Supporting information
Crystallographic Information File (CIF) https://doi.org/10.1107/S160053680705413X/wm2155sup1.cif | |
Structure factor file (CIF format) https://doi.org/10.1107/S160053680705413X/wm2155Isup2.hkl |
YMgGa single crystals were obtained by heating appropriate amounts of the elements (Mg 99.95%, Y 99.9%, Ga 99.998%) inside an argon filled sealed tantalum tube in a high-frequency induction furnace at 1373 K. The sample was then heat-treated at 573 K for seven d to improve crystal growth. Large single crystals were removed from the surface of the sample and cut into smaller pieces. Bulk samples were characterized by X-ray powder diffraction.
The highest peak in the final Fourier map is located is 1.05 Å, and the deepest hole 1.51 Å from Y1. The measured crystal was an inversion twin with an approximate twin ratio of 1:1 (Flack parameter 0.43 (5).
Data collection: SMART (Bruker, 2001); cell refinement: SAINT (Bruker, 2001); data reduction: SAINT; program(s) used to solve structure: SHELXTL (Sheldrick, 2001); program(s) used to refine structure: SHELXTL; molecular graphics: DIAMOND (Crystal Impact, 2006); software used to prepare material for publication: SHELXTL and publCIF (Westrip, 2007).
YMgGa | Dx = 4.505 Mg m−3 |
Mr = 182.94 | Ag Kα radiation, λ = 0.56085 Å |
Hexagonal, P62m | Cell parameters from 801 reflections |
Hall symbol: P -6 -2 | θ = 3.6–22.4° |
a = 7.2689 (10) Å | µ = 16.83 mm−1 |
c = 4.4205 (9) Å | T = 293 K |
V = 202.27 (6) Å3 | Block, grey |
Z = 3 | 0.09 × 0.07 × 0.05 mm |
F(000) = 246 |
Bruker Apex1 diffractometer | 333 independent reflections |
Radiation source: fine-focus sealed tube | 324 reflections with I > 2σ(I) |
Graphite monochromator | Rint = 0.087 |
Detector resolution: 7.31 pixels mm-1 | θmax = 26.3°, θmin = 2.6° |
ω–scans | h = −11→11 |
Absorption correction: multi-scan (SADABS; Sheldrick, 2001) | k = −11→11 |
Tmin = 0.276, Tmax = 0.431 | l = −6→6 |
4365 measured reflections |
Refinement on F2 | Primary atom site location: structure-invariant direct methods |
Least-squares matrix: full | Secondary atom site location: difference Fourier map |
R[F2 > 2σ(F2)] = 0.035 | w = 1/[σ2(Fo2) + (0.0466P)2 + 0.5229P] where P = (Fo2 + 2Fc2)/3 |
wR(F2) = 0.088 | (Δ/σ)max = 0.001 |
S = 1.15 | Δρmax = 1.65 e Å−3 |
333 reflections | Δρmin = −1.78 e Å−3 |
13 parameters | Absolute structure: Flack (1983), 136 Friedel pairs |
0 restraints | Absolute structure parameter: 0.43 (5) |
YMgGa | Z = 3 |
Mr = 182.94 | Ag Kα radiation, λ = 0.56085 Å |
Hexagonal, P62m | µ = 16.83 mm−1 |
a = 7.2689 (10) Å | T = 293 K |
c = 4.4205 (9) Å | 0.09 × 0.07 × 0.05 mm |
V = 202.27 (6) Å3 |
Bruker Apex1 diffractometer | 333 independent reflections |
Absorption correction: multi-scan (SADABS; Sheldrick, 2001) | 324 reflections with I > 2σ(I) |
Tmin = 0.276, Tmax = 0.431 | Rint = 0.087 |
4365 measured reflections |
R[F2 > 2σ(F2)] = 0.035 | 0 restraints |
wR(F2) = 0.088 | Δρmax = 1.65 e Å−3 |
S = 1.15 | Δρmin = −1.78 e Å−3 |
333 reflections | Absolute structure: Flack (1983), 136 Friedel pairs |
13 parameters | Absolute structure parameter: 0.43 (5) |
Geometry. All e.s.d.'s (except the e.s.d. in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell e.s.d.'s are taken into account individually in the estimation of e.s.d.'s in distances, angles and torsion angles; correlations between e.s.d.'s in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell e.s.d.'s is used for estimating e.s.d.'s involving l.s. planes. |
Refinement. Refinement of F2 against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F2, conventional R-factors R are based on F, with F set to zero for negative F2. The threshold expression of F2 > σ(F2) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F2 are statistically about twice as large as those based on F, and R-factors based on ALL data will be even larger. |
x | y | z | Uiso*/Ueq | ||
Y1 | 0.57308 (15) | 1.0000 | 0.5000 | 0.0116 (2) | |
Ga1 | 0.3333 | 0.6667 | 1.0000 | 0.0104 (3) | |
Ga2 | 0.0000 | 1.0000 | 0.5000 | 0.0125 (4) | |
Mg1 | 0.2443 (5) | 1.0000 | 1.0000 | 0.0109 (7) |
U11 | U22 | U33 | U12 | U13 | U23 | |
Y1 | 0.0118 (3) | 0.0103 (4) | 0.0121 (4) | 0.0052 (2) | 0.000 | 0.000 |
Ga1 | 0.0101 (4) | 0.0101 (4) | 0.0112 (6) | 0.0050 (2) | 0.000 | 0.000 |
Ga2 | 0.0138 (6) | 0.0138 (6) | 0.0100 (9) | 0.0069 (3) | 0.000 | 0.000 |
Mg1 | 0.0088 (14) | 0.0102 (19) | 0.0141 (17) | 0.0051 (9) | 0.000 | 0.000 |
Y1—Ga1i | 3.0936 (4) | Ga1—Y1xii | 3.0936 (4) |
Y1—Ga1ii | 3.0936 (4) | Ga2—Mg1xiii | 2.835 (3) |
Y1—Ga1iii | 3.0936 (4) | Ga2—Mg1 | 2.835 (3) |
Y1—Ga1 | 3.0936 (4) | Ga2—Mg1xiv | 2.835 (3) |
Y1—Ga2iv | 3.1033 (12) | Ga2—Mg1xv | 2.835 (3) |
Y1—Mg1ii | 3.255 (3) | Ga2—Mg1ii | 2.835 (3) |
Y1—Mg1 | 3.255 (3) | Ga2—Mg1xvi | 2.835 (3) |
Y1—Mg1v | 3.4869 (8) | Ga2—Y1xvii | 3.1033 (12) |
Y1—Mg1vi | 3.4868 (8) | Ga2—Y1ix | 3.1033 (12) |
Y1—Mg1vii | 3.4868 (8) | Ga2—Y1xviii | 3.1033 (12) |
Y1—Mg1viii | 3.4868 (8) | Mg1—Ga1i | 2.803 (3) |
Y1—Y1v | 3.7491 (7) | Mg1—Ga2x | 2.835 (2) |
Ga1—Mg1 | 2.803 (3) | Mg1—Mg1xvi | 3.076 (7) |
Ga1—Mg1ix | 2.803 (3) | Mg1—Mg1xiv | 3.076 (7) |
Ga1—Mg1vii | 2.803 (3) | Mg1—Y1x | 3.255 (3) |
Ga1—Y1x | 3.0936 (4) | Mg1—Y1ix | 3.4869 (8) |
Ga1—Y1ix | 3.0936 (4) | Mg1—Y1xix | 3.4869 (8) |
Ga1—Y1xi | 3.0936 (4) | Mg1—Y1xi | 3.4868 (8) |
Ga1—Y1vii | 3.0936 (4) | Mg1—Y1xvii | 3.4868 (8) |
Ga1i—Y1—Ga1ii | 160.23 (4) | Mg1xiii—Ga2—Mg1 | 143.50 (5) |
Ga1i—Y1—Ga1iii | 91.197 (16) | Mg1xiii—Ga2—Mg1xiv | 143.50 (5) |
Ga1ii—Y1—Ga1iii | 85.420 (15) | Mg1—Ga2—Mg1xiv | 65.69 (10) |
Ga1i—Y1—Ga1 | 85.420 (15) | Mg1xiii—Ga2—Mg1xv | 65.69 (10) |
Ga1ii—Y1—Ga1 | 91.197 (16) | Mg1—Ga2—Mg1xv | 143.50 (5) |
Ga1iii—Y1—Ga1 | 160.23 (4) | Mg1xiv—Ga2—Mg1xv | 102.44 (13) |
Ga1i—Y1—Ga2iv | 99.89 (2) | Mg1xiii—Ga2—Mg1ii | 65.69 (10) |
Ga1ii—Y1—Ga2iv | 99.89 (2) | Mg1—Ga2—Mg1ii | 102.44 (13) |
Ga1iii—Y1—Ga2iv | 99.89 (2) | Mg1xiv—Ga2—Mg1ii | 143.50 (5) |
Ga1—Y1—Ga2iv | 99.89 (2) | Mg1xv—Ga2—Mg1ii | 65.69 (10) |
Ga1i—Y1—Mg1ii | 111.04 (4) | Mg1xiii—Ga2—Mg1xvi | 102.44 (13) |
Ga1ii—Y1—Mg1ii | 52.33 (3) | Mg1—Ga2—Mg1xvi | 65.69 (10) |
Ga1iii—Y1—Mg1ii | 52.33 (3) | Mg1xiv—Ga2—Mg1xvi | 65.69 (10) |
Ga1—Y1—Mg1ii | 111.04 (4) | Mg1xv—Ga2—Mg1xvi | 143.50 (5) |
Ga2iv—Y1—Mg1ii | 137.24 (5) | Mg1ii—Ga2—Mg1xvi | 143.50 (5) |
Ga1i—Y1—Mg1 | 52.33 (3) | Mg1xiii—Ga2—Y1xvii | 128.78 (6) |
Ga1ii—Y1—Mg1 | 111.04 (4) | Mg1—Ga2—Y1xvii | 71.75 (3) |
Ga1iii—Y1—Mg1 | 111.04 (4) | Mg1xiv—Ga2—Y1xvii | 71.75 (3) |
Ga1—Y1—Mg1 | 52.33 (3) | Mg1xv—Ga2—Y1xvii | 71.75 (3) |
Ga2iv—Y1—Mg1 | 137.24 (5) | Mg1ii—Ga2—Y1xvii | 71.75 (3) |
Mg1ii—Y1—Mg1 | 85.53 (10) | Mg1xvi—Ga2—Y1xvii | 128.78 (6) |
Ga1i—Y1—Mg1v | 49.99 (5) | Mg1xiii—Ga2—Y1ix | 71.75 (3) |
Ga1ii—Y1—Mg1v | 149.44 (7) | Mg1—Ga2—Y1ix | 71.75 (3) |
Ga1iii—Y1—Mg1v | 105.24 (5) | Mg1xiv—Ga2—Y1ix | 128.78 (6) |
Ga1—Y1—Mg1v | 87.44 (4) | Mg1xv—Ga2—Y1ix | 128.78 (6) |
Ga2iv—Y1—Mg1v | 50.55 (5) | Mg1ii—Ga2—Y1ix | 71.75 (3) |
Mg1ii—Y1—Mg1v | 153.75 (6) | Mg1xvi—Ga2—Y1ix | 71.75 (3) |
Mg1—Y1—Mg1v | 92.07 (7) | Y1xvii—Ga2—Y1ix | 120.0 |
Ga1i—Y1—Mg1vi | 149.44 (7) | Mg1xiii—Ga2—Y1xviii | 71.75 (3) |
Ga1ii—Y1—Mg1vi | 49.99 (5) | Mg1—Ga2—Y1xviii | 128.78 (6) |
Ga1iii—Y1—Mg1vi | 87.44 (4) | Mg1xiv—Ga2—Y1xviii | 71.75 (3) |
Ga1—Y1—Mg1vi | 105.24 (5) | Mg1xv—Ga2—Y1xviii | 71.75 (3) |
Ga2iv—Y1—Mg1vi | 50.55 (5) | Mg1ii—Ga2—Y1xviii | 128.78 (6) |
Mg1ii—Y1—Mg1vi | 92.07 (7) | Mg1xvi—Ga2—Y1xviii | 71.75 (3) |
Mg1—Y1—Mg1vi | 153.75 (6) | Y1xvii—Ga2—Y1xviii | 120.0 |
Mg1v—Y1—Mg1vi | 101.11 (10) | Y1ix—Ga2—Y1xviii | 120.0 |
Ga1i—Y1—Mg1vii | 87.44 (4) | Ga1—Mg1—Ga1i | 96.93 (12) |
Ga1ii—Y1—Mg1vii | 105.24 (5) | Ga1—Mg1—Ga2 | 114.538 (6) |
Ga1iii—Y1—Mg1vii | 149.44 (7) | Ga1i—Mg1—Ga2 | 114.538 (6) |
Ga1—Y1—Mg1vii | 49.99 (5) | Ga1—Mg1—Ga2x | 114.538 (6) |
Ga2iv—Y1—Mg1vii | 50.55 (5) | Ga1i—Mg1—Ga2x | 114.538 (6) |
Mg1ii—Y1—Mg1vii | 153.75 (6) | Ga2—Mg1—Ga2x | 102.44 (12) |
Mg1—Y1—Mg1vii | 92.07 (7) | Ga1—Mg1—Mg1xvi | 101.54 (6) |
Mg1v—Y1—Mg1vii | 52.34 (12) | Ga1i—Mg1—Mg1xvi | 161.54 (6) |
Mg1vi—Y1—Mg1vii | 78.67 (2) | Ga2—Mg1—Mg1xvi | 57.15 (5) |
Ga1i—Y1—Mg1viii | 105.24 (5) | Ga2x—Mg1—Mg1xvi | 57.15 (5) |
Ga1ii—Y1—Mg1viii | 87.44 (4) | Ga1—Mg1—Mg1xiv | 161.54 (6) |
Ga1iii—Y1—Mg1viii | 49.99 (5) | Ga1i—Mg1—Mg1xiv | 101.54 (6) |
Ga1—Y1—Mg1viii | 149.44 (7) | Ga2—Mg1—Mg1xiv | 57.15 (5) |
Ga2iv—Y1—Mg1viii | 50.55 (5) | Ga2x—Mg1—Mg1xiv | 57.15 (5) |
Mg1ii—Y1—Mg1viii | 92.07 (7) | Mg1xvi—Mg1—Mg1xiv | 60.0 |
Mg1—Y1—Mg1viii | 153.75 (6) | Ga1—Mg1—Y1x | 60.87 (6) |
Mg1v—Y1—Mg1viii | 78.67 (2) | Ga1i—Mg1—Y1x | 60.87 (6) |
Mg1vi—Y1—Mg1viii | 52.34 (12) | Ga2—Mg1—Y1x | 171.54 (11) |
Mg1vii—Y1—Mg1viii | 101.11 (10) | Ga2x—Mg1—Y1x | 86.01 (3) |
Ga1i—Y1—Y1v | 52.703 (6) | Mg1xvi—Mg1—Y1x | 129.48 (4) |
Ga1ii—Y1—Y1v | 134.380 (9) | Mg1xiv—Mg1—Y1x | 129.48 (4) |
Ga1iii—Y1—Y1v | 52.703 (6) | Ga1—Mg1—Y1 | 60.87 (6) |
Ga1—Y1—Y1v | 134.380 (9) | Ga1i—Mg1—Y1 | 60.87 (6) |
Ga2iv—Y1—Y1v | 74.21 (3) | Ga2—Mg1—Y1 | 86.01 (3) |
Mg1ii—Y1—Y1v | 101.53 (2) | Ga2x—Mg1—Y1 | 171.54 (11) |
Mg1—Y1—Y1v | 101.53 (2) | Mg1xvi—Mg1—Y1 | 129.48 (4) |
Mg1v—Y1—Y1v | 53.32 (5) | Mg1xiv—Mg1—Y1 | 129.48 (4) |
Mg1vi—Y1—Y1v | 104.56 (7) | Y1x—Mg1—Y1 | 85.53 (10) |
Mg1vii—Y1—Y1v | 104.56 (7) | Ga1—Mg1—Y1ix | 57.70 (2) |
Mg1viii—Y1—Y1v | 53.32 (5) | Ga1i—Mg1—Y1ix | 128.28 (9) |
Mg1—Ga1—Mg1ix | 120.0 | Ga2—Mg1—Y1ix | 57.70 (3) |
Mg1—Ga1—Mg1vii | 120.000 (1) | Ga2x—Mg1—Y1ix | 117.00 (8) |
Mg1ix—Ga1—Mg1vii | 120.0 | Mg1xvi—Mg1—Y1ix | 63.83 (6) |
Mg1—Ga1—Y1x | 66.80 (4) | Mg1xiv—Mg1—Y1ix | 109.25 (6) |
Mg1ix—Ga1—Y1x | 134.247 (10) | Y1x—Mg1—Y1ix | 118.53 (8) |
Mg1vii—Ga1—Y1x | 72.31 (4) | Y1—Mg1—Y1ix | 67.47 (3) |
Mg1—Ga1—Y1ix | 72.31 (4) | Ga1—Mg1—Y1xix | 128.28 (9) |
Mg1ix—Ga1—Y1ix | 66.80 (4) | Ga1i—Mg1—Y1xix | 57.70 (2) |
Mg1vii—Ga1—Y1ix | 134.247 (10) | Ga2—Mg1—Y1xix | 117.00 (8) |
Y1x—Ga1—Y1ix | 139.045 (6) | Ga2x—Mg1—Y1xix | 57.70 (3) |
Mg1—Ga1—Y1xi | 72.31 (4) | Mg1xvi—Mg1—Y1xix | 109.25 (6) |
Mg1ix—Ga1—Y1xi | 66.80 (4) | Mg1xiv—Mg1—Y1xix | 63.83 (6) |
Mg1vii—Ga1—Y1xi | 134.247 (10) | Y1x—Mg1—Y1xix | 67.47 (3) |
Y1x—Ga1—Y1xi | 74.593 (12) | Y1—Mg1—Y1xix | 118.53 (8) |
Y1ix—Ga1—Y1xi | 91.197 (16) | Y1ix—Mg1—Y1xix | 172.63 (13) |
Mg1—Ga1—Y1 | 66.80 (4) | Ga1—Mg1—Y1xi | 57.70 (2) |
Mg1ix—Ga1—Y1 | 134.247 (10) | Ga1i—Mg1—Y1xi | 128.28 (9) |
Mg1vii—Ga1—Y1 | 72.31 (4) | Ga2—Mg1—Y1xi | 117.00 (8) |
Y1x—Ga1—Y1 | 91.197 (16) | Ga2x—Mg1—Y1xi | 57.70 (3) |
Y1ix—Ga1—Y1 | 74.593 (12) | Mg1xvi—Mg1—Y1xi | 63.83 (6) |
Y1xi—Ga1—Y1 | 139.045 (6) | Mg1xiv—Mg1—Y1xi | 109.25 (6) |
Mg1—Ga1—Y1vii | 134.247 (10) | Y1x—Mg1—Y1xi | 67.47 (3) |
Mg1ix—Ga1—Y1vii | 72.31 (4) | Y1—Mg1—Y1xi | 118.53 (8) |
Mg1vii—Ga1—Y1vii | 66.80 (4) | Y1ix—Mg1—Y1xi | 78.67 (2) |
Y1x—Ga1—Y1vii | 139.045 (6) | Y1xix—Mg1—Y1xi | 100.84 (3) |
Y1ix—Ga1—Y1vii | 74.593 (12) | Ga1—Mg1—Y1xvii | 128.28 (9) |
Y1xi—Ga1—Y1vii | 139.045 (6) | Ga1i—Mg1—Y1xvii | 57.70 (2) |
Y1—Ga1—Y1vii | 74.593 (12) | Ga2—Mg1—Y1xvii | 57.70 (3) |
Mg1—Ga1—Y1xii | 134.247 (10) | Ga2x—Mg1—Y1xvii | 117.00 (8) |
Mg1ix—Ga1—Y1xii | 72.31 (4) | Mg1xvi—Mg1—Y1xvii | 109.25 (6) |
Mg1vii—Ga1—Y1xii | 66.80 (4) | Mg1xiv—Mg1—Y1xvii | 63.83 (6) |
Y1x—Ga1—Y1xii | 74.593 (12) | Y1x—Mg1—Y1xvii | 118.53 (8) |
Y1ix—Ga1—Y1xii | 139.045 (6) | Y1—Mg1—Y1xvii | 67.47 (3) |
Y1xi—Ga1—Y1xii | 74.593 (12) | Y1ix—Mg1—Y1xvii | 100.84 (3) |
Y1—Ga1—Y1xii | 139.045 (6) | Y1xix—Mg1—Y1xvii | 78.67 (2) |
Y1vii—Ga1—Y1xii | 91.197 (16) | Y1xi—Mg1—Y1xvii | 172.63 (13) |
Symmetry codes: (i) y, x+1, −z+2; (ii) x, y, z−1; (iii) y, x+1, −z+1; (iv) x+1, y, z; (v) −y+2, x−y+2, z; (vi) −x+y, −x+1, z−1; (vii) −x+y, −x+1, z; (viii) −y+2, x−y+2, z−1; (ix) −y+1, x−y+1, z; (x) x, y, z+1; (xi) −y+1, x−y+1, z+1; (xii) −x+y, −x+1, z+1; (xiii) −x+y−1, −x+1, z−1; (xiv) −y+1, x−y+2, z; (xv) −y+1, x−y+2, z−1; (xvi) −x+y−1, −x+1, z; (xvii) −x+y, −x+2, z; (xviii) x−1, y, z; (xix) −x+y, −x+2, z+1. |
Experimental details
Crystal data | |
Chemical formula | YMgGa |
Mr | 182.94 |
Crystal system, space group | Hexagonal, P62m |
Temperature (K) | 293 |
a, c (Å) | 7.2689 (10), 4.4205 (9) |
V (Å3) | 202.27 (6) |
Z | 3 |
Radiation type | Ag Kα, λ = 0.56085 Å |
µ (mm−1) | 16.83 |
Crystal size (mm) | 0.09 × 0.07 × 0.05 |
Data collection | |
Diffractometer | Bruker Apex1 diffractometer |
Absorption correction | Multi-scan (SADABS; Sheldrick, 2001) |
Tmin, Tmax | 0.276, 0.431 |
No. of measured, independent and observed [I > 2σ(I)] reflections | 4365, 333, 324 |
Rint | 0.087 |
(sin θ/λ)max (Å−1) | 0.789 |
Refinement | |
R[F2 > 2σ(F2)], wR(F2), S | 0.035, 0.088, 1.15 |
No. of reflections | 333 |
No. of parameters | 13 |
Δρmax, Δρmin (e Å−3) | 1.65, −1.78 |
Absolute structure | Flack (1983), 136 Friedel pairs |
Absolute structure parameter | 0.43 (5) |
Computer programs: SMART (Bruker, 2001), SAINT (Bruker, 2001), SAINT, SHELXTL (Sheldrick, 2001), DIAMOND (Crystal Impact, 2006), SHELXTL and publCIF (Westrip, 2007).
Ga1—Mg1 | 2.803 (3) | Ga2—Y1ii | 3.1033 (12) |
Ga1—Y1i | 3.0936 (4) | Mg1—Mg1iii | 3.076 (7) |
Ga2—Mg1 | 2.835 (3) | Mg1—Y1i | 3.255 (3) |
Symmetry codes: (i) x, y, z+1; (ii) −x+y, −x+2, z; (iii) −x+y−1, −x+1, z. |
The potential use of magnesium alloys as storage materials for hydrogen has led to a large number of investigations on different magnesium alloys (Sakintuna et al., 2007). The studies of compounds in the systems Mg—Y, Mg—Ga and Mg—Y—Zn have shown some very interesting hydrogen absorbing properties, such as hydrogen induced nanowhisker formation and improved hydrogen absorption/desorption properties, as compared to pure Mg (Zlotea et al., 2006; Sahlberg & Andersson, 2007). Recently we have grown single crystals of YMgGa, and determined its crystal structure. The existence of this phase and the unit-cell parameters were previously reported (Kraft et al., 2003), but no crystal structure refinement has been published.
In the title compound Mg and Ga atoms form a network with distorted channels which are occupied by Y atoms. YMgGa crystallizes in the hexagonal ZrNiAl type structure which is related to the Fe2P type structure (Rundqvist & Jellinek, 1959). The two Fe sites are then occupied with Mg and Y atoms, and the two distinct Ga atoms are located at the corresponding P positions. The Mg—Ga distances, 2.803 (3) and 2.835 (3) Å, respectively, are in agreement with the binary Mg—Ga compounds (Smith et al., 1969). However, the Mg—Mg distance is 3.076 (7) Å, which is significantly shorter than in metallic magnesium, 3.20 Å (Owen et al., 1935). The strong Mg—Ga and Mg—Mg interactions lead to a three-dimensional network which is shown in Figure 1. The Y—Mg (3.255 (3) Å) and Y—Ga (3.0936 (4) Å and 3.1033 (12) Å) distances are likewise in agreement with the binary compounds (Smith et al., 1965; Schob & Parthé, 1965).
The coordination around Ga can be described as a slightly distorted capped trigonal prism. Ga1 is surrounded by 3 Mg atoms at 2.803 (3) Å and by 6 Y atoms at 3.0936 (4) Å in a [3 + 6] coordination. The Mg atoms form a triangle and the Y atoms are situated in the corners of a trigonal prism. Ga2 has a [6 + 3] coordination by 6 Mg at 2.835 (3) Å forming a trigonal prism that is capped by 3 Y at 3.1033 (12) Å. The Mg atom is tetrahedrally coordinated by 4 Ga atoms at 2.803 (3) and 2.835 (3) Å, and has 2 additional Mg neighbours at 3.076 (7) Å. The Y atom has 5 Ga neighbours in a pyramidal coordination and 6 additional Mg atoms forming a trigonal prism. The different coordination polyhedra around each atom are displayed in Figure 2.