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Acta Cryst. (2018). C74, 295-299
https://doi.org/10.1107/S2053229618001973
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Synthesis and crystal structure of a new Cu3Au-type ternary phase in the Au–In–Pd system: distribution of atoms over crystallographic positions

E. A. Ptashkina, E. G. Kabanova, A. I. Tursina, A. V. Yatsenko and V. N. Kuznetsov
A new Cu3Au-type ternary phase (τ phase) is found in the AuPd-rich part of the Au–In–Pd system. It has a broad homogeneity range based on extensive (Pd,Au) and (In,Au) replacement, with the composition varying between Au17.7In25.3Pd57.0 and Au50.8In16.2Pd33.0. The occupancies of the crystallographic positions were studied by single-crystal X-ray diffraction for three samples of different composition. The sites with m\overline{3}m symmetry are occupied by atoms with a smaller scattering power than the atoms located on 4/mmm sites. Two extreme structure models were refined. Within the first, the occupation type changes from (Au,In,Pd)3(Pd,In) to (Au,Pd)3(In,Pd,Au) with an increase in the Au gross content. For the second model, the occupation type (Au,In,Pd)3(Pd,Au) remains essentially unchanged for all Au concentrations. Although the diffraction data do not allow the choice of one of these models, the latter model, where Au substitutes In on 4/mmm sites, seems to be preferable, since it agrees with the fact that the homogeneity range of the τ phase is inclined to the Au corner and provides the same occupation type for all the studied samples of different compositions.
Keywords: inter­metallic compound; gold; palladium; indium; Cu3Au structure type; mixed occupancy; Au–In–Pd ternary phase; crystal structure; valence electronic concentration; VEC.
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Supporting information

cif

Crystallographic Information File (CIF) https://doi.org/10.1107/S2053229618001973/qp3003sup1.cif
Contains datablocks global, 1A, 1B, 2A, 2B, 3A, 3B

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S2053229618001973/qp30031Asup2.hkl
Contains datablock 1A

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S2053229618001973/qp30031Bsup3.hkl
Contains datablock 1B

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S2053229618001973/qp30032Asup4.hkl
Contains datablock 2A

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S2053229618001973/qp30032Bsup5.hkl
Contains datablock 2B

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S2053229618001973/qp30033Asup6.hkl
Contains datablock 3A

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S2053229618001973/qp30033Bsup7.hkl
Contains datablock 3B

CCDC references: 1821598; 1821597; 1821596; 1821595; 1821594; 1821593

Computing details top

For all structures, data collection: CAD-4 Diffractometer Control Software (Enraf–Nonius, 1993); data reduction: PROFIT (Strel'tsov & Zavodnik, 1989); program(s) used to refine structure: SHELXL2014 (Sheldrick, 2015); molecular graphics: DIAMOND (Brandenburg, 2007); software used to prepare material for publication: publCIF (Westrip, 2010).

Gold indium dipalladium (1A) top
Crystal data top
Au1.23In0.93Pd1.84Mo Kα radiation, λ = 0.71073 Å
Mr = 545.03Cell parameters from 24 reflections
Cubic, Pm3mθ = 23.1–23.2°
a = 4.0340 (6) ŵ = 88.69 mm1
V = 65.65 (3) Å3T = 295 K
Z = 1Irregular block, black
F(000) = 2270.05 × 0.04 × 0.04 mm
Dx = 13.787 Mg m3
Data collection top
Nonius CAD-4
diffractometer		Rint = 0.055
Radiation source: fine-focus sealed tubeθmax = 44.8°, θmin = 5.1°
profile data from ω scansh = 88
Absorption correction: empirical (using intensity measurements)
[ψ scan (North et al., 1968) followed by multiscan (Blessing, 1995)]		k = 88
Tmin = 0.108, Tmax = 0.268l = 08
1152 measured reflections2 standard reflections every 120 min
79 independent reflections intensity decay: none
74 reflections with I > 2σ(I)
Refinement top
Refinement on F21 restraint
Least-squares matrix: full w = 1/[σ2(Fo2) + (0.0397P)2]
where P = (Fo2 + 2Fc2)/3
R[F2 > 2σ(F2)] = 0.022(Δ/σ)max < 0.001
wR(F2) = 0.071Δρmax = 2.24 e Å3
S = 1.09Δρmin = 1.84 e Å3
79 reflectionsExtinction correction: SHELXL2014 (Sheldrick, 2015), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
7 parametersExtinction coefficient: 0.019 (5)
Special details top

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.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Pd20.00000.00000.00000.0180 (4)0.88 (7)
In10.00000.00000.00000.0180 (4)0.12 (7)
Au30.00000.50000.50000.0162 (3)0.4106
Pd40.00000.50000.50000.0162 (3)0.32 (2)
In50.00000.50000.50000.0162 (3)0.27 (2)
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Pd20.0180 (4)0.0180 (4)0.0180 (4)0.0000.0000.000
In10.0180 (4)0.0180 (4)0.0180 (4)0.0000.0000.000
Au30.0150 (3)0.0167 (3)0.0167 (3)0.0000.0000.000
Pd40.0150 (3)0.0167 (3)0.0167 (3)0.0000.0000.000
In50.0150 (3)0.0167 (3)0.0167 (3)0.0000.0000.000
Geometric parameters (Å, º) top
Pd2—In5i2.8525 (4)Au3—Pd2ix2.8525 (4)
Pd2—Au32.8525 (4)Au3—In5x2.8525 (4)
Pd2—Pd42.8525 (4)Au3—Pd4vi2.8525 (4)
Pd2—In52.8525 (4)Au3—In1ix2.8525 (4)
Pd2—Au3ii2.8525 (4)Au3—Au3x2.8525 (4)
Pd2—In5iii2.8525 (4)Au3—Pd4vii2.8525 (4)
Pd2—In5iv2.8525 (4)Au3—Pd4viii2.8525 (4)
Pd2—Au3v2.8525 (4)Pd4—In5vi2.8525 (4)
Pd2—In5v2.8525 (4)Pd4—In5vii2.8525 (4)
Pd2—In5ii2.8525 (4)Pd4—In5viii2.8525 (4)
Pd2—Au3iv2.8525 (4)Pd4—Pd2ix2.8525 (4)
Pd2—Au3iii2.8525 (4)Pd4—In5x2.8525 (4)
In1—In5i2.8525 (4)Pd4—Pd4vi2.8525 (4)
In1—Au32.8525 (4)Pd4—In1ix2.8525 (4)
In1—Pd42.8525 (4)Pd4—Au3x2.8525 (4)
In1—In52.8525 (4)Pd4—Pd4vii2.8525 (4)
In1—Au3ii2.8525 (4)Pd4—Pd4viii2.8525 (4)
In1—In5iii2.8525 (4)In5—In5vi2.8525 (4)
In1—In5iv2.8525 (4)In5—In5vii2.8525 (4)
In1—Au3v2.8525 (4)In5—In5viii2.8525 (4)
In1—In5v2.8525 (4)In5—Pd2ix2.8525 (4)
In1—In5ii2.8525 (4)In5—In5x2.8525 (4)
In1—Au3iv2.8525 (4)In5—Pd4vi2.8525 (4)
In1—Au3iii2.8525 (4)In5—In1ix2.8525 (4)
Au3—In5vi2.8525 (4)In5—Au3x2.8525 (4)
Au3—In5vii2.8525 (4)In5—Pd4vii2.8525 (4)
Au3—In5viii2.8525 (4)In5—Pd4viii2.8525 (4)
In5i—Pd2—Au360.0Pd2ix—Au3—In1ix0.0
In5i—Pd2—Pd460.0In5x—Au3—In1ix120.0
Au3—Pd2—Pd40.0Pd4vi—Au3—In1ix60.0
In5i—Pd2—In560.0In5vi—Au3—Au3x120.0
Au3—Pd2—In50.0Pd2—Au3—Au3x60.0
Pd4—Pd2—In50.0In1—Au3—Au3x60.0
In5i—Pd2—Au3ii120.0In5vii—Au3—Au3x60.0
Au3—Pd2—Au3ii180.0In5viii—Au3—Au3x180.0
Pd4—Pd2—Au3ii180.0Pd2ix—Au3—Au3x120.0
In5—Pd2—Au3ii180.0In5x—Au3—Au3x0.0
In5i—Pd2—In5iii180.0Pd4vi—Au3—Au3x120.0
Au3—Pd2—In5iii120.0In1ix—Au3—Au3x120.0
Pd4—Pd2—In5iii120.0In5vi—Au3—Pd4vii180.0
In5—Pd2—In5iii120.0Pd2—Au3—Pd4vii60.0
Au3ii—Pd2—In5iii60.0In1—Au3—Pd4vii60.0
In5i—Pd2—In5iv60.0In5vii—Au3—Pd4vii0.0
Au3—Pd2—In5iv60.0In5viii—Au3—Pd4vii120.0
Pd4—Pd2—In5iv60.0Pd2ix—Au3—Pd4vii120.0
In5—Pd2—In5iv60.0In5x—Au3—Pd4vii60.0
Au3ii—Pd2—In5iv120.0Pd4vi—Au3—Pd4vii180.0
In5iii—Pd2—In5iv120.0In1ix—Au3—Pd4vii120.0
In5i—Pd2—Au3v120.0Au3x—Au3—Pd4vii60.0
Au3—Pd2—Au3v120.0In5vi—Au3—Pd4viii60.0
Pd4—Pd2—Au3v120.0Pd2—Au3—Pd4viii120.0
In5—Pd2—Au3v120.0In1—Au3—Pd4viii120.0
Au3ii—Pd2—Au3v60.0In5vii—Au3—Pd4viii120.0
In5iii—Pd2—Au3v60.0In5viii—Au3—Pd4viii0.0
In5iv—Pd2—Au3v180.0Pd2ix—Au3—Pd4viii60.0
In5i—Pd2—In5v120.0In5x—Au3—Pd4viii180.0
Au3—Pd2—In5v120.0Pd4vi—Au3—Pd4viii60.0
Pd4—Pd2—In5v120.0In1ix—Au3—Pd4viii60.0
In5—Pd2—In5v120.0Au3x—Au3—Pd4viii180.0
Au3ii—Pd2—In5v60.0Pd4vii—Au3—Pd4viii120.0
In5iii—Pd2—In5v60.0In5vi—Pd4—Pd2120.0
In5iv—Pd2—In5v180.0In5vi—Pd4—In1120.0
Au3v—Pd2—In5v0.0Pd2—Pd4—In10.0
In5i—Pd2—In5ii120.0In5vi—Pd4—In5vii180.0
Au3—Pd2—In5ii180.0Pd2—Pd4—In5vii60.0
Pd4—Pd2—In5ii180.0In1—Pd4—In5vii60.0
In5—Pd2—In5ii180.0In5vi—Pd4—In5viii60.0
Au3ii—Pd2—In5ii0.0Pd2—Pd4—In5viii120.0
In5iii—Pd2—In5ii60.0In1—Pd4—In5viii120.0
In5iv—Pd2—In5ii120.0In5vii—Pd4—In5viii120.0
Au3v—Pd2—In5ii60.0In5vi—Pd4—Pd2ix60.0
In5v—Pd2—In5ii60.0Pd2—Pd4—Pd2ix180.0
In5i—Pd2—Au3iv60.0In1—Pd4—Pd2ix180.0
Au3—Pd2—Au3iv60.0In5vii—Pd4—Pd2ix120.0
Pd4—Pd2—Au3iv60.0In5viii—Pd4—Pd2ix60.0
In5—Pd2—Au3iv60.0In5vi—Pd4—In5x120.0
Au3ii—Pd2—Au3iv120.0Pd2—Pd4—In5x60.0
In5iii—Pd2—Au3iv120.0In1—Pd4—In5x60.0
In5iv—Pd2—Au3iv0.0In5vii—Pd4—In5x60.0
Au3v—Pd2—Au3iv180.0In5viii—Pd4—In5x180.0
In5v—Pd2—Au3iv180.0Pd2ix—Pd4—In5x120.0
In5ii—Pd2—Au3iv120.0In5vi—Pd4—Pd4vi0.0
In5i—Pd2—Au3iii180.0Pd2—Pd4—Pd4vi120.0
Au3—Pd2—Au3iii120.0In1—Pd4—Pd4vi120.0
Pd4—Pd2—Au3iii120.0In5vii—Pd4—Pd4vi180.0
In5—Pd2—Au3iii120.0In5viii—Pd4—Pd4vi60.0
Au3ii—Pd2—Au3iii60.0Pd2ix—Pd4—Pd4vi60.0
In5iii—Pd2—Au3iii0.0In5x—Pd4—Pd4vi120.0
In5iv—Pd2—Au3iii120.0In5vi—Pd4—In1ix60.0
Au3v—Pd2—Au3iii60.0Pd2—Pd4—In1ix180.0
In5v—Pd2—Au3iii60.0In1—Pd4—In1ix180.0
In5ii—Pd2—Au3iii60.0In5vii—Pd4—In1ix120.0
Au3iv—Pd2—Au3iii120.0In5viii—Pd4—In1ix60.0
In5i—In1—Au360.0Pd2ix—Pd4—In1ix0.0
In5i—In1—Pd460.0In5x—Pd4—In1ix120.0
Au3—In1—Pd40.0Pd4vi—Pd4—In1ix60.0
In5i—In1—In560.0In5vi—Pd4—Au3x120.0
Au3—In1—In50.0Pd2—Pd4—Au3x60.0
Pd4—In1—In50.0In1—Pd4—Au3x60.0
In5i—In1—Au3ii120.0In5vii—Pd4—Au3x60.0
Au3—In1—Au3ii180.0In5viii—Pd4—Au3x180.0
Pd4—In1—Au3ii180.0Pd2ix—Pd4—Au3x120.0
In5—In1—Au3ii180.0In5x—Pd4—Au3x0.0
In5i—In1—In5iii180.0Pd4vi—Pd4—Au3x120.0
Au3—In1—In5iii120.0In1ix—Pd4—Au3x120.0
Pd4—In1—In5iii120.0In5vi—Pd4—Pd4vii180.0
In5—In1—In5iii120.0Pd2—Pd4—Pd4vii60.0
Au3ii—In1—In5iii60.0In1—Pd4—Pd4vii60.0
In5i—In1—In5iv60.0In5vii—Pd4—Pd4vii0.0
Au3—In1—In5iv60.0In5viii—Pd4—Pd4vii120.0
Pd4—In1—In5iv60.0Pd2ix—Pd4—Pd4vii120.0
In5—In1—In5iv60.0In5x—Pd4—Pd4vii60.0
Au3ii—In1—In5iv120.0Pd4vi—Pd4—Pd4vii180.0
In5iii—In1—In5iv120.0In1ix—Pd4—Pd4vii120.0
In5i—In1—Au3v120.0Au3x—Pd4—Pd4vii60.0
Au3—In1—Au3v120.0In5vi—Pd4—Pd4viii60.0
Pd4—In1—Au3v120.0Pd2—Pd4—Pd4viii120.0
In5—In1—Au3v120.0In1—Pd4—Pd4viii120.0
Au3ii—In1—Au3v60.0In5vii—Pd4—Pd4viii120.0
In5iii—In1—Au3v60.0In5viii—Pd4—Pd4viii0.0
In5iv—In1—Au3v180.0Pd2ix—Pd4—Pd4viii60.0
In5i—In1—In5v120.0In5x—Pd4—Pd4viii180.0
Au3—In1—In5v120.0Pd4vi—Pd4—Pd4viii60.0
Pd4—In1—In5v120.0In1ix—Pd4—Pd4viii60.0
In5—In1—In5v120.0Au3x—Pd4—Pd4viii180.0
Au3ii—In1—In5v60.0Pd4vii—Pd4—Pd4viii120.0
In5iii—In1—In5v60.0In5vi—In5—Pd2120.0
In5iv—In1—In5v180.0In5vi—In5—In1120.0
Au3v—In1—In5v0.0Pd2—In5—In10.0
In5i—In1—In5ii120.0In5vi—In5—In5vii180.0
Au3—In1—In5ii180.0Pd2—In5—In5vii60.0
Pd4—In1—In5ii180.0In1—In5—In5vii60.0
In5—In1—In5ii180.0In5vi—In5—In5viii60.0
Au3ii—In1—In5ii0.0Pd2—In5—In5viii120.0
In5iii—In1—In5ii60.0In1—In5—In5viii120.0
In5iv—In1—In5ii120.0In5vii—In5—In5viii120.0
Au3v—In1—In5ii60.0In5vi—In5—Pd2ix60.0
In5v—In1—In5ii60.0Pd2—In5—Pd2ix180.0
In5i—In1—Au3iv60.0In1—In5—Pd2ix180.0
Au3—In1—Au3iv60.0In5vii—In5—Pd2ix120.0
Pd4—In1—Au3iv60.0In5viii—In5—Pd2ix60.0
In5—In1—Au3iv60.0In5vi—In5—In5x120.0
Au3ii—In1—Au3iv120.0Pd2—In5—In5x60.0
In5iii—In1—Au3iv120.0In1—In5—In5x60.0
In5iv—In1—Au3iv0.0In5vii—In5—In5x60.0
Au3v—In1—Au3iv180.0In5viii—In5—In5x180.0
In5v—In1—Au3iv180.0Pd2ix—In5—In5x120.0
In5ii—In1—Au3iv120.0In5vi—In5—Pd4vi0.0
In5i—In1—Au3iii180.0Pd2—In5—Pd4vi120.0
Au3—In1—Au3iii120.0In1—In5—Pd4vi120.0
Pd4—In1—Au3iii120.0In5vii—In5—Pd4vi180.0
In5—In1—Au3iii120.0In5viii—In5—Pd4vi60.0
Au3ii—In1—Au3iii60.0Pd2ix—In5—Pd4vi60.0
In5iii—In1—Au3iii0.0In5x—In5—Pd4vi120.0
In5iv—In1—Au3iii120.0In5vi—In5—In1ix60.0
Au3v—In1—Au3iii60.0Pd2—In5—In1ix180.0
In5v—In1—Au3iii60.0In1—In5—In1ix180.0
In5ii—In1—Au3iii60.0In5vii—In5—In1ix120.0
Au3iv—In1—Au3iii120.0In5viii—In5—In1ix60.0
In5vi—Au3—Pd2120.0Pd2ix—In5—In1ix0.0
In5vi—Au3—In1120.0In5x—In5—In1ix120.0
Pd2—Au3—In10.0Pd4vi—In5—In1ix60.0
In5vi—Au3—In5vii180.0In5vi—In5—Au3x120.0
Pd2—Au3—In5vii60.0Pd2—In5—Au3x60.0
In1—Au3—In5vii60.0In1—In5—Au3x60.0
In5vi—Au3—In5viii60.0In5vii—In5—Au3x60.0
Pd2—Au3—In5viii120.0In5viii—In5—Au3x180.0
In1—Au3—In5viii120.0Pd2ix—In5—Au3x120.0
In5vii—Au3—In5viii120.0In5x—In5—Au3x0.0
In5vi—Au3—Pd2ix60.0Pd4vi—In5—Au3x120.0
Pd2—Au3—Pd2ix180.0In1ix—In5—Au3x120.0
In1—Au3—Pd2ix180.0In5vi—In5—Pd4vii180.0
In5vii—Au3—Pd2ix120.0Pd2—In5—Pd4vii60.0
In5viii—Au3—Pd2ix60.0In1—In5—Pd4vii60.0
In5vi—Au3—In5x120.0In5vii—In5—Pd4vii0.0
Pd2—Au3—In5x60.0In5viii—In5—Pd4vii120.0
In1—Au3—In5x60.0Pd2ix—In5—Pd4vii120.0
In5vii—Au3—In5x60.0In5x—In5—Pd4vii60.0
In5viii—Au3—In5x180.0Pd4vi—In5—Pd4vii180.0
Pd2ix—Au3—In5x120.0In1ix—In5—Pd4vii120.0
In5vi—Au3—Pd4vi0.0Au3x—In5—Pd4vii60.0
Pd2—Au3—Pd4vi120.0In5vi—In5—Pd4viii60.0
In1—Au3—Pd4vi120.0Pd2—In5—Pd4viii120.0
In5vii—Au3—Pd4vi180.0In1—In5—Pd4viii120.0
In5viii—Au3—Pd4vi60.0In5vii—In5—Pd4viii120.0
Pd2ix—Au3—Pd4vi60.0In5viii—In5—Pd4viii0.0
In5x—Au3—Pd4vi120.0Pd2ix—In5—Pd4viii60.0
In5vi—Au3—In1ix60.0In5x—In5—Pd4viii180.0
Pd2—Au3—In1ix180.0Pd4vi—In5—Pd4viii60.0
In1—Au3—In1ix180.0In1ix—In5—Pd4viii60.0
In5vii—Au3—In1ix120.0Au3x—In5—Pd4viii180.0
In5viii—Au3—In1ix60.0Pd4vii—In5—Pd4viii120.0
Symmetry codes: (i) y, z, x; (ii) x, y1, z1; (iii) y1, z1, x; (iv) y+1, x, z; (v) y, x, z1; (vi) y, z, x+1; (vii) y1, z, x; (viii) y+1, x+1, z; (ix) x, y+1, z+1; (x) y, x, z.
Gold indium dipalladium (1B) top
Crystal data top
Au1.23In0.93Pd1.84Mo Kα radiation, λ = 0.71073 Å
Mr = 545.03Cell parameters from 24 reflections
Cubic, Pm3mθ = 23.1–23.2°
a = 4.0340 (6) ŵ = 88.69 mm1
V = 65.65 (3) Å3T = 295 K
Z = 1Irregular block, black
F(000) = 2270.05 × 0.04 × 0.04 mm
Dx = 13.787 Mg m3
Data collection top
Nonius CAD-4
diffractometer		Rint = 0.055
Radiation source: fine-focus sealed tubeθmax = 44.8°, θmin = 5.1°
profile data from ω scansh = 88
Absorption correction: empirical (using intensity measurements)
[ψ scan (North et al., 1968) followed by multiscan (Blessing, 1995)]		k = 88
Tmin = 0.108, Tmax = 0.268l = 08
1152 measured reflections2 standard reflections every 120 min
79 independent reflections intensity decay: none
74 reflections with I > 2σ(I)
Refinement top
Refinement on F21 restraint
Least-squares matrix: full w = 1/[σ2(Fo2) + (0.0407P)2]
where P = (Fo2 + 2Fc2)/3
R[F2 > 2σ(F2)] = 0.022(Δ/σ)max < 0.001
wR(F2) = 0.073Δρmax = 2.07 e Å3
S = 1.09Δρmin = 1.38 e Å3
79 reflectionsExtinction correction: SHELXL2014 (Sheldrick, 2015), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
7 parametersExtinction coefficient: 0.016 (5)
Special details top

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.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Pd10.00000.00000.00000.0177 (5)0.994 (8)
Au20.00000.00000.00000.0177 (5)0.005 (8)
Pd50.00000.50000.50000.0160 (3)0.281 (3)
Au30.00000.50000.50000.0160 (3)0.409 (3)
In40.00000.50000.50000.0160 (3)0.3107
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Pd10.0177 (5)0.0177 (5)0.0177 (5)0.0000.0000.000
Au20.0177 (5)0.0177 (5)0.0177 (5)0.0000.0000.000
Pd50.0149 (3)0.0166 (3)0.0166 (3)0.0000.0000.000
Au30.0149 (3)0.0166 (3)0.0166 (3)0.0000.0000.000
In40.0149 (3)0.0166 (3)0.0166 (3)0.0000.0000.000
Geometric parameters (Å, º) top
Pd1—In4i2.8525 (4)Pd5—Pd1ix2.8525 (4)
Pd1—Pd52.8525 (4)Pd5—In4x2.8525 (4)
Pd1—Au32.8525 (4)Pd5—Au3vi2.8525 (4)
Pd1—In42.8525 (4)Pd5—Au2ix2.8525 (4)
Pd1—Pd5ii2.8525 (4)Pd5—Pd5x2.8525 (4)
Pd1—In4iii2.8525 (4)Pd5—Au3vii2.8525 (4)
Pd1—In4iv2.8525 (4)Pd5—Au3viii2.8525 (4)
Pd1—Pd5v2.8525 (4)Au3—In4vi2.8525 (4)
Pd1—In4v2.8525 (4)Au3—In4vii2.8525 (4)
Pd1—In4ii2.8525 (4)Au3—In4viii2.8525 (4)
Pd1—Pd5iv2.8525 (4)Au3—Pd1ix2.8525 (4)
Pd1—Pd5iii2.8525 (4)Au3—In4x2.8525 (4)
Au2—In4i2.8525 (4)Au3—Au3vi2.8525 (4)
Au2—Pd52.8525 (4)Au3—Au2ix2.8525 (4)
Au2—Au32.8525 (4)Au3—Pd5x2.8525 (4)
Au2—In42.8525 (4)Au3—Au3vii2.8525 (4)
Au2—Pd5ii2.8525 (4)Au3—Au3viii2.8525 (4)
Au2—In4iii2.8525 (4)In4—In4vi2.8525 (4)
Au2—In4iv2.8525 (4)In4—In4vii2.8525 (4)
Au2—Pd5v2.8525 (4)In4—In4viii2.8525 (4)
Au2—In4v2.8525 (4)In4—Pd1ix2.8525 (4)
Au2—In4ii2.8525 (4)In4—In4x2.8525 (4)
Au2—Pd5iv2.8525 (4)In4—Au3vi2.8525 (4)
Au2—Pd5iii2.8525 (4)In4—Au2ix2.8525 (4)
Pd5—In4vi2.8525 (4)In4—Pd5x2.8525 (4)
Pd5—In4vii2.8525 (4)In4—Au3vii2.8525 (4)
Pd5—In4viii2.8525 (4)In4—Au3viii2.8525 (4)
In4i—Pd1—Pd560.0Pd1ix—Pd5—Au2ix0.0
In4i—Pd1—Au360.0In4x—Pd5—Au2ix120.0
Pd5—Pd1—Au30.0Au3vi—Pd5—Au2ix60.0
In4i—Pd1—In460.0In4vi—Pd5—Pd5x120.0
Pd5—Pd1—In40.0Pd1—Pd5—Pd5x60.0
Au3—Pd1—In40.0Au2—Pd5—Pd5x60.0
In4i—Pd1—Pd5ii120.0In4vii—Pd5—Pd5x60.0
Pd5—Pd1—Pd5ii180.0In4viii—Pd5—Pd5x180.0
Au3—Pd1—Pd5ii180.0Pd1ix—Pd5—Pd5x120.0
In4—Pd1—Pd5ii180.0In4x—Pd5—Pd5x0.0
In4i—Pd1—In4iii180.0Au3vi—Pd5—Pd5x120.0
Pd5—Pd1—In4iii120.0Au2ix—Pd5—Pd5x120.0
Au3—Pd1—In4iii120.0In4vi—Pd5—Au3vii180.0
In4—Pd1—In4iii120.0Pd1—Pd5—Au3vii60.0
Pd5ii—Pd1—In4iii60.0Au2—Pd5—Au3vii60.0
In4i—Pd1—In4iv60.0In4vii—Pd5—Au3vii0.0
Pd5—Pd1—In4iv60.0In4viii—Pd5—Au3vii120.0
Au3—Pd1—In4iv60.0Pd1ix—Pd5—Au3vii120.0
In4—Pd1—In4iv60.0In4x—Pd5—Au3vii60.0
Pd5ii—Pd1—In4iv120.0Au3vi—Pd5—Au3vii180.0
In4iii—Pd1—In4iv120.0Au2ix—Pd5—Au3vii120.0
In4i—Pd1—Pd5v120.0Pd5x—Pd5—Au3vii60.0
Pd5—Pd1—Pd5v120.0In4vi—Pd5—Au3viii60.0
Au3—Pd1—Pd5v120.0Pd1—Pd5—Au3viii120.0
In4—Pd1—Pd5v120.0Au2—Pd5—Au3viii120.0
Pd5ii—Pd1—Pd5v60.0In4vii—Pd5—Au3viii120.0
In4iii—Pd1—Pd5v60.0In4viii—Pd5—Au3viii0.0
In4iv—Pd1—Pd5v180.0Pd1ix—Pd5—Au3viii60.0
In4i—Pd1—In4v120.0In4x—Pd5—Au3viii180.0
Pd5—Pd1—In4v120.0Au3vi—Pd5—Au3viii60.0
Au3—Pd1—In4v120.0Au2ix—Pd5—Au3viii60.0
In4—Pd1—In4v120.0Pd5x—Pd5—Au3viii180.0
Pd5ii—Pd1—In4v60.0Au3vii—Pd5—Au3viii120.0
In4iii—Pd1—In4v60.0In4vi—Au3—Pd1120.0
In4iv—Pd1—In4v180.0In4vi—Au3—Au2120.0
Pd5v—Pd1—In4v0.0Pd1—Au3—Au20.0
In4i—Pd1—In4ii120.0In4vi—Au3—In4vii180.0
Pd5—Pd1—In4ii180.0Pd1—Au3—In4vii60.0
Au3—Pd1—In4ii180.0Au2—Au3—In4vii60.0
In4—Pd1—In4ii180.0In4vi—Au3—In4viii60.0
Pd5ii—Pd1—In4ii0.0Pd1—Au3—In4viii120.0
In4iii—Pd1—In4ii60.0Au2—Au3—In4viii120.0
In4iv—Pd1—In4ii120.0In4vii—Au3—In4viii120.0
Pd5v—Pd1—In4ii60.0In4vi—Au3—Pd1ix60.0
In4v—Pd1—In4ii60.0Pd1—Au3—Pd1ix180.0
In4i—Pd1—Pd5iv60.0Au2—Au3—Pd1ix180.0
Pd5—Pd1—Pd5iv60.0In4vii—Au3—Pd1ix120.0
Au3—Pd1—Pd5iv60.0In4viii—Au3—Pd1ix60.0
In4—Pd1—Pd5iv60.0In4vi—Au3—In4x120.0
Pd5ii—Pd1—Pd5iv120.0Pd1—Au3—In4x60.0
In4iii—Pd1—Pd5iv120.0Au2—Au3—In4x60.0
In4iv—Pd1—Pd5iv0.0In4vii—Au3—In4x60.0
Pd5v—Pd1—Pd5iv180.0In4viii—Au3—In4x180.0
In4v—Pd1—Pd5iv180.0Pd1ix—Au3—In4x120.0
In4ii—Pd1—Pd5iv120.0In4vi—Au3—Au3vi0.0
In4i—Pd1—Pd5iii180.0Pd1—Au3—Au3vi120.0
Pd5—Pd1—Pd5iii120.0Au2—Au3—Au3vi120.0
Au3—Pd1—Pd5iii120.0In4vii—Au3—Au3vi180.0
In4—Pd1—Pd5iii120.0In4viii—Au3—Au3vi60.0
Pd5ii—Pd1—Pd5iii60.0Pd1ix—Au3—Au3vi60.0
In4iii—Pd1—Pd5iii0.0In4x—Au3—Au3vi120.0
In4iv—Pd1—Pd5iii120.0In4vi—Au3—Au2ix60.0
Pd5v—Pd1—Pd5iii60.0Pd1—Au3—Au2ix180.0
In4v—Pd1—Pd5iii60.0Au2—Au3—Au2ix180.0
In4ii—Pd1—Pd5iii60.0In4vii—Au3—Au2ix120.0
Pd5iv—Pd1—Pd5iii120.0In4viii—Au3—Au2ix60.0
In4i—Au2—Pd560.0Pd1ix—Au3—Au2ix0.0
In4i—Au2—Au360.0In4x—Au3—Au2ix120.0
Pd5—Au2—Au30.0Au3vi—Au3—Au2ix60.0
In4i—Au2—In460.0In4vi—Au3—Pd5x120.0
Pd5—Au2—In40.0Pd1—Au3—Pd5x60.0
Au3—Au2—In40.0Au2—Au3—Pd5x60.0
In4i—Au2—Pd5ii120.0In4vii—Au3—Pd5x60.0
Pd5—Au2—Pd5ii180.0In4viii—Au3—Pd5x180.0
Au3—Au2—Pd5ii180.0Pd1ix—Au3—Pd5x120.0
In4—Au2—Pd5ii180.0In4x—Au3—Pd5x0.0
In4i—Au2—In4iii180.0Au3vi—Au3—Pd5x120.0
Pd5—Au2—In4iii120.0Au2ix—Au3—Pd5x120.0
Au3—Au2—In4iii120.0In4vi—Au3—Au3vii180.0
In4—Au2—In4iii120.0Pd1—Au3—Au3vii60.0
Pd5ii—Au2—In4iii60.0Au2—Au3—Au3vii60.0
In4i—Au2—In4iv60.0In4vii—Au3—Au3vii0.0
Pd5—Au2—In4iv60.0In4viii—Au3—Au3vii120.0
Au3—Au2—In4iv60.0Pd1ix—Au3—Au3vii120.0
In4—Au2—In4iv60.0In4x—Au3—Au3vii60.0
Pd5ii—Au2—In4iv120.0Au3vi—Au3—Au3vii180.0
In4iii—Au2—In4iv120.0Au2ix—Au3—Au3vii120.0
In4i—Au2—Pd5v120.0Pd5x—Au3—Au3vii60.0
Pd5—Au2—Pd5v120.0In4vi—Au3—Au3viii60.0
Au3—Au2—Pd5v120.0Pd1—Au3—Au3viii120.0
In4—Au2—Pd5v120.0Au2—Au3—Au3viii120.0
Pd5ii—Au2—Pd5v60.0In4vii—Au3—Au3viii120.0
In4iii—Au2—Pd5v60.0In4viii—Au3—Au3viii0.0
In4iv—Au2—Pd5v180.0Pd1ix—Au3—Au3viii60.0
In4i—Au2—In4v120.0In4x—Au3—Au3viii180.0
Pd5—Au2—In4v120.0Au3vi—Au3—Au3viii60.0
Au3—Au2—In4v120.0Au2ix—Au3—Au3viii60.0
In4—Au2—In4v120.0Pd5x—Au3—Au3viii180.0
Pd5ii—Au2—In4v60.0Au3vii—Au3—Au3viii120.0
In4iii—Au2—In4v60.0In4vi—In4—Pd1120.0
In4iv—Au2—In4v180.0In4vi—In4—Au2120.0
Pd5v—Au2—In4v0.0Pd1—In4—Au20.0
In4i—Au2—In4ii120.0In4vi—In4—In4vii180.0
Pd5—Au2—In4ii180.0Pd1—In4—In4vii60.0
Au3—Au2—In4ii180.0Au2—In4—In4vii60.0
In4—Au2—In4ii180.0In4vi—In4—In4viii60.0
Pd5ii—Au2—In4ii0.0Pd1—In4—In4viii120.0
In4iii—Au2—In4ii60.0Au2—In4—In4viii120.0
In4iv—Au2—In4ii120.0In4vii—In4—In4viii120.0
Pd5v—Au2—In4ii60.0In4vi—In4—Pd1ix60.0
In4v—Au2—In4ii60.0Pd1—In4—Pd1ix180.0
In4i—Au2—Pd5iv60.0Au2—In4—Pd1ix180.0
Pd5—Au2—Pd5iv60.0In4vii—In4—Pd1ix120.0
Au3—Au2—Pd5iv60.0In4viii—In4—Pd1ix60.0
In4—Au2—Pd5iv60.0In4vi—In4—In4x120.0
Pd5ii—Au2—Pd5iv120.0Pd1—In4—In4x60.0
In4iii—Au2—Pd5iv120.0Au2—In4—In4x60.0
In4iv—Au2—Pd5iv0.0In4vii—In4—In4x60.0
Pd5v—Au2—Pd5iv180.0In4viii—In4—In4x180.0
In4v—Au2—Pd5iv180.0Pd1ix—In4—In4x120.0
In4ii—Au2—Pd5iv120.0In4vi—In4—Au3vi0.0
In4i—Au2—Pd5iii180.0Pd1—In4—Au3vi120.0
Pd5—Au2—Pd5iii120.0Au2—In4—Au3vi120.0
Au3—Au2—Pd5iii120.0In4vii—In4—Au3vi180.0
In4—Au2—Pd5iii120.0In4viii—In4—Au3vi60.0
Pd5ii—Au2—Pd5iii60.0Pd1ix—In4—Au3vi60.0
In4iii—Au2—Pd5iii0.0In4x—In4—Au3vi120.0
In4iv—Au2—Pd5iii120.0In4vi—In4—Au2ix60.0
Pd5v—Au2—Pd5iii60.0Pd1—In4—Au2ix180.0
In4v—Au2—Pd5iii60.0Au2—In4—Au2ix180.0
In4ii—Au2—Pd5iii60.0In4vii—In4—Au2ix120.0
Pd5iv—Au2—Pd5iii120.0In4viii—In4—Au2ix60.0
In4vi—Pd5—Pd1120.0Pd1ix—In4—Au2ix0.0
In4vi—Pd5—Au2120.0In4x—In4—Au2ix120.0
Pd1—Pd5—Au20.0Au3vi—In4—Au2ix60.0
In4vi—Pd5—In4vii180.0In4vi—In4—Pd5x120.0
Pd1—Pd5—In4vii60.0Pd1—In4—Pd5x60.0
Au2—Pd5—In4vii60.0Au2—In4—Pd5x60.0
In4vi—Pd5—In4viii60.0In4vii—In4—Pd5x60.0
Pd1—Pd5—In4viii120.0In4viii—In4—Pd5x180.0
Au2—Pd5—In4viii120.0Pd1ix—In4—Pd5x120.0
In4vii—Pd5—In4viii120.0In4x—In4—Pd5x0.0
In4vi—Pd5—Pd1ix60.0Au3vi—In4—Pd5x120.0
Pd1—Pd5—Pd1ix180.0Au2ix—In4—Pd5x120.0
Au2—Pd5—Pd1ix180.0In4vi—In4—Au3vii180.0
In4vii—Pd5—Pd1ix120.0Pd1—In4—Au3vii60.0
In4viii—Pd5—Pd1ix60.0Au2—In4—Au3vii60.0
In4vi—Pd5—In4x120.0In4vii—In4—Au3vii0.0
Pd1—Pd5—In4x60.0In4viii—In4—Au3vii120.0
Au2—Pd5—In4x60.0Pd1ix—In4—Au3vii120.0
In4vii—Pd5—In4x60.0In4x—In4—Au3vii60.0
In4viii—Pd5—In4x180.0Au3vi—In4—Au3vii180.0
Pd1ix—Pd5—In4x120.0Au2ix—In4—Au3vii120.0
In4vi—Pd5—Au3vi0.0Pd5x—In4—Au3vii60.0
Pd1—Pd5—Au3vi120.0In4vi—In4—Au3viii60.0
Au2—Pd5—Au3vi120.0Pd1—In4—Au3viii120.0
In4vii—Pd5—Au3vi180.0Au2—In4—Au3viii120.0
In4viii—Pd5—Au3vi60.0In4vii—In4—Au3viii120.0
Pd1ix—Pd5—Au3vi60.0In4viii—In4—Au3viii0.0
In4x—Pd5—Au3vi120.0Pd1ix—In4—Au3viii60.0
In4vi—Pd5—Au2ix60.0In4x—In4—Au3viii180.0
Pd1—Pd5—Au2ix180.0Au3vi—In4—Au3viii60.0
Au2—Pd5—Au2ix180.0Au2ix—In4—Au3viii60.0
In4vii—Pd5—Au2ix120.0Pd5x—In4—Au3viii180.0
In4viii—Pd5—Au2ix60.0Au3vii—In4—Au3viii120.0
Symmetry codes: (i) y, z, x; (ii) x, y1, z1; (iii) y1, z1, x; (iv) y+1, x, z; (v) y, x, z1; (vi) y, z, x+1; (vii) y1, z, x; (viii) y+1, x+1, z; (ix) x, y+1, z+1; (x) y, x, z.
Gold indium dipalladium (2A) top
Crystal data top
Au1.49In0.89Pd1.62Ag Kα radiation, λ = 0.56087 Å
Mr = 568.20Cell parameters from 24 reflections
Cubic, Pm3mθ = 21.0–21.1°
a = 4.0408 (10) ŵ = 54.65 mm1
V = 65.98 (5) Å3T = 295 K
Z = 1Irregular plate, black
F(000) = 2360.11 × 0.09 × 0.05 mm
Dx = 14.300 Mg m3
Data collection top
Nonius CAD-4
diffractometer		Rint = 0.053
Radiation source: fine-focus sealed tubeθmax = 44.5°, θmin = 4.0°
profile data from ω scansh = 1010
Absorption correction: empirical (using intensity measurements)
[ψ scan (North et al., 1968) followed by multiscan (Blessing, 1995)]		k = 010
Tmin = 0.079, Tmax = 0.245l = 010
1263 measured reflections2 standard reflections every 120 min
148 independent reflections intensity decay: none
117 reflections with I > 2σ(I)
Refinement top
Refinement on F21 restraint
Least-squares matrix: full w = 1/[σ2(Fo2) + (0.0128P)2]
where P = (Fo2 + 2Fc2)/3
R[F2 > 2σ(F2)] = 0.026(Δ/σ)max < 0.001
wR(F2) = 0.050Δρmax = 2.25 e Å3
S = 0.96Δρmin = 2.39 e Å3
148 reflectionsExtinction correction: SHELXL2014 (Sheldrick, 2015), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
7 parametersExtinction coefficient: 0.027 (4)
Special details top

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.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Pd10.00000.00000.00000.0140 (2)0.082 (4)
In20.00000.00000.00000.0140 (2)0.888
Au30.00000.00000.00000.0140 (2)0.029 (4)
Pd50.00000.50000.50000.01117 (9)0.5125 (19)
Au40.00000.50000.50000.01117 (9)0.4875 (19)
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Pd10.0140 (2)0.0140 (2)0.0140 (2)0.0000.0000.000
In20.0140 (2)0.0140 (2)0.0140 (2)0.0000.0000.000
Au30.0140 (2)0.0140 (2)0.0140 (2)0.0000.0000.000
Pd50.01058 (13)0.01146 (11)0.01146 (11)0.0000.0000.000
Au40.01058 (13)0.01146 (11)0.01146 (11)0.0000.0000.000
Geometric parameters (Å, º) top
Pd1—Au4i2.8573 (12)Au3—Pd5ii2.8573 (12)
Pd1—Pd52.8573 (12)Au3—Au4iii2.8573 (12)
Pd1—Au42.8573 (12)Au3—Au4iv2.8573 (12)
Pd1—Pd5ii2.8573 (12)Au3—Pd5v2.8573 (12)
Pd1—Au4iii2.8573 (12)Au3—Au4v2.8573 (12)
Pd1—Au4iv2.8573 (12)Au3—Au4ii2.8573 (12)
Pd1—Pd5v2.8573 (12)Au3—Pd5iv2.8573 (12)
Pd1—Au4v2.8573 (12)Au3—Pd5iii2.8573 (12)
Pd1—Au4ii2.8573 (12)Au3—Pd5i2.8573 (12)
Pd1—Pd5iv2.8573 (12)Pd5—Au4vi2.8573 (12)
Pd1—Pd5iii2.8573 (12)Pd5—Au4vii2.8573 (12)
Pd1—Pd5i2.8573 (12)Pd5—Au4viii2.8573 (12)
In2—Au4i2.8573 (12)Pd5—Pd1ix2.8573 (12)
In2—Pd52.8573 (12)Pd5—Au4x2.8573 (12)
In2—Au42.8573 (12)Pd5—Pd5vi2.8573 (12)
In2—Pd5ii2.8573 (12)Pd5—In2ix2.8573 (12)
In2—Au4iii2.8573 (12)Pd5—Pd5vii2.8573 (12)
In2—Au4iv2.8573 (12)Pd5—Pd5viii2.8573 (12)
In2—Pd5v2.8573 (12)Au4—Au4vi2.8573 (12)
In2—Au4v2.8573 (12)Au4—Au4vii2.8573 (12)
In2—Au4ii2.8573 (12)Au4—Au4viii2.8573 (12)
In2—Pd5iv2.8573 (12)Au4—Pd1ix2.8573 (12)
In2—Pd5iii2.8573 (12)Au4—Au4x2.8573 (12)
In2—Pd5i2.8573 (12)Au4—Pd5vi2.8573 (12)
Au3—Au4i2.8573 (12)Au4—In2ix2.8573 (12)
Au3—Pd52.8573 (12)Au4—Pd5vii2.8573 (12)
Au3—Au42.8573 (12)Au4—Pd5viii2.8573 (12)
Au4i—Pd1—Pd560.0Au4iv—Au3—Au4ii120.0
Au4i—Pd1—Au460.0Pd5v—Au3—Au4ii60.0
Pd5—Pd1—Au40.0Au4v—Au3—Au4ii60.0
Au4i—Pd1—Pd5ii120.0Au4i—Au3—Pd5iv60.0
Pd5—Pd1—Pd5ii180.0Pd5—Au3—Pd5iv60.0
Au4—Pd1—Pd5ii180.0Au4—Au3—Pd5iv60.0
Au4i—Pd1—Au4iii180.0Pd5ii—Au3—Pd5iv120.0
Pd5—Pd1—Au4iii120.0Au4iii—Au3—Pd5iv120.0
Au4—Pd1—Au4iii120.0Au4iv—Au3—Pd5iv0.0
Pd5ii—Pd1—Au4iii60.0Pd5v—Au3—Pd5iv180.0
Au4i—Pd1—Au4iv60.0Au4v—Au3—Pd5iv180.0
Pd5—Pd1—Au4iv60.0Au4ii—Au3—Pd5iv120.0
Au4—Pd1—Au4iv60.0Au4i—Au3—Pd5iii180.0
Pd5ii—Pd1—Au4iv120.0Pd5—Au3—Pd5iii120.0
Au4iii—Pd1—Au4iv120.0Au4—Au3—Pd5iii120.0
Au4i—Pd1—Pd5v120.0Pd5ii—Au3—Pd5iii60.0
Pd5—Pd1—Pd5v120.0Au4iii—Au3—Pd5iii0.0
Au4—Pd1—Pd5v120.0Au4iv—Au3—Pd5iii120.0
Pd5ii—Pd1—Pd5v60.0Pd5v—Au3—Pd5iii60.0
Au4iii—Pd1—Pd5v60.0Au4v—Au3—Pd5iii60.0
Au4iv—Pd1—Pd5v180.0Au4ii—Au3—Pd5iii60.0
Au4i—Pd1—Au4v120.0Pd5iv—Au3—Pd5iii120.0
Pd5—Pd1—Au4v120.0Au4i—Au3—Pd5i0.0
Au4—Pd1—Au4v120.0Pd5—Au3—Pd5i60.0
Pd5ii—Pd1—Au4v60.0Au4—Au3—Pd5i60.0
Au4iii—Pd1—Au4v60.0Pd5ii—Au3—Pd5i120.0
Au4iv—Pd1—Au4v180.0Au4iii—Au3—Pd5i180.0
Pd5v—Pd1—Au4v0.0Au4iv—Au3—Pd5i60.0
Au4i—Pd1—Au4ii120.0Pd5v—Au3—Pd5i120.0
Pd5—Pd1—Au4ii180.0Au4v—Au3—Pd5i120.0
Au4—Pd1—Au4ii180.0Au4ii—Au3—Pd5i120.0
Pd5ii—Pd1—Au4ii0.0Pd5iv—Au3—Pd5i60.0
Au4iii—Pd1—Au4ii60.0Pd5iii—Au3—Pd5i180.0
Au4iv—Pd1—Au4ii120.0Au4vi—Pd5—Pd1120.0
Pd5v—Pd1—Au4ii60.0Au4vi—Pd5—In2120.0
Au4v—Pd1—Au4ii60.0Pd1—Pd5—In20.0
Au4i—Pd1—Pd5iv60.0Au4vi—Pd5—Au3120.0
Pd5—Pd1—Pd5iv60.0Pd1—Pd5—Au30.0
Au4—Pd1—Pd5iv60.0In2—Pd5—Au30.0
Pd5ii—Pd1—Pd5iv120.0Au4vi—Pd5—Au4vii180.0
Au4iii—Pd1—Pd5iv120.0Pd1—Pd5—Au4vii60.0
Au4iv—Pd1—Pd5iv0.0In2—Pd5—Au4vii60.0
Pd5v—Pd1—Pd5iv180.0Au3—Pd5—Au4vii60.0
Au4v—Pd1—Pd5iv180.0Au4vi—Pd5—Au4viii60.0
Au4ii—Pd1—Pd5iv120.0Pd1—Pd5—Au4viii120.0
Au4i—Pd1—Pd5iii180.0In2—Pd5—Au4viii120.0
Pd5—Pd1—Pd5iii120.0Au3—Pd5—Au4viii120.0
Au4—Pd1—Pd5iii120.0Au4vii—Pd5—Au4viii120.0
Pd5ii—Pd1—Pd5iii60.0Au4vi—Pd5—Pd1ix60.0
Au4iii—Pd1—Pd5iii0.0Pd1—Pd5—Pd1ix180.0
Au4iv—Pd1—Pd5iii120.0In2—Pd5—Pd1ix180.0
Pd5v—Pd1—Pd5iii60.0Au3—Pd5—Pd1ix180.0
Au4v—Pd1—Pd5iii60.0Au4vii—Pd5—Pd1ix120.0
Au4ii—Pd1—Pd5iii60.0Au4viii—Pd5—Pd1ix60.0
Pd5iv—Pd1—Pd5iii120.0Au4vi—Pd5—Au4x120.0
Au4i—Pd1—Pd5i0.0Pd1—Pd5—Au4x60.0
Pd5—Pd1—Pd5i60.0In2—Pd5—Au4x60.0
Au4—Pd1—Pd5i60.0Au3—Pd5—Au4x60.0
Pd5ii—Pd1—Pd5i120.0Au4vii—Pd5—Au4x60.0
Au4iii—Pd1—Pd5i180.0Au4viii—Pd5—Au4x180.0
Au4iv—Pd1—Pd5i60.0Pd1ix—Pd5—Au4x120.0
Pd5v—Pd1—Pd5i120.0Au4vi—Pd5—Pd5vi0.0
Au4v—Pd1—Pd5i120.0Pd1—Pd5—Pd5vi120.0
Au4ii—Pd1—Pd5i120.0In2—Pd5—Pd5vi120.0
Pd5iv—Pd1—Pd5i60.0Au3—Pd5—Pd5vi120.0
Pd5iii—Pd1—Pd5i180.0Au4vii—Pd5—Pd5vi180.0
Au4i—In2—Pd560.0Au4viii—Pd5—Pd5vi60.0
Au4i—In2—Au460.0Pd1ix—Pd5—Pd5vi60.0
Pd5—In2—Au40.0Au4x—Pd5—Pd5vi120.0
Au4i—In2—Pd5ii120.0Au4vi—Pd5—In2ix60.0
Pd5—In2—Pd5ii180.0Pd1—Pd5—In2ix180.0
Au4—In2—Pd5ii180.0In2—Pd5—In2ix180.0
Au4i—In2—Au4iii180.0Au3—Pd5—In2ix180.0
Pd5—In2—Au4iii120.0Au4vii—Pd5—In2ix120.0
Au4—In2—Au4iii120.0Au4viii—Pd5—In2ix60.0
Pd5ii—In2—Au4iii60.0Pd1ix—Pd5—In2ix0.0
Au4i—In2—Au4iv60.0Au4x—Pd5—In2ix120.0
Pd5—In2—Au4iv60.0Pd5vi—Pd5—In2ix60.0
Au4—In2—Au4iv60.0Au4vi—Pd5—Pd5vii180.0
Pd5ii—In2—Au4iv120.0Pd1—Pd5—Pd5vii60.0
Au4iii—In2—Au4iv120.0In2—Pd5—Pd5vii60.0
Au4i—In2—Pd5v120.0Au3—Pd5—Pd5vii60.0
Pd5—In2—Pd5v120.0Au4vii—Pd5—Pd5vii0.0
Au4—In2—Pd5v120.0Au4viii—Pd5—Pd5vii120.0
Pd5ii—In2—Pd5v60.0Pd1ix—Pd5—Pd5vii120.0
Au4iii—In2—Pd5v60.0Au4x—Pd5—Pd5vii60.0
Au4iv—In2—Pd5v180.0Pd5vi—Pd5—Pd5vii180.0
Au4i—In2—Au4v120.0In2ix—Pd5—Pd5vii120.0
Pd5—In2—Au4v120.0Au4vi—Pd5—Pd5viii60.0
Au4—In2—Au4v120.0Pd1—Pd5—Pd5viii120.0
Pd5ii—In2—Au4v60.0In2—Pd5—Pd5viii120.0
Au4iii—In2—Au4v60.0Au3—Pd5—Pd5viii120.0
Au4iv—In2—Au4v180.0Au4vii—Pd5—Pd5viii120.0
Pd5v—In2—Au4v0.0Au4viii—Pd5—Pd5viii0.0
Au4i—In2—Au4ii120.0Pd1ix—Pd5—Pd5viii60.0
Pd5—In2—Au4ii180.0Au4x—Pd5—Pd5viii180.0
Au4—In2—Au4ii180.0Pd5vi—Pd5—Pd5viii60.0
Pd5ii—In2—Au4ii0.0In2ix—Pd5—Pd5viii60.0
Au4iii—In2—Au4ii60.0Pd5vii—Pd5—Pd5viii120.0
Au4iv—In2—Au4ii120.0Au4vi—Au4—Pd1120.0
Pd5v—In2—Au4ii60.0Au4vi—Au4—In2120.0
Au4v—In2—Au4ii60.0Pd1—Au4—In20.0
Au4i—In2—Pd5iv60.0Au4vi—Au4—Au3120.0
Pd5—In2—Pd5iv60.0Pd1—Au4—Au30.0
Au4—In2—Pd5iv60.0In2—Au4—Au30.0
Pd5ii—In2—Pd5iv120.0Au4vi—Au4—Au4vii180.0
Au4iii—In2—Pd5iv120.0Pd1—Au4—Au4vii60.0
Au4iv—In2—Pd5iv0.0In2—Au4—Au4vii60.0
Pd5v—In2—Pd5iv180.0Au3—Au4—Au4vii60.0
Au4v—In2—Pd5iv180.0Au4vi—Au4—Au4viii60.0
Au4ii—In2—Pd5iv120.0Pd1—Au4—Au4viii120.0
Au4i—In2—Pd5iii180.0In2—Au4—Au4viii120.0
Pd5—In2—Pd5iii120.0Au3—Au4—Au4viii120.0
Au4—In2—Pd5iii120.0Au4vii—Au4—Au4viii120.0
Pd5ii—In2—Pd5iii60.0Au4vi—Au4—Pd1ix60.0
Au4iii—In2—Pd5iii0.0Pd1—Au4—Pd1ix180.0
Au4iv—In2—Pd5iii120.0In2—Au4—Pd1ix180.0
Pd5v—In2—Pd5iii60.0Au3—Au4—Pd1ix180.0
Au4v—In2—Pd5iii60.0Au4vii—Au4—Pd1ix120.0
Au4ii—In2—Pd5iii60.0Au4viii—Au4—Pd1ix60.0
Pd5iv—In2—Pd5iii120.0Au4vi—Au4—Au4x120.0
Au4i—In2—Pd5i0.0Pd1—Au4—Au4x60.0
Pd5—In2—Pd5i60.0In2—Au4—Au4x60.0
Au4—In2—Pd5i60.0Au3—Au4—Au4x60.0
Pd5ii—In2—Pd5i120.0Au4vii—Au4—Au4x60.0
Au4iii—In2—Pd5i180.0Au4viii—Au4—Au4x180.0
Au4iv—In2—Pd5i60.0Pd1ix—Au4—Au4x120.0
Pd5v—In2—Pd5i120.0Au4vi—Au4—Pd5vi0.0
Au4v—In2—Pd5i120.0Pd1—Au4—Pd5vi120.0
Au4ii—In2—Pd5i120.0In2—Au4—Pd5vi120.0
Pd5iv—In2—Pd5i60.0Au3—Au4—Pd5vi120.0
Pd5iii—In2—Pd5i180.0Au4vii—Au4—Pd5vi180.0
Au4i—Au3—Pd560.0Au4viii—Au4—Pd5vi60.0
Au4i—Au3—Au460.0Pd1ix—Au4—Pd5vi60.0
Pd5—Au3—Au40.0Au4x—Au4—Pd5vi120.0
Au4i—Au3—Pd5ii120.0Au4vi—Au4—In2ix60.0
Pd5—Au3—Pd5ii180.0Pd1—Au4—In2ix180.0
Au4—Au3—Pd5ii180.0In2—Au4—In2ix180.0
Au4i—Au3—Au4iii180.0Au3—Au4—In2ix180.0
Pd5—Au3—Au4iii120.0Au4vii—Au4—In2ix120.0
Au4—Au3—Au4iii120.0Au4viii—Au4—In2ix60.0
Pd5ii—Au3—Au4iii60.0Pd1ix—Au4—In2ix0.0
Au4i—Au3—Au4iv60.0Au4x—Au4—In2ix120.0
Pd5—Au3—Au4iv60.0Pd5vi—Au4—In2ix60.0
Au4—Au3—Au4iv60.0Au4vi—Au4—Pd5vii180.0
Pd5ii—Au3—Au4iv120.0Pd1—Au4—Pd5vii60.0
Au4iii—Au3—Au4iv120.0In2—Au4—Pd5vii60.0
Au4i—Au3—Pd5v120.0Au3—Au4—Pd5vii60.0
Pd5—Au3—Pd5v120.0Au4vii—Au4—Pd5vii0.0
Au4—Au3—Pd5v120.0Au4viii—Au4—Pd5vii120.0
Pd5ii—Au3—Pd5v60.0Pd1ix—Au4—Pd5vii120.0
Au4iii—Au3—Pd5v60.0Au4x—Au4—Pd5vii60.0
Au4iv—Au3—Pd5v180.0Pd5vi—Au4—Pd5vii180.0
Au4i—Au3—Au4v120.0In2ix—Au4—Pd5vii120.0
Pd5—Au3—Au4v120.0Au4vi—Au4—Pd5viii60.0
Au4—Au3—Au4v120.0Pd1—Au4—Pd5viii120.0
Pd5ii—Au3—Au4v60.0In2—Au4—Pd5viii120.0
Au4iii—Au3—Au4v60.0Au3—Au4—Pd5viii120.0
Au4iv—Au3—Au4v180.0Au4vii—Au4—Pd5viii120.0
Pd5v—Au3—Au4v0.0Au4viii—Au4—Pd5viii0.0
Au4i—Au3—Au4ii120.0Pd1ix—Au4—Pd5viii60.0
Pd5—Au3—Au4ii180.0Au4x—Au4—Pd5viii180.0
Au4—Au3—Au4ii180.0Pd5vi—Au4—Pd5viii60.0
Pd5ii—Au3—Au4ii0.0In2ix—Au4—Pd5viii60.0
Au4iii—Au3—Au4ii60.0Pd5vii—Au4—Pd5viii120.0
Symmetry codes: (i) y, z, x; (ii) x, y1, z1; (iii) y1, z1, x; (iv) y+1, x, z; (v) y, x, z1; (vi) y, z, x+1; (vii) y1, z, x; (viii) y+1, x+1, z; (ix) x, y+1, z+1; (x) y, x, z.
Gold indium dipalladium (2B) top
Crystal data top
Au1.49In0.89Pd1.62Ag Kα radiation, λ = 0.56087 Å
Mr = 568.20Cell parameters from 24 reflections
Cubic, Pm3mθ = 21.0–21.1°
a = 4.0408 (10) ŵ = 54.65 mm1
V = 65.98 (5) Å3T = 295 K
Z = 1Irregular plate, black
F(000) = 2360.11 × 0.09 × 0.05 mm
Dx = 14.300 Mg m3
Data collection top
Nonius CAD-4
diffractometer		Rint = 0.053
Radiation source: fine-focus sealed tubeθmax = 44.5°, θmin = 4.0°
profile data from ω scansh = 1010
Absorption correction: empirical (using intensity measurements)
[ψ scan (North et al., 1968) followed by multiscan (Blessing, 1995)]		k = 010
Tmin = 0.079, Tmax = 0.245l = 010
1263 measured reflections2 standard reflections every 120 min
148 independent reflections intensity decay: none
117 reflections with I > 2σ(I)
Refinement top
Refinement on F21 restraint
Least-squares matrix: full w = 1/[σ2(Fo2) + (0.0128P)2]
where P = (Fo2 + 2Fc2)/3
R[F2 > 2σ(F2)] = 0.025(Δ/σ)max < 0.001
wR(F2) = 0.050Δρmax = 2.34 e Å3
S = 0.96Δρmin = 2.41 e Å3
148 reflectionsExtinction correction: SHELXL2014 (Sheldrick, 2015), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
7 parametersExtinction coefficient: 0.028 (4)
Special details top

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.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Pd10.00000.00000.00000.0141 (2)0.881 (4)
Au20.00000.00000.00000.0141 (2)0.119 (4)
Pd40.00000.50000.50000.01119 (9)0.2464 (19)
Au30.00000.50000.50000.01119 (9)0.4576 (19)
In50.00000.50000.50000.01119 (9)0.296
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Pd10.0141 (2)0.0141 (2)0.0141 (2)0.0000.0000.000
Au20.0141 (2)0.0141 (2)0.0141 (2)0.0000.0000.000
Pd40.01062 (13)0.01148 (10)0.01148 (10)0.0000.0000.000
Au30.01062 (13)0.01148 (10)0.01148 (10)0.0000.0000.000
In50.01062 (13)0.01148 (10)0.01148 (10)0.0000.0000.000
Geometric parameters (Å, º) top
Pd1—In5i2.8573 (12)Pd4—Pd1ix2.8573 (12)
Pd1—Pd42.8573 (12)Pd4—In5x2.8573 (12)
Pd1—Au32.8573 (12)Pd4—Au3vi2.8573 (12)
Pd1—In52.8573 (12)Pd4—Au2ix2.8573 (12)
Pd1—Pd4ii2.8573 (12)Pd4—Pd4x2.8573 (12)
Pd1—In5iii2.8573 (12)Pd4—Au3vii2.8573 (12)
Pd1—In5iv2.8573 (12)Pd4—Au3viii2.8573 (12)
Pd1—Pd4v2.8573 (12)Au3—In5vi2.8573 (12)
Pd1—In5v2.8573 (12)Au3—In5vii2.8573 (12)
Pd1—In5ii2.8573 (12)Au3—In5viii2.8573 (12)
Pd1—Pd4iv2.8573 (12)Au3—Pd1ix2.8573 (12)
Pd1—Pd4iii2.8573 (12)Au3—In5x2.8573 (12)
Au2—In5i2.8573 (12)Au3—Au3vi2.8573 (12)
Au2—Pd42.8573 (12)Au3—Au2ix2.8573 (12)
Au2—Au32.8573 (12)Au3—Pd4x2.8573 (12)
Au2—In52.8573 (12)Au3—Au3vii2.8573 (12)
Au2—Pd4ii2.8573 (12)Au3—Au3viii2.8573 (12)
Au2—In5iii2.8573 (12)In5—In5vi2.8573 (12)
Au2—In5iv2.8573 (12)In5—In5vii2.8573 (12)
Au2—Pd4v2.8573 (12)In5—In5viii2.8573 (12)
Au2—In5v2.8573 (12)In5—Pd1ix2.8573 (12)
Au2—In5ii2.8573 (12)In5—In5x2.8573 (12)
Au2—Pd4iv2.8573 (12)In5—Au3vi2.8573 (12)
Au2—Pd4iii2.8573 (12)In5—Au2ix2.8573 (12)
Pd4—In5vi2.8573 (12)In5—Pd4x2.8573 (12)
Pd4—In5vii2.8573 (12)In5—Au3vii2.8573 (12)
Pd4—In5viii2.8573 (12)In5—Au3viii2.8573 (12)
In5i—Pd1—Pd460.0Pd1ix—Pd4—Au2ix0.0
In5i—Pd1—Au360.0In5x—Pd4—Au2ix120.0
Pd4—Pd1—Au30.0Au3vi—Pd4—Au2ix60.0
In5i—Pd1—In560.0In5vi—Pd4—Pd4x120.0
Pd4—Pd1—In50.0Pd1—Pd4—Pd4x60.0
Au3—Pd1—In50.0Au2—Pd4—Pd4x60.0
In5i—Pd1—Pd4ii120.0In5vii—Pd4—Pd4x60.0
Pd4—Pd1—Pd4ii180.0In5viii—Pd4—Pd4x180.0
Au3—Pd1—Pd4ii180.0Pd1ix—Pd4—Pd4x120.0
In5—Pd1—Pd4ii180.0In5x—Pd4—Pd4x0.0
In5i—Pd1—In5iii180.0Au3vi—Pd4—Pd4x120.0
Pd4—Pd1—In5iii120.0Au2ix—Pd4—Pd4x120.0
Au3—Pd1—In5iii120.0In5vi—Pd4—Au3vii180.0
In5—Pd1—In5iii120.0Pd1—Pd4—Au3vii60.0
Pd4ii—Pd1—In5iii60.0Au2—Pd4—Au3vii60.0
In5i—Pd1—In5iv60.0In5vii—Pd4—Au3vii0.0
Pd4—Pd1—In5iv60.0In5viii—Pd4—Au3vii120.0
Au3—Pd1—In5iv60.0Pd1ix—Pd4—Au3vii120.0
In5—Pd1—In5iv60.0In5x—Pd4—Au3vii60.0
Pd4ii—Pd1—In5iv120.0Au3vi—Pd4—Au3vii180.0
In5iii—Pd1—In5iv120.0Au2ix—Pd4—Au3vii120.0
In5i—Pd1—Pd4v120.0Pd4x—Pd4—Au3vii60.0
Pd4—Pd1—Pd4v120.0In5vi—Pd4—Au3viii60.0
Au3—Pd1—Pd4v120.0Pd1—Pd4—Au3viii120.0
In5—Pd1—Pd4v120.0Au2—Pd4—Au3viii120.0
Pd4ii—Pd1—Pd4v60.0In5vii—Pd4—Au3viii120.0
In5iii—Pd1—Pd4v60.0In5viii—Pd4—Au3viii0.0
In5iv—Pd1—Pd4v180.0Pd1ix—Pd4—Au3viii60.0
In5i—Pd1—In5v120.0In5x—Pd4—Au3viii180.0
Pd4—Pd1—In5v120.0Au3vi—Pd4—Au3viii60.0
Au3—Pd1—In5v120.0Au2ix—Pd4—Au3viii60.0
In5—Pd1—In5v120.0Pd4x—Pd4—Au3viii180.0
Pd4ii—Pd1—In5v60.0Au3vii—Pd4—Au3viii120.0
In5iii—Pd1—In5v60.0In5vi—Au3—Pd1120.0
In5iv—Pd1—In5v180.0In5vi—Au3—Au2120.0
Pd4v—Pd1—In5v0.0Pd1—Au3—Au20.0
In5i—Pd1—In5ii120.0In5vi—Au3—In5vii180.0
Pd4—Pd1—In5ii180.0Pd1—Au3—In5vii60.0
Au3—Pd1—In5ii180.0Au2—Au3—In5vii60.0
In5—Pd1—In5ii180.0In5vi—Au3—In5viii60.0
Pd4ii—Pd1—In5ii0.0Pd1—Au3—In5viii120.0
In5iii—Pd1—In5ii60.0Au2—Au3—In5viii120.0
In5iv—Pd1—In5ii120.0In5vii—Au3—In5viii120.0
Pd4v—Pd1—In5ii60.0In5vi—Au3—Pd1ix60.0
In5v—Pd1—In5ii60.0Pd1—Au3—Pd1ix180.0
In5i—Pd1—Pd4iv60.0Au2—Au3—Pd1ix180.0
Pd4—Pd1—Pd4iv60.0In5vii—Au3—Pd1ix120.0
Au3—Pd1—Pd4iv60.0In5viii—Au3—Pd1ix60.0
In5—Pd1—Pd4iv60.0In5vi—Au3—In5x120.0
Pd4ii—Pd1—Pd4iv120.0Pd1—Au3—In5x60.0
In5iii—Pd1—Pd4iv120.0Au2—Au3—In5x60.0
In5iv—Pd1—Pd4iv0.0In5vii—Au3—In5x60.0
Pd4v—Pd1—Pd4iv180.0In5viii—Au3—In5x180.0
In5v—Pd1—Pd4iv180.0Pd1ix—Au3—In5x120.0
In5ii—Pd1—Pd4iv120.0In5vi—Au3—Au3vi0.0
In5i—Pd1—Pd4iii180.0Pd1—Au3—Au3vi120.0
Pd4—Pd1—Pd4iii120.0Au2—Au3—Au3vi120.0
Au3—Pd1—Pd4iii120.0In5vii—Au3—Au3vi180.0
In5—Pd1—Pd4iii120.0In5viii—Au3—Au3vi60.0
Pd4ii—Pd1—Pd4iii60.0Pd1ix—Au3—Au3vi60.0
In5iii—Pd1—Pd4iii0.0In5x—Au3—Au3vi120.0
In5iv—Pd1—Pd4iii120.0In5vi—Au3—Au2ix60.0
Pd4v—Pd1—Pd4iii60.0Pd1—Au3—Au2ix180.0
In5v—Pd1—Pd4iii60.0Au2—Au3—Au2ix180.0
In5ii—Pd1—Pd4iii60.0In5vii—Au3—Au2ix120.0
Pd4iv—Pd1—Pd4iii120.0In5viii—Au3—Au2ix60.0
In5i—Au2—Pd460.0Pd1ix—Au3—Au2ix0.0
In5i—Au2—Au360.0In5x—Au3—Au2ix120.0
Pd4—Au2—Au30.0Au3vi—Au3—Au2ix60.0
In5i—Au2—In560.0In5vi—Au3—Pd4x120.0
Pd4—Au2—In50.0Pd1—Au3—Pd4x60.0
Au3—Au2—In50.0Au2—Au3—Pd4x60.0
In5i—Au2—Pd4ii120.0In5vii—Au3—Pd4x60.0
Pd4—Au2—Pd4ii180.0In5viii—Au3—Pd4x180.0
Au3—Au2—Pd4ii180.0Pd1ix—Au3—Pd4x120.0
In5—Au2—Pd4ii180.0In5x—Au3—Pd4x0.0
In5i—Au2—In5iii180.0Au3vi—Au3—Pd4x120.0
Pd4—Au2—In5iii120.0Au2ix—Au3—Pd4x120.0
Au3—Au2—In5iii120.0In5vi—Au3—Au3vii180.0
In5—Au2—In5iii120.0Pd1—Au3—Au3vii60.0
Pd4ii—Au2—In5iii60.0Au2—Au3—Au3vii60.0
In5i—Au2—In5iv60.0In5vii—Au3—Au3vii0.0
Pd4—Au2—In5iv60.0In5viii—Au3—Au3vii120.0
Au3—Au2—In5iv60.0Pd1ix—Au3—Au3vii120.0
In5—Au2—In5iv60.0In5x—Au3—Au3vii60.0
Pd4ii—Au2—In5iv120.0Au3vi—Au3—Au3vii180.0
In5iii—Au2—In5iv120.0Au2ix—Au3—Au3vii120.0
In5i—Au2—Pd4v120.0Pd4x—Au3—Au3vii60.0
Pd4—Au2—Pd4v120.0In5vi—Au3—Au3viii60.0
Au3—Au2—Pd4v120.0Pd1—Au3—Au3viii120.0
In5—Au2—Pd4v120.0Au2—Au3—Au3viii120.0
Pd4ii—Au2—Pd4v60.0In5vii—Au3—Au3viii120.0
In5iii—Au2—Pd4v60.0In5viii—Au3—Au3viii0.0
In5iv—Au2—Pd4v180.0Pd1ix—Au3—Au3viii60.0
In5i—Au2—In5v120.0In5x—Au3—Au3viii180.0
Pd4—Au2—In5v120.0Au3vi—Au3—Au3viii60.0
Au3—Au2—In5v120.0Au2ix—Au3—Au3viii60.0
In5—Au2—In5v120.0Pd4x—Au3—Au3viii180.0
Pd4ii—Au2—In5v60.0Au3vii—Au3—Au3viii120.0
In5iii—Au2—In5v60.0In5vi—In5—Pd1120.0
In5iv—Au2—In5v180.0In5vi—In5—Au2120.0
Pd4v—Au2—In5v0.0Pd1—In5—Au20.0
In5i—Au2—In5ii120.0In5vi—In5—In5vii180.0
Pd4—Au2—In5ii180.0Pd1—In5—In5vii60.0
Au3—Au2—In5ii180.0Au2—In5—In5vii60.0
In5—Au2—In5ii180.0In5vi—In5—In5viii60.0
Pd4ii—Au2—In5ii0.0Pd1—In5—In5viii120.0
In5iii—Au2—In5ii60.0Au2—In5—In5viii120.0
In5iv—Au2—In5ii120.0In5vii—In5—In5viii120.0
Pd4v—Au2—In5ii60.0In5vi—In5—Pd1ix60.0
In5v—Au2—In5ii60.0Pd1—In5—Pd1ix180.0
In5i—Au2—Pd4iv60.0Au2—In5—Pd1ix180.0
Pd4—Au2—Pd4iv60.0In5vii—In5—Pd1ix120.0
Au3—Au2—Pd4iv60.0In5viii—In5—Pd1ix60.0
In5—Au2—Pd4iv60.0In5vi—In5—In5x120.0
Pd4ii—Au2—Pd4iv120.0Pd1—In5—In5x60.0
In5iii—Au2—Pd4iv120.0Au2—In5—In5x60.0
In5iv—Au2—Pd4iv0.0In5vii—In5—In5x60.0
Pd4v—Au2—Pd4iv180.0In5viii—In5—In5x180.0
In5v—Au2—Pd4iv180.0Pd1ix—In5—In5x120.0
In5ii—Au2—Pd4iv120.0In5vi—In5—Au3vi0.0
In5i—Au2—Pd4iii180.0Pd1—In5—Au3vi120.0
Pd4—Au2—Pd4iii120.0Au2—In5—Au3vi120.0
Au3—Au2—Pd4iii120.0In5vii—In5—Au3vi180.0
In5—Au2—Pd4iii120.0In5viii—In5—Au3vi60.0
Pd4ii—Au2—Pd4iii60.0Pd1ix—In5—Au3vi60.0
In5iii—Au2—Pd4iii0.0In5x—In5—Au3vi120.0
In5iv—Au2—Pd4iii120.0In5vi—In5—Au2ix60.0
Pd4v—Au2—Pd4iii60.0Pd1—In5—Au2ix180.0
In5v—Au2—Pd4iii60.0Au2—In5—Au2ix180.0
In5ii—Au2—Pd4iii60.0In5vii—In5—Au2ix120.0
Pd4iv—Au2—Pd4iii120.0In5viii—In5—Au2ix60.0
In5vi—Pd4—Pd1120.0Pd1ix—In5—Au2ix0.0
In5vi—Pd4—Au2120.0In5x—In5—Au2ix120.0
Pd1—Pd4—Au20.0Au3vi—In5—Au2ix60.0
In5vi—Pd4—In5vii180.0In5vi—In5—Pd4x120.0
Pd1—Pd4—In5vii60.0Pd1—In5—Pd4x60.0
Au2—Pd4—In5vii60.0Au2—In5—Pd4x60.0
In5vi—Pd4—In5viii60.0In5vii—In5—Pd4x60.0
Pd1—Pd4—In5viii120.0In5viii—In5—Pd4x180.0
Au2—Pd4—In5viii120.0Pd1ix—In5—Pd4x120.0
In5vii—Pd4—In5viii120.0In5x—In5—Pd4x0.0
In5vi—Pd4—Pd1ix60.0Au3vi—In5—Pd4x120.0
Pd1—Pd4—Pd1ix180.0Au2ix—In5—Pd4x120.0
Au2—Pd4—Pd1ix180.0In5vi—In5—Au3vii180.0
In5vii—Pd4—Pd1ix120.0Pd1—In5—Au3vii60.0
In5viii—Pd4—Pd1ix60.0Au2—In5—Au3vii60.0
In5vi—Pd4—In5x120.0In5vii—In5—Au3vii0.0
Pd1—Pd4—In5x60.0In5viii—In5—Au3vii120.0
Au2—Pd4—In5x60.0Pd1ix—In5—Au3vii120.0
In5vii—Pd4—In5x60.0In5x—In5—Au3vii60.0
In5viii—Pd4—In5x180.0Au3vi—In5—Au3vii180.0
Pd1ix—Pd4—In5x120.0Au2ix—In5—Au3vii120.0
In5vi—Pd4—Au3vi0.0Pd4x—In5—Au3vii60.0
Pd1—Pd4—Au3vi120.0In5vi—In5—Au3viii60.0
Au2—Pd4—Au3vi120.0Pd1—In5—Au3viii120.0
In5vii—Pd4—Au3vi180.0Au2—In5—Au3viii120.0
In5viii—Pd4—Au3vi60.0In5vii—In5—Au3viii120.0
Pd1ix—Pd4—Au3vi60.0In5viii—In5—Au3viii0.0
In5x—Pd4—Au3vi120.0Pd1ix—In5—Au3viii60.0
In5vi—Pd4—Au2ix60.0In5x—In5—Au3viii180.0
Pd1—Pd4—Au2ix180.0Au3vi—In5—Au3viii60.0
Au2—Pd4—Au2ix180.0Au2ix—In5—Au3viii60.0
In5vii—Pd4—Au2ix120.0Pd4x—In5—Au3viii180.0
In5viii—Pd4—Au2ix60.0Au3vii—In5—Au3viii120.0
Symmetry codes: (i) y, z, x; (ii) x, y1, z1; (iii) y1, z1, x; (iv) y+1, x, z; (v) y, x, z1; (vi) y, z, x+1; (vii) y1, z, x; (viii) y+1, x+1, z; (ix) x, y+1, z+1; (x) y, x, z.
Digold indium palladium (3A) top
Crystal data top
Au1.77In0.86Pd1.37Ag Kα radiation, λ = 0.56087 Å
Mr = 592.96Cell parameters from 24 reflections
Cubic, Pm3mθ = 21.0–21.1°
a = 4.0538 (10) ŵ = 61.39 mm1
V = 66.62 (5) Å3T = 295 K
Z = 1Irregular block, black
F(000) = 2450.10 × 0.09 × 0.08 mm
Dx = 14.781 Mg m3
Data collection top
Nonius CAD-4
diffractometer		Rint = 0.067
Radiation source: fine-focus sealed tubeθmax = 44.9°, θmin = 4.0°
profile data from ω scansh = 010
Absorption correction: empirical (using intensity measurements)
[ψ scan (North et al., 1968) followed by multiscan (Blessing, 1995)]		k = 1010
Tmin = 0.052, Tmax = 0.188l = 010
1283 measured reflections2 standard reflections every 120 min
150 independent reflections intensity decay: none
113 reflections with I > 2σ(I)
Refinement top
Refinement on F21 restraint
Least-squares matrix: full w = 1/[σ2(Fo2) + (0.019P)2]
where P = (Fo2 + 2Fc2)/3
R[F2 > 2σ(F2)] = 0.023(Δ/σ)max < 0.001
wR(F2) = 0.061Δρmax = 2.51 e Å3
S = 1.04Δρmin = 3.29 e Å3
150 reflectionsExtinction correction: SHELXL2014 (Sheldrick, 2015), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
7 parametersExtinction coefficient: 0.011 (4)
Special details top

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.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Pd10.00000.00000.00000.0124 (3)0.067 (7)
In20.00000.00000.00000.0124 (3)0.8602
Au30.00000.00000.00000.0124 (3)0.072 (7)
Pd50.00000.50000.50000.00987 (10)0.435 (3)
Au40.00000.50000.50000.00987 (10)0.565 (3)
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Pd10.0124 (3)0.0124 (3)0.0124 (3)0.0000.0000.000
In20.0124 (3)0.0124 (3)0.0124 (3)0.0000.0000.000
Au30.0124 (3)0.0124 (3)0.0124 (3)0.0000.0000.000
Pd50.00940 (16)0.01010 (12)0.01010 (12)0.0000.0000.000
Au40.00940 (16)0.01010 (12)0.01010 (12)0.0000.0000.000
Geometric parameters (Å, º) top
Pd1—Au4i2.8665 (12)Au3—Pd5ii2.8665 (12)
Pd1—Pd52.8665 (12)Au3—Au4iii2.8665 (12)
Pd1—Au42.8665 (12)Au3—Au4iv2.8665 (12)
Pd1—Pd5ii2.8665 (12)Au3—Pd5v2.8665 (12)
Pd1—Au4iii2.8665 (12)Au3—Au4v2.8665 (12)
Pd1—Au4iv2.8665 (12)Au3—Au4ii2.8665 (12)
Pd1—Pd5v2.8665 (12)Au3—Pd5iv2.8665 (12)
Pd1—Au4v2.8665 (12)Au3—Pd5iii2.8665 (12)
Pd1—Au4ii2.8665 (12)Au3—Pd5i2.8665 (12)
Pd1—Pd5iv2.8665 (12)Pd5—Au4vi2.8665 (12)
Pd1—Pd5iii2.8665 (12)Pd5—Au4vii2.8665 (12)
Pd1—Pd5i2.8665 (12)Pd5—Au4viii2.8665 (12)
In2—Au4i2.8665 (12)Pd5—Pd1ix2.8665 (12)
In2—Pd52.8665 (12)Pd5—Au4x2.8665 (12)
In2—Au42.8665 (12)Pd5—Pd5vi2.8665 (12)
In2—Pd5ii2.8665 (12)Pd5—In2ix2.8665 (12)
In2—Au4iii2.8665 (12)Pd5—Pd5vii2.8665 (12)
In2—Au4iv2.8665 (12)Pd5—Pd5viii2.8665 (12)
In2—Pd5v2.8665 (12)Au4—Au4vi2.8665 (12)
In2—Au4v2.8665 (12)Au4—Au4vii2.8665 (12)
In2—Au4ii2.8665 (12)Au4—Au4viii2.8665 (12)
In2—Pd5iv2.8665 (12)Au4—Pd1ix2.8665 (12)
In2—Pd5iii2.8665 (12)Au4—Au4x2.8665 (12)
In2—Pd5i2.8665 (12)Au4—Pd5vi2.8665 (12)
Au3—Au4i2.8665 (12)Au4—In2ix2.8665 (12)
Au3—Pd52.8665 (12)Au4—Pd5vii2.8665 (12)
Au3—Au42.8665 (12)Au4—Pd5viii2.8665 (12)
Au4i—Pd1—Pd560.0Au4iv—Au3—Au4ii120.0
Au4i—Pd1—Au460.0Pd5v—Au3—Au4ii60.0
Pd5—Pd1—Au40.0Au4v—Au3—Au4ii60.0
Au4i—Pd1—Pd5ii120.0Au4i—Au3—Pd5iv60.0
Pd5—Pd1—Pd5ii180.0Pd5—Au3—Pd5iv60.0
Au4—Pd1—Pd5ii180.0Au4—Au3—Pd5iv60.0
Au4i—Pd1—Au4iii180.0Pd5ii—Au3—Pd5iv120.0
Pd5—Pd1—Au4iii120.0Au4iii—Au3—Pd5iv120.0
Au4—Pd1—Au4iii120.0Au4iv—Au3—Pd5iv0.0
Pd5ii—Pd1—Au4iii60.0Pd5v—Au3—Pd5iv180.0
Au4i—Pd1—Au4iv60.0Au4v—Au3—Pd5iv180.0
Pd5—Pd1—Au4iv60.0Au4ii—Au3—Pd5iv120.0
Au4—Pd1—Au4iv60.0Au4i—Au3—Pd5iii180.0
Pd5ii—Pd1—Au4iv120.0Pd5—Au3—Pd5iii120.0
Au4iii—Pd1—Au4iv120.0Au4—Au3—Pd5iii120.0
Au4i—Pd1—Pd5v120.0Pd5ii—Au3—Pd5iii60.0
Pd5—Pd1—Pd5v120.0Au4iii—Au3—Pd5iii0.0
Au4—Pd1—Pd5v120.0Au4iv—Au3—Pd5iii120.0
Pd5ii—Pd1—Pd5v60.0Pd5v—Au3—Pd5iii60.0
Au4iii—Pd1—Pd5v60.0Au4v—Au3—Pd5iii60.0
Au4iv—Pd1—Pd5v180.0Au4ii—Au3—Pd5iii60.0
Au4i—Pd1—Au4v120.0Pd5iv—Au3—Pd5iii120.0
Pd5—Pd1—Au4v120.0Au4i—Au3—Pd5i0.0
Au4—Pd1—Au4v120.0Pd5—Au3—Pd5i60.0
Pd5ii—Pd1—Au4v60.0Au4—Au3—Pd5i60.0
Au4iii—Pd1—Au4v60.0Pd5ii—Au3—Pd5i120.0
Au4iv—Pd1—Au4v180.0Au4iii—Au3—Pd5i180.0
Pd5v—Pd1—Au4v0.0Au4iv—Au3—Pd5i60.0
Au4i—Pd1—Au4ii120.0Pd5v—Au3—Pd5i120.0
Pd5—Pd1—Au4ii180.0Au4v—Au3—Pd5i120.0
Au4—Pd1—Au4ii180.0Au4ii—Au3—Pd5i120.0
Pd5ii—Pd1—Au4ii0.0Pd5iv—Au3—Pd5i60.0
Au4iii—Pd1—Au4ii60.0Pd5iii—Au3—Pd5i180.0
Au4iv—Pd1—Au4ii120.0Au4vi—Pd5—Pd1120.0
Pd5v—Pd1—Au4ii60.0Au4vi—Pd5—In2120.0
Au4v—Pd1—Au4ii60.0Pd1—Pd5—In20.0
Au4i—Pd1—Pd5iv60.0Au4vi—Pd5—Au3120.0
Pd5—Pd1—Pd5iv60.0Pd1—Pd5—Au30.0
Au4—Pd1—Pd5iv60.0In2—Pd5—Au30.0
Pd5ii—Pd1—Pd5iv120.0Au4vi—Pd5—Au4vii180.0
Au4iii—Pd1—Pd5iv120.0Pd1—Pd5—Au4vii60.0
Au4iv—Pd1—Pd5iv0.0In2—Pd5—Au4vii60.0
Pd5v—Pd1—Pd5iv180.0Au3—Pd5—Au4vii60.0
Au4v—Pd1—Pd5iv180.0Au4vi—Pd5—Au4viii60.0
Au4ii—Pd1—Pd5iv120.0Pd1—Pd5—Au4viii120.0
Au4i—Pd1—Pd5iii180.0In2—Pd5—Au4viii120.0
Pd5—Pd1—Pd5iii120.0Au3—Pd5—Au4viii120.0
Au4—Pd1—Pd5iii120.0Au4vii—Pd5—Au4viii120.0
Pd5ii—Pd1—Pd5iii60.0Au4vi—Pd5—Pd1ix60.0
Au4iii—Pd1—Pd5iii0.0Pd1—Pd5—Pd1ix180.0
Au4iv—Pd1—Pd5iii120.0In2—Pd5—Pd1ix180.0
Pd5v—Pd1—Pd5iii60.0Au3—Pd5—Pd1ix180.0
Au4v—Pd1—Pd5iii60.0Au4vii—Pd5—Pd1ix120.0
Au4ii—Pd1—Pd5iii60.0Au4viii—Pd5—Pd1ix60.0
Pd5iv—Pd1—Pd5iii120.0Au4vi—Pd5—Au4x120.0
Au4i—Pd1—Pd5i0.0Pd1—Pd5—Au4x60.0
Pd5—Pd1—Pd5i60.0In2—Pd5—Au4x60.0
Au4—Pd1—Pd5i60.0Au3—Pd5—Au4x60.0
Pd5ii—Pd1—Pd5i120.0Au4vii—Pd5—Au4x60.0
Au4iii—Pd1—Pd5i180.0Au4viii—Pd5—Au4x180.0
Au4iv—Pd1—Pd5i60.0Pd1ix—Pd5—Au4x120.0
Pd5v—Pd1—Pd5i120.0Au4vi—Pd5—Pd5vi0.0
Au4v—Pd1—Pd5i120.0Pd1—Pd5—Pd5vi120.0
Au4ii—Pd1—Pd5i120.0In2—Pd5—Pd5vi120.0
Pd5iv—Pd1—Pd5i60.0Au3—Pd5—Pd5vi120.0
Pd5iii—Pd1—Pd5i180.0Au4vii—Pd5—Pd5vi180.0
Au4i—In2—Pd560.0Au4viii—Pd5—Pd5vi60.0
Au4i—In2—Au460.0Pd1ix—Pd5—Pd5vi60.0
Pd5—In2—Au40.0Au4x—Pd5—Pd5vi120.0
Au4i—In2—Pd5ii120.0Au4vi—Pd5—In2ix60.0
Pd5—In2—Pd5ii180.0Pd1—Pd5—In2ix180.0
Au4—In2—Pd5ii180.0In2—Pd5—In2ix180.0
Au4i—In2—Au4iii180.0Au3—Pd5—In2ix180.0
Pd5—In2—Au4iii120.0Au4vii—Pd5—In2ix120.0
Au4—In2—Au4iii120.0Au4viii—Pd5—In2ix60.0
Pd5ii—In2—Au4iii60.0Pd1ix—Pd5—In2ix0.0
Au4i—In2—Au4iv60.0Au4x—Pd5—In2ix120.0
Pd5—In2—Au4iv60.0Pd5vi—Pd5—In2ix60.0
Au4—In2—Au4iv60.0Au4vi—Pd5—Pd5vii180.0
Pd5ii—In2—Au4iv120.0Pd1—Pd5—Pd5vii60.0
Au4iii—In2—Au4iv120.0In2—Pd5—Pd5vii60.0
Au4i—In2—Pd5v120.0Au3—Pd5—Pd5vii60.0
Pd5—In2—Pd5v120.0Au4vii—Pd5—Pd5vii0.0
Au4—In2—Pd5v120.0Au4viii—Pd5—Pd5vii120.0
Pd5ii—In2—Pd5v60.0Pd1ix—Pd5—Pd5vii120.0
Au4iii—In2—Pd5v60.0Au4x—Pd5—Pd5vii60.0
Au4iv—In2—Pd5v180.0Pd5vi—Pd5—Pd5vii180.0
Au4i—In2—Au4v120.0In2ix—Pd5—Pd5vii120.0
Pd5—In2—Au4v120.0Au4vi—Pd5—Pd5viii60.0
Au4—In2—Au4v120.0Pd1—Pd5—Pd5viii120.0
Pd5ii—In2—Au4v60.0In2—Pd5—Pd5viii120.0
Au4iii—In2—Au4v60.0Au3—Pd5—Pd5viii120.0
Au4iv—In2—Au4v180.0Au4vii—Pd5—Pd5viii120.0
Pd5v—In2—Au4v0.0Au4viii—Pd5—Pd5viii0.0
Au4i—In2—Au4ii120.0Pd1ix—Pd5—Pd5viii60.0
Pd5—In2—Au4ii180.0Au4x—Pd5—Pd5viii180.0
Au4—In2—Au4ii180.0Pd5vi—Pd5—Pd5viii60.0
Pd5ii—In2—Au4ii0.0In2ix—Pd5—Pd5viii60.0
Au4iii—In2—Au4ii60.0Pd5vii—Pd5—Pd5viii120.0
Au4iv—In2—Au4ii120.0Au4vi—Au4—Pd1120.0
Pd5v—In2—Au4ii60.0Au4vi—Au4—In2120.0
Au4v—In2—Au4ii60.0Pd1—Au4—In20.0
Au4i—In2—Pd5iv60.0Au4vi—Au4—Au3120.0
Pd5—In2—Pd5iv60.0Pd1—Au4—Au30.0
Au4—In2—Pd5iv60.0In2—Au4—Au30.0
Pd5ii—In2—Pd5iv120.0Au4vi—Au4—Au4vii180.0
Au4iii—In2—Pd5iv120.0Pd1—Au4—Au4vii60.0
Au4iv—In2—Pd5iv0.0In2—Au4—Au4vii60.0
Pd5v—In2—Pd5iv180.0Au3—Au4—Au4vii60.0
Au4v—In2—Pd5iv180.0Au4vi—Au4—Au4viii60.0
Au4ii—In2—Pd5iv120.0Pd1—Au4—Au4viii120.0
Au4i—In2—Pd5iii180.0In2—Au4—Au4viii120.0
Pd5—In2—Pd5iii120.0Au3—Au4—Au4viii120.0
Au4—In2—Pd5iii120.0Au4vii—Au4—Au4viii120.0
Pd5ii—In2—Pd5iii60.0Au4vi—Au4—Pd1ix60.0
Au4iii—In2—Pd5iii0.0Pd1—Au4—Pd1ix180.0
Au4iv—In2—Pd5iii120.0In2—Au4—Pd1ix180.0
Pd5v—In2—Pd5iii60.0Au3—Au4—Pd1ix180.0
Au4v—In2—Pd5iii60.0Au4vii—Au4—Pd1ix120.0
Au4ii—In2—Pd5iii60.0Au4viii—Au4—Pd1ix60.0
Pd5iv—In2—Pd5iii120.0Au4vi—Au4—Au4x120.0
Au4i—In2—Pd5i0.0Pd1—Au4—Au4x60.0
Pd5—In2—Pd5i60.0In2—Au4—Au4x60.0
Au4—In2—Pd5i60.0Au3—Au4—Au4x60.0
Pd5ii—In2—Pd5i120.0Au4vii—Au4—Au4x60.0
Au4iii—In2—Pd5i180.0Au4viii—Au4—Au4x180.0
Au4iv—In2—Pd5i60.0Pd1ix—Au4—Au4x120.0
Pd5v—In2—Pd5i120.0Au4vi—Au4—Pd5vi0.0
Au4v—In2—Pd5i120.0Pd1—Au4—Pd5vi120.0
Au4ii—In2—Pd5i120.0In2—Au4—Pd5vi120.0
Pd5iv—In2—Pd5i60.0Au3—Au4—Pd5vi120.0
Pd5iii—In2—Pd5i180.0Au4vii—Au4—Pd5vi180.0
Au4i—Au3—Pd560.0Au4viii—Au4—Pd5vi60.0
Au4i—Au3—Au460.0Pd1ix—Au4—Pd5vi60.0
Pd5—Au3—Au40.0Au4x—Au4—Pd5vi120.0
Au4i—Au3—Pd5ii120.0Au4vi—Au4—In2ix60.0
Pd5—Au3—Pd5ii180.0Pd1—Au4—In2ix180.0
Au4—Au3—Pd5ii180.0In2—Au4—In2ix180.0
Au4i—Au3—Au4iii180.0Au3—Au4—In2ix180.0
Pd5—Au3—Au4iii120.0Au4vii—Au4—In2ix120.0
Au4—Au3—Au4iii120.0Au4viii—Au4—In2ix60.0
Pd5ii—Au3—Au4iii60.0Pd1ix—Au4—In2ix0.0
Au4i—Au3—Au4iv60.0Au4x—Au4—In2ix120.0
Pd5—Au3—Au4iv60.0Pd5vi—Au4—In2ix60.0
Au4—Au3—Au4iv60.0Au4vi—Au4—Pd5vii180.0
Pd5ii—Au3—Au4iv120.0Pd1—Au4—Pd5vii60.0
Au4iii—Au3—Au4iv120.0In2—Au4—Pd5vii60.0
Au4i—Au3—Pd5v120.0Au3—Au4—Pd5vii60.0
Pd5—Au3—Pd5v120.0Au4vii—Au4—Pd5vii0.0
Au4—Au3—Pd5v120.0Au4viii—Au4—Pd5vii120.0
Pd5ii—Au3—Pd5v60.0Pd1ix—Au4—Pd5vii120.0
Au4iii—Au3—Pd5v60.0Au4x—Au4—Pd5vii60.0
Au4iv—Au3—Pd5v180.0Pd5vi—Au4—Pd5vii180.0
Au4i—Au3—Au4v120.0In2ix—Au4—Pd5vii120.0
Pd5—Au3—Au4v120.0Au4vi—Au4—Pd5viii60.0
Au4—Au3—Au4v120.0Pd1—Au4—Pd5viii120.0
Pd5ii—Au3—Au4v60.0In2—Au4—Pd5viii120.0
Au4iii—Au3—Au4v60.0Au3—Au4—Pd5viii120.0
Au4iv—Au3—Au4v180.0Au4vii—Au4—Pd5viii120.0
Pd5v—Au3—Au4v0.0Au4viii—Au4—Pd5viii0.0
Au4i—Au3—Au4ii120.0Pd1ix—Au4—Pd5viii60.0
Pd5—Au3—Au4ii180.0Au4x—Au4—Pd5viii180.0
Au4—Au3—Au4ii180.0Pd5vi—Au4—Pd5viii60.0
Pd5ii—Au3—Au4ii0.0In2ix—Au4—Pd5viii60.0
Au4iii—Au3—Au4ii60.0Pd5vii—Au4—Pd5viii120.0
Symmetry codes: (i) y, z, x; (ii) x, y1, z1; (iii) y1, z1, x; (iv) y+1, x, z; (v) y, x, z1; (vi) y, z, x+1; (vii) y1, z, x; (viii) y+1, x+1, z; (ix) x, y+1, z+1; (x) y, x, z.
Digold indium palladium (3B) top
Crystal data top
Au1.77In0.86Pd1.37Ag Kα radiation, λ = 0.56087 Å
Mr = 592.96Cell parameters from 24 reflections
Cubic, Pm3mθ = 21.0–21.1°
a = 4.0538 (10) ŵ = 61.39 mm1
V = 66.62 (5) Å3T = 295 K
Z = 1Irregular block, black
F(000) = 2450.10 × 0.09 × 0.08 mm
Dx = 14.781 Mg m3
Data collection top
Nonius CAD-4
diffractometer		Rint = 0.067
Radiation source: fine-focus sealed tubeθmax = 44.9°, θmin = 4.0°
profile data from ω scansh = 010
Absorption correction: empirical (using intensity measurements)
[ψ scan (North et al., 1968) followed by multiscan (Blessing, 1995)]		k = 1010
Tmin = 0.052, Tmax = 0.188l = 010
1283 measured reflections2 standard reflections every 120 min
150 independent reflections intensity decay: none
113 reflections with I > 2σ(I)
Refinement top
Refinement on F21 restraint
Least-squares matrix: full w = 1/[σ2(Fo2) + (0.0185P)2]
where P = (Fo2 + 2Fc2)/3
R[F2 > 2σ(F2)] = 0.022(Δ/σ)max < 0.001
wR(F2) = 0.061Δρmax = 2.55 e Å3
S = 1.04Δρmin = 3.44 e Å3
150 reflectionsExtinction correction: SHELXL2014 (Sheldrick, 2015), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
7 parametersExtinction coefficient: 0.011 (4)
Special details top

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.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
Pd10.00000.00000.00000.0124 (3)0.843 (7)
Au20.00000.00000.00000.0124 (3)0.157 (7)
Pd40.00000.50000.50000.00990 (10)0.176 (3)
Au30.00000.50000.50000.00990 (10)0.537 (3)
In50.00000.50000.50000.00990 (10)0.2867
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Pd10.0124 (3)0.0124 (3)0.0124 (3)0.0000.0000.000
Au20.0124 (3)0.0124 (3)0.0124 (3)0.0000.0000.000
Pd40.00944 (15)0.01013 (12)0.01013 (12)0.0000.0000.000
Au30.00944 (15)0.01013 (12)0.01013 (12)0.0000.0000.000
In50.00944 (15)0.01013 (12)0.01013 (12)0.0000.0000.000
Geometric parameters (Å, º) top
Pd1—In5i2.8665 (7)Pd4—Pd1ix2.8665 (7)
Pd1—Pd42.8665 (7)Pd4—In5x2.8665 (7)
Pd1—Au32.8665 (7)Pd4—Au3vi2.8665 (7)
Pd1—In52.8665 (7)Pd4—Au2ix2.8665 (7)
Pd1—Pd4ii2.8665 (7)Pd4—Pd4x2.8665 (7)
Pd1—In5iii2.8665 (7)Pd4—Au3vii2.8665 (7)
Pd1—In5iv2.8665 (7)Pd4—Au3viii2.8665 (7)
Pd1—Pd4v2.8665 (7)Au3—In5vi2.8665 (7)
Pd1—In5v2.8665 (7)Au3—In5vii2.8665 (7)
Pd1—In5ii2.8665 (7)Au3—In5viii2.8665 (7)
Pd1—Pd4iv2.8665 (7)Au3—Pd1ix2.8665 (7)
Pd1—Pd4iii2.8665 (7)Au3—In5x2.8665 (7)
Au2—In5i2.8665 (7)Au3—Au3vi2.8665 (7)
Au2—Pd42.8665 (7)Au3—Au2ix2.8665 (7)
Au2—Au32.8665 (7)Au3—Pd4x2.8665 (7)
Au2—In52.8665 (7)Au3—Au3vii2.8665 (7)
Au2—Pd4ii2.8665 (7)Au3—Au3viii2.8665 (7)
Au2—In5iii2.8665 (7)In5—In5vi2.8665 (7)
Au2—In5iv2.8665 (7)In5—In5vii2.8665 (7)
Au2—Pd4v2.8665 (7)In5—In5viii2.8665 (7)
Au2—In5v2.8665 (7)In5—Pd1ix2.8665 (7)
Au2—In5ii2.8665 (7)In5—In5x2.8665 (7)
Au2—Pd4iv2.8665 (7)In5—Au3vi2.8665 (7)
Au2—Pd4iii2.8665 (7)In5—Au2ix2.8665 (7)
Pd4—In5vi2.8665 (7)In5—Pd4x2.8665 (7)
Pd4—In5vii2.8665 (7)In5—Au3vii2.8665 (7)
Pd4—In5viii2.8665 (7)In5—Au3viii2.8665 (7)
In5i—Pd1—Pd460.0Pd1ix—Pd4—Au2ix0.0
In5i—Pd1—Au360.0In5x—Pd4—Au2ix120.0
Pd4—Pd1—Au30.0Au3vi—Pd4—Au2ix60.0
In5i—Pd1—In560.0In5vi—Pd4—Pd4x120.0
Pd4—Pd1—In50.0Pd1—Pd4—Pd4x60.0
Au3—Pd1—In50.0Au2—Pd4—Pd4x60.0
In5i—Pd1—Pd4ii120.0In5vii—Pd4—Pd4x60.0
Pd4—Pd1—Pd4ii180.0In5viii—Pd4—Pd4x180.0
Au3—Pd1—Pd4ii180.0Pd1ix—Pd4—Pd4x120.0
In5—Pd1—Pd4ii180.0In5x—Pd4—Pd4x0.0
In5i—Pd1—In5iii180.0Au3vi—Pd4—Pd4x120.0
Pd4—Pd1—In5iii120.0Au2ix—Pd4—Pd4x120.0
Au3—Pd1—In5iii120.0In5vi—Pd4—Au3vii180.0
In5—Pd1—In5iii120.0Pd1—Pd4—Au3vii60.0
Pd4ii—Pd1—In5iii60.0Au2—Pd4—Au3vii60.0
In5i—Pd1—In5iv60.0In5vii—Pd4—Au3vii0.0
Pd4—Pd1—In5iv60.0In5viii—Pd4—Au3vii120.0
Au3—Pd1—In5iv60.0Pd1ix—Pd4—Au3vii120.0
In5—Pd1—In5iv60.0In5x—Pd4—Au3vii60.0
Pd4ii—Pd1—In5iv120.0Au3vi—Pd4—Au3vii180.0
In5iii—Pd1—In5iv120.0Au2ix—Pd4—Au3vii120.0
In5i—Pd1—Pd4v120.0Pd4x—Pd4—Au3vii60.0
Pd4—Pd1—Pd4v120.0In5vi—Pd4—Au3viii60.0
Au3—Pd1—Pd4v120.0Pd1—Pd4—Au3viii120.0
In5—Pd1—Pd4v120.0Au2—Pd4—Au3viii120.0
Pd4ii—Pd1—Pd4v60.0In5vii—Pd4—Au3viii120.0
In5iii—Pd1—Pd4v60.0In5viii—Pd4—Au3viii0.0
In5iv—Pd1—Pd4v180.0Pd1ix—Pd4—Au3viii60.0
In5i—Pd1—In5v120.0In5x—Pd4—Au3viii180.0
Pd4—Pd1—In5v120.0Au3vi—Pd4—Au3viii60.0
Au3—Pd1—In5v120.0Au2ix—Pd4—Au3viii60.0
In5—Pd1—In5v120.0Pd4x—Pd4—Au3viii180.0
Pd4ii—Pd1—In5v60.0Au3vii—Pd4—Au3viii120.0
In5iii—Pd1—In5v60.0In5vi—Au3—Pd1120.0
In5iv—Pd1—In5v180.0In5vi—Au3—Au2120.0
Pd4v—Pd1—In5v0.0Pd1—Au3—Au20.0
In5i—Pd1—In5ii120.0In5vi—Au3—In5vii180.0
Pd4—Pd1—In5ii180.0Pd1—Au3—In5vii60.0
Au3—Pd1—In5ii180.0Au2—Au3—In5vii60.0
In5—Pd1—In5ii180.0In5vi—Au3—In5viii60.0
Pd4ii—Pd1—In5ii0.0Pd1—Au3—In5viii120.0
In5iii—Pd1—In5ii60.0Au2—Au3—In5viii120.0
In5iv—Pd1—In5ii120.0In5vii—Au3—In5viii120.0
Pd4v—Pd1—In5ii60.0In5vi—Au3—Pd1ix60.0
In5v—Pd1—In5ii60.0Pd1—Au3—Pd1ix180.0
In5i—Pd1—Pd4iv60.0Au2—Au3—Pd1ix180.0
Pd4—Pd1—Pd4iv60.0In5vii—Au3—Pd1ix120.0
Au3—Pd1—Pd4iv60.0In5viii—Au3—Pd1ix60.0
In5—Pd1—Pd4iv60.0In5vi—Au3—In5x120.0
Pd4ii—Pd1—Pd4iv120.0Pd1—Au3—In5x60.0
In5iii—Pd1—Pd4iv120.0Au2—Au3—In5x60.0
In5iv—Pd1—Pd4iv0.0In5vii—Au3—In5x60.0
Pd4v—Pd1—Pd4iv180.0In5viii—Au3—In5x180.0
In5v—Pd1—Pd4iv180.0Pd1ix—Au3—In5x120.0
In5ii—Pd1—Pd4iv120.0In5vi—Au3—Au3vi0.0
In5i—Pd1—Pd4iii180.0Pd1—Au3—Au3vi120.0
Pd4—Pd1—Pd4iii120.0Au2—Au3—Au3vi120.0
Au3—Pd1—Pd4iii120.0In5vii—Au3—Au3vi180.0
In5—Pd1—Pd4iii120.0In5viii—Au3—Au3vi60.0
Pd4ii—Pd1—Pd4iii60.0Pd1ix—Au3—Au3vi60.0
In5iii—Pd1—Pd4iii0.0In5x—Au3—Au3vi120.0
In5iv—Pd1—Pd4iii120.0In5vi—Au3—Au2ix60.0
Pd4v—Pd1—Pd4iii60.0Pd1—Au3—Au2ix180.0
In5v—Pd1—Pd4iii60.0Au2—Au3—Au2ix180.0
In5ii—Pd1—Pd4iii60.0In5vii—Au3—Au2ix120.0
Pd4iv—Pd1—Pd4iii120.0In5viii—Au3—Au2ix60.0
In5i—Au2—Pd460.0Pd1ix—Au3—Au2ix0.0
In5i—Au2—Au360.0In5x—Au3—Au2ix120.0
Pd4—Au2—Au30.0Au3vi—Au3—Au2ix60.0
In5i—Au2—In560.0In5vi—Au3—Pd4x120.0
Pd4—Au2—In50.0Pd1—Au3—Pd4x60.0
Au3—Au2—In50.0Au2—Au3—Pd4x60.0
In5i—Au2—Pd4ii120.0In5vii—Au3—Pd4x60.0
Pd4—Au2—Pd4ii180.0In5viii—Au3—Pd4x180.0
Au3—Au2—Pd4ii180.0Pd1ix—Au3—Pd4x120.0
In5—Au2—Pd4ii180.0In5x—Au3—Pd4x0.0
In5i—Au2—In5iii180.0Au3vi—Au3—Pd4x120.0
Pd4—Au2—In5iii120.0Au2ix—Au3—Pd4x120.0
Au3—Au2—In5iii120.0In5vi—Au3—Au3vii180.0
In5—Au2—In5iii120.0Pd1—Au3—Au3vii60.0
Pd4ii—Au2—In5iii60.0Au2—Au3—Au3vii60.0
In5i—Au2—In5iv60.0In5vii—Au3—Au3vii0.0
Pd4—Au2—In5iv60.0In5viii—Au3—Au3vii120.0
Au3—Au2—In5iv60.0Pd1ix—Au3—Au3vii120.0
In5—Au2—In5iv60.0In5x—Au3—Au3vii60.0
Pd4ii—Au2—In5iv120.0Au3vi—Au3—Au3vii180.0
In5iii—Au2—In5iv120.0Au2ix—Au3—Au3vii120.0
In5i—Au2—Pd4v120.0Pd4x—Au3—Au3vii60.0
Pd4—Au2—Pd4v120.0In5vi—Au3—Au3viii60.0
Au3—Au2—Pd4v120.0Pd1—Au3—Au3viii120.0
In5—Au2—Pd4v120.0Au2—Au3—Au3viii120.0
Pd4ii—Au2—Pd4v60.0In5vii—Au3—Au3viii120.0
In5iii—Au2—Pd4v60.0In5viii—Au3—Au3viii0.0
In5iv—Au2—Pd4v180.0Pd1ix—Au3—Au3viii60.0
In5i—Au2—In5v120.0In5x—Au3—Au3viii180.0
Pd4—Au2—In5v120.0Au3vi—Au3—Au3viii60.0
Au3—Au2—In5v120.0Au2ix—Au3—Au3viii60.0
In5—Au2—In5v120.0Pd4x—Au3—Au3viii180.0
Pd4ii—Au2—In5v60.0Au3vii—Au3—Au3viii120.0
In5iii—Au2—In5v60.0In5vi—In5—Pd1120.0
In5iv—Au2—In5v180.0In5vi—In5—Au2120.0
Pd4v—Au2—In5v0.0Pd1—In5—Au20.0
In5i—Au2—In5ii120.0In5vi—In5—In5vii180.0
Pd4—Au2—In5ii180.0Pd1—In5—In5vii60.0
Au3—Au2—In5ii180.0Au2—In5—In5vii60.0
In5—Au2—In5ii180.0In5vi—In5—In5viii60.0
Pd4ii—Au2—In5ii0.0Pd1—In5—In5viii120.0
In5iii—Au2—In5ii60.0Au2—In5—In5viii120.0
In5iv—Au2—In5ii120.0In5vii—In5—In5viii120.0
Pd4v—Au2—In5ii60.0In5vi—In5—Pd1ix60.0
In5v—Au2—In5ii60.0Pd1—In5—Pd1ix180.0
In5i—Au2—Pd4iv60.0Au2—In5—Pd1ix180.0
Pd4—Au2—Pd4iv60.0In5vii—In5—Pd1ix120.0
Au3—Au2—Pd4iv60.0In5viii—In5—Pd1ix60.0
In5—Au2—Pd4iv60.0In5vi—In5—In5x120.0
Pd4ii—Au2—Pd4iv120.0Pd1—In5—In5x60.0
In5iii—Au2—Pd4iv120.0Au2—In5—In5x60.0
In5iv—Au2—Pd4iv0.0In5vii—In5—In5x60.0
Pd4v—Au2—Pd4iv180.0In5viii—In5—In5x180.0
In5v—Au2—Pd4iv180.0Pd1ix—In5—In5x120.0
In5ii—Au2—Pd4iv120.0In5vi—In5—Au3vi0.0
In5i—Au2—Pd4iii180.0Pd1—In5—Au3vi120.0
Pd4—Au2—Pd4iii120.0Au2—In5—Au3vi120.0
Au3—Au2—Pd4iii120.0In5vii—In5—Au3vi180.0
In5—Au2—Pd4iii120.0In5viii—In5—Au3vi60.0
Pd4ii—Au2—Pd4iii60.0Pd1ix—In5—Au3vi60.0
In5iii—Au2—Pd4iii0.0In5x—In5—Au3vi120.0
In5iv—Au2—Pd4iii120.0In5vi—In5—Au2ix60.0
Pd4v—Au2—Pd4iii60.0Pd1—In5—Au2ix180.0
In5v—Au2—Pd4iii60.0Au2—In5—Au2ix180.0
In5ii—Au2—Pd4iii60.0In5vii—In5—Au2ix120.0
Pd4iv—Au2—Pd4iii120.0In5viii—In5—Au2ix60.0
In5vi—Pd4—Pd1120.0Pd1ix—In5—Au2ix0.0
In5vi—Pd4—Au2120.0In5x—In5—Au2ix120.0
Pd1—Pd4—Au20.0Au3vi—In5—Au2ix60.0
In5vi—Pd4—In5vii180.0In5vi—In5—Pd4x120.0
Pd1—Pd4—In5vii60.0Pd1—In5—Pd4x60.0
Au2—Pd4—In5vii60.0Au2—In5—Pd4x60.0
In5vi—Pd4—In5viii60.0In5vii—In5—Pd4x60.0
Pd1—Pd4—In5viii120.0In5viii—In5—Pd4x180.0
Au2—Pd4—In5viii120.0Pd1ix—In5—Pd4x120.0
In5vii—Pd4—In5viii120.0In5x—In5—Pd4x0.0
In5vi—Pd4—Pd1ix60.0Au3vi—In5—Pd4x120.0
Pd1—Pd4—Pd1ix180.0Au2ix—In5—Pd4x120.0
Au2—Pd4—Pd1ix180.0In5vi—In5—Au3vii180.0
In5vii—Pd4—Pd1ix120.0Pd1—In5—Au3vii60.0
In5viii—Pd4—Pd1ix60.0Au2—In5—Au3vii60.0
In5vi—Pd4—In5x120.0In5vii—In5—Au3vii0.0
Pd1—Pd4—In5x60.0In5viii—In5—Au3vii120.0
Au2—Pd4—In5x60.0Pd1ix—In5—Au3vii120.0
In5vii—Pd4—In5x60.0In5x—In5—Au3vii60.0
In5viii—Pd4—In5x180.0Au3vi—In5—Au3vii180.0
Pd1ix—Pd4—In5x120.0Au2ix—In5—Au3vii120.0
In5vi—Pd4—Au3vi0.0Pd4x—In5—Au3vii60.0
Pd1—Pd4—Au3vi120.0In5vi—In5—Au3viii60.0
Au2—Pd4—Au3vi120.0Pd1—In5—Au3viii120.0
In5vii—Pd4—Au3vi180.0Au2—In5—Au3viii120.0
In5viii—Pd4—Au3vi60.0In5vii—In5—Au3viii120.0
Pd1ix—Pd4—Au3vi60.0In5viii—In5—Au3viii0.0
In5x—Pd4—Au3vi120.0Pd1ix—In5—Au3viii60.0
In5vi—Pd4—Au2ix60.0In5x—In5—Au3viii180.0
Pd1—Pd4—Au2ix180.0Au3vi—In5—Au3viii60.0
Au2—Pd4—Au2ix180.0Au2ix—In5—Au3viii60.0
In5vii—Pd4—Au2ix120.0Pd4x—In5—Au3viii180.0
In5viii—Pd4—Au2ix60.0Au3vii—In5—Au3viii120.0
Symmetry codes: (i) y, z, x; (ii) x, y1, z1; (iii) y1, z1, x; (iv) y+1, x, z; (v) y, x, z1; (vi) y, z, x+1; (vii) y1, z, x; (viii) y+1, x+1, z; (ix) x, y+1, z+1; (x) y, x, z.
Refined atomic occupancies in samples 1–3 using models A and B top
Alloy No., compositionOccupancy on positionModel AModel B
1, Au30.8In23.3Pd45.91aIn: 0.12 (7)Au: 0.005 (8)
Pd: 0.88 (7)Pd: 0.995 (8)
3cAu: 0.411Au: 0.409 (3)
In: 0.27 (2)In: 0.311
Pd: 0.32 (2)Pd: 0.280 (3)
2, Au37.3In22.2Pd40.51aAu: 0.029 (4)Au: 0.119 (4)
In: 0.888Pd: 0.881 (4)
Pd: 0.083 (4)
3cAu: 0.4875 (19)Au: 0.4576 (19)
Pd: 0.5125 (19)In: 0.296
Pd: 0.2464 (19)
3, Au44.2In21.5Pd34.31aAu: 0.073 (7)Au: 0.157 (7)
In: 0.860Pd: 0.843 (7)
Pd: 0.067 (7)
3cAu: 0.565 (3)Au: 0.537 (3)
Pd: 0.435 (3)In: 0.287
Pd: 0.176 (3)
Results of structure refinement with the sigma's artificially increased by the factor of 10 for all `sublattice' reflections top
Alloy No., compositionModel AModel B
1, Au30.8In23.3Pd45.9R0.02440.0225
wR(F2)0.10950.1110
GooF0.9320.926
Occupancy on 1aIn: 0.20 (10)Au: 0.0a
Pd: 0.80 (10)Pd: 1.0a
Occupancy on 3cAu: 0.411Au: 0.410
In: 0.24 (3)In: 0.311
Pd: 0.35 (3)Pd: 0.279
2, Au37.3In22.2Pd40.5R0.02850.0265
wR(F2)0.12120.1216
GooF0.7450.748
Occupancy on 1aAu: 0.026 (10)Au: 0.119 (10)
In: 0.888Pd: 0.881 (10)
Pd: 0.086 (10)
Occupancy on 3cAu: 0.489 (4)Au: 0.458 (4)
Pd: 0.511 (4)In: 0.296
Pd: 0.246 (4)
3, Au44.2In21.5Pd34.3R0.02300.0227
wR(F2)0.15730.1576
GooF0.7950.797
Occupancy on 1aAu: 0.072 (12)Au: 0.161 (12)
In: 0.860Pd: 0.839 (12)
Pd: 0.068 (12)
Occupancy on 3cAu: 0.565 (4)Au: 0.536 (4)
Pd: 0.435 (4)In: 0.287
Pd: 0.177 (4)
Note: (a) manually fitted, refinement unstable.
Phase and chemical (EDX data) compositions of studied alloys in the Au–In–Pd ternary system top
Alloy No.Average composition, at.%PhaseAu, at.%In, at.%Pd, at.%
1Au30.8In23.3Pd45.9τ30.823.345.9
2Au37.3In22.2Pd40.5τ37.322.240.5
3Au47.1In20.7Pd32.2τ44.221.534.3
fcca51.220.428.4
4Au61.9In13.9Pd24.2τ49.817.532.7
fcc66.012.221.8
5Au11.5In26.3Pd62.2τ17.725.357.0
InPd8.033.158.9
InPd25.431.862.8
6Au20.9In24.1Pd55.0τ23.523.852.7
InPd12.835.152.1
7Au14.2In29.1Pd56.7τ18.925.355.8
InPd8.633.258.2
8Au22.5In32.2Pd45.3τ31.823.844.4
InPd21.733.045.3
9Au50.8In16.2Pd33.0τ50.816.233.0
10Au61.9In15.7Pd22.4τ48.419.532.1
fcc63.315.021.7
Note: (a) fcc is a phase based on (Au,Pd) solid solution.

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