Ca²⁺ does not induce significant structural modification around the Y site. On the other hand, the Ni—O1 and Ni—O2 distances are found to decrease upon doping in spite of a bigger ionic radius for Ca²⁺, as suggested earlier (Massarotti et al., 1999). The shortening of both axial Ni—O1 and equatorial Ni—O2 distances is due to the effects of hole doping on the electronic structure close to the Fermi level (Lannuzel et al., 2001).

Experimental top

Single crystals of Y_1.90Ca_0.10BaNiO₅ were prepared using a self-flux method, as described by Yokoo et al. (1995). We first synthetized a ceramic sample of the parent compound Y₂BaNiO₅ by solid-state reaction from a mixture of NiO, Y₂O₃ and BaCO₃ in air. We then added this polycrystalline sample to a mixture of CaCO₃, NiO and BaCO₃, in a mole ratio of CaCO₃:NiO:BaCO₃:Y₂O₃ = 1.62:45:45:10. This mixture was then heated at 1723 K for 2 h in a Pt crucible, and slowly cooled (2 K h^-1) to room temperature.

Computing details top

Data collection: CAD-4-PC Software (Enraf-Nonius, 1992); cell refinement: CAD-4-PC Software; data reduction: JANA2000 (Petrícek & Dusek, 2000); program(s) used to refine structure: JANA2000; molecular graphics: DIAMOND (Brandenburg, 1999); software used to prepare material for publication: JANA2000.

Figures top

	Fig. 1. A view of the unit cell of Y_1.90Ca_0.10BaNiO₅. Displacement ellipsoids are drawn here at the 97% probability level. Ni—O bonds of the central NiO₆ octahedra and unit-cell edges are shown.
	Fig. 2. Schematic view of the crystallographic structure of Y_1.90Ca_0.10BaNiO₅ highlighting the existence of linear chains of vertex-sharing NiO₆ octahedra.

(I) top

Crystal data top

Y_1.90Ca_0.10BaNiO₅	D_x = 6.097 Mg m⁻³
M_r = 449	Mo Kα radiation, λ = 0.71069 Å
Orthorhombic, Immm	Cell parameters from 25 reflections
a = 3.7527 (5) Å	θ = 7.4–15.0°
b = 5.7581 (9) Å	µ = 34.10 mm⁻¹
c = 11.313 (2) Å	T = 293 K
V = 244.46 (6) Å³	Thick needle, black
Z = 2	0.16 × 0.02 × 0.02 mm
F(000) = 400

Data collection top

CAD-4 diffractometer	R_int = 0.035
ω scans	θ_max = 38.0°, θ_min = 3.6°
Absorption correction: gaussian (JANA2000; Petrícek & Dusek, 2000)	h = −6→6
T_min = 0.420, T_max = 0.511	k = −9→9
2650 measured reflections	l = −19→19
409 independent reflections	3 standard reflections every 60 min
387 reflections with I > 2σ(I)	intensity decay: 0.8%

Refinement top

Refinement on F²	Weighting scheme based on measured s.u.'s w = 1/[σ²(I) + 0.001024I²]
R[F² > 2σ(F²)] = 0.016	(Δ/σ)_max = 0.003
wR(F²) = 0.042	Δρ_max = 1.07 e Å⁻³
S = 1.00	Δρ_min = −1.64 e Å⁻³
409 reflections	Extinction correction: B-C type 1 Lorentzian isotropic
22 parameters	Extinction coefficient: 0.45 (2)

Crystal data top

Y_1.90Ca_0.10BaNiO₅	V = 244.46 (6) Å³
M_r = 449	Z = 2
Orthorhombic, Immm	Mo Kα radiation
a = 3.7527 (5) Å	µ = 34.10 mm⁻¹
b = 5.7581 (9) Å	T = 293 K
c = 11.313 (2) Å	0.16 × 0.02 × 0.02 mm

Data collection top

CAD-4 diffractometer	387 reflections with I > 2σ(I)
Absorption correction: gaussian (JANA2000; Petrícek & Dusek, 2000)	R_int = 0.035
T_min = 0.420, T_max = 0.511	3 standard reflections every 60 min
2650 measured reflections	intensity decay: 0.8%
409 independent reflections

Refinement top

R[F² > 2σ(F²)] = 0.016	22 parameters
wR(F²) = 0.042	Δρ_max = 1.07 e Å⁻³
S = 1.00	Δρ_min = −1.64 e Å⁻³
409 reflections

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
Y	0.5	0	0.20285 (2)	0.00457 (7)	0.951 (4)
Ca	0.5	0	0.20285	0.00457	0.049
Ba	0.5	0.5	0	0.00822 (6)
Ni	0	0	0	0.00560 (11)
O1	0.5	0	0	0.0094 (7)
O2	0	0.2400 (2)	0.14833 (12)	0.0081 (3)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
Y	0.00578 (14)	0.00403 (13)	0.00390 (12)	0	0	0
Ca	0.00578	0.00403	0.00390	0	0	0
Ba	0.01105 (12)	0.00640 (11)	0.00722 (11)	0	0	0
Ni	0.0039 (2)	0.0071 (2)	0.00575 (18)	0	0	0
O1	0.0076 (12)	0.0161 (14)	0.0044 (10)	0	0	0
O2	0.0096 (6)	0.0066 (6)	0.0080 (6)	0	0	−0.0018 (4)

Geometric parameters (Å, º) top

Y—O1	2.2949 (2)	Ba—O2^viii	2.9287 (12)
Y—O2	2.4107 (10)	Ba—O2^ix	2.9287 (12)
Y—O2ⁱ	2.4107 (10)	Ba—O2^x	2.9287 (12)
Y—O2ⁱⁱ	2.2528 (15)	Ba—O2^xi	2.9287 (12)
Y—O2ⁱⁱⁱ	2.2528 (15)	Ba—O2^xii	2.9287 (12)
Y—O2^iv	2.4107 (10)	Ni—O1^xiii	1.8764 (3)
Y—O2^v	2.4107 (10)	Ni—O1	1.8764 (3)
Ba—O1	2.8791 (5)	Ni—O2	2.1740 (15)
Ba—O1^vi	2.8791 (5)	Ni—O2^xiv	2.1740 (15)
Ba—O2	2.9287 (12)	Ni—O2^ix	2.1740 (15)
Ba—O2ⁱ	2.9287 (12)	Ni—O2^iv	2.1740 (15)
Ba—O2^vii	2.9287 (12)

O1—Y—O2	75.18 (3)	O2ⁱ—Ba—O2^xi	110.08 (3)
O1—Y—O2ⁱ	75.18 (3)	O2ⁱ—Ba—O2^xii	61.47 (4)
O1—Y—O2ⁱⁱ	138.36 (3)	O2^vii—Ba—O2	100.31 (2)
O1—Y—O2ⁱⁱⁱ	138.36 (3)	O2^vii—Ba—O2ⁱ	180
O1—Y—O2^iv	75.18 (3)	O2^vii—Ba—O2^viii	79.69 (2)
O1—Y—O2^v	75.18 (3)	O2^vii—Ba—O2^ix	61.47 (4)
O2—Y—O2ⁱ	102.22 (4)	O2^vii—Ba—O2^x	110.08 (3)
O2—Y—O2ⁱⁱ	79.06 (4)	O2^vii—Ba—O2^xi	69.92 (3)
O2—Y—O2ⁱⁱⁱ	124.90 (3)	O2^vii—Ba—O2^xii	118.53 (4)
O2—Y—O2^iv	69.97 (4)	O2^viii—Ba—O2	180
O2—Y—O2^v	150.35 (4)	O2^viii—Ba—O2ⁱ	100.31 (2)
O2ⁱ—Y—O2	102.22 (4)	O2^viii—Ba—O2^vii	79.69 (2)
O2ⁱ—Y—O2ⁱⁱ	79.06 (4)	O2^viii—Ba—O2^ix	110.08 (3)
O2ⁱ—Y—O2ⁱⁱⁱ	124.90 (3)	O2^viii—Ba—O2^x	61.47 (4)
O2ⁱ—Y—O2^iv	150.35 (4)	O2^viii—Ba—O2^xi	118.53 (4)
O2ⁱ—Y—O2^v	69.97 (4)	O2^viii—Ba—O2^xii	69.92 (3)
O2ⁱⁱ—Y—O2	79.06 (4)	O2^ix—Ba—O2	69.92 (3)
O2ⁱⁱ—Y—O2ⁱ	79.06 (4)	O2^ix—Ba—O2ⁱ	118.53 (4)
O2ⁱⁱ—Y—O2ⁱⁱⁱ	83.28 (5)	O2^ix—Ba—O2^vii	61.47 (4)
O2ⁱⁱ—Y—O2^iv	124.90 (3)	O2^ix—Ba—O2^viii	110.08 (3)
O2ⁱⁱ—Y—O2^v	124.90 (3)	O2^ix—Ba—O2^x	79.69 (2)
O2ⁱⁱⁱ—Y—O2	124.90 (3)	O2^ix—Ba—O2^xi	100.31 (2)
O2ⁱⁱⁱ—Y—O2ⁱ	124.90 (3)	O2^ix—Ba—O2^xii	180
O2ⁱⁱⁱ—Y—O2ⁱⁱ	83.28 (5)	O2^x—Ba—O2	118.53 (4)
O2ⁱⁱⁱ—Y—O2^iv	79.06 (4)	O2^x—Ba—O2ⁱ	69.92 (3)
O2ⁱⁱⁱ—Y—O2^v	79.06 (4)	O2^x—Ba—O2^vii	110.08 (3)
O2^iv—Y—O2	69.97 (4)	O2^x—Ba—O2^viii	61.47 (4)
O2^iv—Y—O2ⁱ	150.35 (4)	O2^x—Ba—O2^ix	79.69 (2)
O2^iv—Y—O2ⁱⁱ	124.90 (3)	O2^x—Ba—O2^xi	180
O2^iv—Y—O2ⁱⁱⁱ	79.06 (4)	O2^x—Ba—O2^xii	100.31 (2)
O2^iv—Y—O2^v	102.22 (4)	O2^xi—Ba—O2	61.47 (4)
O2^v—Y—O2	150.35 (4)	O2^xi—Ba—O2ⁱ	110.08 (3)
O2^v—Y—O2ⁱ	69.97 (4)	O2^xi—Ba—O2^vii	69.92 (3)
O2^v—Y—O2ⁱⁱ	124.90 (3)	O2^xi—Ba—O2^viii	118.53 (4)
O2^v—Y—O2ⁱⁱⁱ	79.06 (4)	O2^xi—Ba—O2^ix	100.31 (2)
O2^v—Y—O2^iv	102.22 (4)	O2^xi—Ba—O2^x	180
O1—Ba—O1^vi	180	O2^xi—Ba—O2^xii	79.69 (2)
O1—Ba—O2	59.26 (2)	O2^xii—Ba—O2	110.08 (3)
O1—Ba—O2ⁱ	59.26 (2)	O2^xii—Ba—O2ⁱ	61.47 (4)
O1—Ba—O2^vii	120.74 (2)	O2^xii—Ba—O2^vii	118.53 (4)
O1—Ba—O2^viii	120.74 (2)	O2^xii—Ba—O2^viii	69.92 (3)
O1—Ba—O2^ix	59.26 (2)	O2^xii—Ba—O2^ix	180
O1—Ba—O2^x	59.26 (2)	O2^xii—Ba—O2^x	100.31 (2)
O1—Ba—O2^xi	120.74 (2)	O2^xii—Ba—O2^xi	79.69 (2)
O1—Ba—O2^xii	120.74 (2)	O1^xiii—Ni—O1	180
O1^vi—Ba—O1	180	O1^xiii—Ni—O2	90
O1^vi—Ba—O2	120.74 (2)	O1^xiii—Ni—O2^xiv	90
O1^vi—Ba—O2ⁱ	120.74 (2)	O1^xiii—Ni—O2^ix	90
O1^vi—Ba—O2^vii	59.26 (2)	O1^xiii—Ni—O2^iv	90
O1^vi—Ba—O2^viii	59.26 (2)	O1—Ni—O1^xiii	180
O1^vi—Ba—O2^ix	120.74 (2)	O1—Ni—O2	90
O1^vi—Ba—O2^x	120.74 (2)	O1—Ni—O2^xiv	90
O1^vi—Ba—O2^xi	59.26 (2)	O1—Ni—O2^ix	90
O1^vi—Ba—O2^xii	59.26 (2)	O1—Ni—O2^iv	90
O2—Ba—O2ⁱ	79.69 (2)	O2—Ni—O2^xiv	180
O2—Ba—O2^vii	100.31 (2)	O2—Ni—O2^ix	101.04 (5)
O2—Ba—O2^viii	180	O2—Ni—O2^iv	78.96 (5)
O2—Ba—O2^ix	69.92 (3)	O2^xiv—Ni—O2	180
O2—Ba—O2^x	118.53 (4)	O2^xiv—Ni—O2^ix	78.96 (5)
O2—Ba—O2^xi	61.47 (4)	O2^xiv—Ni—O2^iv	101.04 (5)
O2—Ba—O2^xii	110.08 (3)	O2^ix—Ni—O2	101.04 (5)
O2ⁱ—Ba—O2	79.69 (2)	O2^ix—Ni—O2^xiv	78.96 (5)
O2ⁱ—Ba—O2^vii	180	O2^ix—Ni—O2^iv	180
O2ⁱ—Ba—O2^viii	100.31 (2)	O2^iv—Ni—O2	78.96 (5)
O2ⁱ—Ba—O2^ix	118.53 (4)	O2^iv—Ni—O2^xiv	101.04 (5)
O2ⁱ—Ba—O2^x	69.92 (3)	O2^iv—Ni—O2^ix	180

Symmetry codes: (i) x+1, y, z; (ii) −x+1/2, −y+1/2, −z+1/2; (iii) x+1/2, y−1/2, −z+1/2; (iv) −x, −y, z; (v) −x+1, −y, z; (vi) x, y+1, z; (vii) −x, −y+1, −z; (viii) −x+1, −y+1, −z; (ix) x, y, −z; (x) x+1, y, −z; (xi) −x, −y+1, z; (xii) −x+1, −y+1, z; (xiii) x−1, y, z; (xiv) −x, −y, −z.

Experimental details

Crystal data
Chemical formula	Y_1.90Ca_0.10BaNiO₅
M_r	449
Crystal system, space group	Orthorhombic, Immm
Temperature (K)	293
a, b, c (Å)	3.7527 (5), 5.7581 (9), 11.313 (2)
V (Å³)	244.46 (6)
Z	2
Radiation type	Mo Kα
µ (mm⁻¹)	34.10
Crystal size (mm)	0.16 × 0.02 × 0.02

Data collection
Diffractometer	CAD-4 diffractometer
Absorption correction	Gaussian (JANA2000; Petrícek & Dusek, 2000)
T_min, T_max	0.420, 0.511
No. of measured, independent and observed [I > 2σ(I)] reflections	2650, 409, 387
R_int	0.035
(sin θ/λ)_max (Å⁻¹)	0.865

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.016, 0.042, 1.00
No. of reflections	409
No. of parameters	22
No. of restraints	?
Δρ_max, Δρ_min (e Å⁻³)	1.07, −1.64

Computer programs: CAD-4-PC Software (Enraf-Nonius, 1992), CAD-4-PC Software, JANA2000 (Petrícek & Dusek, 2000), JANA2000, DIAMOND (Brandenburg, 1999).

Selected geometric parameters (Å, º) top

Y—O1	2.2949 (2)	Ba—O2	2.9287 (12)
Y—O2	2.4107 (10)	Ni—O1ⁱⁱ	1.8764 (3)
Y—O2ⁱ	2.2528 (15)	Ni—O2	2.1740 (15)
Ba—O1	2.8791 (5)

O2—Ni—O2ⁱⁱⁱ	101.04 (5)	O2—Ni—O2^iv	78.96 (5)

Symmetry codes: (i) −x+1/2, −y+1/2, −z+1/2; (ii) x−1, y, z; (iii) x, y, −z; (iv) −x, −y, z.

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