Crystal structure, electronic structure, and optical properties of the novel Li4CdGe2S7, a wide-bandgap quaternary sulfide with a polar structure derived from lonsdaleite

Craig, A.J.; Shin, S.H.; Cho, J.B.; Balijapelly, S.; Kelly, J.C.; Stoyko, S.S.; Choudhury, A.; Jang, J.I.; Aitken, J.A.

doi:10.1107/S2053229622008014

Crystal structure, electronic structure, and optical properties of the novel Li₄CdGe₂S₇, a wide-bandgap quaternary sulfide with a polar structure derived from lonsdaleite

A. J. Craig, S. H. Shin, J. B. Cho, S. Balijapelly, J. C. Kelly, S. S. Stoyko, A. Choudhury, J. I. Jang and J. A. Aitken

The novel quaternary thiogermanate Li₄CdGe₂S₇ (tetralithium cadmium digermanium heptasulfide) was discovered from a solid-state reaction at 750 °C. Single-crystal X-ray diffraction data were collected and used to solve and refine the structure. Li₄CdGe₂S₇ is a member of the small, but growing, class of I₄–II–IV₂–VI₇ diamond-like materials. The compound adopts the Cu₅Si₂S₇ structure type, which is a derivative of lonsdaleite. Crystallizing in the polar space group Cc, Li₄CdGe₂S₇ contains 14 crystallographically unique ions, all residing on general positions. Like all diamond-like structures, the compound is built of corner-sharing tetrahedral units that create a relatively dense three-dimensional assembly. The title compound is the major phase of the reaction product, as evidenced by powder X-ray diffraction and optical diffuse reflectance spectroscopy. While the compound exhibits a second-harmonic generation (SHG) response comparable to that of the AgGaS₂ (AGS) reference material in the IR region, its laser-induced damage threshold (LIDT) is over an order of magnitude greater than AGS for λ = 1.064 µm and τ = 30 ps. Bond valence sums, global instability index, minimum bounding ellipsoid (MBE) analysis, and electronic structure calculations using density functional theory (DFT) were used to further evaluate the crystal structure and electronic structure of the compound and provide a comparison with the analogous I₂–II–IV–VI₄ diamond-like compound Li₂CdGeS₄. Li₄CdGe₂S₇ appears to be a better IR nonlinear optical (NLO) candidate than Li₂CdGeS₄ and one of the most promising contenders to date. The exceptional LIDT is likely due, at least in part, to the wider optical bandgap of ∼3.6 eV.

Keywords: crystal structure; thiogermanate; diamond-like; wide bandgap; lonsdaleite; quaternary sulfide.

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Supporting information

	Crystallographic Information File (CIF) https://doi.org/10.1107/S2053229622008014/wp3029sup1.cif Contains datablocks I, global
	Structure factor file (CIF format) https://doi.org/10.1107/S2053229622008014/wp3029Isup2.hkl Contains datablock I

CCDC reference: 2195746

Computing details top

Data collection: APEX2 (Bruker, 2010); cell refinement: SMART (Bruker, 2010); data reduction: SMART (Bruker, 2010); program(s) used to solve structure: SHELXT (Sheldrick, 2015a); program(s) used to refine structure: SHELXL2018 (Sheldrick, 2015b); molecular graphics: CrystalMaker (Palmer, 2019); software used to prepare material for publication: SHELXL2018 (Sheldrick, 2015b).

Tetralithium cadmium digermanium heptasulfide top

Crystal data top

Li₄CdGe₂S₇	F(000) = 944
M_r = 509.76	D_x = 2.926 Mg m⁻³
Monoclinic, Cc	Mo Kα radiation, λ = 0.71073 Å
a = 16.8354 (10) Å	Cell parameters from 7524 reflections
b = 6.7870 (4) Å	θ = 2.4–33.0°
c = 10.1499 (6) Å	µ = 8.18 mm⁻¹
β = 93.710 (3)°	T = 293 K
V = 1157.32 (12) Å³	Polyhedra, colourless
Z = 4	0.21 × 0.12 × 0.11 mm

Data collection top

Bruker SMART APEXII diffractometer	2612 reflections with I > 2σ(I)
φ and ω scan	R_int = 0.017
Absorption correction: multi-scan (SADABS; Sheldrick, 2002)	θ_max = 27.5°, θ_min = 2.4°
T_min = 0.549, T_max = 0.747	h = −21→21
7415 measured reflections	k = −8→8
2634 independent reflections	l = −13→13

Refinement top

Refinement on F²	w = 1/[σ²(F_o²) + (0.0097P)² + 0.0293P] where P = (F_o² + 2F_c²)/3
Least-squares matrix: full	(Δ/σ)_max = 0.001
R[F² > 2σ(F²)] = 0.010	Δρ_max = 0.27 e Å⁻³
wR(F²) = 0.024	Δρ_min = −0.21 e Å⁻³
S = 1.08	Extinction correction: SHELXL2018 (Sheldrick, 2015b), Fc^*=kFc[1+0.001xFc²λ³/sin(2θ)]^-1/4
2634 reflections	Extinction coefficient: 0.00183 (7)
129 parameters	Absolute structure: Refined as an inversion twin.
2 restraints	Absolute structure parameter: 0.001 (5)

Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Refinement. Refined as a 2-component inversion twin.

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

	x	y	z	U_iso*/U_eq
Li1	0.3309 (6)	0.1842 (15)	0.5012 (10)	0.0224 (18)
Li2	0.1207 (8)	0.3276 (14)	0.4190 (13)	0.025 (2)
Li3	0.9764 (7)	0.3297 (11)	0.7180 (11)	0.0199 (19)
Li4	0.7674 (6)	0.1619 (14)	0.6423 (10)	0.025 (2)
Cd	0.54849 (2)	0.36329 (3)	0.56327 (4)	0.01770 (6)
Ge1	0.40538 (2)	0.33494 (7)	0.84280 (2)	0.01042 (11)
Ge2	0.19465 (2)	0.17688 (7)	0.77467 (2)	0.01045 (10)
S1	0.50089 (4)	0.29460 (12)	0.00091 (8)	0.01425 (15)
S2	0.43895 (5)	0.16838 (12)	0.66829 (7)	0.01398 (16)
S3	0.37399 (5)	0.35832 (12)	0.31017 (8)	0.01570 (17)
S4	0.30151 (5)	0.16992 (11)	0.92654 (7)	0.01258 (16)
S5	0.22120 (5)	0.33369 (13)	0.59790 (8)	0.01651 (18)
S6	0.66610 (5)	0.36507 (11)	0.73450 (8)	0.01491 (16)
S7	0.09614 (4)	0.32632 (13)	0.86708 (8)	0.01446 (16)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
Li1	0.022 (4)	0.025 (4)	0.021 (3)	−0.001 (3)	0.006 (3)	−0.001 (3)
Li2	0.028 (4)	0.021 (4)	0.025 (4)	−0.002 (3)	0.000 (3)	0.001 (3)
Li3	0.021 (3)	0.023 (4)	0.016 (4)	0.000 (3)	0.004 (3)	0.002 (3)
Li4	0.026 (4)	0.025 (4)	0.024 (4)	0.003 (3)	−0.003 (3)	−0.001 (3)
Cd	0.01709 (9)	0.01891 (11)	0.01720 (9)	0.00053 (13)	0.00176 (6)	0.00054 (13)
Ge1	0.00954 (19)	0.0111 (2)	0.01056 (18)	−0.00010 (12)	0.00062 (14)	−0.00022 (12)
Ge2	0.00921 (18)	0.01191 (19)	0.01018 (18)	−0.00051 (13)	0.00025 (13)	−0.00008 (13)
S1	0.0124 (3)	0.0164 (4)	0.0135 (3)	−0.0005 (3)	−0.0020 (2)	0.0005 (3)
S2	0.0160 (3)	0.0138 (4)	0.0124 (3)	−0.0002 (3)	0.0032 (3)	−0.0021 (3)
S3	0.0179 (4)	0.0117 (4)	0.0175 (4)	−0.0012 (3)	0.0018 (3)	−0.0008 (3)
S4	0.0098 (3)	0.0163 (4)	0.0115 (3)	−0.0024 (3)	−0.0002 (3)	0.0023 (3)
S5	0.0173 (4)	0.0203 (4)	0.0120 (4)	−0.0021 (3)	0.0011 (3)	0.0036 (3)
S6	0.0150 (4)	0.0124 (4)	0.0171 (3)	−0.0010 (3)	−0.0013 (3)	−0.0017 (3)
S7	0.0130 (4)	0.0146 (4)	0.0161 (3)	0.0020 (3)	0.0035 (3)	−0.0005 (3)

Geometric parameters (Å, º) top

Li1—S5	2.374 (10)	Li4—S6	2.428 (10)
Li1—S2	2.408 (10)	Li4—S4^ix	2.567 (11)
Li1—S3	2.421 (10)	Cd—S1^x	2.5235 (8)
Li1—S4ⁱ	2.559 (10)	Cd—S7^ix	2.5441 (9)
Li2—S1ⁱⁱ	2.380 (13)	Cd—S6	2.5487 (10)
Li2—S5	2.401 (13)	Cd—S2	2.5576 (9)
Li2—S7ⁱⁱⁱ	2.437 (10)	Ge1—S3^x	2.1680 (8)
Li2—S6^iv	2.447 (12)	Ge1—S2	2.2055 (9)
Li3—S3^v	2.385 (10)	Ge1—S1^xi	2.2141 (8)
Li3—S1^v	2.420 (12)	Ge1—S4	2.2862 (8)
Li3—S2^vi	2.428 (7)	Ge2—S5	2.1577 (8)
Li3—S7^vii	2.440 (12)	Ge2—S6^xii	2.2024 (10)
Li4—S5^viii	2.393 (9)	Ge2—S7	2.2045 (8)
Li4—S3^v	2.397 (10)	Ge2—S4	2.2926 (9)

S5—Li1—S2	107.5 (4)	Ge1^xiii—S1—Li2^ix	112.5 (3)
S5—Li1—S3	113.8 (4)	Ge1^xiii—S1—Li3^iv	123.0 (3)
S2—Li1—S3	109.5 (4)	Li2^ix—S1—Li3^iv	113.2 (4)
S5—Li1—S4ⁱ	112.5 (4)	Ge1^xiii—S1—Cdⁱⁱⁱ	105.78 (3)
S2—Li1—S4ⁱ	106.8 (4)	Li2^ix—S1—Cdⁱⁱⁱ	98.4 (3)
S3—Li1—S4ⁱ	106.5 (4)	Li3^iv—S1—Cdⁱⁱⁱ	99.34 (19)
S1ⁱⁱ—Li2—S5	108.3 (5)	Ge1—S2—Li1	108.8 (2)
S1ⁱⁱ—Li2—S7ⁱⁱⁱ	106.0 (5)	Ge1—S2—Li3^xii	113.3 (3)
S5—Li2—S7ⁱⁱⁱ	104.4 (4)	Li1—S2—Li3^xii	111.3 (4)
S1ⁱⁱ—Li2—S6^iv	113.2 (4)	Ge1—S2—Cd	107.38 (3)
S5—Li2—S6^iv	110.4 (5)	Li1—S2—Cd	102.5 (2)
S7ⁱⁱⁱ—Li2—S6^iv	114.0 (5)	Li3^xii—S2—Cd	113.0 (3)
S3^v—Li3—S1^v	109.9 (4)	Ge1ⁱⁱⁱ—S3—Li3^iv	113.5 (2)
S3^v—Li3—S2^vi	113.8 (5)	Ge1ⁱⁱⁱ—S3—Li4^iv	109.1 (2)
S1^v—Li3—S2^vi	101.4 (3)	Li3^iv—S3—Li4^iv	102.6 (4)
S3^v—Li3—S7^vii	110.0 (4)	Ge1ⁱⁱⁱ—S3—Li1	115.4 (2)
S1^v—Li3—S7^vii	112.3 (5)	Li3^iv—S3—Li1	108.3 (3)
S2^vi—Li3—S7^vii	109.3 (4)	Li4^iv—S3—Li1	107.0 (4)
S5^viii—Li4—S3^v	107.5 (4)	Ge1—S4—Ge2	109.01 (3)
S5^viii—Li4—S6	111.9 (4)	Ge1—S4—Li1^xiv	115.6 (2)
S3^v—Li4—S6	105.7 (4)	Ge2—S4—Li1^xiv	110.3 (2)
S5^viii—Li4—S4^ix	110.0 (4)	Ge1—S4—Li4ⁱⁱ	108.5 (2)
S3^v—Li4—S4^ix	115.7 (4)	Ge2—S4—Li4ⁱⁱ	110.8 (2)
S6—Li4—S4^ix	106.1 (3)	Li1^xiv—S4—Li4ⁱⁱ	102.4 (4)
S1^x—Cd—S7^ix	112.35 (3)	Ge2—S5—Li1	110.0 (2)
S1^x—Cd—S6	112.75 (3)	Ge2—S5—Li4^xv	112.6 (3)
S7^ix—Cd—S6	105.41 (3)	Li1—S5—Li4^xv	102.9 (4)
S1^x—Cd—S2	110.77 (3)	Ge2—S5—Li2	116.5 (3)
S7^ix—Cd—S2	109.70 (2)	Li1—S5—Li2	102.1 (4)
S6—Cd—S2	105.52 (3)	Li4^xv—S5—Li2	111.3 (3)
S3^x—Ge1—S2	116.24 (3)	Ge2^vi—S6—Li4	117.8 (2)
S3^x—Ge1—S1^xi	112.82 (3)	Ge2^vi—S6—Li2^v	116.6 (2)
S2—Ge1—S1^xi	107.87 (3)	Li4—S6—Li2^v	104.7 (3)
S3^x—Ge1—S4	110.03 (3)	Ge2^vi—S6—Cd	106.34 (3)
S2—Ge1—S4	106.82 (3)	Li4—S6—Cd	105.6 (2)
S1^xi—Ge1—S4	101.95 (3)	Li2^v—S6—Cd	104.6 (3)
S5—Ge2—S6^xii	111.99 (3)	Ge2—S7—Li2^x	114.4 (3)
S5—Ge2—S7	109.20 (3)	Ge2—S7—Li3^xvi	110.8 (3)
S6^xii—Ge2—S7	111.08 (3)	Li2^x—S7—Li3^xvi	104.3 (4)
S5—Ge2—S4	111.93 (3)	Ge2—S7—Cdⁱⁱ	112.60 (3)
S6^xii—Ge2—S4	104.90 (3)	Li2^x—S7—Cdⁱⁱ	112.1 (3)
S7—Ge2—S4	107.62 (3)	Li3^xvi—S7—Cdⁱⁱ	101.6 (2)

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

Known I₄–II–IV₂–VI₇ diamond-like compounds with structures derived from cubic diamond (C2) or lonsdaleite (Cc) with the corresponding SHG responses and optical bandgaps where applicable top

Compound	Space Group	SHG response*	E_g (eV)	Reference
Li₄MgGe₂S₇	Cc	0.7 × AGS (λ = 2.09 µm)	4.12	Abudurusuli et al. (2021)
Li₄MnGe₂S₇	Cc			Kaib et al. (2013)
Li₄MnSn₂Se₇	Cc			Kaib et al. (2013)
Li₄CdGe₂S₇	Cc	~ 1 × AGS (λ = 1.8 µm)	3.6	This work
Li₄CdSn₂S₇	Cc	χ⁽²⁾ = 35.0±3.5 pm V^-1	2.59	Zhang, Stoyko et al. (2020)
Li₄HgGe₂S₇	Cc	1.5 × AGS (λ = 2.09 µm)	2.75	Wu et al. (2017)
Li₄HgSn₂S₇	Cc			Aitken (2001)
Li₄HgSn₂Se₇	Cc	3.6 × AGS (λ = 2.09 µm)	2.1	Guo et al. (2019)
Ag₄CdGe₂S₇	Cc			Gulay et al. (2002)
Ag₄HgGe₂S₇	Cc			Gulay et al. (2002)
Cu₄MnGe₂S₇	Cc	χ⁽²⁾ = 2.33 × 0.86 pm V^-1	1.98	Glenn et al. (2021)
Cu₄FeGe₂S₇	C2			Craig et al. (2020)
Cu₄CoGe₂S₇	C2			Craig et al. (2020)
Cu₄NiSi₂S₇	C2			Schäfer et al. (1980)
Cu₄NiGe₂S₇	C2			Schäfer et al. (1980)
Cu₄ZnGe₂Se₇	C2	weak	0.91	Sinagra et al. (2021)

* χ⁽²⁾ values are assessed at the static limit, where the sample and the reference are phase matching and multiphoton absorption is not a factor.

Extended connectivity table for Li₄CdGe₂S₇ used to predict structural distortions in accordance with Pauling's second rule top

Anions

*CMP = compensated

Bond distances in Li₄CdGe₂S₇ and Li₂CdGeS₄ top

Li₄CdGe₂S₇	Bond distance	Li₂CdGeS₄	Bond distance
Li1—S5	2.374 (10)	Li—S3	2.402 (9)
Li1—S2	2.408 (10)	Li—S1	2.41 (2)
Li1—S3	2.421 (10)	Li—S1	2.424 (7)
Li1—S4	2.559 (10)	Li—S2	2.446 (6)
Avg Li1—S	2.44 (2)	Avg Li—S	2.42 (2)

Li2—S1	2.380 (13)
Li2—S5	2.401 (13)
Li2—S7	2.437 (10)
Li2—S6	2.447 (12)
Avg Li2—S	2.42 (2)

Li3—S3	2.385 (10)
Li3—S1	2.420 (12)
Li3—S2	2.428 (7)
Li3—S7	2.440 (12)
Avg Li3—S	2.42 (2)

Li4—S5	2.392 (9)
Li4—S3	2.397 (10)
Li4—S6	2.428 (10)
Li4—S4	2.567 (11)
Avg Li4—S	2.45 (2)
Avg Li—S	2.43 (4)

Cd—S1	2.5235 (8)	Cd—S3	2.5204 (10)
Cd—S7	2.5440 (9)	Cd—S1	2.5493 (12)
Cd—S6	2.5487 (10)	Cd—S2	2.5568 (6)
Cd—S2	2.5575 (9)	Cd—S2	2.5568 (6)
Avg Cd—S	2.543 (2)	Avg Cd—S	2.546 (2)

Ge1—S3	2.1680 (8)	Ge—S3	2.2075 (14)
Ge1—S2	2.2055 (9)	Ge—S1	2.2099 (9)
Ge1—S1	2.2141 (8)	Ge—S2	2.2152 (6)
Ge1—S4	2.2862 (8)	Ge—S2	2.2152 (6)
Avg Ge1—S	2.218 (2)	Avg Ge—S	2.212 (2)

Ge2—S5	2.1577 (8)
Ge2—S6	2.2024 (10)
Ge2—S7	2.2045 (8)
Ge2—S4	2.2926 (9)
Avg Ge2—S	2.214 (2)
Avg Ge—S	2.216 (2)

Bond angles (°) for Li₄CdGe₂S₇ and Li₂CdGeS₄ top

Li₄CdGe₂S₇	Bond angle	Li₂CdGeS₄	Bond angle
S5—Li1—S2	107.5 (4)	S3—Li—S2	110.3 (4)
S5—Li1—S3	113.8 (4)	S3—Li—S1	107.9 (5)
S2—Li1—S3	109.5 (4)	S2—Li—S1	109.9 (5)
S5—Li1—S4	112.5 (4)	S3—Li—S2	106.3 (5)
S2—Li1—S4	106.8 (4)	S2—Li—S2	108.9 (5)
S3—Li1—S4	106.5 (4)	S1—Li—S2	113.4 (5)
Avg S—Li1—S	109 (1)	Avg S—Li—S	109 (1)

S1—Li2—S5	108.3 (5)
S1—Li2—S7	106.0 (5)
S5—Li2—S7	104.4 (4)
S1—Li2—S6	113.3 (4)
S5—Li2—S6	110.4 (5)
S7—Li2—S6	114.0 (5)
Avg S—Li1—S	109 (1)

S3—Li3—S1	109.9 (4)
S3—Li3—S2	113.8 (5)
S1—Li3—S2	101.4 (3)
S3—Li3—S7	110.0 (4)
S1—Li3—S7	112.3 (5)
S2—Li3—S7	109.3 (4)
Avg S-Li1-S	109 (1)

S5—Li4—S3	107.5 (4)
S5—Li4—S6	111.9 (4)
S3—Li4—S6	105.7 (4)
S5—Li4—S4	110.0 (4)
S3—Li4—S4	115.7 (4)
S6—Li4—S4	106.1 (3)
Avg S—Li1—S	109 (1)
Avg S—Li—S	109 (2)

S1—Cd—S7	112.35 (3)	S3—Cd—S1	110.32 (4)
S1—Cd—S6	112.75 (3)	S3—Cd—S2	110.10 (2)
S7—Cd—S6	105.41 (3)	S1—Cd—S2	108.14 (2)
S1—Cd—S2	110.77 (3)	S3—Cd—S2	110.10 (2)
S7—Cd—S2	109.69 (2)	S1—Cd—S2	108.14 (2)
S6—Cd—S2	105.52 (3)	S2—Cd—S2	110.01 (3)
Avg S—Cd—S	109.42 (7)	Avg S—Cd—S	109.47 (6)

S3—Ge1—S2	116.23 (3)
S3—Ge1—S1	112.82 (3)
S2—Ge1—S1	107.87 (3)
S3—Ge1—S4	110.03 (3)
S2—Ge1—S4	106.82 (3)
S1—Ge1—S4	101.95 (3)
Avg S—Ge1—S	109.29 (7)

S5—Ge2—S6	111.99 (3)	S3—Ge—S1	110.69 (5)
S5—Ge2—S7	109.20 (3)	S3—Ge—S2	108.64 (3)
S6—Ge2—S7	111.08 (3)	S1—Ge—S2	111.15 (3)
S5—Ge2—S4	111.93 (3)	S3—Ge—S2	108.64 (3)
S6—Ge2—S4	104.90 (3)	S1—Ge—S2	111.15 (3)
S7—Ge2—S4	107.62 (3)	S2—Ge—S2	106.43 (4)
Avg S—Ge2—S	109.5 (5)	Avg S—Ge—S	109.45 (9)
Avg S—Ge—S	109.4 (5)

PIEFACE ellipsoid data (Å) for Li₄CdGe₂S₇ (top) and Li₂CdGeS₄ (bottom)* top

Atom	R1	R2	R3	<R>	σ(R)	S	D	Coordination number
Li1	2.533	2.433	2.350	2.439	0.075	0.005	0.094	4
Li2	2.538	2.375	2.326	2.413	0.091	0.044	0.088	4
Li3	2.529	2.438	2.278	2.415	0.104	-0.029	0.079	4
Li4	2.596	2.444	2.290	2.444	0.125	-0.005	0.049	4
Cd	2.616	2.552	2.456	2.541	0.066	-0.013	0.088	4
Ge1	2.285	2.215	2.139	2.213	0.060	-0.004	0.145	4
Ge2	2.283	2.201	2.155	2.213	0.053	0.015	0.076	4
S1	2.524	2.338	2.227	2.363	0.122	0.026	0.317	4
S2	2.556	2.353	2.279	2.396	0.117	0.048	0.141	4
S3	2.418	2.332	2.265	2.338	0.062	0.006	0.169	4
S4	2.552	2.452	2.264	2.423	0.119	-0.037	0.147	4
S5	2.434	2.314	2.224	2.324	0.086	0.010	0.192	4
S6	2.500	2.363	2.332	2.399	0.073	0.042	0.221	4
S7	2.532	2.366	2.301	2.400	0.097	0.038	0.189	4

Li	2.493	2.424	2.338	2.418	0.063	-0.008	0.038	4
Cd	2.565	2.553	2.519	2.546	0.020	-0.008	0.032	4
Ge	2.256	2.205	2.173	2.211	0.034	0.008	0.044	4
S1	2.476	2.381	2.325	2.394	0.062	0.015	0.219	4
S2	2.500	2.382	2.326	2.403	0.072	0.024	0.162	4
S3	2.413	2.390	2.317	2.373	0.041	-0.021	0.233	4

*R1, R2, and R3 are the radii of the ellipsoids, R is the average ellipsoid radius, σ(R) is the polyhedral distortion, S is the shape parameter, and D is the center displacement, which shows the atom displacement relative to the center of the ellipsoid.

Calculated BVSs and G values for Li₄CdGe₂S₇ and Li₂CdGeS₄ top

Compound	Li⁺ (avg)	Cd²⁺	Ge⁴⁺ (avg)	S^2- (avg)	G
Li₄CdGe₂S₇¹	1.07	1.96	4.04	2.05	0.08
Li₄CdGe₂S₇*	1.07	2.10	4.04	2.07	0.09
Li₂CdGeS₄¹	1.10	1.95	4.06	2.06	0.07
Li₂CdGeS₄*	1.10	2.08	4.06	2.09	0.09

1 Cd—S r₀ value from Brown & Altermatt (1985). * Cd—S r₀ value from Palenik (2006).

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