Structures of incommensurate and commensurate composite crystals RbxMnO2 (x = 1.3711, 1.3636)

Nuss, J.; Pfeiffer, S.; van Smaalen, S.; Jansen, M.

doi:10.1107/S0108768109053312

Structures of incommensurate and commensurate composite crystals Rb_xMnO₂ (x = 1.3711, 1.3636)

J. Nuss, S. Pfeiffer, S. van Smaalen and M. Jansen

Rb_1.3711MnO₂ (Rb₁₁Mn₈O₁₆) has been synthesized via the azide/nitrate route from a stoichiometric mixture of the precursors Mn₂O₃, RbNO₃ and RbN₃. The structure of this extremely air- and moisture-sensitive compound can best be described in terms of an incommensurate composite structure, built up by a honeycomb-like framework of Rb ions, as one subsystem and by a second subsystem of chains, consisting of edge-sharing MnO_4/2 tetrahedra. These two composite substructures interpenetrate in such a way that the manganate chain polyanions centre the channels of the Rb-honeycomb framework. Crystals transform by an aging process into Rb_1.3636MnO₂ (Rb₁₅Mn₁₁O₂₂), which has a similar structure but a different commensurate modulation. Two reasons can be established for the origin of the modulations: the charge ordering of Mn²⁺/Mn³⁺ on one hand, and the incompatibility of the Mn—Mn and Rb—Rb separations on the other.

Keywords: alkali metal manganate; composite crystal; incommensurate/commensurate modulated structures.

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Supporting information

	Crystallographic Information File (CIF) https://doi.org/10.1107/S0108768109053312/ck5041sup1.cif Contains datablocks global, Rb11Mn8O16, Rb15Mn11O22
	Structure factor file (CIF format) https://doi.org/10.1107/S0108768109053312/ck5041Rb11Mn8O16sup2.hkl Contains datablock Rb11Mn8O16
	Structure factor file (CIF format) https://doi.org/10.1107/S0108768109053312/ck5041Rb15Mn11O22sup3.hkl Contains datablock Rb15Mn11O22

Computing details top

For both structures, data collection: SMART32 (Bruker AXS); cell refinement: SAINT (Bruker AXS); data reduction: SAINT (Bruker AXS); program(s) used to refine structure: Jana2006 (Petricek, Dusek & Palatinus, 2006); software used to prepare material for publication: Jana2006 (Petricek, Dusek & Palatinus, 2006).

(Rb11Mn8O16) top

Crystal data top

Mn_0.729O_1.458Rb	F(000) = 1070
M_r = 148.8	D_x = 4.042 Mg m⁻³
Orthorhombic, Fddd(00γ)ss0†	Mo Kα radiation, λ = 0.71073 Å
q = 1.45870c*‡	Cell parameters from 6202 reflections
a = 12.2070 (8) Å	θ = 2.3–35.0°
b = 20.1548 (14) Å	µ = 23.39 mm⁻¹
c = 3.9753 (3) Å	T = 296 K
V = 978.04 (12) Å³	Fragment, black
Z = 16	0.30 × 0.15 × 0.10 × 0.10 (radius) mm

† Symmetry operations: (1) x₁, x₂, x₃, x₄; (2) −x₁, −x₂+1/2, x₃+1/2, x₄; (3) −x₁+1/2, x₂, −x₃+1/2, −x₄+1/2; (4) x₁, −x₂+1/2, −x₃+1/2, −x₄+1/2; (5) −x₁+1/4, −x₂+1/4, −x₃+1/4, −x₄; (6) x₁+3/4, x₂+1/4, −x₃+3/4, −x₄; (7) x₁+1/4, −x₂+1/4, x₃+1/4, x₄+1/2; (8) −x₁+1/4, x₂+1/4, x₃+1/4, x₄+1/2; (9) x₁, x₂+1/2, x₃+1/2, x₄; (10) −x₁, −x₂, x₃, x₄; (11) −x₁+1/2, x₂+1/2, −x₃, −x₄+1/2; (12) x₁, −x₂, −x₃, −x₄+1/2; (13) −x₁+1/4, −x₂+3/4, −x₃+3/4, −x₄; (14) x₁+3/4, x₂+3/4, −x₃+1/4, −x₄; (15) x₁+1/4, −x₂+3/4, x₃+3/4, x₄+1/2; (16) −x₁+1/4, x₂+3/4, x₃+3/4, x₄+1/2; (17) x₁+1/2, x₂, x₃+1/2, x₄; (18) −x₁+1/2, −x₂+1/2, x₃, x₄; (19) −x₁, x₂, −x₃, −x₄+1/2; (20) x₁+1/2, −x₂+1/2, −x₃, −x₄+1/2; (21) −x₁+3/4, −x₂+1/4, −x₃+3/4, −x₄; (22) x₁+1/4, x₂+1/4, −x₃+1/4, −x₄; (23) x₁+3/4, −x₂+1/4, x₃+3/4, x₄+1/2; (24) −x₁+3/4, x₂+1/4, x₃+3/4, x₄+1/2; (25) x₁+1/2, x₂+1/2, x₃, x₄; (26) −x₁+1/2, −x₂, x₃+1/2, x₄; (27) −x₁, x₂+1/2, −x₃+1/2, −x₄+1/2; (28) x₁+1/2, −x₂, −x₃+1/2, −x₄+1/2; (29) −x₁+3/4, −x₂+3/4, −x₃+1/4, −x₄; (30) x₁+1/4, x₂+3/4, −x₃+3/4, −x₄; (31) x₁+3/4, −x₂+3/4, x₃+1/4, x₄+1/2; (32) −x₁+3/4, x₂+3/4, x₃+1/4, x₄+1/2.

‡ $W^{1}=\left(\matrix{ 1 & 0 & 0 & 0 \cr 0 & 1 & 0 & 0 \cr 0 & 0 & 1 & 0 \cr 0 & 0 & 0 & 1 \cr }\right)$ ; $W^{2}=\left(\matrix{ 1 & 0 & 0 & 0 \cr 0 & 1 & 0 & 0 \cr 0 & 0 & 0 & 1 \cr 0 & 0 & 1 & 0 \cr }\right)$

Data collection top

Bruker CCD, APEX I diffractometer	11525 independent reflections
Radiation source: X-ray tube	4058 reflections with I > 2σ(I)
Graphite monochromator	R_int = 0.059
ωscan	θ_max = 35.0°, θ_min = 0.9°
Absorption correction: multi-scan semi empirical (using intensity measurements) absorption correction with SADABS, G.M. Sheldrick, SADABS, Version 2008/1, University of Göttingen. Germany.	h = −19→19
T_min = 0.055, T_max = 0.156	k = −32→31
57761 measured reflections	l = −11→11

Refinement top

Refinement on F	0 restraints
R[F² > 2σ(F²)] = 0.041	0 constraints
wR(F²) = 0.050	Weighting scheme based on measured s.u.'s w = 1/(σ²(F) + 0.0001F²)
S = 1.18	(Δ/σ)_max = 0.017
11525 reflections	Δρ_max = 1.67 e Å⁻³
139 parameters	Δρ_min = −2.04 e Å⁻³

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

	x	y	z	U_iso*/U_eq	Occ. (<1)
Rb1	0	0.333668 (8)	0	0.03085 (6)
Mn1	0	0	0.25	0.01526 (5)
O1	0.07780 (11)	0.03818 (6)	0.75	0.0334 (3)	0.5

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
Rb1	0.02382 (9)	0.02341 (9)	0.04532 (13)	0	0.00298 (9)	0
Mn1	0.01779 (10)	0.01488 (9)	0.01311 (9)	0	0	0
O1	0.0438 (7)	0.0363 (6)	0.0200 (4)	−0.0153 (6)	−0.0006 (5)	−0.0052 (4)

Geometric parameters (Å, º) top

	Average	Minimum	Maximum
Rb1—Rb1ⁱ	3.917 (3)	3.492 (2)	4.125 (3)
Rb1—Rb1ⁱⁱ	3.921 (3)	3.492 (2)	4.125 (3)
Rb1—Mn1ⁱⁱⁱ	356.1 (2)	3.3875 (15)	3.899 (3)
Rb1—Mn1^iv	401.7 (2)	3.3875 (15)	4.817 (2)
Rb1—Mn1^v	415.4 (3)	3.460 (3)	4.781 (2)
Rb1—Mn1^vi	368.0 (3)	3.459 (3)	3.974 (2)
Rb1—Mn1^vii	368.8 (3)	3.459 (3)	4.175 (2)
Rb1—O1ⁱ	143.8 (5)	2.838 (11)	3.166 (12)
Rb1—O1ⁱⁱ	90.5 (3)	2.900 (11)	3.365 (11)
Rb1—O1^viii	283.0 (8)	2.900 (11)	5.322 (10)
Rb1—O1^ix	190.2 (6)	2.900 (11)	4.539 (11)
Rb1—O1^x	225.6 (7)	2.838 (11)	3.365 (11)
Rb1—O1^vi	191.1 (6)	2.754 (12)	3.985 (10)
Rb1—O1^xi	114.3 (4)	2.893 (10)	3.898 (11)
Rb1—O1^xii	112.7 (4)	2.802 (9)	3.016 (10)
Rb1—O1^xiii	226.5 (8)	2.646 (9)	4.330 (10)
Rb1—O1^xiv	130.4 (3)	3.297 (10)	5.656 (12)
Rb1—O1^xv	206.9 (6)	2.763 (11)	4.312 (9)
Rb1—O1^xvi	117.7 (3)	2.754 (12)	5.365 (12)
Rb1—O1^xvii	120.7 (4)	2.930 (11)	4.330 (10)
Rb1—O1^xviii	108.7 (4)	2.646 (9)	2.930 (11)
Rb1—O1^xix	224.1 (8)	2.802 (9)	3.898 (11)
Rb1—O1^xx	252.4 (6)	3.297 (10)	4.715 (11)
Mn1—Mn1^xxi	2.7248 (12)	2.6560 (14)	2.7861 (12)
Mn1—Mn1^xxii	2.7258 (12)	2.6560 (14)	2.7861 (12)
Mn1—O1^xxi	1.967 (9)	1.830 (8)	2.010 (11)
Mn1—O1	1.885 (9)	1.863 (10)	1.942 (10)
Mn1—O1^xxiii	1.967 (9)	1.830 (8)	2.010 (11)
Mn1—O1^xxiv	1.885 (9)	1.863 (10)	1.942 (10)
Mn1—O1^xxv	1.884 (9)	1.861 (8)	1.941 (10)
Mn1—O1^xxvi	1.965 (9)	1.839 (8)	2.010 (10)
Mn1—O1^xxvii	1.884 (9)	1.861 (8)	1.941 (10)
Mn1—O1^xxviii	1.965 (9)	1.839 (8)	2.010 (10)
O1—O1^xxi	2.952 (13)	2.733 (14)	3.076 (14)
O1—O1^xxii	2.955 (13)	2.750 (14)	3.076 (13)
O1—O1^xxiv	2.719 (14)	2.481 (12)	2.879 (15)
O1—O1^xxix	3.299 (14)	3.213 (14)	3.385 (14)
O1—O1^xxvii	2.823 (13)	2.802 (12)	2.895 (14)

Rb1ⁱ—Rb1—Rb1ⁱⁱ	60.91 (5)	58.32 (6)	62.57 (5)
Mn1^xxi—Mn1—Mn1^xxii	180	180	180
Mn1^xxi—Mn1—O1^xxi	43.7 (3)	42.0 (3)	46.5 (3)
Mn1^xxi—Mn1—O1	133.8 (3)	131.6 (3)	138.8 (3)
Mn1^xxi—Mn1—O1^xxiii	43.7 (3)	42.0 (3)	46.5 (3)
Mn1^xxi—Mn1—O1^xxiv	133.8 (3)	131.6 (3)	138.8 (3)
Mn1^xxi—Mn1—O1^xxv	46.3 (3)	41.4 (3)	48.4 (3)
Mn1^xxi—Mn1—O1^xxvi	136.3 (3)	133.5 (3)	138.0 (3)
Mn1^xxi—Mn1—O1^xxvii	46.3 (3)	41.4 (3)	48.4 (3)
Mn1^xxi—Mn1—O1^xxviii	136.3 (3)	133.5 (3)	138.0 (3)
Mn1^xxii—Mn1—O1^xxi	136.3 (3)	133.5 (3)	138.0 (3)
Mn1^xxii—Mn1—O1	46.2 (3)	41.2 (3)	48.4 (3)
Mn1^xxii—Mn1—O1^xxiii	136.3 (3)	133.5 (3)	138.0 (3)
Mn1^xxii—Mn1—O1^xxiv	46.2 (3)	41.2 (3)	48.4 (3)
Mn1^xxii—Mn1—O1^xxv	133.7 (3)	131.6 (3)	138.6 (3)
Mn1^xxii—Mn1—O1^xxvi	43.7 (3)	42.0 (3)	46.5 (3)
Mn1^xxii—Mn1—O1^xxvii	133.7 (3)	131.6 (3)	138.6 (3)
Mn1^xxii—Mn1—O1^xxviii	43.7 (3)	42.0 (3)	46.5 (3)
O1^xxi—Mn1—O1	100.9 (4)	95.4 (4)	104.9 (5)
O1^xxi—Mn1—O1^xxiii	87.4 (4)	83.9 (4)	92.9 (4)
O1^xxi—Mn1—O1^xxiv	143.6 (4)	138.9 (4)	153.8 (4)
O1^xxi—Mn1—O1^xxvi	112.1 (4)	109.2 (4)	115.6 (4)
O1^xxi—Mn1—O1^xxviii	129.9 (4)	126.0 (4)	133.3 (4)
O1—Mn1—O1^xxiii	143.6 (4)	138.9 (4)	153.8 (5)
O1—Mn1—O1^xxiv	92.4 (4)	82.3 (4)	96.7 (4)
O1—Mn1—O1^xxv	148.9 (4)	144.3 (4)	150.4 (4)
O1—Mn1—O1^xxvii	97.7 (4)	96.5 (4)	101.1 (4)
O1^xxiii—Mn1—O1^xxiv	100.9 (4)	95.4 (4)	104.9 (5)
O1^xxiii—Mn1—O1^xxvi	129.9 (4)	126.0 (4)	133.3 (4)
O1^xxiii—Mn1—O1^xxviii	112.1 (4)	109.2 (4)	115.6 (4)
O1^xxiv—Mn1—O1^xxv	97.7 (4)	96.5 (4)	101.1 (4)
O1^xxiv—Mn1—O1^xxvii	148.9 (4)	144.3 (4)	150.4 (4)
O1^xxv—Mn1—O1^xxvi	100.8 (4)	95.6 (5)	104.9 (4)
O1^xxv—Mn1—O1^xxvii	92.5 (4)	82.9 (4)	96.7 (4)
O1^xxv—Mn1—O1^xxviii	143.8 (4)	138.9 (4)	153.0 (5)
O1^xxvi—Mn1—O1^xxvii	143.8 (4)	138.9 (4)	153.0 (4)
O1^xxvi—Mn1—O1^xxviii	87.4 (4)	84.0 (4)	92.9 (4)
O1^xxvii—Mn1—O1^xxviii	100.8 (4)	95.6 (5)	104.9 (4)
Mn1—O1—Mn1^xxii	90.1 (4)	85.6 (4)	96.6 (4)
Mn1—O1—O1^xxi	39.9 (3)	38.2 (3)	41.9 (3)
Mn1—O1—O1^xxii	123.8 (5)	119.1 (6)	132.8 (5)
Mn1—O1—O1^xxiv	43.8 (3)	41.6 (3)	48.8 (3)
Mn1—O1—O1^xxix	110.8 (4)	107.5 (4)	114.9 (4)
Mn1—O1—O1^xxvii	41.2 (3)	39.2 (3)	42.2 (3)
Mn1^xxii—O1—O1^xxi	119.8 (4)	116.1 (5)	125.8 (6)
Mn1^xxii—O1—O1^xxii	39.2 (3)	36.6 (3)	42.5 (3)
Mn1^xxii—O1—O1^xxiv	46.3 (3)	43.5 (3)	48.0 (3)
Mn1^xxii—O1—O1^xxix	33.9 (2)	32.2 (3)	35.6 (3)
Mn1^xxii—O1—O1^xxvii	126.6 (5)	121.9 (5)	128.8 (5)
O1^xxi—O1—O1^xxiv	78.1 (4)	75.7 (4)	81.5 (4)
O1^xxi—O1—O1^xxix	149.1 (4)	148.3 (4)	152.6 (4)
O1^xxii—O1—O1^xxiv	81.5 (4)	78.2 (4)	87.0 (4)
O1^xxii—O1—O1^xxvii	164.4 (5)	159.6 (6)	169.1 (5)
O1^xxiv—O1—O1^xxix	72.1 (3)	69.6 (3)	74.8 (4)
O1^xxiv—O1—O1^xxvii	82.4 (4)	78.4 (4)	84.1 (4)
O1^xxix—O1—O1^xxvii	153.5 (5)	148.4 (5)	155.5 (5)

Symmetry codes: (i) −x₁, −x₂+1/2, x₃−1/2, x₄; (ii) −x₁, −x₂+1/2, x₃+1/2, x₄; (iii) x₁, x₂+1/2, x₃+1/2, x₄; (iv) x₁, x₂+1/2, x₃+3/2, x₄; (v) −x₁+1/4, −x₂+1/4, −x₃+1/4, −x₄; (vi) −x₁+1/4, −x₂+1/4, −x₃+5/4, −x₄; (vii) −x₁−1/4, −x₂+1/4, −x₃+7/4, −x₄; (viii) −x₁, −x₂+1/2, x₃+3/2, x₄; (ix) x₁, −x₂+1/2, −x₃+1/2, −x₄+1/2; (x) x₁, −x₂+1/2, −x₃+3/2, −x₄+1/2; (xi) x₁−1/4, x₂+1/4, −x₃+3/4, −x₄; (xii) x₁−1/4, x₂+1/4, −x₃+7/4, −x₄; (xiii) x₁−1/4, x₂+1/4, −x₃+11/4, −x₄; (xiv) x₁+1/4, x₂+1/4, −x₃+9/4, −x₄; (xv) x₁−1/4, −x₂+1/4, x₃−1/4, x₄+1/2; (xvi) x₁−1/4, −x₂+1/4, x₃+3/4, x₄+1/2; (xvii) −x₁+1/4, x₂+1/4, x₃−7/4, x₄+1/2; (xviii) −x₁+1/4, x₂+1/4, x₃−3/4, x₄+1/2; (xix) −x₁+1/4, x₂+1/4, x₃+1/4, x₄+1/2; (xx) −x₁−1/4, x₂+1/4, x₃−1/4, x₄+1/2; (xxi) x₁, x₂, x₃−1, x₄; (xxii) x₁, x₂, x₃+1, x₄; (xxiii) −x₁, −x₂, x₃−1, x₄; (xxiv) −x₁, −x₂, x₃, x₄; (xxv) −x₁, x₂, −x₃, −x₄+1/2; (xxvi) −x₁, x₂, −x₃+1, −x₄+1/2; (xxvii) x₁, −x₂, −x₃, −x₄+1/2; (xxviii) x₁, −x₂, −x₃+1, −x₄+1/2; (xxix) −x₁, x₂, −x₃+2, −x₄+1/2.

(Rb15Mn11O22) top

Crystal data top

Mn_0.733O_1.467Rb	F(000) = 1073
M_r = 149.2	D_x = 4.066 Mg m⁻³
Orthorhombic, Fddd(00γ)ss0†	Mo Kα radiation, λ = 0.71073 Å
q = 1.46667c*‡	Cell parameters from 4478 reflections
a = 12.1639 (4) Å	θ = 2.7–33.8°
b = 20.1013 (7) Å	µ = 23.57 mm⁻¹
c = 3.9865 (2) Å	T = 296 K
V = 974.74 (7) Å³	Fragment, black
Z = 16	0.30 × 0.15 × 0.10 × 0.10 (radius) mm

Data collection top

Bruker CCD, APEX I diffractometer	9909 independent reflections
Radiation source: X-ray tube	2130 reflections with I > 3σ(I)
Graphite monochromator	R_int = 0.096
ωscan	θ_max = 38.1°, θ_min = 1.4°
Absorption correction: multi-scan semi empirical (using intensity measurements) absorption correction with SADABS, G.M. Sheldrick, SADABS, Version 2008/1, University of Göttingen. Germany.	h = −20→20
T_min = 0.059, T_max = 0.166	k = −32→34
79001 measured reflections	l = −15→15

Refinement top

Refinement on F	143 parameters
R[F² > 2σ(F²)] = 0.041	0 restraints
wR(F²) = 0.059	0 constraints
S = 1.17	Weighting scheme based on measured s.u.'s w = 1/(σ²(F) + 0.0001F²)
9909 reflections	(Δ/σ)_max = 0.008

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

	x	y	z	U_iso*/U_eq	Occ. (<1)
Rb1	0	0.333818 (17)	0	0.02096 (7)
Mn1	0	0	0.25	0.01076 (7)
O1	0.0762 (2)	0.03829 (10)	0.75	0.0295 (5)	0.5

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
Rb1	0.01193 (10)	0.01349 (9)	0.03745 (17)	0	0.00060 (9)	0
Mn1	0.01063 (12)	0.00840 (11)	0.01326 (12)	0	0	0
O1	0.0422 (12)	0.0236 (7)	0.0226 (7)	−0.0116 (11)	−0.0011 (8)	−0.0042 (7)

Geometric parameters (Å, º) top

	Average	Minimum	Maximum
Rb1—Mn1ⁱ	52.82 (3)	3.392 (2)	3.852 (2)
Rb1—Mn1ⁱⁱ	59.11 (4)	3.392 (2)	4.786 (2)
Rb1—Mn1ⁱⁱⁱ	61.87 (4)	3.450 (3)	4.741 (3)
Rb1—Mn1^iv	54.37 (4)	3.443 (2)	3.951 (3)
Rb1—Mn1^v	54.46 (4)	3.443 (2)	4.090 (3)
Rb1—O1ⁱ	14.99 (6)	3.470 (16)	4.072 (18)
Rb1—O1^vi	20.76 (12)	2.85 (2)	3.06 (2)
Rb1—O1^vii	13.10 (7)	3.158 (18)	3.361 (16)
Rb1—O1^viii	43.6 (2)	2.894 (18)	5.254 (18)
Rb1—O1^ix	48.79 (18)	3.470 (16)	5.205 (19)
Rb1—O1^x	28.73 (16)	2.894 (18)	4.43 (2)
Rb1—O1^xi	33.86 (19)	2.85 (2)	3.361 (16)
Rb1—O1^iv	27.42 (15)	2.74 (2)	3.733 (13)
Rb1—O1^xii	16.44 (10)	2.87 (2)	3.882 (19)
Rb1—O1^xiii	17.45 (12)	2.81 (2)	3.130 (19)
Rb1—O1^xiv	34.1 (2)	2.670 (18)	4.33 (2)
Rb1—O1^xv	17.86 (8)	3.196 (19)	5.68 (2)
Rb1—O1^xvi	30.32 (15)	2.798 (13)	4.344 (17)
Rb1—O1^xvii	16.15 (8)	2.74 (2)	5.351 (18)
Rb1—O1^xviii	17.42 (10)	2.99 (2)	4.33 (2)
Rb1—O1^xix	16.71 (12)	2.670 (18)	2.894 (18)
Rb1—O1^xx	33.9 (2)	2.81 (2)	3.882 (19)
Rb1—O1^xxi	36.16 (17)	3.196 (19)	4.576 (14)
Mn1—Mn1^xxii	2.718 (2)	2.641 (2)	2.796 (2)
Mn1—Mn1^xxiii	2.718 (2)	2.641 (2)	2.796 (2)
Mn1—O1^xxii	1.962 (16)	1.862 (16)	2.005 (14)
Mn1—O1	1.889 (16)	1.857 (13)	1.934 (17)
Mn1—O1^xxiv	1.962 (16)	1.862 (16)	2.005 (14)
Mn1—O1^xxv	1.889 (16)	1.857 (13)	1.934 (17)
Mn1—O1^xxvi	1.889 (16)	1.857 (13)	1.934 (17)
Mn1—O1^xxvii	1.962 (16)	1.862 (16)	2.005 (14)
Mn1—O1^xxviii	1.889 (16)	1.857 (13)	1.934 (17)
Mn1—O1^xxix	1.962 (16)	1.862 (16)	2.005 (14)
O1—O1^xxii	2.97 (2)	2.80 (2)	3.09 (2)
O1—O1^xxiii	2.97 (2)	2.80 (2)	3.09 (2)
O1—O1^xxv	2.73 (2)	2.58 (3)	2.857 (18)
O1—O1^xxx	3.27 (2)	3.17 (2)	3.37 (2)
O1—O1^xxviii	2.83 (2)	2.81 (2)	2.88 (2)

Mn1^xxii—Mn1—Mn1^xxiii	180	180	180
Mn1^xxii—Mn1—O1^xxii	44.0 (5)	42.2 (6)	46.5 (5)
Mn1^xxii—Mn1—O1	133.8 (6)	131.4 (5)	138.1 (6)
Mn1^xxii—Mn1—O1^xxiv	44.0 (5)	42.2 (6)	46.5 (5)
Mn1^xxii—Mn1—O1^xxv	133.8 (6)	131.4 (5)	138.1 (6)
Mn1^xxii—Mn1—O1^xxvi	46.2 (6)	41.9 (6)	48.6 (5)
Mn1^xxii—Mn1—O1^xxvii	136.0 (5)	133.5 (5)	137.8 (6)
Mn1^xxii—Mn1—O1^xxviii	46.2 (6)	41.9 (6)	48.6 (5)
Mn1^xxii—Mn1—O1^xxix	136.0 (5)	133.5 (5)	137.8 (6)
Mn1^xxiii—Mn1—O1^xxii	136.0 (5)	133.5 (5)	137.8 (6)
Mn1^xxiii—Mn1—O1	46.2 (6)	41.9 (6)	48.6 (5)
Mn1^xxiii—Mn1—O1^xxiv	136.0 (5)	133.5 (5)	137.8 (6)
Mn1^xxiii—Mn1—O1^xxv	46.2 (6)	41.9 (6)	48.6 (5)
Mn1^xxiii—Mn1—O1^xxvi	133.8 (6)	131.4 (5)	138.1 (6)
Mn1^xxiii—Mn1—O1^xxvii	44.0 (5)	42.2 (6)	46.5 (5)
Mn1^xxiii—Mn1—O1^xxviii	133.8 (6)	131.4 (5)	138.1 (6)
Mn1^xxiii—Mn1—O1^xxix	44.0 (5)	42.2 (6)	46.5 (5)
O1^xxii—Mn1—O1	101.9 (7)	96.6 (8)	106.6 (8)
O1^xxii—Mn1—O1^xxiv	88.0 (7)	84.3 (7)	93.0 (7)
O1^xxii—Mn1—O1^xxv	141.6 (7)	136.8 (8)	146.9 (7)
O1^xxii—Mn1—O1^xxvii	111.0 (7)	107.8 (7)	115.1 (7)
O1^xxii—Mn1—O1^xxix	131.1 (8)	125.2 (8)	136.9 (8)
O1—Mn1—O1^xxiv	141.6 (7)	136.8 (8)	146.9 (8)
O1—Mn1—O1^xxv	92.4 (7)	83.8 (8)	97.3 (8)
O1—Mn1—O1^xxvi	148.1 (7)	146.8 (8)	149.7 (6)
O1—Mn1—O1^xxviii	97.7 (8)	96.7 (7)	98.9 (8)
O1^xxiv—Mn1—O1^xxv	101.9 (7)	96.6 (8)	106.6 (8)
O1^xxiv—Mn1—O1^xxvii	131.1 (8)	125.2 (8)	136.9 (8)
O1^xxiv—Mn1—O1^xxix	111.0 (7)	107.8 (8)	115.1 (7)
O1^xxv—Mn1—O1^xxvi	97.7 (8)	96.7 (8)	98.9 (8)
O1^xxv—Mn1—O1^xxviii	148.1 (7)	146.8 (8)	149.7 (8)
O1^xxvi—Mn1—O1^xxvii	101.9 (7)	96.6 (8)	106.6 (7)
O1^xxvi—Mn1—O1^xxviii	92.4 (7)	83.8 (8)	97.3 (8)
O1^xxvi—Mn1—O1^xxix	141.6 (7)	136.8 (8)	146.9 (8)
O1^xxvii—Mn1—O1^xxviii	141.6 (7)	136.8 (8)	146.9 (7)
O1^xxvii—Mn1—O1^xxix	88.0 (7)	84.3 (7)	93.0 (7)
O1^xxviii—Mn1—O1^xxix	101.9 (7)	96.6 (8)	106.6 (7)
Mn1—O1—Mn1^xxiii	89.8 (7)	85.5 (5)	94.2 (8)
Mn1—O1—O1^xxii	39.3 (5)	37.6 (5)	41.4 (5)
Mn1—O1—O1^xxiii	122.5 (9)	116.8 (9)	128.0 (9)
Mn1—O1—O1^xxv	43.8 (5)	41.4 (5)	48.1 (6)
Mn1—O1—O1^xxx	111.4 (8)	106.7 (8)	116.5 (7)
Mn1—O1—O1^xxviii	41.1 (5)	39.6 (5)	42.2 (5)
Mn1^xxiii—O1—O1^xxii	118.5 (7)	116.5 (8)	121.6 (8)
Mn1^xxiii—O1—O1^xxiii	38.8 (5)	35.8 (5)	42.0 (5)
Mn1^xxiii—O1—O1^xxv	46.0 (5)	43.5 (5)	47.8 (5)
Mn1^xxiii—O1—O1^xxx	34.5 (4)	32.5 (4)	36.8 (4)
Mn1^xxiii—O1—O1^xxviii	125.9 (9)	124.0 (9)	128.0 (10)
O1^xxii—O1—O1^xxv	77.3 (6)	75.9 (6)	79.4 (7)
O1^xxii—O1—O1^xxx	149.0 (7)	147.3 (7)	152.1 (7)
O1^xxiii—O1—O1^xxv	80.3 (7)	76.4 (7)	83.7 (7)
O1^xxiii—O1—O1^xxviii	162.9 (9)	157.4 (9)	167.0 (9)
O1^xxv—O1—O1^xxx	72.7 (6)	69.2 (6)	76.2 (6)
O1^xxv—O1—O1^xxviii	82.0 (7)	80.3 (7)	83.8 (8)
O1^xxx—O1—O1^xxviii	153.9 (9)	150.4 (9)	156.5 (10)

Symmetry codes: (i) x₁, x₂+1/2, x₃+1/2, x₄; (ii) x₁, x₂+1/2, x₃+3/2, x₄; (iii) −x₁+1/4, −x₂+1/4, −x₃+1/4, −x₄; (iv) −x₁+1/4, −x₂+1/4, −x₃+5/4, −x₄; (v) −x₁−1/4, −x₂+1/4, −x₃+7/4, −x₄; (vi) −x₁, −x₂+1/2, x₃−1/2, x₄; (vii) −x₁, −x₂+1/2, x₃+1/2, x₄; (viii) −x₁, −x₂+1/2, x₃+3/2, x₄; (ix) −x₁, x₂+1/2, −x₃+3/2, −x₄+1/2; (x) x₁, −x₂+1/2, −x₃+1/2, −x₄+1/2; (xi) x₁, −x₂+1/2, −x₃+3/2, −x₄+1/2; (xii) x₁−1/4, x₂+1/4, −x₃+3/4, −x₄; (xiii) x₁−1/4, x₂+1/4, −x₃+7/4, −x₄; (xiv) x₁−1/4, x₂+1/4, −x₃+11/4, −x₄; (xv) x₁+1/4, x₂+1/4, −x₃+9/4, −x₄; (xvi) x₁−1/4, −x₂+1/4, x₃−1/4, x₄+1/2; (xvii) x₁−1/4, −x₂+1/4, x₃+3/4, x₄+1/2; (xviii) −x₁+1/4, x₂+1/4, x₃−7/4, x₄+1/2; (xix) −x₁+1/4, x₂+1/4, x₃−3/4, x₄+1/2; (xx) −x₁+1/4, x₂+1/4, x₃+1/4, x₄+1/2; (xxi) −x₁−1/4, x₂+1/4, x₃−1/4, x₄+1/2; (xxii) x₁, x₂, x₃−1, x₄; (xxiii) x₁, x₂, x₃+1, x₄; (xxiv) −x₁, −x₂, x₃−1, x₄; (xxv) −x₁, −x₂, x₃, x₄; (xxvi) −x₁, x₂, −x₃, −x₄+1/2; (xxvii) −x₁, x₂, −x₃+1, −x₄+1/2; (xxviii) x₁, −x₂, −x₃, −x₄+1/2; (xxix) x₁, −x₂, −x₃+1, −x₄+1/2; (xxx) −x₁, x₂, −x₃+2, −x₄+1/2.

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