Incommensurate density modulation in a Na-rich plagioclase feldspar: Z-contrast imaging and single-crystal X-ray diffraction study

Xu, H.; Jin, S.; Noll, B.C.

doi:10.1107/S205252061601578X

Incommensurate density modulation in a Na-rich plagioclase feldspar: Z-contrast imaging and single-crystal X-ray diffraction study

Plagioclase feldspars are the most abundant mineral in the Earth's crust. Intermediate plagioclase feldspars commonly display incommensurately modulated or aperiodic structures. Z-contrast images show both Ca–Na ordering and density modulation. The local structure of lamellae domains has I1-like symmetry. The neighboring lamellae domains are in an inversion twinning relationship. With a state-of-the-art X-ray diffraction unit, second-order satellite reflections (f-reflections) are observed for the first time in andesine (An₄₅), a Na-rich e-plagioclase. The f-reflections indicate a structure with a density modulation which is close to a Ca-rich e-plagioclase. The similarity between this e-andesine structure and previously solved e-labradorite structure is confirmed. Refinement of the structure shows density modulation of ∼ 7 mol % in compositional variation of the anorthite (An) component. The results from Z-contrast imaging and low-temperature single X-ray diffraction (XRD) provide a structure consistent with density modulation. The discovery of f-reflections in Na-rich e-plagioclase extends the composition range of e1 structure with density modulation to as low as at least An₄₅, which is the lower end of the composition range of Bøggild intergrowth. The new result supports the loop-shaped solvus for Bøggild intergrowth, below which is a homogenous stable area for e1 structure in the phase diagram. The phase transition between e2 structure without density modulation and e1 structure with density modulation should happen at low temperature. There is a change in modulation period accompanying the phase transition, as well as higher occupancy of Al in the T₁o site. The andesine with density modulation also indicates extremely slow cooling of its host rock.

Keywords: density modulation; Z-contrast imaging; e-plagioclase; andesine; incommensurate.

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Supporting information

	Crystallographic Information File (CIF) https://doi.org/10.1107/S205252061601578X/dk5048sup1.cif Contains datablocks global, I
	Structure factor file (CIF format) https://doi.org/10.1107/S205252061601578X/dk5048Isup2.hkl Contains datablock I
	Graphic Interchange Format (GIF) image https://doi.org/10.1107/S205252061601578X/dk5048sup3.gif The modulated structure illustrated in (3+1)D superspace. The phase parameter t is shown as time in the movie. Ca and Na atoms are shown as large spheres, with blue for Ca and yellow for Na partial occupancies. Al/Si atoms are shown as small spheres; occupancies for Si and Al atoms are shown with dark blue and light blue colours, respectively
	Portable Document Format (PDF) file https://doi.org/10.1107/S205252061601578X/dk5048sup4.pdf Supporting figure showing the stereographic net of andesine

B-IncStrDB reference: 12652EIb3rf

CCDC reference: 1508719

Computing details top

(I) top

Crystal data top

Ca_0.49Na_0.51Si_2.56Al_1.44O₈	V = 1336.52 (7) Å³
M_r = 270.1	Z = 8
Triclinic, X1(αβγ)0†	F(000) = 1071
q = 0.091630a* + 0.025810b* + -0.284580c*	D_x = 2.685 Mg m⁻³
a = 8.1661 (3) Å	Mo Kα radiation, λ = 0.71073 Å
b = 12.8545 (2) Å	µ = 1.24 mm⁻¹
c = 14.2350 (4) Å	T = 100 K
α = 93.5777 (8)°	Block, colorless
β = 116.3090 (7)°	0.08 × 0.06 × 0.05 mm
γ = 89.593 (3)°

† Symmetry operations: (1) x₁, x₂, x₃, x₄; (2) −x₁, −x₂, −x₃, −x₄; (3) x₁+1/2, x₂+1/2, x₃, x₄+1/2; (4) −x₁+1/2, −x₂+1/2, −x₃, −x₄+1/2; (5) x₁, x₂, x₃+1/2, x₄+1/2; (6) −x₁, −x₂, −x₃+1/2, −x₄+1/2; (7) x₁+1/2, x₂+1/2, x₃+1/2, x₄; (8) −x₁+1/2, −x₂+1/2, −x₃+1/2, −x₄.

Data collection top

Bruker CCD diffractometer	R_int = 0.081
Radiation source: X-ray tube	θ_max = 29.6°, θ_min = 2.1°
Graphite monochromator	h = −11→11
146201 measured reflections	k = −17→17
9366 independent reflections	l = −20→20
7205 reflections with I > 3σ(I)

Refinement top

Refinement on F²	0 restraints
R[F² > 2σ(F²)] = 0.029	250 constraints
wR(F²) = 0.111	Weighting scheme based on measured s.u.'s w = 1/(σ²(I) + 0.0016I²)
S = 1.84	(Δ/σ)_max = 0.049
9366 reflections	Extinction correction: B-C type 1 Gaussian isotropic (Becker & Coppens, 1974)
642 parameters	Extinction coefficient: 3500 (700)

Special details top

Refinement. Ristrictions

restric T1o* -1 restric T1m* -1 restric T2o* -1 restric T2m* -1 restric M1* 11 restric M* -4

Equations

equation : o[M1Na]=1-o[M2Ca]-o[M1Ca] equation : o[T1oAl]=1-o[T1oSi] equation : o[T1mAl]=1-o[T1mSi] equation : o[T2oAl]=1-o[T2oSi] equation : o[T2mAl]=1-o[T2mSi]

Fixed Commands

fixed ind o[T*] fixed ind osin1[T*] fixed ind ocos1[T*] fixed ind osin2[T*] fixed ind ocos2[T*]

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

	x	y	z	U_iso*/U_eq	Occ. (<1)
M1na	0.26775 (13)	−0.01365 (17)	0.07936 (18)	0.0202 (4)	0.510 (4)
M1ca	0.26775 (13)	−0.01365 (17)	0.07936 (18)	0.0202 (4)	0.154 (6)
M2ca	0.26963 (19)	0.02545 (17)	0.05004 (14)	0.0233 (5)	0.336 (7)
T1osi	0.49368 (3)	0.335066 (19)	−0.10656 (2)	0.00664 (9)	0.3575
T1msi	0.50306 (3)	0.318113 (18)	0.116245 (18)	0.00665 (9)	0.7438
T2osi	0.68597 (3)	0.109332 (18)	0.15800 (2)	0.00649 (10)	0.7467
T2msi	0.18102 (3)	0.379800 (18)	0.178557 (18)	0.00642 (10)	0.712
T1oal	0.49368 (3)	0.335066 (19)	−0.10656 (2)	0.00664 (9)	0.6425
T1mal	0.50306 (3)	0.318113 (18)	0.116245 (18)	0.00665 (9)	0.2562
T2oal	0.68597 (3)	0.109332 (18)	0.15800 (2)	0.00649 (10)	0.2533
T2mal	0.18102 (3)	0.379800 (18)	0.178557 (18)	0.00642 (10)	0.288
Oa1	0.49699 (10)	0.37113 (5)	0.01169 (5)	0.0142 (2)
Oa2	0.58167 (9)	−0.00654 (5)	0.13895 (5)	0.0095 (2)
Obo	0.81207 (9)	0.10585 (5)	0.09456 (6)	0.0130 (2)
Obm	0.31727 (10)	0.35300 (6)	0.12377 (6)	0.0176 (3)
Oco	0.48737 (10)	0.20658 (5)	−0.13874 (5)	0.0129 (2)
Ocm	0.51582 (9)	0.18991 (5)	0.10842 (5)	0.0136 (2)
Odo	0.29948 (9)	0.39226 (5)	0.30739 (5)	0.0120 (2)
Odm	0.68923 (10)	0.36738 (5)	0.21617 (5)	0.0141 (2)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
M1na	0.0067 (3)	0.0328 (6)	0.0158 (6)	−0.0014 (3)	0.0025 (3)	−0.0160 (4)
M1ca	0.0067 (3)	0.0328 (6)	0.0158 (6)	−0.0014 (3)	0.0025 (3)	−0.0160 (4)
M2ca	0.0125 (5)	0.0331 (12)	0.0168 (7)	0.0053 (5)	0.0014 (4)	−0.0106 (7)
T1osi	0.00689 (13)	0.00851 (13)	0.00426 (13)	−0.00095 (9)	0.00212 (10)	0.00110 (9)
T1msi	0.00713 (13)	0.00836 (12)	0.00405 (13)	0.00284 (8)	0.00214 (9)	0.00042 (8)
T2osi	0.00643 (13)	0.00551 (12)	0.00658 (13)	0.00046 (9)	0.00208 (10)	0.00001 (9)
T2msi	0.00649 (13)	0.00629 (12)	0.00591 (14)	0.00097 (8)	0.00214 (10)	0.00120 (9)
T1oal	0.00689 (13)	0.00851 (13)	0.00426 (13)	−0.00095 (9)	0.00212 (10)	0.00110 (9)
T1mal	0.00713 (13)	0.00836 (12)	0.00405 (13)	0.00284 (8)	0.00214 (9)	0.00042 (8)
T2oal	0.00643 (13)	0.00551 (12)	0.00658 (13)	0.00046 (9)	0.00208 (10)	0.00001 (9)
T2mal	0.00649 (13)	0.00629 (12)	0.00591 (14)	0.00097 (8)	0.00214 (10)	0.00120 (9)
Oa1	0.0205 (3)	0.0166 (3)	0.0078 (3)	0.0023 (2)	0.0081 (3)	0.0030 (2)
Oa2	0.0104 (3)	0.0089 (3)	0.0086 (3)	0.0007 (2)	0.0035 (2)	0.0019 (2)
Obo	0.0127 (3)	0.0123 (3)	0.0160 (3)	−0.0010 (2)	0.0082 (3)	−0.0001 (2)
Obm	0.0143 (3)	0.0178 (3)	0.0243 (4)	0.0010 (3)	0.0121 (3)	−0.0021 (3)
Oco	0.0124 (3)	0.0149 (3)	0.0109 (3)	−0.0011 (2)	0.0046 (2)	0.0013 (2)
Ocm	0.0125 (3)	0.0144 (3)	0.0103 (3)	0.0044 (2)	0.0022 (2)	−0.0022 (2)
Odo	0.0127 (3)	0.0119 (3)	0.0073 (3)	−0.0001 (2)	0.0005 (2)	0.0017 (2)
Odm	0.0124 (3)	0.0128 (3)	0.0102 (3)	0.0013 (2)	−0.0009 (3)	−0.0012 (2)

Bond lengths (Å) top

	Average	Minimum	Maximum
M1na—M1naⁱ	3.963 (4)	3.923 (4)	4.041 (4)
M1na—M1ca	0	0	0
M1na—M1caⁱ	3.963 (4)	3.923 (4)	4.041 (4)
M1na—M2ca	0.682 (9)	0.204 (10)	1.069 (10)
M1na—M2caⁱ	3.940 (4)	3.876 (5)	4.002 (5)
M1na—T1osiⁱⁱ	3.166 (5)	3.089 (6)	3.291 (6)
M1na—T1osiⁱⁱⁱ	3.255 (6)	3.147 (7)	3.324 (7)
M1na—T1msiⁱⁱ	3.294 (6)	3.115 (7)	3.628 (7)
M1na—T2osi	3.463 (4)	3.192 (5)	3.670 (5)
M1na—T2msi^iv	3.363 (4)	3.151 (5)	3.660 (5)
M1na—T1oalⁱⁱ	3.166 (5)	3.089 (6)	3.291 (6)
M1na—T1oalⁱⁱⁱ	3.255 (6)	3.147 (7)	3.324 (7)
M1na—T1malⁱⁱ	3.294 (6)	3.115 (7)	3.628 (7)
M1na—T1malⁱⁱⁱ	3.783 (6)	3.417 (7)	4.074 (7)
M1na—T2oal	3.463 (4)	3.192 (5)	3.670 (5)
M1na—T2mal^iv	3.363 (4)	3.151 (5)	3.660 (5)
M1na—Oa1ⁱⁱ	2.454 (5)	2.291 (6)	2.709 (6)
M1na—Oa2	2.345 (3)	2.302 (4)	2.405 (4)
M1na—Odo^v	2.419 (7)	2.403 (8)	2.465 (8)
M1ca—M1caⁱ	3.963 (4)	3.923 (4)	4.041 (4)
M1ca—M2ca	0.682 (9)	0.204 (10)	1.069 (10)
M1ca—M2caⁱ	3.940 (4)	3.876 (5)	4.002 (5)
M1ca—T1osiⁱⁱ	3.166 (5)	3.089 (6)	3.291 (6)
M1ca—T1osiⁱⁱⁱ	3.255 (6)	3.147 (7)	3.324 (7)
M1ca—T1msiⁱⁱ	3.294 (6)	3.115 (7)	3.628 (7)
M1ca—T2osi	3.463 (4)	3.192 (5)	3.670 (5)
M1ca—T2msi^iv	3.363 (4)	3.151 (5)	3.660 (5)
M1ca—T1oalⁱⁱ	3.166 (5)	3.089 (6)	3.291 (6)
M1ca—T1oalⁱⁱⁱ	3.255 (6)	3.147 (7)	3.324 (7)
M1ca—T1malⁱⁱ	3.294 (6)	3.115 (7)	3.628 (7)
M1ca—T1malⁱⁱⁱ	3.783 (6)	3.417 (7)	4.074 (7)
M1ca—T2oal	3.463 (4)	3.192 (5)	3.670 (5)
M1ca—T2mal^iv	3.363 (4)	3.151 (5)	3.660 (5)
M1ca—T2mal^v	3.615 (7)	3.562 (8)	3.705 (8)
M1ca—Oa1ⁱⁱ	2.454 (5)	2.291 (6)	2.709 (6)
M1ca—Oa2	2.345 (3)	2.302 (4)	2.405 (4)
M1ca—Odo^v	2.419 (7)	2.403 (8)	2.465 (8)
M2ca—M2caⁱ	4.028 (5)	3.945 (6)	4.197 (6)
M2ca—T1osiⁱⁱ	3.316 (4)	3.268 (5)	3.365 (5)
M2ca—T1osiⁱⁱⁱ	3.129 (4)	3.047 (6)	3.198 (6)
M2ca—T1msiⁱⁱⁱ	3.235 (4)	3.160 (5)	3.320 (5)
M2ca—T2osi	3.212 (3)	3.142 (5)	3.344 (5)
M2ca—T1oalⁱⁱ	3.316 (4)	3.268 (5)	3.365 (5)
M2ca—T1oalⁱⁱⁱ	3.129 (4)	3.047 (6)	3.198 (6)
M2ca—T1malⁱⁱⁱ	3.235 (4)	3.160 (5)	3.320 (5)
M2ca—T2oal	3.212 (3)	3.142 (5)	3.344 (5)
M2ca—T2oal^vi	3.498 (5)	3.440 (6)	3.560 (6)
M2ca—T2mal^iv	3.613 (4)	3.436 (5)	3.766 (5)
M2ca—Oa1ⁱⁱⁱ	2.387 (4)	2.314 (5)	2.457 (5)
M2ca—Oa2	2.342 (3)	2.278 (5)	2.446 (5)
M2ca—Obo^vi	2.431 (4)	2.390 (6)	2.486 (6)
T1osi—T1oal	0	0	0
T1osi—Oa1	1.7070 (17)	1.6437 (17)	1.7514 (17)
T1osi—Obo^vii	1.6981 (17)	1.6410 (17)	1.7381 (17)
T1osi—Oco	1.6812 (15)	1.6156 (15)	1.7270 (15)
T1osi—Odo^viii	1.7122 (13)	1.6483 (14)	1.7593 (14)
T1msi—T1mal	0	0	0
T1msi—Oa1	1.6586 (17)	1.6149 (17)	1.7241 (17)
T1msi—Obm	1.6307 (19)	1.601 (2)	1.690 (2)
T1msi—Ocm	1.6525 (15)	1.6107 (15)	1.7170 (15)
T1msi—Odm	1.6503 (13)	1.6131 (13)	1.7048 (13)
T2osi—T2oal	0	0	0
T2osi—Oa2	1.6681 (14)	1.6416 (14)	1.7126 (14)
T2osi—Obo	1.6459 (19)	1.616 (2)	1.693 (2)
T2osi—Ocm	1.6476 (15)	1.6166 (15)	1.6883 (15)
T2osi—Odm^ix	1.6296 (13)	1.6024 (13)	1.6693 (13)
T2msi—T2mal	0	0	0
T2msi—Oa2^x	1.6710 (13)	1.6379 (14)	1.7246 (14)
T2msi—Obm	1.644 (2)	1.605 (2)	1.705 (2)
T2msi—Ocoⁱⁱⁱ	1.6430 (15)	1.5998 (16)	1.7085 (16)
T2msi—Odo	1.6486 (13)	1.6147 (13)	1.7096 (13)
T1oal—T2malⁱⁱⁱ	3.0203 (7)	2.9880 (8)	3.0472 (8)
T1oal—Oa1	1.7070 (17)	1.6437 (17)	1.7514 (17)
T1oal—Obo^vii	1.6981 (17)	1.6410 (17)	1.7381 (17)
T1oal—Oco	1.6812 (15)	1.6156 (15)	1.7270 (15)
T1oal—Odo^viii	1.7122 (13)	1.6483 (14)	1.7593 (14)
T1mal—T2oal	3.0240 (7)	2.9907 (7)	3.0465 (7)
T1mal—Oa1	1.6586 (17)	1.6149 (17)	1.7241 (17)
T1mal—Obm	1.6307 (19)	1.601 (2)	1.690 (2)
T1mal—Ocm	1.6525 (15)	1.6107 (15)	1.7170 (15)
T1mal—Odm	1.6503 (13)	1.6131 (13)	1.7048 (13)
T2oal—T2mal^iv	2.9863 (7)	2.9719 (7)	3.0005 (7)
T2oal—Oa2	1.6681 (14)	1.6416 (14)	1.7126 (14)
T2oal—Obo	1.6459 (19)	1.616 (2)	1.693 (2)
T2oal—Ocm	1.6476 (15)	1.6166 (15)	1.6883 (15)
T2oal—Odm^ix	1.6296 (13)	1.6024 (13)	1.6693 (13)
T2mal—Oa2^x	1.6710 (13)	1.6379 (14)	1.7246 (14)
T2mal—Obm	1.644 (2)	1.605 (2)	1.705 (2)
T2mal—Ocoⁱⁱⁱ	1.6430 (15)	1.5998 (16)	1.7085 (16)
T2mal—Odo	1.6486 (13)	1.6147 (13)	1.7096 (13)

Symmetry codes: (i) −x₁, −x₂, −x₃, −x₄; (ii) x₁−1/2, x₂−1/2, x₃, x₄+1/2; (iii) −x₁+1/2, −x₂+1/2, −x₃, −x₄+1/2; (iv) x₁+1/2, x₂−1/2, x₃, x₄+1/2; (v) −x₁+1/2, −x₂+1/2, −x₃+1/2, −x₄; (vi) −x₁+1, −x₂, −x₃, −x₄; (vii) −x₁+3/2, −x₂+1/2, −x₃, −x₄+1/2; (viii) x₁, x₂, x₃−1/2, x₄+1/2; (ix) −x₁+3/2, −x₂+1/2, −x₃+1/2, −x₄; (x) x₁−1/2, x₂+1/2, x₃, x₄+1/2.

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