List of 256 Solutions and 1703 Compounds in FTlite


List of 256 Solutions

1. FTlite-A1 1
FCC-A1 Prototype-Cu Strukturbericht = A1; Pearson = cF4; Space Group = Fm-3m (225); [I]
C, N, B and H interstitial (Pearson = cF8 with interstitials)

2. FTlite-A11
ORTH-A11;Prototype-Ga Strukturbericht = A11; Pearson = oC8; Space group = Cmca (64);
Orthorhombic-Ga(alpha)

3. FTlite-A12
CBCC-A12;Prototype-Mn Strukturbericht = A12; Pearson = cI58; Space group = I-43m (217); [I-!5]
alpha-Mn, beta/gamma-A12Mg17, chi-(Mo,W)5Fe12Cr12, Mg24RE5 (RE=Y,Tb,Dy,Ho,Er,Tm,Lu), Fe12RE17 stable

4. FTlite-A13
CUB-A13;Prototype-Mn Strukturbericht = A13; Pearson = cP20; Space group = P4132 (213); [I]
beta-Mn and Ag3Al are stable; with C and N interstitials

5. FTlite-A15
CUB-A15;Prototype-Cr3Si Strukturbericht = A15; Pearson = cP8; Space group = Pm-3n (223);
Cr3Si, Cr3Pt, Mo3Al, Mo3Si, Nb3Al, Nb3Sn, V3Co, V3Ni, V3Si and V3Sn are stable

6. FTlite-A17M
oP142;Prototype-Hf54Os17 Pearson = oP142; Space group = Immm (71);
Ag17Mg54 with solubility in Sn

7. FTlite-A2 1
BCC-A2 Prototype-W Strukturbericht = A2; Pearson = cI2; Space Group = Im-3m (229); [I]
C, H, N and B interstitial on tetrahedral sites

8. FTlite-A3 1
HCP-A3 Prototype-Mg Strukturbericht = A3; Peason = hP2; Space group = P63/mmc (194); [I]
with M2X-hcp carbides, nitrides, borides, hydrides and oxides

9. FTlite-A3"
HCP-Zn;Prototype-Mg Strukturbericht = A3; Pearson = hP2; Space group = P63/mmc (194); [I-!5]
Higher c/a ratio than Mg-HCP_A3

10. FTlite-A3'
DHCP-A3';Prototype-La Strukturbericht = A3'; Pearson = hP4; Space group = P63/mmc (194);
La, Ce, Pr, Nd, Pm

11. FTlite-A3M_
oP156;Prototype-Al11Mn4 Pearson = oP156;
'Al3Mn'-high T

12. FTlite-A3RE
hR12;Prototype-BaPb3 Pearson = hR12; Space group = R-3m (166);
Al3Tb and beta-Al3Y are stable

13. FTlite-A4 1
DIAM-A4;Prototype-C (diamond) Strukturbericht = A4; Pearson = cF8; Space group = Fd-3m (227); [I-!5]
C-diamond, Ge, alpha-Sn and Si are stable

14. FTlite-A5 1
BCT-A5;Prototype-Sn Strukturbericht = A5; Pearson = tI4; Space group = I41/amd (141);
Beta-Sn

15. FTlite-A6 1
TET-A6;Prototype-In Strukturbericht = A6; Pearson = tI2; Space group = I4/mmm (139); [I]
Tetragonal-In(alpha)

16. FTlite-A6o
TET-A6o;Prototype-In Strukturbericht = A6; Pearson = tI2; Space group = I4/mmm (139); [I]
Ordered tetragonal solution found in In-rich systems with Bi, Cd, Pb & Sn.

17. FTlite-A7 1
RHOM-A7;Prototype-As Strukturbericht = A7; Pearson = hR2; Space group = R-3m (166); [I]
Rhombohedral-As(alpha)

18. FTlite-A9 1
A9;Prototype-C (graphite) Strukturbericht = A9; Pearson = hP4; Space group = P63/mmc (194);
C-graphite(alpha) with solubility of boron

19. FTlite-A9ME
hP12;Prototype-Al9Co2Sr Pearson = hP12; Space group = P6/mmm (191); [I]
all Al9(Co,Fe,Ni)2(Ba,Sr) combinations are stable;

20. FTlite-Af 1
HEX-Af;Prototype-HgSn9 Strukturbericht = Af; Pearson = hP1; Space group = P6/mmm (191);
gamma-HgSn9 (disordered), gamma-InSn are stable

21. FTlite-AFMS
AlFeMnSi_alpha
Al-Fe-Mn-Si quaternary solution

22. FTlite-Ag 1
Ag;Prototype-B Strukturbericht = Ag; Pearson = tP50; Space group = P42/nnm (134); [-I]
Tetragonal-boron(beta) is metastable;

23. FTlite-Al4M
Al4Mn Pearson = hP574; Space group = P63/mmc;
Phase at 80 at.% Al in Al-Mn with solubility for Fe and Cr

24. FTlite-AlCr
Al11Cr2 Pearson = mC616; Space group = C2/c (15);
with solubility in Mn

25. FTlite-AlM1
AlMnSi_alpha (tau9) Pearson = cP138; Space group = Pm-3 (200)
approx. stoichiometry Al9Mn2Si with solubility of Fe

26. FTlite-AMg3
cF264;Prototype-AgMg3 Pearson = cF264; Space group = P63cm (202);
AgMg3 with Al, In, Sn solubility

27. FTlite-aP15
aP15;Prototype-Al11Mn4 Pearson = aP15; Space group = P-1 (2);
Al11Mn4(low-T)

28. FTlite-aP18
aP18;Prototype-Al2Fe Pearson = aP18; Space group = P1 (1);
ksi-Al2Fe

29. FTlite-aP20
aP20;Prototype-Nd2Sn3 Pearson = aP20; Space group = P-1 (2);
La2Sn3, Pr2Sn3 and Sm2Sn3 are stable;

30. FTlite-aP22
aP22;Prototype-Ca8In3 Pearson = aP22; Space group = P-1 (2);
Al3Ca8 and In3Ca8 are stable

31. FTlite-aP40
aP40;Prototype-Cu7In3 Pearson = aP40; Space group = P-1 (2);
Cu7In3 is stable

32. FTlite-aRho
aRHOM;Prototype-B Pearson = hR12; Space group = R-3m (166);
Rhombohedral-Boron(alpha);

33. FTlite-AsP
AsP-orthorhombic
AsP (approx. "As3P2") precise structure unknown

34. FTlite-B''
B'' 'non-FCC monoclinic' C2/m
(METASTABLE PHASE) [-J]

35. FTlite-B1 1
FCC-B1;Prototype-NaCl (halite) Strukturbericht = B1; Pearson = cF8; Space group = Fm-3m (225); [I]
PbX (X=S,Se,Te), SnX (X=S,Te), RESb (RE=Ce,Nd,Pr,Sm) are stable

36. FTlite-B11
B11;Prototype-CuTi Strukturbericht = B11; Pearson = tP4; Space group = P4/nmm (129); [I]
AgTi, AgZr, gamma-CuTi, beta1-NiZn are stable

37. FTlite-B2 1
BCC-B2;Prototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221); [I]
MgRE and ZnRE (RE=Ce,Dy,Er,Eu,Gd,Ho,La,Nd,Pr,Sm,Tb,Tm,Y), MgSc and AlSc are stable

38. FTlite-B20
B20;Prototype-FeSi Struktutbericht = B20; Pearson = cP8; Space group = P213 (198); [I]
(Co,Cr,Fe,Mn)Si monosilicide

39. FTlite-B27
B27;Prototype-FeB Strukturbericht = B27; Pearson = oP8; Space group = Pnma (62); [I]
CoB, FeB, TiB, ZrB, HfB, TiSi, ZrSi and RESi (RE=La,Ce,Pr,Nd,Pm,Sm,Eu,Gd,Tb,Dy,Ho,Er,Tm,Yb,Lu)

40. FTlite-B2_a
BCC-B2a!BCC-A2 Prototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221); [I]
CuZn-beta', NiZn-beta, AgMg, AgLi, CaIn are stable

41. FTlite-B2_b
BCC-B2b bPrototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221); [I]
Equiatomic Ni-Ti phase with ca. 10 at.% range.

42. FTlite-B2_c
BCC-B2c;Prototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221); [I]
Ordered BCC phase AlNi

43. FTlite-B2_d
BCC-B2d!BCC-A2 order/disorder model (221)
AlFe, AlMn, FeSi are stable ([I]-Option)

44. FTlite-B3 1
B3;Prototype-ZnS (sphalerite) Strukturbericht = B3; Pearson = cF8; Space group = F-43m (216); [J]
ZnS, beta-3C-SiC, (Al,Ga,In)[P,As,Sb] are stable; BN-cubic(beta) is stable;

45. FTlite-B31
B31;Prototype-FeAs Strukturbericht = B31; Pearson = oP8; Space group = Pnma (62);
CoP, FeP, MnP and NiSi are stable

46. FTlite-B32
B32;Prototype-NaTl Strukturbericht = B32; Pearson = cF16; Space group = Fd-3m (227);
beta-AlLi, InLi, InNa and LiZn are stable

47. FTlite-B33
B33;Prototype-CrB Strukturbericht = B33; Pearson = oC8; Space group = Cmcm (63);
CrB, NbB, NiB, VB, WB, CaSi, SrSi, BaSi, CaSn, SrSn, LaSn, AlHf, AlY, RESi (RE=Sc,Y) are stable

48. FTlite-B35
B35;Prototype-CoSn Strukturbericht = B35; Pearson = hP6; Space group = P6/mmm (191);
CoSn, FeSn are stable

49. FTlite-B3Si
oP340;Prototype-B3Si Pearson = oP340; Space group = Pnnm (58);
B-Si binary phase at ca. 75 at.% B. Stable to ca. 1548 K.

50. FTlite-B4 1
B4;Prototype-ZnS (wurtzite) Strukturbericht = B4; Pearson = hP4; Space group = P63mc (186); [J]
AlN, GaN, InN and ZnS are stable; gamma-BN is metastable; 2H-SiC is metastable

51. FTlite-B6Si
B6Si Pearson = oP280; Space group = Pnnm (58);
B-Si phase at ca. 86 at.% B. Stable to ca. 2113 K.

52. FTlite-B81
B81;Prototype-NiAs Strukturbericht = B81; Pearson = hP4; Space group = P63/mmc (194); [J]
epsilon-AlCu, NiBi, CoS(jaipurite), (Fe,Ni)S-pyrrhotite are stable

53. FTlite-B82
B82;Prototype-InNi2 Strukturbericht = B82; Pearson = hP6; Space group = P63/mmc (194);
"Co1.75Ge"-type InNi2, SnTi2, FeSb-epsilon, "Co3Sn2", "Fe5Sn3", theta-Ni2Si and beta-BiMn stable

54. FTlite-Bb 1
Bb;Prototype-AgZn Strukturbericht = Bb; Pearson = hP9; Space group = P-3 (147);
eta-AgZn (also called Beta-prime)

55. FTlite-Beta
Beta;Prototype-Mg28Al45 Pearson = cF1832; Space group = Fd-3m (227);
"Al3Mg2"

56. FTlite-Bg 1
Bg;Prototype-MoB Strukturbericht = Bg; Pearson = tI16; Space group = I41/amd (141);
alpha-MoB and alpha-WB are stable

57. FTlite-Bk 1
Bk;Prototype-BN Strukturbericht = Bk; Pearson = hP4; Space group = P63/mmc (194);
alpha-BN is stable

58. FTlite-bRho
bRHOM;Prototype-B Pearson = hR105 (hR423); Space group = R-3m (166);
Rhombohedral-boron(beta)

59. FTlite-B_nS
B_nSI
B-Si binary phase between ca. 94 to 99 at.% B. Stable to ca. 2298 K.

60. FTlite-C1 1
C1;Prototype-CaF2 (fluorite) Strukrturbericht = C1; Pearson = cF12; Space group = Fm-3m (225); [I]
delta-HfH2, TiH2 and delta-ZrH2 are stable

61. FTlite-C11b
C11b;Prototype-MoSi2 Strukturbericht = C11b; Pearson = tI6; Space group = I4/mmm (139); [I]
AlCr2, MoSi2, AgTi2, CuTi2, ZnTi2, AgZr2, CuZr2, PdTi2, ScAg2, ScCu2, TiPd2 are stable

62. FTlite-C12
C12;Prototype-CaSi2 Strukturbericht = C12; Pearson = hR6; Space group = R-3m (166);
CaSi2 dissolving CaAl2

63. FTlite-C14
C14;Prototype-MgZn2 (Laves) Strukturbericht = C14; Pearson = hP12; Space group = P63/mmc (194); [I-!5]
Al2Zr,CaLi2,Cr2(Ti,Zr),Fe2Sc,Fe2Ti,Mg2(Ca,Sr,Ba),Mg2RE(RE = Y,Tb,Dy,Ho,Er,Tm,Yb,Lu) are stable phases

64. FTlite-C15
C15;Prototype-MgCu2 (Laves) Strukturbericht = C15; Pearson = cF24; Space group = Fd-3m (227); [I-!5]
Al2Ca, Al2Sc, Al2Y, Al2Ba, Al2RE (RE=La to Lu), Cr2Nb, Co2Hf, Co2Ta, Co2Zr, Mn2Y, Mg2RE & Fe2RE(RE = La,Ce,Pr,Nd,Sm,Gd)

65. FTlite-C15a
C15a;Prototype-MgCu2 (Laves) Strukturbericht = C15; Pearson = cF24; Space group = Fd-3m (227); [I]
Ag2Na is stable;

66. FTlite-C15b
C15b;Prototype-MgSnCu4 (Laves) Strukturbericht = C15; Pearson = cF24; Space group = F-43m (216);
Ni5Zr Stable to ca. 1590 K

67. FTlite-C16
C16;Prototype-Al2Cu Strukturbericht = C16; Pearson = tI12; Space group = I4/mcm (140); [I] CoSn2, FeSn2, MnSn2, NiTa2, C
theta-Al2Cu, Co2B, Fe2B, Mn2B, Mo2B, Ni2B, Ta2B, W2B, Zr2Fe, Ta2Si, Zr2Si and Zr2Ni are stable

68. FTlite-C19
C19;Prototype-Sm Strukturbericht = C19; Pearson = hR3; Space group = R-3m (166);
alpha-Sm is stable

69. FTlite-C1a
aC1;Prototype-CaF2 (antifluorite) Strukturbericht = C1; Pearson = cF12; Space group = Fm-3m (225); [J]
Mg2Si, Mg2Sn, Mg2Ge, Mg2Pb, CoSi2, NiSi2, Al2Au, beta-Ni3S2 are stable

70. FTlite-C22
C22;Prototype-Fe2P Strukturbericht = C22; Pearson = hP9; Space group = P-62m (189);
Fe2P, Mn2P, Ni2P and FeNiP are stable

71. FTlite-C23
C23;Prototype-PbCl2 (cotunnite) Strukturbericht = C23; Pearson = oP12; Space group = Pnma (62); [I]
alpha-BaH2, CaH2 and alpha-SrH2 are stable

72. FTlite-C23a
C23;Prototype-Co2Si Strukturbericht = C23/C37; Pearson = oP12; Space group = Pnma (62); [I]
Co2Si, AlRE2 (RE=Pr,Nd,Sm,Gd,Tb,Dy,Ho,Er), CuCa2, PbCa2, SnCa2, SnSr2, Sr2Si, Ca2Si, Ni2Si are stable

73. FTlite-C32
C32;Prototype-AlB2 Strukturbericht = C32; Pearson = hP3; Space group = P6/mmm (191); [I]
AlB2, CrB2, HfB2, MgB2, MnB2, NbB2, TiB2, VB2 & ZrB2 are stable

74. FTlite-C32o
C32o;Prototype-AlB2 Strukturbericht = C32; Pearson = hP3; Space group = P6/mmm (191); [I]
RESi2, RE2Si3 and RE3Si5 stoichiometry (o = ordered)

75. FTlite-C36
C36;Prototype-MgNi2 (Laves) Strukturbericht = C36; Pearson = hP24; Space group = P63/mmc (194); [I]
Al2Ba, (Al,Mg)2Ca, Al2Sr, Co2Ta, Cr2Zr, Cu2Mg, Mg2Ba, MgNi2, Mg2Sr, MgZn2 are stable

76. FTlite-C38
C38;Prototype-Cu2Sb Strukturbericht = C38; Pearson = tP6; Space group = P4/nmm (129);
Cu2As and Cu2Sb are stable

77. FTlite-C40
C40;Prototype-CrSi2 Strukturbericht = C40; Pearson = hP9; Space group = P6222 (180);
CrSi2, NbSi2, TaSi2, VSi2, WSi2 are stable (Al,Ti solubility); Al2W is stable HT

78. FTlite-C42
C42;Prototype-CeCu2 Strukturbericht = C42; Pearson = oI12; Space group = Imma (72); [I]
Al2Sr, REZn2, (Al,Mg,Zn,Cu,Ag)2{Ca,Sr,Ba} and (Mg,Zn)2{Ce,Dy,Eu,Er,Gd,Ho,La,Lu,Nd,Pm,Pr,Sc,Sm,Tb,Tm,Y,Yb}

79. FTlite-C49
C49;Prototype-ZrSi2 Strukturbericht = C49; Pearson = oC12; Space group = Cmcm (63); [I]
HfSi2 and ZrSi2 are stable; RESn2 (RE = heavy rare-earth) are stable

80. FTlite-C54
C54;Prototype-TiSi2 Strukturbericht = C54; Pearson = oF24; Space group = Fddd (70); [I]
Si2Ti (dissolving Cr, Al, Zr), RuAl2 and ZrSn2 are stable

81. FTlite-Ca 1
Ca;Prototype-NiMg2 Strukturbericht = Ca; Pearson = hP18; Space group = P6222 (180)
NiMg2 with Cu solubility

82. FTlite-Cb 1
Cb;Prototype-CuMg2 Strukturbericht = Cb; Pearson = oF48; Space group = Fddd (70); [I]
CuMg2 (with Ni and Li solubility), BCr2, BMn2, NbSn2 and VSn2 are stable;

83. FTlite-Cc 1
Cc;Prototype-ThSi2 Strukturbericht = Cc; Pearson = tI12; Space group = I41/amd (141); [I]
RESi2, "RE5Si9" and RE3Si5 stoichiometry

84. FTlite-cF16
Tao3;Prototype-MnCu2Al Pearson = cF16 (ordered); Space group = Fm-3m (225);
REMg(Mg,Zn)2

85. FTlite-cF96
cF96;Prototype-Ti2Ni Pearson = cF96; Space group = Fd-3m (227); [I-!5]
Ti2Co, Ti2Ni and Hf2Co are stable

86. FTlite-cI26
cI26;Prototype-Al12W Pearson = cI26; Space group = Im-3 (204);
Al12Mn, Al12Mo, Al12W, Al12Re are stable (with Fe and Ru solubility)

87. FTlite-cP5
cP5;Prototype-Fe4N Pearson = cP5; Space group = Pm-3m (221); [I]
Fe4N, Co4N and Mn4N are stable (Co,Cr,Ni dissolution and C substitution).

88. FTlite-cP60
cP60;Prototype-Ba8Ga7 Pearson = cP60; Space group = P213 (198);
Al7Sr8 is stable;

89. FTlite-D011
D011;Prototype-Fe3C (cementite) Strukturbericht = D011/D020; Pearson = oP16; Space group = Pnma (62); [I]
M3C-cementite Fe3C, Mn3C, Co3B, Ni3B, Al3Ni, RE3Ni and Ni3Si are stable (Co,Cr,Nb,N,Ni,W solubility)

90. FTlite-D018
D018;Prototype-Na3As Strukturbericht = D018; Pearson = hP8; Space group = P63/mmc (194);
Na3As, Na3Bi, Na3P, Na3Sb, Rb3Bi are stable;

91. FTlite-D019
D019;Prototype-Ni3Sn Strukturbericht = D019; Pearson = hP8; Space group = P63/mmc (194); [I]
Ni3Sn(LT), Ti3Sn, M3Al (M=Mo,Nb,Ta,Ti,Zr), RE3Al (RE=La,Ce,Pr,Nd) & Al3RE (RE=Y,La,Ce,Pr,Nd,Sm,Gd), Co3W are stable

92. FTlite-D021
D021;Prototype-Cu3P Strukturbericht = D021; Pearson = hP24; Space group = P63cm (185); [I]
Cu3P, K3Bi are stable

93. FTlite-D022
D022;Prototype-TiAl3 Strukturbericht = D022; Pearson = tI8; Space group = I4/mmm (139); [I]
Al3Cr, Al3Hf, Al3Mo, Al3Nb, Al3Ta, Al3Ti, Al3V and Ni3V are stable

94. FTlite-D023
D023;Prototype-ZrAl3 Strukturbericht = D023; Pearson = tI16; Space group = I4/mmm (139); [I]
Al3Zr and Al3Hf(HT) with soluble Ti, Cr, V

95. FTlite-D024
D024;Prototype-Ni3Ti Strukturbericht = D024; Pearson = hP16; Space group = P63/mmc (194); [I]
Ni3Ti and Al3Dy are stable

96. FTlite-D03
D03;Prototype-BiF3 Strukturbericht = D03; Pearson = cF16; Space group = Fm-3m (225); [I]
beta-Ni3Sn(ht), M3RE (M = Mg,Zn, RE = Ce,La,Pr,Nd,Sm,Gd,Tb,Dy,Lu,Tm), Mn3Si, gamma-Cu3Sn, Cu3Sb(ht)

97. FTlite-D03a
D03a;Prototype-BiF3 Strukturbericht = D03a; Pearson = cF16; Space group = Fm-3m (225); [I]
Fe3Al & Fe3Si are stable

98. FTlite-D03b
D03b;Prototype-BiF3 Strukturbericht = D03b; Pearson = cF16; Space group = Fm-3m (225);
Li2MgSn

99. FTlite-D0a
D0a;Prototype-Cu3Ti Strukturbericht = D0a; Pearson = oP8; Space group = Pmmn (59);
Ag3Sn, Ni3Mo, Ni3Nb and Ni3Ta are stable

100. FTlite-D13
D13;Prototype-Al4Ba Strukturbericht = D13; Pearson = tI10; Space group = I4/mmm (139); [I]
Al4Ca, Al4Sr, Al4Ba, Al4Eu with Mg, Si and Zn solubility

101. FTlite-D13a
D13a;Al2CaZn2 ordered D13 Pearson = tI10; Space group = I4/mmm (139); [I]
Al2CaZn2, Al2REZn2 (RE = La,Ce,Pr,Nd) are stable

102. FTlite-D13b
D13b;Prototype-Al4Ba Strukturbericht = D13b; Pearson = tI10; Space group = I4/mmc (139);
Al11La3, Al11Ce3, Al11Pr3, Al11Nd3 and Al11Sm3 are stable phases.

103. FTlite-D13c
D13c;Prototype-BaNiSn3 Strukturbericht = D13c; Pearson = tI10; Space group = I4/mmc (139);
Ordered Al4Ba structure for Al3CuY, Al3CuLa and Al3CuCe

104. FTlite-D1a
D1a;Prototype-MoNi4 Strukturbericht = D1a; Pearson = tI10; Space group = I4/m (87);
MoNi4, WNi4, Ag4Sc and Cu4Sc are stable

105. FTlite-D1g
D1g;Prototype-B4C Strukturbericht = D1g; Pearson = hR15; Space group = R-3m (166); [I]
B4C

106. FTlite-D21
D21;Prototype-CaB6 Strukturbericht = D21; Pearson = cP7; Space group = Pm-3m (221);
CaB6, SrB6 and BaB6 are stable

107. FTlite-D22
V;Prototype-Mg2Zn11 Strukturbericht = D22; Pearson = cP39; Space group = Pm-3 (200)
Mg2Zn11(V-phase) and Mg2Cu6Al5 are stable compounds

108. FTlite-D23
D23;Prototype-NaZn13 Strukturbericht = D23; Pearson = cF112; Space group = Fm-3c (226); [I]
XZn13 (X = Na,Ca,Sr,Ba,La,Eu) with Mg solubility Re8Zn8Zn96(full

109. FTlite-D2b
D2b;Prototype-Mn12Th Strukturbericht = D2b; Pearson = tI26; Space group = I4/mmm (139);
Mg12RE, Mn12RE, Zn12RE, Al8Cr4RE

110. FTlite-D2d
D2d;Prototype-CaCu5 Strukturbericht = D2d; Pearson = hP6; Space group = P6/mmm (191); [I]
Zn5RE (RE=Ce,La,Eu) CaZn5, CaCu5, SrZn5, SrCu5, SrAg5 and BaAg5 are stable ReZn2Zn

111. FTlite-D2h
D2h;Prototype-Al6Mn Strukturbericht = D2h; Pearson = oC28; Space group = Cmcm (63);
Al6Mn, Al6Ru and Al6Re are stable (with solubility of Fe and Zn)

112. FTlite-D513
D513;Prototype-Al3Ni2 Strukturbericht = D513; Pearson = hP5; Space group = P-3m1 (164);
Al-Ni phase at ca. 60-65 at.% Al. Stable to 1406 K

113. FTlite-D5a
D5a;Prototype-Si2U3 Strukturbericht = D5a; Pearson = tP10; Space group = P4/mbm (127);
RE3Si2 (RE=La,Ce), Si2Sc2Al, Si2Hf3, Si2Zr3 are stable

114. FTlite-D71
D71;Prototype-Al4C3 Strukturbericht = D71; Pearson = hR21; Space group = R-3m (166);
Al4C3 dissolving SiC

115. FTlite-D73a
D73a;Prototype-Th3P4 Strukturbericht = D73 (anti); Pearson = cI28; Space group = I-43d (220);
RE4Sb3 (RE = Ce,Nd,Pr,Sm) are stable

116. FTlite-D7b
D7b;Prototype-Ta3B4 Strukturbericht = D7b; Pearson = oI14; Space group = Immm (71);
Cr3B4, Hf3B4, Mn3B4, Nb3B4 and Ti3B4 are stable

117. FTlite-D810
D810;Prototype-Al8Cr5 Strukturbericht = D810; Pearson = hR26; Space group = R3m (160);
Al8Mn5 with Cu and Fe solubility

118. FTlite-D82
gamma-brass;Prototype-Cu5Zn8 Strukturbericht = D82; Pearson = cI52; Space group = I-43m (217); [I-!5]
Al8Fe5, (Ag,Cu,Fe)5Zn8, gamma-AlCu(HT), Fe5Zn8-gamma are stable

119. FTlite-D83
D83;Prototype-Cu9Al4 Strukturbericht = D83; Pearson = cP52; Space group = P-43m (215); [I]
gamma-Cu9Al4(low-T), Co4Zn9 and "InAg2" are stable

120. FTlite-D84
D84;Prototype-Cr23C6 Strukturbericht = D84; Pearson = cF116; Space group = Fm-3m (225); Cr(4a)Cr(8c)C
Cr23C6 and Mn23C6 are stable (with Co,Fe,Mo,Nb,Ni,Ta,V,W substitution); Ni20Al3B6-tau is stable

121. FTlite-D85
Mu;Prototype-Fe7W6 Strukturbericht = D85; Pearson = hR13; Space group R-3m (166); [I-!5]
Frank-Kasper phase in Co-Fe-Mo-Nb-Ni-W+(Cr,Mn,Ta,Ti) typically around A7B6 stoich.

122. FTlite-D86
D86;Prototype-Cu15Si4 Strukturbericht = D86; Pearson = cI76; Space group = I-43m (217);
epsilon-Cu15Si4 with Al and Ni solubility

123. FTlite-D88
D88;Prototype-Mn5Si3 Strukturbericht = D88; Pearson = hP16; Space group = P63/mcm (193); [I-!5]
(Si,Sn,Ti)3(Cr,Fe,Mn,Nb,RE,Ta,Ti,V,Zr)3(Cr,Fe,Mn,Nb,RE,Ta,Ti,V,Zr)2(Va,Si,Al,B,C,N)1

124. FTlite-D88b
D88b;Prototype-Mn5Si3 Strukturbericht = D88; Pearson = hP16; Space group = P63/mcm (193); [I-!5]
Sb3RE5

125. FTlite-D8a
D8a;Prototype-Mn23Th6 Strukturbericht = D8a; Pearson = cF116; Space group = Fm-3m (225); [I]
Mn23RE6, Fe23RE6, (Mg,Li)23Sr6, Co23Hf6, Co23Zr6 are stable; 32f/32f/2

126. FTlite-D8b
Sigma;Prototype-FeCr Strukturbericht = D8b; Pearson = tP30; Space group = P42/mnm (136); [I-!5]
A8B4C18 intermetallic in Al-Nb-Ta-(Ti) and Co-Cr-Fe-Mn-Mo-Ni-V-(W)

127. FTlite-D8d
D8d;Prototype-Al9Co2 Strukturbericht = D8d; Pearson = mP22; Space group = P21/c (14);
Al9Co2 with Cr, Fe, Ni solubility

128. FTlite-D8e
Tau;Prototype-Mg32(Al,Zn)49 Strukturbericht = D8e; Pearson = cI162; Space group = Im-3 (204);
Al-Mg-Zn-Cu-Ag phase: (Mg)26(Al,Mg)6(Ag,Al,Cu,Mg,Zn)12(Al,Zn)36(Al)1

129. FTlite-D8g
D8g;Prototype-Ga2Mg5 Strukturbericht = D8g; Pearson = oI28; Space group = Ibam (72);
Mg5Ga2, Mg5In2 and Mg5Tl2 are stable

130. FTlite-D8h
D8h;Prototype-B2W Strukturbericht = D8h; Pearson = hP12; Space group = P63/mmc (194);
Also called W2B5

131. FTlite-D8l
D81;Prototype-Cr5B3 Strukturbericht = D8l; Pearson = tI32; Space group = I4/mcm (140);
RE5Si3 (RE=La,Ce,Pr,Nd), Ca5Ag3, Ca5Zn3, Ca5Si3, Ca5Sn3, Sr5Pb3, Sr5Sn3 are stable

132. FTlite-D8m
D8m;Prototype-W5Si3 Strukturbericht = D8m; Pearson = tI32; Space group = I4/mcm (140); [I]
(Cr,Mo,Nb,V,W)5Si3 with Fe, Si and Ti solubility & (La,Ce,Pr)5Sn3 are stable;

133. FTlite-Dlta
AlCu_delta Al2Cu3 Pearson = hR*; Space group = R-3m (166);
delta-Al2Cu3 phase containing 60 at.% Cu in Al-Cu with solubility for Zn. Stable to ca. 1233 K.

134. FTlite-E 12
E;Prototype-CeCr2Al20 Pearson = cF184; Space group = Fd-3m (227); [I]
Zn22Zr, Al10V, CeCr2Al20, RECr2Al20, CaCr2Al20, Mg3Cr2Al18

135. FTlite-E1a
E1a;Prototype-Re3B Strukturbericht = E1a; Pearson = oC16; Space group = Cmcm (63); [I]
CoZr3, FeZr3 are stable; (also ZnCa3)

136. FTlite-E21
kappa;Prototype-CaTiO3 Strukturbericht = E21; Pearson = cP5; Space group = Pm-3m (221);
kappa carbide (Fe,Mn)3(Al,Fe,Mn)(C,Va), Fe3AlC, Mn3AlC, Ti3AlC are stable

137. FTlite-E93
eta;Prototype-Fe3W3C Strukturbericht = E93; Pearson = cF112; Space group = Fd-3m (227);
A2B4C, A4B2C and A3B3C carbides in the C-Co-Fe-Mo-Nb-Ni-Si-Ta-V-W system

138. FTlite-E94
E94;Prototype-Al5C3N Strukturbericht = E94; Pearson = hP18; Space group = P63mc (186); [I]
Al4Sic4 and Al5C3N are stable and form a solution.

139. FTlite-E9a
E9a;Prototype-Al7Cu2Fe Strukturbericht = E9a; Pearson = tP40; Space group = P4/mnc (128); [I]
Al7Cu(Cu,Fe,Mn,Zr)1(Mn,Fe,Zr)1 Al7Cu2Fe, Al7CuMn2 and "Al43Cu10Zr11-tau9" are stable

140. FTlite-Eta
Eta;Prototype-Al5Fe2 Pearson = oS24; Space group = Cmcm (63);
Phase at ca. 71.5 at.% Al in Al-Fe. Solubility for Mn and Zn.

141. FTlite-EtaH
eta1;Prototype-AlCu Pearson = oC16; Space group = Cmmm (65);
Al-Cu phase at ca. 50 at.% Cu with solubility for Zn. Stable 560-624oC

142. FTlite-FeZ2
FeZn-delta1 Pearson = hP556; Space group = P63/mmc (194);
'FeZn7'

143. FTlite-Fm53
I;REZn6Mg3 Fm53
Icosahedral

144. FTlite-Gam1
FeZn-Gamma-1 brass cF408 F-43m
Fe-Zn binary phase at ca. 74-78 at.% Zn. Stable to ca. 820 K.

145. FTlite-Gam5
gamma;Prototype-AlCu High-temperature Al-Cu phase at 62-69 at.% Cu with solubility for Zn.
Stable between ca. 1073 and 1273 K.

146. FTlite-gam8
gamma-ortho Pearson = oP*; Space group = Pban (50);
Co11(Hf,Zr)2 stable;

147. FTlite-hex5
hP142;Prototype-Cd58Gd13 Pearson = hP142; Space group = P63mc (186);
RE13Zn58

148. FTlite-hP12
eta-MoC Pearson = hP12; Space group = P63/mmc (194);
Mo(C)0.67 approx. compo. (high-T only) (Mo,W)C with carbon vacancies and vanadium substitution

149. FTlite-hP26
AlMnSi_beta Pearson = hP26; Space group = P63/mmc (194);
~Al9Mn3Si

150. FTlite-hP3
hP3;Prototype-AlB2 Pearson = hP3; Space group = P6/mmm (191); [I]
(Ca,Sr)[Al,Si]2 (not present in Ca-Al and Ca-Si subsystems) ordered ternary solid solution

151. FTlite-hP36
hP36;Prototype-ErZn5 Pearson = hP36; Space group = P63/mmc (194);
Zn5RE (RE=Er,Ho,Lu,Tm,Y) are stable

152. FTlite-hP38
hP38;Prototype-Ni17Th2 Pearson = hP38; Space group = P63/mmc (194);
(Mg,Zn,Al,Fe)17{RE,Sr,Ca}2: Mg17Ce2, Mg17Sr2, Mg17La2, Mg17Eu, Zn17RE2 stable.

153. FTlite-hP3_
CuZn_delta CuZn3(h) Pearson = hP3; Space group = P-6 (187);
delta-CuZn3 phase containing 70-76 at.% Cu in Cu-Zn. Stable between 560-700oC

154. FTlite-hP5
hP5;Prototype-Ce2SO2 Pearson = hP5; Space group = P-3m1 (164);
CaAl2Si2 and SrAl2Si2 are stable;

155. FTlite-hP6
hP6;Prototype-Ni2Al Pearson = hP6; Space group = P-3m1 (164);
Ni2Al and Fe2Si are stable;

156. FTlite-hP8
hP8;Prototype-BaCu Pearson = hP8; Space group = P63/mmc (194);
BaCu, SrCu are stable

157. FTlite-hP8*
hP8;Prototype-LiB Pearson = hP8; Space group = P63/mmc (194);
LiB is stable

158. FTlite-hP8_
hP8;Prototype-TbCu7 Pearson = hP8; Space group = P6/mmm (191);
Cu6Y phase at ca. 86 at.% Cu. Stable to ca. 1183 K.

159. FTlite-hP94
hP94;Prototype-Mg38Sr9 Pearson = hP94; Space group = P63/mmc (194);
Mg38Sr9 dissolving Al and Ca

160. FTlite-hP_G
AgMg4;gamma_hp hexagonal
AgMg4 with Sn and In solubility

161. FTlite-hR12
hR12;Prototype-Ni3Pu; Pearson = hR12; Space group = R-3m (166);
Fe3RE (RE = Y,Sm,Tb,Dy,Er,Tm,Lu), Ni3Y are stable;

162. FTlite-hR21
hR21;Prototype-Sn4P3 Pearson = hR21; Space group = R-3m (166);
V4C3-x with carbon deficit as "V4C2.65" (or V3C2)

163. FTlite-hR3
hR3;Prototype-"SbSn" Pearson = hR3; Space group = R-3m (166); [I]
"SbSn" with solubility for Pb, Bi

164. FTlite-hR36
hR36;Prototype-Be3Nb Pearson = hR36; Space group = R-3m (166);
Fe3RE (RE = Gd,Ho)

165. FTlite-hR48
hR48;Prototype-Mg3In Pearson = hR48; Space group = R-3m (166); [I]
MgIn3

166. FTlite-hR57
hR57;Prototype-Th2Zn17 Pearson = hR57; Space group = R-3m (166);
Zn17RE2 (RE=all rare-earths except Sc and Eu) + Fe17RE2 (RE=Pr,Sm,Gd)

167. FTlite-hR60
hR60;Prototype-HoAl3 Pearson = hR60; Space group = R-3m (166);
Al3Ho and Al3Dy are stable end-members

168. FTlite-HSig
High_Sigma [I]
A sigma variant formed between Cr and Mn

169. FTlite-Ia3
beta_Mg3X2(high-T) Ia3 solid solution (Mg)3[Mg,Va]1{Bi,Sb,As}2

170. FTlite-IM1
IM1-CaMgZn Pearson = hP36; Space group = P63/mmc (194); {Ca}[Mg,Zn](Mg,Zn)4

171. FTlite-L'2
L'2;Prototype-TiH2 Strukturbericht = L'2; Pearson = tI6; Space group = I4/mmm (139);
TiH2(lt), ZrH2 are stable

172. FTlite-L10
L10;Prototype-AuCu Strukturbericht = L10; Pearson = tP2; Space group = P4/mmm (123); [I]
AlTi is stable

173. FTlite-L10a
L10a;Prototype-AuCu Strukturbericht = L10a; Pearson = tP2; Space group = P4/mmm (123); [I]
InMg ordered FCC

174. FTlite-L12
L12;Prototype-AuCu3 Strukturbericht = L12; Pearson = cP4; Space group = Pm-3m (221); [I]
Al3Er, Al3Sc, Al3Tm, Al3Yb, Pt3Ti, most Sn3RE & Pb3RE are stable (metastable: Cr,Cu,Li,Mg,Ti,V,Zr,...)

175. FTlite-L12b
L12b;Prototype-AuCu3 Strukturbericht = L12; Pearson = cP4; Space group = Pm-3m (221);
AlSc3, AlCe3, AlPr3, SnCe3 and SnPr3 are stable

176. FTlite-L12c
L12-FCC!FCC-A1 Strukturbericht = L12; Pearson = cP4; Space group = Pm-3m (221); [I]
Ordered FCC phase in Al-Ni, Fe-Ni and Ni-Si

177. FTlite-L12d
L12d;Prototype-AuCu3 Strukturbericht = L12; Pearson = cP4; Space group = Pm-3m (221); [I]
MgIn3, InMg3 and Ag3In are stable

178. FTlite-L12e
FCC-L12!FCC-A1 Prototype-AuCu3 Strukturbericht = L12; Pearson = cP4; Space group = Pm-3m (221); [I]
Ag3Mg with solubility of In

179. FTlite-L17X
cF420;Prototype-Li17Pb4 Pearson = cF420; Spac group = F-43m (216);
(Li,Mg)17Sn4 solid solution

180. FTlite-L21
Heusler;Prototype-AlCu2Mn Strukturbericht = L21; Pearson = cF16; Space group = Fm-3m (225); [I]
AlCu2Mn, AlNi2Hf, AlNi2Ti are stable

181. FTlite-L2A
Prototype-Li2Ag
Li2Ag: (Ag,Li)1(Ag,Li)2

182. FTlite-L3A
Prototype-Li3Ag
Li3Ag: (Li,Ag)1(Li)3

183. FTlite-L6A
Prototype-Li6Ag
Li6Ag: (Li,Ag)1(Li)6

184. FTlite-Li2Z
Zn3Li2 Space group = P-3m (164);
High-temperature allotropic form of low-temperature stoichiometric Zn3Li2

185. FTlite-Liqu
Liquid metal [I]

186. FTlite-m102
mC102;Prototype-Al13Fe4 Pearson = mC102; Space group = C2/m (12);
Al13Co4, Al13Fe4('Al3Fe') and Al13Ru4 are stable, with solubility for Mn, Ni, Si, V and Zn.

187. FTlite-m110
Mg2Zn3 Pearson = mC110; Space group = C2/m (12);
Mg-Zn phase at ca. 60 at.% Zn with solubility for Al and Cu. Stable to 689 K.

188. FTlite-mC18
mC18;Prototype-Ni7Zr2 Pearson = mC18; Space group = C2/m (12);
Co7Nb2, Ni7Zr2 are stable;

189. FTlite-mC28
mC28;Prototype-Zn13Co Pearson = mC28; Space group = C12/m1 (12); [I]
gamma2-CoZn13 and zeta-FeZn13 are stable;

190. FTlite-mC52
AlFeSi_beta (Tau 6) Pearson = mC52; Space group = C2/c (15);
approx. stoichiometry Al9Fe2Si2 or Al14Fe3Si3. Looks usually like plates or acicular in Al-Fe-Si alloys

191. FTlite-Mg3X
Mg3Sb2(low-T) alpha dissolving Sn and Si

192. FTlite-Mg5X
cF448;Prototype-Mg5Gd Pearson = cF448; Space group = F-43m (216);
Mg5Sm and Mg5Gd are stable phases.

193. FTlite-MgCZ
Mg3Ce2Zn3

194. FTlite-MgZn
Mg12Zn13
Mg-Zn phase at ca. 50 at.% Zn with solubility for Al and Cu. Stable to ca. 620 K.

195. FTlite-mP12
mP12;Prototype-CuP2 Pearson = mP12; Space group = P21/c (14);
AgP2 and CuP2 are stable;

196. FTlite-mS14
mS14;Prototype-Ni3Sn4 Pearson = mS14; Space group = C2/m (12)
Phase at ca.44 at.% Ni in the Ni-Sn system, with solubility for Cu

197. FTlite-mS20
eta2;Prototype-AlCu Pearson = mS20; Space group = C2/m (12);
AlCu-eta(LT) and theta-CuIn ('Cu11In9') are stable

198. FTlite-mS24
mS24;Prototype-SiAs Pearson = mS24; Space group = C2/m (12);
GeAs2 and SiAs2 are stable

199. FTlite-mS28
Hägg;Prototype-Mn5C2 Pearson = mS28; Space group = C2/c (15); structure: Fe1(8f)Fe
chi-Fe5C2 (metastable) with Mn and V substitution

200. FTlite-mS54
mS54;Prototype-Al14Ca13 Pearson = mS54; Space group = C2/m (12);
Al14Ca13 with Zn solubility

201. FTlite-NCL1
tP20;Prototype-Mn11Si19 Pearson = tP20; Space group = P-4n2 (118);
Nowotny chimney ladder (NCL1) phase

202. FTlite-Ni3M
Ni3Ta
Phase at ca. 75 at.% Ni, exists in Mo-Ni and Ni-Ta.

203. FTlite-oC16
oC16;Prototype-AlCe Pearson = oC16; Space group = Cmcm (63);
AlLa and AlCe are stable phases

204. FTlite-oC20
oC20;Prototype-V2B3 Pearson = oC20; Space group = Cmcm (63);
Nb2B3 and V2B3 are stable

205. FTlite-oC52
oC52;Prototype-YbFe2Al10 Pearson = oC52; Space group = Cmcm (63);
REFe2Al10 (RE=Y,La,Ce,Nd,Pr,Sm,Gd,Tb,Dy,Ho,Er,Tm,Yb,Lu)

206. FTlite-oF40
oF40;Prototype-Al3Zr2 Pearson = oF40; Space group = Fdd2 (51);
Al3Hf2 and Al3Zr2 are stable

207. FTlite-oI12
oI12;Prototype-GdSi2 Pearson = oI12; Space group = Imma (74); [I]
RESi2, "RE5Si9" and RE3Si5 stoichiometry

208. FTlite-oI28
oI28;Prototype-Al11La3 Pearson = oI28; Space group = Immm (71);
Al11La3(lt), Al11Ce3, Al11Pr3, Al11Nd3 and several Zn11RE3 are stable phases.

209. FTlite-oI44
oI44;Prototype-Ti6Sn5 Pearson = oI44; Space group = Immm (71);
Ti6Sn5 and Nb6Sn5 are stable

210. FTlite-oI6
oI6;Prototype-MoPt2 Pearson = oI6; Space group = Immm (71);
CrNi2, MoNi2, VNi2 are stable;

211. FTlite-oP12
oP12;Prototype-TiNiSi Pearson = oP12; Space group = Pnma (62);
CaMgSi excess Ca2Si

212. FTlite-oP16
oP16;Prototype-AlEr Pearson = oP16; Space group = Pmma (57);
AlPr, AlNd, AlSm, AlGd, AlTb, AlDy, AlHo and AlEr are stable phases.

213. FTlite-oP20
oP20;Prototype-ZrAu4 Pearson = oP20; Space group = Pnma (62);
beta'-Cu4Ti stable to 1158 K.

214. FTlite-oP24
oP24;Prototype-GeAs2 Pearson = oP24; Space group = Pbam (55);
GeAs2 and SiAs2 are stable

215. FTlite-oP36
oP36;Prototype-Sm5Ge4 Pearson = oP36; Space group = Pnma (62); [I-!5]
RE5Si4 and RE5Sn4 are stable;

216. FTlite-oS12
oS12;Prototype-ZrGa2 Pearson = oS12; Space group = Cmmm (65);
PrSn2, NdSn2 and SmSn2 are stable

217. FTlite-oS16
oS16;Prototype-GdSn3 Pearson = oS16; Space group = Amm2 (38);
YSn3-alpha, GdSn3-alpha, HoSn3-alpha, ErSn3-alpha, TmSn3-alpha are stable

218. FTlite-oS20
oS20;Prototype-LaZn4 Pearson = oS20; Space group = Cmcm (63);
La(Mg,Zn)4

219. FTlite-oS24
oS24;Prototype-SmSb2 Pearson = oS24; Space group = Cmca (64);
RESb2(RE = Ce,Nd,Pr,Sm) are stable

220. FTlite-oS28
oS28;Prototype-Tb3Sn7 Pearson = oS28; Space group = Cmmm (65);
Tb3Sn7-alpha, Pr3Sn7, Sm3Sn7 and Dy3Sn7-alpha are stable

221. FTlite-oS32
oS32;Prototype-Pu3Pd5 Pearson = oS32; Space group = Cmcm (63);
RE3Sn5 (RE=La,Ce,Pr,Nd) are stable;

222. FTlite-oS36
oS36;Prototype-Li7Ge2 Pearson = oS36; Space group = Cmmm (65); [I]
Li7Sn2 is stable

223. FTlite-oS48
Luobusaite;Prototype-FeSi2 Pearson = oS48; Space group = Cmca (64);
beta-FeSi2 stable below ~1223K with Al solubility

224. FTlite-oS68
oS68;Prototype-Zr7Ni10 Pearson = oS68; Space group = C2ca (64);
'Ni10Zr7'

225. FTlite-P3m1
alpha_Mg3X2(low-T) P-3m1 solid solution (Mg)3[Mg,Va]1{Bi,Sb,As}2

226. FTlite-Phi
Phi;AlMgZn Pearson = o*; Space group = Pbcm (57);
Phase in the Al-Mg-Zn system with stoichiometry (Mg)6(Al,Zn)5 with solubility for Cu.

227. FTlite-Pmna
oP16;Prototype-YZn3 Pearson = oP16; Space group = Pmna (62);
RE4Zn4Zn4Zn4

228. FTlite-Pnma
U2 Mg4SixAly Orthorhombic Pnma
(METASTABLE PHASE) [-I]

229. FTlite-prB2
pre-B'' 'FCC monoclinic' C2/m
(METASTABLE PHASE) [-J]

230. FTlite-P_6
B' Mg9Si7Al3(Va,Al,Si,Mg,Cu) Hexagonal P_6
(METASTABLE PHASE) [-I]

231. FTlite-Q 12
Q;Prototype-Th7S12 Space group = P63/m (176);
(Q-phase)

232. FTlite-R 12
R;phase
Phase found in high-temperature Ni-based alloys, its formation being promoted by the presence of Mo.

233. FTlite-RedP
Red-Phosphorus amorphous
Red phosphorus with solubility for As

234. FTlite-RZ2L
ReZn2(LT) prototype: unknow

235. FTlite-S 12
S;Prototype-Al2CuMg Pearson = oS16; Space group = Cmcm (63);
Al2CuMg-S is stable; (ordered E1a structure);

236. FTlite-Tao1
Tau;Prototype-Al11La3 Pearson = oI28; Space group = Immm ordered
Ce3Zn9(Mg,Zn)2

237. FTlite-Tao2
Tao2
RE2Zn45Mg53 (RE = Ce,Nd)

238. FTlite-Tao4
Tau4;RE2Zn9Mg5 unknown structure
RE=(Ce,Nd,Dy,Pr,Sm)

239. FTlite-Tao5
Tau5;RE3Zn30Mg13 unknown structure
RE=(Ce,Nd,Dy,Pr,Sm,Y)

240. FTlite-Tao7
Tao7
RE20Zn81Mg19 (RE = Cd,Nd)

241. FTlite-Tau2
AlFeSi_gamma (Tau 2) Monoclinic
approx. stoichiometry Al3FeSi

242. FTlite-Tau5
AlFeSi_alpha (Tau 5) Pearson = hP245; Space group = P63/mmc (194);
approx. stoichiometry Al7Fe2Si; Looks usually like chinese script or rod-like in Al-Fe-Si alloys

243. FTlite-Tau_
AlCuZn_Tau rhombohedral [I]
Al4Cu3Zn phase

244. FTlite-tI12
tI12;Prototype-La2Sb Pearson = tI12; Space group = I4/mmm (139);
RE2Sb (RE = Ce,Nd,Pr,Sm) are stable

245. FTlite-tI18
tI18;Prototype-Pt8Ti Pearson = tI18; Space group = I4/mmm (139);
Ni8(Nb,Ta) are stable

246. FTlite-tI24
tI24;Prototype-HfGa2 Pearson = tI24; Space group = I41/amd (141); [I]
Pb2Pr and Pb2Nd are stable (Al2Mg is metastable)

247. FTlite-tI48
tI48;Prototype-BaCd11 Pearson = tI48; Space group = I41/amd (141);
CaZn11, CeZn11, LaZn11, NdZn11, PrZn11, YbZn11 and Zn11RE (RE=La,Ce,Pr,Nd,Yb) are stable Re4Zn4Zn8Zn32(full

248. FTlite-tI84
tI84;Prototype-Ho11Ge10 Pearson = tI84; Space group = I4/mmm (139); structure = Ho1(
RE11Sn10 are stable; with Ge and Si substitution of Sn; Ho11Ge10, Ce11Ge

249. FTlite-tI92
tI92;Prototype-Mg41Ce5 Pearson = tI92; Space group = I4/m (87);
Mg41RE5 (RE = La,Ce,Pr,Nd,Sm) with Al solubility

250. FTlite-tP20
tP20;Prototype-Al2Zr3 Pearson = tP20; Space group = P42/mnm (136); [I]
Al2Hf3, Al2Zr3, (Al,Mg)2(RE)3 (RE=Y,Gd,Tb,Dy,Ho,Er,Tm,Lu), Li2Sr3, Zn2Zr3 are stable

251. FTlite-tP3
Ferdisilicite;Prototype-FeSi2 Pearson = tP3; Space group = P4/mmm (123);
alpha-FeSi2(ht) stable above ~1223K with stoichiometry near Fe0.92Si2

252. FTlite-tP32
tP32;Prototype-Ti3P Pearson = tP32; Space group = P42/n (86); [I]
M3P (M = Hf, Ta, Ti, V, Zr) and X3Si (X = Nb, Ta, Ti, Zr) are stable

253. FTlite-tP36
tP36;Prototype-Zr5Si4; Pearson = tP36; Space group = P41212 (92);
RE5Si4 (RE=Sc,La,Ce,Pr,Nd,Pm,Sm,Gd), Zr5Si4, Ti5Si4 and Hf5Si4 are stable

254. FTlite-X 12
X;LPSO-18R Long-Period-Stacking-Order Phase
REZnMg12 (RE = Gd,Y,Dy,Tb,Ho,Er,Tm,Lu)

255. FTlite-Z22X
tI100;Prototype-Pu3Zn22 Pearson = tI100; Space group = I41/amd (141);
Zn22RE3 (RE=Ce,Gd,La,Nd,Pm,Pr,Sm) are stable

256. FTlite-Zeta
zeta;Prototype-AlCu Al9Cu11
zeta_Al9Cu11 phase at ca. 55 at.% Cu with solubility for Zn. Stable to ca. 863 K.


List of 1703 Compounds

Ags1-s5,lAg2BasAg2Ba3s
Ag2CasAg2GasAg2Scs
Ag2SrsAg2Sr3sAg3Be8s
Ag3Ca5sAg3Ga2sAg3P11s
Ag3SbsAg4ScsAg4Srs
Ag5BasAg5SrsAg5Sr3s
Ag7Ca2sAg9Ca2sAgBas
AgCasAgCa3sAgCu4Zrs
AgMg4sAgP2sAgScs
AgSrsAgTi2sAgZrs
AgZr2sAls1-s9,lAl10Vs
Al11Cr2sAl11Cu5Mn3sAl11Fe3Si6s
Al11Mn3Zn2sAl11Mn4sAl12Mns
Al12WsAl13Co4sAl13Cr2s
Al13Cr4Si4sAl14Ca13sAl14Fe3Si3s
Al15Cu8Li2sAl18Cr2Mg3sAl18Mg3Mn2s
Al18Mg3Ta2sAl18Mg3Ti2sAl18Mg3V2s
Al18Mg3W2sAl2AusAl2Bas1,s2
Al2Cas1,s2Al2CaZn2sAl2Cus1-s3
Al2Cu3sAl2CuLisAl2CuMgs
Al2FesAl2HfsAl2Hf3s
Al2Lis1,s2Al2Li18Si6sAl2Li3s
Al2Mn2Si3sAl2ScsAl2Srs1,s2
Al2Tis1,s2Al2WsAl2Y3s
Al2ZrsAl2Zr3sAl23CuFe4s
Al23V4sAl3BCsAl3Ca8s
Al3CosAl3Crs1,s2Al3Cus
Al3Cu2sAl3CuCesAl3CuLas
Al3Hfs1,s2Al3Hf2sAl3Hf4s
Al3Lis1-s3Al3Li15Si6sAl3Li7Si4s
Al3MgsAl3MnSi2sAl3Nbs
Al3NisAl3Ni5sAl3Scs
Al3TasAl3Ta2s1,s2Al3Tis1-s3
Al3Vs1-s3Al3Ys1,s2Al3Zrs1-s3
Al3Zr2sAl3Zr5sAl30Mg23s
Al39Cu33Zr6sAl4BasAl4C3s
Al4C4SisAl4CasAl4Ces
Al4CrsAl4FesAl4Li9s
Al4MgYsAl4MnsAl4Srs
Al4WsAl4Zr5sAl5Ba4s
Al5C3NsAl5Co2sAl5Cu2Mg8Si6s
Al5Cu6Mg2sAl5CuLi3sAl5Lis
Al5WsAl53Mg14Li33sAl57Cu11Li32s
Al6FesAl6MnsAl6Ni3Sis
Al69Ta39sAl7Cu2FesAl7Cu2Zrs
Al7Cu3Mg6sAl7CuFe2sAl7CuMn2s
Al7CuZr2sAl7Sr8sAl7Ta5s
Al7VsAl7W3sAl77W23s
Al8C7B4sAl8C7SisAl8Cr5s1,s2
Al8CrYsAl8EuFe2sAl8FeMg3Si6s
Al8Mn4YsAl8V5sAl9Co2s
Al9Co2BasAl9Co2SrsAl9Cr4s1,s2
Al9Cu11sAl9Fe2BasAl9Fe2Srs
Al9Ni2BasAl9Ni2SrsAl99Mn23s
AlAssAlAusAlAu2s
AlAu4sAlB12sAlB2s
AlCa5Zn2sAlCeSi2sAlCos
AlCr2sAlCr2B2sAlCr3B4s
AlCusAlCu3Mn2sAlH3s
AlHfsAlHf2sAlLis1,s2
AlLiSisAlMgsAlMgAgs
AlMgB14sAlNs1-s3AlNaSis
AlPsAlSbsAlScs
AlSc2sAlSc2Si2sAlSn2Zr5s
AlTasAlTi2CsAlTi3Cs
AlYsAlY2sAlZrs1,s2
AlZr2sAlZr3sAss1-s5,l
As2Cu5sAsCu8sAsIns
Aus1,s2,lAu2PbsAu2Tis
Au3InsAu4Zn5sAu5Zn3s
Au7In3sAu8Al3sAuIns
AuIn2sAuSnsAuSn2s
AuSn4sAuTi3sAuZn3s
Bs1-s7,lB4NdsB5Nd2s
B6NdsB66NdsBas1-s3,l
Ba2SisBa2ZnsBa3Si4s
Ba5Si3sBaAl2Si2sBaB6s
BaBe13sBaC2s1,s2BaCus
BaCu13sBaH2s1,s2BaSis
BaSi2sBaZnsBaZn13s
BaZn2sBaZn5sBes1-s3,l
Bis1-s4,lBi2KsBi2K3s
Bi3In5sBi3NisBi4K5s
BiInsBiIn2sBiLis
BiNasBNs1,s2Cs1,s2,l
Cas1-s3,lCa14Si19sCa2Cus
Ca2Mg5Zn13sCa2Mg55Zn43sCa2Ni7s
Ca2PbsCa2SisCa2Sns
Ca3Mg3Zn14sCa3P2sCa3Si4s
Ca3ZnsCa4Al3MgsCa5Pb3s
Ca5Si3sCa5Zn3sCa7Mg6Si14s
CaAl2Si2sCaAlH5sCaB6s
CaBe13sCaC2s1-s4,lCaCr2Al20s
CaCusCaCu5sCaH2s
CaLi2sCaMgSisCaNi2s
CaNi3sCaNi5sCaPbs
CaPb3sCaSisCaSi2s
CaTi2Al20sCaZnsCaZn11s
CaZn13sCaZn2sCaZn3s
CaZn5sCes1-s4,lCe11Sn10s
Ce12Y21Mg67sCe13Zn58sCe2Als
Ce2Co17sCe2Co7sCe2Fe17s
Ce2InsCe2Mg17sCe2Mn3Als
Ce2Mn7Al10sCe2SbsCe2Sn5s
Ce2Zn17s1,s2Ce2Zn45Mg53sCe2Zn9Mg5s
Ce20Zn81Mg19sCe24Co11sCe3Als1,s2
Ce3Al11s1,s2Ce3InsCe3In5s
Ce3Si2sCe3Si5sCe3Sns
Ce3Sn5sCe3Sn7sCe3Zn11s
Ce3Zn22sCe3Zn30Mg13sCe3Zn9Mg2s
Ce4Sb3sCe5Co19sCe5In4s
Ce5Mg41sCe5Si3s1,s2Ce5Si4s1,s2
Ce5Sn3s1,s2Ce5Sn4sCe6Zn83Mg11s
Ce9In11sCeAlsCeAl13Mg6s
CeAl2sCeAl3s1,s2CeCo2s
CeCo3sCeCo5sCeCr2Al20s
CeCr4Al5sCeCusCeCu2s
CeCu4sCeCu4Al8sCeCu5s
CeCu6sCeFe2sCeFe2Al10s
CeIn2sCeIn3sCeMgs
CeMg12sCeMg2sCeMg3s
CeMn4Al8sCeSbsCeSb2s
CeSisCeSi2sCeSn3s
CeTi2Al20sCeV2Al20sCeZns
CeZn11sCeZn12sCeZn2s
CeZn2Al2sCeZn2MgsCeZn3s
CeZn5sCos1-s5,lCo11Hf2s
Co11Zr2sCo16Nb9sCo17Sm2s
Co19Sm5sCo2BsCo2Hfs
Co2NsCo2NbsCo2Sis
Co2SmsCo2Tas1-s3Co2Tis1-s3
Co2ZrsCo23C6sCo23Hf6s
Co23Zr6sCo3BsCo3C2s
Co3NbsCo3SisCo3Sms
Co3TisCo3VsCo3Ws
Co4Sm9sCo4Zn9sCo5Sms
Co6W6CsCo7C3sCo7Nb2s
Co7Sm2sCo7Ta2sCoBs
CoHfsCoHf2sCoIn2s
CoIn3sCoNsCoN3s
CoSisCoSi2sCoSm3s
CoSn2sCoTisCoTi2s
CoV3sCoZn7sCoZrs
CoZr2sCoZr3sCrs1-s5,l
Cr2BsCr2CsCr2Hfs1,s2
Cr2NsCr2PsCr2Tas1,s2
Cr2Tis1,s2Cr2Zrs1-s3Cr23C6s
Cr3B4sCr3CsCr3C2s
Cr3Mn5sCr3PsCr3Sis
Cr5B3sCr5Si3s1-s3Cr7C3s
CrBsCrB2sCrB4s
CrNsCrSisCrSi2s
CrZn13sCrZn17sCus1-s4,l
Cu10Sn3sCu10Zr7sCu12Sn10s
Cu15Si4sCu16Mg6Si7sCu19Si6s
Cu2EusCu2HosCu2Las
Cu2Mgs1-s3Cu2NdsCu2Ps
Cu2PrsCu2SbsCu2Scs
Cu2SmsCu2TisCu2TiZrs
Cu2Ys1,s2Cu2ZrsCu3Ass
Cu3GesCu3Mg2SisCu3Ps1,s2
Cu3Sbs1,s2Cu3Sns1,s2Cu3Ti2s
Cu33Si7sCu37La3sCu4Ins
Cu4LasCu4NdsCu4Prs
Cu4SbsCu4ScsCu4Sms
Cu4SnsCu4Ti3sCu4Ys
Cu5EusCu5Hos1,s2Cu5Las
Cu5NdsCu5PrsCu5Sms
Cu5SrsCu5Zr8sCu51Zr14s
Cu6Las1,s2Cu6NdsCu6Prs
Cu6SbsCu6SmsCu6Sn5s
Cu7Ga2sCu7Ho2sCu7In3s
Cu7In4sCu7Sb2sCu7Y2s
Cu8Zr3sCu9Ho2sCu9Si2s
Cu9Zr2sCuBe2sCuEus
CuEu2sCuHosCuLas
CuNdsCuP2sCuPrs
CuScsCuSmsCuSrs
CuTi2sCuYsCuZrs
CuZr2sDys1-s4,lDy11Sn10s
Dy13Zn58sDy2AlsDy2Al10Mg3s
Dy2Fe17sDy2Zn17s1,s2Dy3Al2s
Dy3Si4sDy3Si5s1,s2Dy3Sn7s1,s2
Dy3Zn11sDy3Zn22sDy5Mg24s
Dy5Si3sDy5Si4sDy5Sn3s1,s2
Dy5Sn4sDy6Fe23sDy6Mn23s
DyAlsDyAl2sDyAl3s1,s2
DyCr2Al20sDyCu4Al8sDyFe2s
DyFe2Al10sDyFe3sDyMgs
DyMg2sDyMg3sDyMn12s
DyMn2sDySisDySi2s1,s2
DySi2Al2sDySn2sDySn3s1,s2
DyTi2Al20sDyV2Al20sDyZns
DyZn11sDyZn12sDyZn2s
DyZn2MgsDyZn3sDyZn5s
DyZn6Mg3sDyZnMg12sErs1-s4,l
Er11Sn10sEr13Zn58sEr2Als
Er2Fe17sEr2Si2Al3sEr2Sn5s
Er2Zn17s1,s2Er3Al2sEr3Al20Mg7s
Er3Si5s1,s2Er3Zn11sEr3Zn22s
Er5Mg24sEr5Si3sEr5Si4s
Er5Sn3sEr5Sn4sEr6Fe23s
Er6Mn23sErAlsErAl2s
ErAl3sErCr2Al20sErCu4Al8s
ErFe2sErFe2Al10sErFe3s
ErMgsErMg2sErMn12s
ErMn2sErSisErSn2s
ErSn3s1,s2ErTi2Al20sErV2Al20s
ErZnsErZn11sErZn12s
ErZn2sErZn2MgsErZn3s
ErZn5sErZn6Mg3sErZnMg12s
Eus1-s3,lEu13Zn58sEu2Mg17s
Eu2Zn17s1,s2Eu3Si5sEu3Zn11s
Eu3Zn22sEu5Si3sEu5Si4s
Eu50Si87sEu8Si11sEuAls
EuAl2sEuAl4sEuCu4Al8s
EuMgsEuMg2sEuMg4s
EuMg5sEuSisEuSi2Al2s
EuSn3sEuTi2Al20sEuV2Al20s
EuZnsEuZn11sEuZn12s
EuZn13sEuZn2sEuZn3s
EuZn5sFes1-s7,lFe18Sc10s
Fe2BsFe2NsFe2Nbs
Fe2PsFe2Scs1,s2Fe2Sis
Fe2TisFe2WsFe3Bs
Fe3Cs1,s2Fe3C2sFe3Ns
Fe3PsFe3Si7sFe3Sn2s
Fe5C2s1,s2Fe5Si3s1,s2Fe5Sn3s1-s3
Fe6Sc29sFe6W6CsFe7C3s
Fe7W6sFe9Sc5sFeBs
FeBe12sFeBe2sFeBe5s
FePsFeP2sFeP4s
FeSbsFeSb2sFeSis1-s3
FeSi2s1-s3FeSnsFeSn2s
FeTisGas1-s4,lGa2Cus
Ga4Cu9sGaAssGaNs
GaPsGaSbsGds1-s4,l
Gd11Sn10sGd13Zn58sGd2Als
Gd2Fe17sGd2Zn17s1,s2Gd3Al2s
Gd3Si5s1,s2Gd3Sn7sGd3Zn11s
Gd3Zn22sGd4Sn11sGd5Si3s
Gd5Si4s1,s2Gd5Sn3sGd5Sn4s
Gd6Fe23sGd6Mn23sGdAls
GdAl2sGdAl3sGdAl4Mgs
GdCr2Al20sGdCu4Al8sGdFe2s
GdFe2Al10sGdFe3sGdMgs
GdMg2sGdMg3sGdMg5s
GdMn12sGdMn2sGdSis
GdSi2s1,s2GdSi2Al2sGdSn2s
GdSn3s1,s2GdTi2Al20sGdV2Al20s
GdZnsGdZn11sGdZn12s
GdZn2sGdZn2MgsGdZn3s
GdZn5sGdZn6Mg3sGdZnMg12s
Ges1-s3,lGeAssGeAs2s
Hs,lHfs1-s3,lHf2Crs
Hf2SisHf3Si2sHf5Si3s1,s2
Hf5Si4sHf5Sn3s1,s2Hf5Sn4s
HfBsHfB2sHfH2s
HfSisHfSi2sHfSn2s
Hos1-s3,lHo11Sn10sHo13Zn58s
Ho2AlsHo2Al10Mg3sHo2Fe17s
Ho2Sn5sHo2Zn17s1,s2Ho3Al2s
Ho3Si4sHo3Si5s1,s2Ho3Zn11s
Ho3Zn22sHo5Mg24sHo5Si3s
Ho5Si4sHo5Si9s1,s2Ho5Sn3s
Ho5Sn4sHo6Fe23sHo6Mn23s
HoAlsHoAl2sHoAl3s
HoCr2Al20sHoCu4Al8sHoFe2s
HoFe2Al10sHoFe3sHoMgs
HoMg2sHoMn12sHoMn2s
HoSisHoSi2Al2sHoSiAl2s
HoSn2sHoSn3s1,s2HoTi2Al20s
HoZnsHoZn11sHoZn12s
HoZn2sHoZn2MgsHoZn3s
HoZn5sHoZn6Mg3sHoZnMg12s
Ins1-s3,lIn2AgsIn2Cas
In5Na3sIn9Na5sInAg3s
InCa3sInMg2sInNs
InNasInNa2sInPs
InSbsInSiNCsKs1-s3,l
K3Bis1,s2KB6sKHs
KSisKZn13sLas1-s4,l
La11Sn10sLa13Zn58sLa2Mg17s
La2Ni3sLa2Ni7s1,s2La2Sn3s
La2Zn17s1,s2La22Al53sLa3Als
La3Al11s1,s2La3Al40Mg17sLa3Nis
La3Si2sLa3Si5sLa3Sn5s
La3Zn11sLa3Zn22sLa5Mg41s
La5Si3s1,s2La5Si4s1,s2La5Sn3s1,s2
La5Sn4sLa5Zn53Mg42sLa7Ni16s
La7Ni3sLaAlsLaAl2s
LaAl3sLaCr2Al20sLaCu2Al10s
LaCu4Al8sLaFe2Al10sLaMgs
LaMg12sLaMg2sLaMg3s
LaNisLaNi3sLaNi5s
LaSisLaSi2sLaSi2Al2s
LaSnsLaSn3sLaTi2Al20s
LaV2Al20sLaZnsLaZn11s
LaZn12sLaZn13sLaZn2s
LaZn2Al2sLaZn2MgsLaZn3s
LaZn4sLaZn5sLis1-s3,l
Li12Si7sLi13Si4sLi2LaH4s
Li2Sr3sLi22Si5sLi23Sr6s
Li3AlH6sLi3BisLi4Bas
Li7Si3sLiAlH4sLiB3s
LiHsLiPbsLiZns
LiZn4sLus1-s3,lLu11Sn10s
Lu13Zn58sLu2AlsLu2Fe17s
Lu2Sn5sLu2Zn17s1,s2Lu3Al2s
Lu3Si5sLu3Zn11sLu3Zn22s
Lu5Mg24sLu5Si3sLu5Si4s
Lu5Sn3sLu6Fe23sLu6Mn23s
LuAlsLuAl2sLuAl3s
LuCu4Al8sLuFe2sLuFe2Al10s
LuFe3sLuMgsLuMg2s
LuMn2sLuMn5sLuSis
LuSn2sLuV2Al20sLuZns
LuZn11sLuZn12sLuZn2s
LuZn2MgsLuZn3sLuZn5s
LuZn6Mg3sLuZnMg12sMgs1-s7,l
Mg11Si7Al3sMg12Zn13sMg17Ba2s
Mg2Bas1,s2Mg2Cas1,s2Mg2Cus1,s2
Mg2GasMg2Ga5sMg2Ges
Mg2NisMg2PbsMg2Sis
Mg2Si6Al3s1,s2Mg2SnsMg2Zns
Mg2Zn11sMg2Zn3sMg23Ba6s
Mg3P2sMg3Si6Al2s1,s2Mg4Si4Al4s
Mg4Si6Als1,s2Mg4Si6Al2sMg4Si7s
Mg4Si8sMg5Ga2sMg5In2s
Mg5Si6s1,s2Mg51Zn20sMg6Si3s
Mg6Si4sMg9Si5sMg9Si7Al3s
Mg9Si7Al5sMg9Si9Al3sMgB2s
MgB20sMgB4sMgB7s
MgBe13sMgCo2sMgGas
MgGa2sMgH2sMgNi2s
MgSisMgSi2Al2sMgSi6Al4s1,s2
MgZn2s1,s2Mns1-s6,lMn11Si19s
Mn19Sn6sMn2BsMn2CaAl10s
Mn2NsMn2NisMn2Ps
Mn2ScsMn2SnsMn2Tis
Mn2Ti2sMn2ZrsMn23C6s
Mn23Sc6sMn3AlCsMn3B4s
Mn3CsMn3C2sMn3Ns
Mn3NisMn3PsMn3Sis
Mn3TisMn5C2sMn5Si3s1,s2
Mn5SiCsMn5Sn3sMn6N4s
Mn6N5sMn6SisMn7C3s
Mn8Si2CsMn9Si2sMn9Ti2s
MnBsMnB2sMnB4s
MnBe12sMnBe2sMnBe5s
MnCa4Al7sMnNsMnNis
MnNi2sMnNi3sMnPs
MnSc4sMnSisMnSn2s
MnTisNlNas1-s3,l
Na2C2s1,s2Na2KsNa2LiAlH6s
Na3AlH6s1,s2Na3AssNa3Bis
Na3PsNa3SbsNa4Bas
NaAlH4sNaB15sNaB6s
NaBasNaHsNaMgH3s
NaSisNaZn13sNbs,l
Nb2B3sNb2CsNb2Zn3s
Nb3B2sNb3B4sNb3C2s
Nb4FeSisNb5B6sNb5Si3s1,s2
Nb5Sn3sNb6Fe7sNbBs
NbB2sNbNsNbNi8s
NbS2sNbSn2sNbZns
NbZn12FesNbZn15sNbZn2s
NbZn3sNbZn7sNds1-s4,l
Nd11Sn10sNd13Zn58sNd2Als
Nd2Fe17sNd2SbsNd2Si3s1,s2
Nd2Sn5sNd2Zn17s1,s2Nd2Zn9Mg5s
Nd20Mg19Zn81sNd3AlsNd3Al11s1,s2
Nd3Al50Mg22sNd3Si4sNd3Sn5s
Nd3Sn7sNd3Zn11sNd3Zn22s
Nd3Zn30Mg13sNd4Sb3sNd5Fe17s
Nd5Mg41sNd5Sb3sNd5Si3s1,s2
Nd5Si4s1,s2Nd5Si9sNd5Sn3s
Nd5Sn4sNd6Mn23sNdAls
NdAl2sNdAl3sNdCr2Al20s
NdCu4Al8sNdFe2Al10sNdMgs
NdMg2sNdMg3sNdMn2s
NdSbsNdSb2sNdSis
NdSi2Al2sNdSnsNdSn2s
NdSn3sNdTi2Al20sNdV2Al20s
NdZnsNdZn11sNdZn12s
NdZn2sNdZn2Al2sNdZn2Mgs
NdZn3sNdZn5sNis1-s5,l
Ni12P5sNi2BsNi2Crs
Ni2Mg3AlsNi2PsNi2Sis1,s2
Ni2TasNi2VsNi2Ys
Ni2Y3sNi23C6sNi3Bs
Ni3PsNi3Sis1,s2Ni3Si2s
Ni3Sns1,s2Ni3TisNi3Vs
Ni3YsNi4B3sNi4Ws
Ni4YsNi5AlB4sNi5P2s
Ni5Si2sNi5Zr4sNi6P5s
Ni7Y2sNi7Zr2sNi8AlB11s
Ni8TasNi8YsNi8Zr3s
NiBsNiP2sNiSis
NiSi2sNiSrsNiTi2s1,s2
NiV3sNiWsNiW2s
NiYsNiY3sNiZn8s
NiZrsNiZr2sPs1-s4
Pbs1-s7,lPb10Nd11sPb10Pr11s
Pb2AusPb2DysPb2Nds
Pb2PrsPb2TbsPb2Zrs
Pb3AusPb3DysPb3Dy5s
Pb3NdsPb3Nd5sPb3Prs
Pb3Pr5sPb3SrsPb3Sr2s
Pb3Sr5sPb3TbsPb3Tb5s
Pb3Zr5sPb4Dy5sPb4Nd3s
Pb4Nd5sPb4Pr3sPb4Pr5s
Pb4Sr5sPb4Tb5sPb5Li22s
Pb5Sr3sPbDysPbNd3s
PbPr3sPbSrsPbSr2s
PbTbsPbZr4sPrs1-s4,l
Pr11Sn10sPr13Zn58sPr2Als
Pr2Fe17sPr2SbsPr2Sn3s
Pr2Sn5sPr2Zn17s1,s2Pr2Zn9Mg5s
Pr3Als1,s2Pr3Al11s1,s2Pr3Al50Mg22s
Pr3Si4sPr3SnsPr3Sn5s1,s2
Pr3Sn7sPr3Zn11sPr3Zn22s
Pr3Zn30Mg13sPr4Sb3sPr5Mg41s
Pr5Sb3sPr5Si3s1,s2Pr5Si4s1,s2
Pr5Si9s1,s2Pr5Sn3s1,s2Pr5Sn4s1,s2
Pr6Mn23sPrAlsPrAl2s
PrAl3sPrCr2Al20sPrCu4Al8s
PrFe2Al10sPrMgsPrMg12s
PrMg2sPrMg3sPrSbs
PrSb2sPrSisPrSi2Al2s
PrSnsPrSn2sPrSn3s
PrTi2Al20sPrV2Al20sPrZns
PrZn11sPrZn12sPrZn2s
PrZn2Al2sPrZn2MgsPrZn3s
PrZn5sSbs1-s3,lSb2Sn3s
Scs1-s4,lSc2Si3sSc5Si3s
Sc5Si4s1,s2ScCu4Al8sScSis
ScV2Al20sSis1-s7,lSi2Vs
Si2WsSi2Zr3sSi3N4s
Si3TisSi3Zr5s1,s2Si4Ti5s
Si4Zr5sSi5V6sSi6Al5s1,s2
SiAssSiAs2sSiCs1-s6
SiPs1,s2SiTa3sSiTis
SiZrsSiZr2sSms1-s4,l
Sm11Sn10sSm13Zn58sSm2Als
Sm2Fe17sSm2SbsSm2Sn3s
Sm2Sn5sSm2Zn17s1,s2Sm2Zn9Mg5s
Sm3Al11sSm3Si5sSm3Sn7s
Sm3Zn11sSm3Zn22sSm3Zn30Mg13s
Sm4Sb3sSm4Sn3sSm5Mg41s
Sm5Sb3sSm5Si3sSm5Si4s1,s2
Sm5Sn3sSm5Sn4sSm6Mn23s
SmAlsSmAl2sSmAl3s
SmCr2Al20sSmCu4Al8sSmFe2s
SmFe2Al10sSmFe3sSmMgs
SmMg2sSmMg3sSmMg5s
SmMn2sSmSbsSmSb2s
SmSisSmSi2s1,s2SmSi2Al2s
SmSn2sSmSn3sSmTi2Al20s
SmV2Al20sSmZnsSmZn11s
SmZn12sSmZn2sSmZn2Mgs
SmZn3sSmZn5sSns1-s5,l
Sn14Ca12Mg7sSn2Li5sSn2Nas
Sn2ZrsSn20Ca31sSn23Ca36s
Sn24Sr14Mg25sSn3CasSn3Ca5s
Sn3Li7sSn3Li8sSn3Nas
Sn3Na4sSn3SrsSn3Sr5s
Sn3SrMg5sSn4Li17sSn4Nas
Sn4Na15sSn4Na9sSn4Srs
Sn5Li13sSn5Li2sSn5Sr3s
Sn5Ti6sSn6Ca7sSn6Nas
SnAg3sSnCasSnLis
SnMgLi4sSnNas1,s2SnNa3s
SnSrsSnSr2sSnSrMgs
SnTi2sSnZr4sSrs1-s3,l
Sr18Zn62Mg20sSr2AlH7sSr2Mg17s
Sr2SisSr2Zn43Mg55sSr35Zn21Mg44s
Sr4Al38Mg58sSr5Si3sSr6Mg23s
Sr9Mg38sSrAlH5sSrB6s
SrBe13sSrC2s1,s2SrH2s1,s2
SrMg2sSrSisSrSi2s1,s2
SrSi2Al2sSrZnsSrZn13s
SrZn2sSrZn5s1,s2Tas1,s2,l
Ta2CsTa2CosTa2Sis
Ta5Si3s1-s3TaNs1,s2TaN3s
Tbs1-s3,lTb11Sn10sTb13Zn58s
Tb2AlsTb2Fe17sTb2Zn17s1,s2
Tb3Al2sTb3Si5sTb3Sn7s1,s2
Tb3Zn11sTb3Zn22sTb5Mg24s
Tb5Si3sTb5Si4sTb5Sn3s
Tb5Sn4sTb6Fe23sTb6Mn23s
TbAlsTbAl2sTbAl3s
TbAl4MgsTbCr2Al20sTbCu4Al8s
TbFe2sTbFe2Al10sTbFe3s
TbMgsTbMg2sTbMg3s
TbMn12sTbMn2sTbSis
TbSi2sTbSi2Al2sTbSn2s
TbSn3sTbTi2Al20sTbV2Al20s
TbZnsTbZn11sTbZn12s
TbZn2sTbZn2MgsTbZn3s
TbZn5sTbZn6Mg3sTbZnMg12s
Tis1-s7,lTi2CsTi2Crs
Ti2HsTi2MnsTi2Zns
Ti3Al2Si5sTi3B4sTi3Sis
Ti5Si3s1,s2Ti5Sn3s1,s2Ti7Al5Si14s
Ti8Al17sTiBsTiB2s
TiH2sTiNsTiSi2s
TiZnsTiZn10sTiZn15s
TiZn2sTiZn3sTiZn5s
Tms1-s3,lTm11Sn10sTm13Zn58s
Tm2AlsTm2Fe17sTm2Sn5s
Tm2Zn17s1,s2Tm3Al2sTm3Si5s
Tm3Zn11sTm3Zn22sTm5Mg24s
Tm5Si3sTm5Si4sTm5Sn3s
Tm6Fe23sTm6Mn23sTmAls
TmAl2sTmAl3sTmCu4Al8s
TmFe2sTmFe2Al10sTmFe3s
TmMgsTmMg2sTmMn12s
TmMn2sTmSisTmSn2s
TmSn3s1,s2TmZnsTmZn11s
TmZn12sTmZn2sTmZn2Mgs
TmZn3sTmZn5sTmZn6Mg3s
TmZnMg12sVs1-s5,lV2B3s
V2HfsV2Tas1,s2V2Zrs
V23C6sV3B2sV3B4s
V3C2sV3SisV3Sns
V4Zn5sV5C2sV5Si3s1,s2
VBsVB2sVNs
VSn2sVZn16sVZn3s
Ws1-s3,lW2BsW2B9s
W3C2sW5Si3s1,s2WBs1,s2
WCsWNs1,s2Ys1-s4,l
Y11Sn10sY13Zn58sY15Zn70Mg15s
Y2Fe17sY2Mn9Al5sY2Sn5s
Y2Zn17s1,s2Y3Si5s1,s2Y3Zn11s
Y3Zn22sY3Zn30Mg13sY5Si3s
Y5Si4sY5Sn3s1,s2Y5Sn4s
Y6Fe23sY6Mn23sYAl2s
Ybs1-s4,lYb13Zn58sYb2Zn17s1,s2
Yb3Si5sYb3Zn11sYb3Zn22s
Yb5Si3sYb5Si4sYb50Si87s
Yb8Si11sYbAl2sYbAl3s
YbCr2Al20sYbCu4Al8sYbFe2Al10s
YbMg2sYbSisYbSi2Al2s
YbTi2Al20sYbV2Al20sYbZns
YbZn11sYbZn12sYbZn2s1,s2
YbZn3sYbZn5sYCr2Al20s
YCu4Al8sYCuAlsYFe2s
YFe2Al10sYFe3sYMn12s
YMn2sYNi5sYSis
YSi2s1,s2YSi2Al2sYSn2s
YSn3s1,s2YV2Al20sYZns
YZn11sYZn12sYZn2s1,s2
YZn2MgsYZn3sYZn5s
YZn6Mg3sYZnMg12sZns1-s9,l
Zn12ScsZn17Sc2s1,s2Zn17Sc3s
Zn2LisZn2ScsZn2Zrs
Zn2Zr3sZn22Fe2TisZn22Zrs
Zn3AlLisZn3Li2sZn3P2s1,s2
Zn3Sb2sZn3Zrs1,s2Zn39Zr5s
Zn4Sb3s1,s2Zn5Li2sZn5Sb3s
Zn58Sc13sZn62Ca8Al30sZn7Li3s
Zn9MnsZnAlLisZnP2s1,s2
ZnSbsZnScsZnZrs
ZnZr2sZrs1-s8,lZr3Sis
Zr5Sn3s1,s2ZrBsZrB12s
ZrB2sZrCsZrH2s
ZrNsZrSi2s