List of 287 Solutions and 1995 Compounds in FTlite


List of 287 Solutions

1. FTlite-A1
FCC-A1 Prototype-Cu Strukturbericht = A1; Pearson = cF4; Space Group = Fm-3m (225); [I]
C, N, B, H and O interstitial (Strukturbericht = B1; Pearson = cF8 with full 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, V3Al, 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
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
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
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
BCT-A5;Prototype-Sn Strukturbericht = A5; Pearson = tI4; Space group = I41/amd (141);
Beta-Sn

15. FTlite-A6
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
RHOM-A7;Prototype-As Strukturbericht = A7; Pearson = hR2; Space group = R-3m (166); [I]
Rhombohedral-As(alpha)

18. FTlite-A9
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
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
Ag;Prototype-B Strukturbericht = Ag; Pearson = tP50; Space group = P42/nnm (134); [-I]
Tetragonal-boron(beta) is metastable;

23. FTlite-Al4M
Al4Mn;Prototype-Al4Mn Pearson = hP574; Space group = P63/mmc;
Al4Mn, Al4Cr solubility for Fe, Zn

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-AM8
AM8;Al63Mo37 with Ti solubility

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

28. FTlite-aP15
aP15;Prototype-Al11Mn4 Pearson = aP15/aP30; Space group = P-1 (2);
Al11Mn4(low-T), tau3-(Al,Si)11Cr4 with Fe solubility

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

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

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

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

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

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

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

36. FTlite-B1
FCC-B1;Prototype-NaCl (halite) Strukturbericht = B1; Pearson = cF8; Space group = Fm-3m (225); [I]
Halite structure; MeS(Me=Ca,Mg,Mn,Pb), PbX(X=S,Se,Te), SnX(X=As,S,Te), RESb (RE=Ce,Nd,Pr,Sm) are stable

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

38. FTlite-B2
BCC-B2!BCC-A2 Prototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221); [I]
AlFe, AlMn, FeSi, AlTi, FeTi, CuZn-beta', CuZr, NiZn, AgLi, AgMg, BeCu, CaIn are stable

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

40. 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)

41. FTlite-B2_a
BCC-B2a;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, AlSc and CoSc are stable

42. 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.

43. FTlite-B2_c
BCC-B2c;Prototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221); [I]
AlNi ordered BCC solution with lattice vacancies

44. FTlite-B2_d
BCC-B2d;Prototype-CsCl Strukturbericht = B2; Pearson = cP2; Space group = Pm-3m (221);
AlMo High-temperature binary Al-Mo phase between ca. 48-54 at.% Mo. Stable from 1743 to 1993 K.

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

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

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

48. 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

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

50. 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.

51. FTlite-B4
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

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

53. FTlite-B8x
B81/B82;NiAs/InNi2 Strukturbericht = B81/B82; Pearson = hP4/hP6; Space group = P63/mmc (194); [I]
B81-prototype_NiAs (Va on 2d sites) and B82-prototype_InNi2 (Me on 2d sites); Many compounds;

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

57. FTlite-Bh
Bh;Prototype-WC Strukturbericht = Bh; Pearson = hP2; Space group = P-6m2 (187);
MoC-gamma, MoP, WC-delta and WN are stable

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

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

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

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

62. FTlite-C11b
C11b;Prototype-MoSi2 Strukturbericht = C11b; Pearson = tI6; Space group = I4/mmm (139); [I]
AlCr2, MoSi2, (Ag,Cd,Cu,Zn)Ti2, AgZr2, TiAu2, CuZr2, PdTi2, ScAg2, ScCu2, TaNi2, TiPd2 are stable

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

64. FTlite-C14
C14;Prototype-MgZn2 (Laves) Strukturbericht = C14; Pearson = hP12; Space group = P63/mmc (194); [I]
Al2Zr,CaLi2,Cr2(Ti,Zr),Fe2(Mo,Sc,Ti,W),Mg2(Ca,Sr,Ba),Mg2RE(RE = Y,Tb,Dy,Ho,Er,Tm,Yb,Lu) are stable phases

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

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

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

68. 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

69. FTlite-C18
C18;Prototype-FeS2 (marcasite) Strukturbericht = C18; Pearson = oP6; Space group = Pnnm (58); [I]
FeS2(marcasite), FeSe2(ferroselite), FeTe2(frohbergite), CuSe2(petricekite), NiAs2(rammelsbergite) are stable

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

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

72. FTlite-C2
C2;Prototype-FeS2 (pyrite) Strukturbericht = C2; Pearson = cP12; Space group = Pa-3 (205); [I]
beta-FeS2(pyrite), NiS2(vaesite), CoS2(cattierite), MnS2(hauerite), CoSe2(trogtalite), MnSe2, NiSe2(penrosite) are stabl

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

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

75. 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

76. FTlite-C3
C3;Prototype-Cu2O (cuprite) Strukturbericht = C3; Pearson = cP6; Space group = Pn-3m (224);
Cu2O-cuprite and Ag2O are stable

77. 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

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

79. FTlite-C36
C36;Prototype-MgNi2 (Laves) Strukturbericht = C36; Pearson = hP24; Space group = P63/mmc (194); [I]
Al2Ba, (Al,Mg)2Ca, Al2Sr, Co2Ta, Cr2Ti, Cr2Zr, Cu2Mg, Mg2Ba, MgNi2, Mg2Sr, MgZn2 are stable

80. FTlite-C38
C38;Prototype-Cu2Sb Strukturbericht = C38; Pearson = tP6; Space group = P4/nmm (129);
Cu2As, eta-Cu2Sb and Cu2Te are stable

81. FTlite-C40
C40;Prototype-CrSi2 Strukturbericht = C40; Pearson = hP9; Space group = P6222 (180);
CrSi2, NbSi2, TaSi2, VSi2, WSi2, HfSn2 are stable (Al,Ti solubility); Al2W is stable HT

82. FTlite-C42
C42;Prototype-CeCu2 Strukturbericht = C42; Pearson = oI12; Space group = Ibam (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}

83. 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; with Al solubility

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

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

86. FTlite-Cb
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;

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

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

89. FTlite-cF96
cF96;Prototype-Ti2Ni Pearson = cF96; Space group = Fd-3m (227); [I-!5]
Ti2Co, Ti2Ni, Sc2Ni, Hf2Fe and Hf2Co are stable

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

91. FTlite-CoY3
CoY3;Prototype-Fe3C (cementite) Strukturbericht = D011/D020; Pearson = oP16; Space group = Pnma (62);
CoRE3 (RE = Y,La,Pr,Nd,Sm,Gd,Tb,Dy,Ho,Er,Tm)

92. 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).

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

94. 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)

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

96. 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

97. FTlite-D02
D02;Prototype-As3Co (Skutterudite) Strukturbericht = D02; Pearson = cI32; Space group = Im-3 (204);
Sb3Co(kieftite) is stable

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

99. 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

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

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

102. 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)

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

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

105. FTlite-D0a
D0a;Prototype-Cu3Ti Strukturbericht = D0a; Pearson = oP8; Space group = Pmmn (59);
Ag3Sn, Ni3Mo, Ni3Nb, Cu2Sb, Ni3Sb and Ni3Ta are stable

106. FTlite-D0e
D0e;Prototype-Ni3P Strukturbericht = D0e; Pearson = tI32; Space group = I-4 (82);
Co3P, Cr3P, Fe3P, Mn3P, Ni3P and V3P(ht) are stable

107. FTlite-D101
D101;Prototype-Mn7C3 Strukturbericht = D101; Pearson = oP40; Space group = Pnma (62);
Cr7C3(HT) and Mn7C3 are stable with Co,Fe,Mo,Nb,Ni,V,W substitution

108. FTlite-D102
D102;Prototype-Th7Fe3 Strukturbericht = D102; Pearson = hP20; Space group = P63mc (186);
Cr7C3(LT) is stable; Borides also stable

109. 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

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

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

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

113. FTlite-D1a
D1a;Prototype-MoNi4 Strukturbericht = D1a; Pearson = tI10; Space group = I4/m (87);
MoNi4, WNi4, Ag4Sc, Au4Ti and Cu4Sc are stable

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

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

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

117. 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

118. FTlite-D23a
D23a;Prototype-NaZn13 Strukturbericht = D23; Pearson = cF112; Space group = Fm-3c (226); [I]
Co13La is stable (RE= La,Ce,Pr,Nd,Sm,Gd,Tb,Dy,Ho,Er,Yb,Lu,Sc,Y). Pm and Tm are not included

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

120. 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, BaAg5 and most RECo5 are stable

121. 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)

122. FTlite-D510
D510;Prototype-Cr3C2 Strukturbericht = D510; Pearson = oP20; Space group = Pnma (62);
Cr3C2 with substitution of Cr by Co,Fe,Mn,Mo,Nb,V and W

123. FTlite-D513
D513;Prototype-Al3Ni2 Strukturbericht = D513; Pearson = hP5; Space group = P-3m1 (164);
Al3Ni2 and In3Ni2 are stable

124. FTlite-D52
D52;Prototype-La2O3 Strukturbericht = D52; Pearson = hP5; Space group = P-3m1 (164);
alpha-Mg3Bi2 and alpha-Mg3Sb2 are stable

125. FTlite-D53
D53;Prototype-Mn2O3 Strukturbericht = D53; Pearson = cI30; Space group = Ia-3 (206);
beta-Mg3Bi2 and beta-Mg3Sb2 are stable

126. FTlite-D59
D59;Prototype-Zn3P2 Strukturbericht = D59; Pearson = tP40; Space group = P42/nmc (137);
alpha-Zn3P2 and alpha-Zn3As2 are stable

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

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

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

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

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

132. FTlite-D82
D82;Prototype-Cu5Zn8 Strukturbericht = D82; Pearson = cI52; Space group = I-43m (217); [-I]
Al8Fe5, Al8Cr5(HT), Al8V5, (Ag,Cu,Fe)5Zn8, AlCu(HT), Fe5Zn8, gamma-NiZn, (Ag,Cu)5Cd8 are stable

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

134. 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

135. 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.

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

137. 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

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

139. 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

140. FTlite-D8b
Sigma;Prototype-FeCr (sigma) 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)

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

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

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

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

145. 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

146. 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;

147. 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.

148. FTlite-E
E;Prototype-CeCr2Al20 Pearson = cF176/cF184; Space group = Fd-3m (227); [I]
Zn22Zr, Al10V, CeCr2Al20, RECr2Al20, CaCr2Al20, Mg3Cr2Al18

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

150. 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

151. 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

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

153. 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

154. 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.

155. 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

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

157. FTlite-Fm53
I;REZn6Mg3 Fm53
Icosahedral

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

159. 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.

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

161. FTlite-h36R
h36R;Prototype-MoAl5 Pearson = hR36; Space group = R-3c (167);
Al3Mo with iron solubility

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

163. 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 Ta,V substitution

164. FTlite-hP18
hP18;prototype-Ti5Ga4 Pearson = hP18; Space group = P63/mcm (193);
Ti5Ga4 is stable

165. FTlite-hP22
hP22;Prototype-Co3Ho4 Pearson = hP22/hP26; Space group = P63/m (176);
Co3RE4 (RE = Y,Gd,Tb,Dy,Ho,Er,Tm,Lu) actually hP22=RE6Co4.5; hP26=RE6Co4.85

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

167. FTlite-hP3
hP3 Struktubericht = A3; Pearson = hP3; Space group = P-6m2 (187);
delta-CuZn3, zeta-AgCd and epsilon-AgCd3 are stable. Disordered.

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

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

170. 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

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

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

173. FTlite-hP70
Co11RE24;Prototype-Co11Ce24 Pearson = hP70; Space group = P63mc (186);
Co11(Ce,Nd)24 is stable phase.

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

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

176. FTlite-hP8c
MAX;Prototype-Cr2AlC Pearson = hP8; Space group = P63/mmc (194);
M2AlC (M=Cr,Ti,V)

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

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

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

180. FTlite-hR12
hR12;Prototype-Ni3Pu; Pearson = hR12; Space group = R-3m (166);
Fe3RE (RE = Y,Sm,Tb,Dy,Er,Tm,Lu), Ni3Y, Co3RE are stable;

181. FTlite-hR21
hR21;Prototype-Sn4P3 Pearson = hR21; Space group = R-3m (166);
Me4C3-x (Me=Ta,V) with carbon deficit as "V4C2.65" (or V3C2)

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

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

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

185. FTlite-hR54
hR54;Prototype-Gd2Co7 Pearson = hR54; Space group = R-3m (166);
RE2Co7 (RE=all rare-earths except Sc, Eu, Pm and Lu)

186. 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) + Co17RE2 (RE=Y,Ce,Pr,Nd,Sm,Gd,Tb,Dy,Ho)

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

188. FTlite-hR72
hR72;Prototype-Ce5Co19; Pearson = hR72; Space group = R-3m (166);
RE5Co19 (RE=La,Ce,Pr,Nd,Sm)

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

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

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

192. FTlite-L10
L10;Prototype-AuCu Strukturbericht = L10; Pearson = tP2; Space group = P4/mmm (123); [I]
AlTi, GaTi and InMg are stable, with Cr,Mo,Nb,Ta,V,W solubility

193. 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,...)

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

195. FTlite-L12c
L12-FCC!FCC-A1 Strukturbericht = L12; Pearson = cP4; Space group = Pm-3m (221); [I]
Ordered FCC phase Ni3Al, Ni3Fe, Ni3Si and Ag3Mg

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

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

198. FTlite-L21
Heusler;Prototype-AlCu2Mn Strukturbericht = L21; Pearson = cF16; Space group = Fm-3m (225); [I]
AlCu2Mn, AlNi2Hf, AlNi2Ti, AlCu2Ti are stable

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

200. FTlite-L3A
Prototype-Li3Ag; Pearson = cF16; Space group = Fm-3m (225)
Li3Ag: (Li,Ag)1(Li)3 (D03)

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

202. FTlite-Li2Z
Zn3Li2 Space group = P-3m1 (164);
High-temperature allotropic form of low-temperature stoichiometric Zn3Li2

203. FTlite-Liqu
Liquid metal [I]

204. 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.

205. 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.

206. FTlite-M12C
cF104;Prototype-Fe6W6C Pearson = cF104; Space group = Fd-3m (227)
Co6W6C and Fe6W6C are stable

207. FTlite-m28C
mS28;Prototype-Ni5Sb2 Pearson = mS28; Space group = C2 (5);
Ni5Sb2

208. FTlite-m28S
Co2RE5;Prototype-Mn5C2 Pearson = mS28; Space group = C2/c (15); structure: Fe1(8f)
Co2RE5(Pr,Nd,Sm) are stable phases. Pm and Tm are not included

209. FTlite-MAX2
MAX2;Prototype-CsYb3Se4 Pearson = hP16; Space group = P63/mmc (194);
M4AlC3 (M=Cr,Ti,V)

210. FTlite-mC14
mS14;Prototype-Ni3Sn4 Pearson = mS14; Space group = C2/c(12)
Phase at ca.44 at.% Ni in the Ni-Sn system, with solubility for Cu

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

212. FTlite-mC22
mC22;Prototype-Mo3Al8 Pearson = mC22; Space group = C2/m (12)
Al8Mo3 is stable with Ti solubility

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

214. FTlite-mC30
mC30;Prototype-Al4W Pearson = mC30; Space group = Cm (8);
Al4Mo, Al4W are stable, with Fe solubility

215. 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

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

217. FTlite-MgCZ
Mg3Ce2Zn3

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

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

220. FTlite-mP24
mP24;Prototype-ZnAs2 Pearson = mP24; Space group = P21/c (14);
ZnAs2 and beta-ZnP2 are stable;

221. FTlite-mP38
mP38;Prototype-Ho12Co7; Pearson = mP38; Space group = P21/c (14);
RE12Co7 (RE = Dy,Er,Ho,Tb) are stable

222. FTlite-mP52
mP52;Prototype-Co5Y8; Pearson = mP52; Space group = P121/c1 (14);
Co5Y8 stable

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

224. FTlite-mS24
mS24;Prototype-SiAs Pearson = mS24; Space group = C2/m (12);
GeAs, GeP and SiAs are stable

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

226. FTlite-mS32
mS32;Prototype-MoAl3 Pearson = mS32; Space group = C2/m (12)
Al3Mo is stable (ht)

227. FTlite-mS44
mS44;Prototype-Ni13Ga9 Pearson = mS44; Space group = C2/m (12);
zeta'-Ni13In9 is stable

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

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

230. FTlite-o20P
oP20;Prototype-Ni3Sn2 Pearson = oP20; Space group = Pnma (62);
Ni3Sn2(lt), Mn3Sn2 and Co3Sn2(lt) are stable

231. FTlite-o20S
Co3RE2;Prototype-La2Ni3 Pearson = oS20; Space group = (64)
Co3La2 is stable phase. Pm and Tm are not included

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

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

234. 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)

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

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

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

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

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

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

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

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

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

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

245. FTlite-oP56
NiMo-delta Pearson = oP56; Space group = P212121 (19); Frank-Kasper phase
"NiMo"-delta Phase between ca.43 & 52 at.% Ni in Mo-Ni system

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

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

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

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

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

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

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

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

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

255. 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.

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

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

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

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

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

261. FTlite-R
R;phase Pearson = hR53;
Phase found in high-temperature Ni-based alloys, its formation being promoted by the presence of Mo.

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

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

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

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

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

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

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

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

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

271. 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

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

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

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

275. FTlite-tI24
tI24;Prototype-HfGa2 Pearson = tI24; Space group = I41/amd (141); [I]
eta-Al2Ti, Ga2Ti, Pb2Pr and Pb2Nd are stable (Al2Mg is metastable)

276. FTlite-tI32
tI32;Prototype-TiAl3 Pearson = tI32; Space group = I4/mmm (139);
epsilon-Al3Ti low-T with Si solubility

277. 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

278. 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

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

280. 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

281. FTlite-tP28
tP28;Prototype-Al5Ti2 Pearson = tP28; Space group = P4/mmm (123);
zeta-Al5Ti2 is stable

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

283. 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

284. 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

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

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

287. 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 1995 Compounds

Ags1-s5,lAg2BasAg2Ba3s
Ag2CasAg2GasAg2Os
Ag2ScsAg2Ses1,s2Ag2Srs
Ag2Sr3sAg2Tes1-s3Ag3Be8s
Ag3Ca5sAg3Ga2sAg3P11s
Ag3SbsAg4ScsAg4Srs
Ag5BasAg5SrsAg5Sr3s
Ag5Te3s1,s2Ag7Ca2sAg9Ca2s
AgBasAgCasAgCa3s
AgCdsAgCu4ZrsAgMg4s
AgP2sAgScsAgSrs
AgTi2sAgZrsAgZr2s
Als1-s9,lAl10VsAl11Cr2s
Al11Cu5Mn3sAl11Fe3Si6sAl11Mn3Zn2s
Al11Mn4sAl116Cr63Si21sAl12Mns
Al12MosAl12WsAl13Co4s
Al13Cr4Si4sAl14Ca13sAl14Fe3Si3s
Al15Cu8Li2sAl17Mo4sAl18Cr2Mg3s
Al18Mg3Mn2sAl18Mg3Mo2sAl18Mg3Ta2s
Al18Mg3Ti2sAl18Mg3V2sAl18Mg3W2s
Al2AusAl2Bas1,s2Al2Cas1,s2
Al2CaZn2sAl2Cus1-s3Al2Cu3s
Al2CuLisAl2CuMgsAl2Fes
Al2HfsAl2Hf3sAl2Lis1,s2
Al2Li18Si6sAl2Li3sAl2Mn2Si3s
Al2O3s1-s4Al2ScsAl2Se3s
Al2Srs1,s2Al2Tis1,s2Al2Ws
Al2Y3sAl2ZrsAl2Zr3s
Al22Mo5sAl23CuFe4sAl23V4s
Al3BCsAl3Ca8sAl3Cos
Al3Crs1,s2Al3CusAl3Cu2s
Al3CuCesAl3CuLasAl3Hfs1,s2
Al3Hf2sAl3Hf4sAl3Lis1-s3
Al3Li15Si6sAl3Li7Si4sAl3Mgs
Al3MnSi2sAl3MosAl3Nbs
Al3NisAl3Ni5sAl3Scs
Al3TasAl3Ta2s1,s2Al3Tis1-s4
Al3Vs1-s3Al3Ys1,s2Al3Zrs1-s3
Al3Zr2sAl3Zr5sAl30Mg23s
Al39Cu33Zr6sAl4BasAl4C3s
Al4C4SisAl4CasAl4Ces
Al4CrsAl4FesAl4Li9s
Al4MgYsAl4MnsAl4Mos
Al4SrsAl4WsAl4Zr5s
Al5Ba4sAl5C3NsAl5Co2s
Al5Cu2Mg8Si6sAl5Cu6Mg2sAl5CuLi3s
Al5LisAl5MosAl5Ws
Al53Mg14Li33sAl57Cu11Li32sAl6Fes
Al6MnsAl6Ni3SisAl63Mo37s
Al69Ta39sAl7CrsAl7Cu2Fes
Al7Cu2ZrsAl7Cu3Mg6sAl7CuFe2s
Al7CuMn2sAl7CuZr2sAl7Sr8s
Al7Ta5sAl7W3sAl77W23s
Al8C7B4sAl8C7SisAl8Cr5s1,s2
Al8CrTi3sAl8CrYsAl8EuFe2s
Al8FeMg3Si6sAl8Mn4YsAl8Mo3s
Al8V5sAl9Co2sAl9Co2Bas
Al9Co2SrsAl9Cr3SisAl9Cr4s1,s2
Al9Cu11sAl9Fe2BasAl9Fe2Srs
Al9Ni2BasAl9Ni2SrsAl99Mn23s
AlAssAlAusAlAu2s
AlAu4sAlB12sAlB2s
AlCa5Zn2sAlCeSi2sAlCos
AlCr2sAlCr2B2sAlCr3B4s
AlCus1,s2AlCu2sAlCu3Mn2s
AlH3sAlHfsAlHf2s
AlLis1,s2AlLiSisAlMgs
AlMgAgsAlMgB14sAlMo3s
AlNs1-s3AlNaSisAlPs
AlSbsAlScsAlSc2s
AlSc2Si2sAlSn2Zr5sAlTas
AlTisAlYsAlY2s
AlZrs1,s2AlZr2sAlZr3s1,s2
Ass1-s5,lAs2Cu5sAs2Te3s
AsCu8sAsInsAus1-s3,l
Au2PbsAu2TisAu3Ins
Au4Zn5sAu5Zn3sAu7In3s
Au8Al3sAuInsAuIn2s
AuSb2sAuSnsAuSn2s
AuSn4sAuTe2sAuTi3s
AuZn3sBs1-s7,lB4Nds
B5Nd2sB6NdsB66Nds
Bas1-s3,lBa2SisBa2Zns
Ba3Si4sBa5Si3sBaAl2Si2s
BaB6sBaBe13sBaC2s1,s2
BaCusBaCu13sBaH2s1,s2
BaSisBaSi2sBaZns
BaZn13sBaZn2sBaZn5s
Bes1-s3,lBis1-s4,lBi2Ks
Bi2K3sBi2TesBi3In5s
Bi3NisBi4K5sBi4Te3s
BiInsBiIn2sBiLis
BiNasBNs1,s2Cs1,s2,l
Cas1-s3,lCa14Si19sCa2Cus
Ca2Mg5Zn13sCa2Mg55Zn43sCa2Ni7s
Ca2PbsCa2SisCa2Sns
Ca3Mg3Zn14sCa3P2sCa3Si4s
Ca3ZnsCa4Al3MgsCa5Pb3s
Ca5Si3sCa5Zn3sCa7Mg6Si14s
CaAl2Si2sCaAlH5sCaB6s
CaBe13sCaC2s1-s4,lCaCr2Al20s
CaCusCaCu5sCaH2s
CaLi2sCaMgSisCaNi2s
CaNi3sCaNi5sCaOs
CaPbsCaPb3sCaSis
CaSi2sCaTi2Al20sCaZns
CaZn11sCaZn13sCaZn2s
CaZn3sCaZn5sCds1-s4,l
Cd10Cu3sCd11Na2sCd2Nas
Cd3Cu4sCd3InsCd5Nis
Cd8Cu5sCdCu2sCdNis
CdSbsCdTisCdTi2s
Ces1-s4,lCe11Sn10sCe12Y21Mg67s
Ce13Zn58sCe2AlsCe2Fe17s
Ce2InsCe2Mg17sCe2Mn3Als
Ce2Mn7Al10sCe2SbsCe2Sn5s
Ce2Zn17s1,s2Ce2Zn45Mg53sCe2Zn9Mg5s
Ce20Zn81Mg19sCe3Als1,s2Ce3Al11s1,s2
Ce3InsCe3In5sCe3Si2s
Ce3Si5sCe3SnsCe3Sn5s
Ce3Sn7sCe3Zn11sCe3Zn22s
Ce3Zn30Mg13sCe3Zn9Mg2sCe4Sb3s
Ce5In4sCe5Mg41sCe5Si3s1,s2
Ce5Si4s1,s2Ce5Sn3s1,s2Ce5Sn4s
Ce6Zn83Mg11sCe9In11sCeAls
CeAl13Mg6sCeAl2sCeAl3s1,s2
CeCr2Al20sCeCr4Al5sCeCus
CeCu2sCeCu4sCeCu4Al8s
CeCu5sCeCu6sCeFe2s
CeFe2Al10sCeIn2sCeIn3s
CeMgsCeMg12sCeMg2s
CeMg3sCeMn4Al8sCeSbs
CeSb2sCeSisCeSi2s
CeSn3sCeTi2Al20sCeV2Al20s
CeZnsCeZn11sCeZn12s
CeZn2sCeZn2Al2sCeZn2Mgs
CeZn3sCeZn5sCos1-s5,l
Co11Ce24sCo11Hf2sCo11Zr2s
Co13LasCo16Nb9sCo17Ce2s
Co17Dy2sCo17Er2sCo17Gd2s
Co17Ho2sCo17La20sCo17Lu2s
Co17Nd2sCo17Pr2sCo17Pr20s
Co17Sm2sCo17Tb2sCo17Tm2s
Co17Y2sCo17Yb2sCo19Ce5s
Co19La5sCo19Nd5sCo19Pr5s
Co19Sm5sCo2BsCo2Ces
Co2DysCo2ErsCo2Gds
Co2HfsCo2HosCo2Lus
Co2NsCo2NbsCo2Nds
Co2Nd5sCo2PrsCo2Pr5s
Co2ScsCo2SisCo2Sms
Co2Sm5sCo2Tas1-s3Co2Tbs
Co2Tis1-s3Co2TmsCo2Ys
Co2YbsCo2ZrsCo23C6s
Co23Hf6sCo23Zr6sCo3Bs
Co3C2sCo3CesCo3Dys
Co3Dy4sCo3ErsCo3Er4s
Co3GdsCo3Gd4sCo3Hos
Co3Ho4sCo3La2sCo3Lus
Co3Lu4sCo3MosCo3Nbs
Co3NdsCo3Nd2sCo3Nd4s
Co3PrsCo3Pr4sCo3Sis
Co3SmsCo3Sn2s1,s2Co3Tbs
Co3Tb4sCo3TisCo3Tms
Co3Tm4sCo3VsCo3Ws
Co3YsCo3Y2sCo3Y4s
Co3YbsCo4Zn9sCo5Ces
Co5DysCo5ErsCo5Gds
Co5HosCo5LasCo5Nds
Co5PrsCo5SmsCo5Tbs
Co5TmsCo5YsCo5Y8s
Co6W6CsCo7C3sCo7Ce2s
Co7Dy12sCo7Dy2sCo7Er12s
Co7Er2sCo7Gd2sCo7Ho12s
Co7Ho2sCo7La2sCo7Nb2s
Co7Nd2sCo7Pr2sCo7Sm2s
Co7Ta2sCo7Tb12sCo7Tb2s
Co7Tm2sCo7Y2sCo7Y6s
CoBsCoDy3sCoEr3s
CoGd3sCoHfsCoHf2s
CoHo3sCoIn2sCoIn3s
CoLa3sCoLu3sCoNs
CoN3sCoNd3sCoOs
CoPr3sCoSbsCoSb2s
CoSb3sCoScsCoSc2s
CoSc3sCoSe2sCoSis
CoSi2sCoSm3sCoSns
CoSn2sCoTb3sCoTes
CoTe2sCoTisCoTi2s
CoV3sCoYsCoY3s
CoZn7sCoZrsCoZr2s
CoZr3sCrs1-s6,lCr2AlCs
Cr2BsCr2CsCr2Hfs1,s2
Cr2NsCr2O3sCr2Ps
Cr2Tas1,s2Cr2Tis1,s2Cr2Zrs1-s3
Cr23C6sCr3B4sCr3Cs
Cr3C2sCr3Mn5sCr3Ps
Cr3SisCr5B3sCr5Si3s1-s3
Cr7C3sCrBsCrB2s
CrB4sCrNsCrSis
CrSi2sCrZn13sCrZn17s
Cus1-s4,lCu10Sn3sCu10Zr7s
Cu12Sn10sCu15Si4sCu16Mg6Si7s
Cu19Si6sCu2EusCu2Hos
Cu2LasCu2Mgs1-s3Cu2Nds
Cu2OsCu2PsCu2Prs
Cu2SbsCu2ScsCu2Ses1,s2
Cu2SmsCu2Tes1-s6Cu2Tis
Cu2TiZrsCu2Ys1,s2Cu2Zrs
Cu3AssCu3GesCu3Mg2Sis
Cu3Ps1,s2Cu3Sbs1,s2Cu3Se2s
Cu3Sns1,s2Cu3Ti2sCu33Si7s
Cu37La3sCu4InsCu4Las
Cu4NdsCu4PrsCu4Sbs
Cu4ScsCu4SmsCu4Sns
Cu4Ti3sCu4YsCu5Eus
Cu5Hos1,s2Cu5LasCu5Nds
Cu5PrsCu5SmsCu5Srs
Cu5Zr8sCu51Zr14sCu6Las1,s2
Cu6NdsCu6PrsCu6Sbs
Cu6SmsCu6Sn5sCu7Ga2s
Cu7Ho2sCu7In3sCu7In4s
Cu7Sb2sCu7Y2sCu8Zr3s
Cu9Ho2sCu9Si2sCu9Zr2s
CuBe2sCuEusCuEu2s
CuHsCuHosCuLas
CuNdsCuOsCuP2s
CuPrsCuScsCuSes1-s3
CuSe2s1,s2CuSmsCuSrs
CuTesCuTi2sCuYs
CuZrsCuZr2sDys1-s4,l
Dy11Sn10sDy13Zn58sDy2Als
Dy2Al10Mg3sDy2Fe17sDy2Zn17s1,s2
Dy3Al2sDy3Si4sDy3Si5s1,s2
Dy3Sn7s1,s2Dy3Zn11sDy3Zn22s
Dy5Mg24sDy5Si3sDy5Si4s
Dy5Sn3s1,s2Dy5Sn4sDy6Fe23s
Dy6Mn23sDyAlsDyAl2s
DyAl3s1,s2DyCr2Al20sDyCu4Al8s
DyFe2sDyFe2Al10sDyFe3s
DyMgsDyMg2sDyMg3s
DyMn12sDyMn2sDySis
DySi2s1,s2DySi2Al2sDySn2s
DySn3s1,s2DyTi2Al20sDyV2Al20s
DyZnsDyZn11sDyZn12s
DyZn2sDyZn2MgsDyZn3s
DyZn5sDyZn6Mg3sDyZnMg12s
Ers1-s4,lEr11Sn10sEr13Zn58s
Er2AlsEr2Fe17sEr2Si2Al3s
Er2Sn5sEr2Zn17s1,s2Er3Al2s
Er3Al20Mg7sEr3Si5s1,s2Er3Zn11s
Er3Zn22sEr5Mg24sEr5Si3s
Er5Si4sEr5Sn3sEr5Sn4s
Er6Fe23sEr6Mn23sErAls
ErAl2sErAl3sErCr2Al20s
ErCu4Al8sErFe2sErFe2Al10s
ErFe3sErMgsErMg2s
ErMn12sErMn2sErSis
ErSn2sErSn3s1,s2ErTi2Al20s
ErV2Al20sErZnsErZn11s
ErZn12sErZn2sErZn2Mgs
ErZn3sErZn5sErZn6Mg3s
ErZnMg12sEus1-s3,lEu13Zn58s
Eu2Mg17sEu2Zn17s1,s2Eu3Si5s
Eu3Zn11sEu3Zn22sEu5Si3s
Eu5Si4sEu50Si87sEu8Si11s
EuAlsEuAl2sEuAl4s
EuCu4Al8sEuMgsEuMg2s
EuMg4sEuMg5sEuSis
EuSi2Al2sEuSn3sEuTi2Al20s
EuV2Al20sEuZnsEuZn11s
EuZn12sEuZn13sEuZn2s
EuZn3sEuZn5sFes1-s7,l
Fe18Sc10sFe2BsFe2Mos
Fe2NsFe2NbsFe2O3s
Fe2PsFe2Scs1,s2Fe2Sis
Fe2TisFe2WsFe3Bs
Fe3Cs1,s2Fe3C2sFe3Ns
Fe3O4s1-s4Fe3PsFe3Sis
Fe3Sn2sFe5C2s1,s2Fe5Si3s1,s2
Fe5Sn3s1-s3Fe6Sc29sFe6W6Cs
Fe60Te71sFe7C3sFe7W6s
Fe9Sc5sFeBsFeBe12s
FeBe2sFeBe5sFePs
FeP2sFeP4sFeSbs
FeSb2sFeSe2sFeSis1-s3
FeSi2s1-s3FeSns1,s2FeSn2s
FeTesFeTe2s1,s2FeTis
Gas1-s4,lGa2CusGa2Te3s
Ga2Te5sGa2TisGa3Te4s
Ga3TisGa3Ti2sGa3Ti5s
Ga39Na22sGa4Cu9sGa4Nas
Ga6SnTe10sGaAssGaNs
GaPsGaSbsGaTes
Gds1-s4,lGd11Sn10sGd12Co7s
Gd13Zn58sGd2AlsGd2Fe17s
Gd2Zn17s1,s2Gd3Al2sGd3Si5s1,s2
Gd3Sn7sGd3Zn11sGd3Zn22s
Gd4Sn11sGd5Si3sGd5Si4s1,s2
Gd5Sn3sGd5Sn4sGd6Fe23s
Gd6Mn23sGdAlsGdAl2s
GdAl3sGdAl4MgsGdCr2Al20s
GdCu4Al8sGdFe2sGdFe2Al10s
GdFe3sGdMgsGdMg2s
GdMg3sGdMg5sGdMn12s
GdMn2sGdSisGdSi2s1,s2
GdSi2Al2sGdSn2sGdSn3s1,s2
GdTi2Al20sGdV2Al20sGdZns
GdZn11sGdZn12sGdZn2s
GdZn2MgsGdZn3sGdZn5s
GdZn6Mg3sGdZnMg12sGes1-s3,l
GeAssGeAs2sGePs
GeTesHs,lHfs1-s3,l
Hf2CrsHf2SisHf3Si2s
Hf5Si3s1,s2Hf5Si4sHf5Sn3s1,s2
Hf5Sn4sHfBsHfB2s
HfH2sHfSisHfSi2s
HfSn2sHos1-s3,lHo11Sn10s
Ho13Zn58sHo2AlsHo2Al10Mg3s
Ho2Fe17sHo2Sn5sHo2Zn17s1,s2
Ho3Al2sHo3Si4sHo3Si5s1,s2
Ho3Zn11sHo3Zn22sHo5Mg24s
Ho5Si3sHo5Si4sHo5Si9s1,s2
Ho5Sn3sHo5Sn4sHo6Fe23s
Ho6Mn23sHoAlsHoAl2s
HoAl3sHoCr2Al20sHoCu4Al8s
HoFe2sHoFe2Al10sHoFe3s
HoMgsHoMg2sHoMn12s
HoMn2sHoSisHoSi2Al2s
HoSiAl2sHoSn2sHoSn3s1,s2
HoTi2Al20sHoZnsHoZn11s
HoZn12sHoZn2sHoZn2Mgs
HoZn3sHoZn5sHoZn6Mg3s
HoZnMg12sIns1-s3,lIn2Ags
In2CasIn2Li3sIn3Li13s
In5Na3sIn9Na5sInAg3s
InCa3sInLi2sInLi6s
InMg2sInNsInNas
InNa2sInPsInSbs
InSiNCsKs1-s3,lK2Os
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
Li2OsLi2Sr3sLi22Si5s
Li23Sr6sLi3AlH6sLi3Bis
Li4BasLi7Si3sLiAlH4s
LiB3sLiHsLiPbs
LiZnsLiZn4sLus1-s3,l
Lu11Sn10sLu13Zn58sLu2Als
Lu2Fe17sLu2Sn5sLu2Zn17s1,s2
Lu3Al2sLu3Si5sLu3Zn11s
Lu3Zn22sLu5Mg24sLu5Si3s
Lu5Si4sLu5Sn3sLu6Fe23s
Lu6Mn23sLuAlsLuAl2s
LuAl3sLuCu4Al8sLuFe2s
LuFe2Al10sLuFe3sLuMgs
LuMg2sLuMn2sLuMn5s
LuSisLuSn2sLuV2Al20s
LuZnsLuZn11sLuZn12s
LuZn2sLuZn2MgsLuZn3s
LuZn5sLuZn6Mg3sLuZnMg12s
Mgs1-s7,lMg11Si7Al3sMg12Zn13s
Mg17Ba2sMg2Bas1,s2Mg2Cas1,s2
Mg2Cus1,s2Mg2GasMg2Ga5s
Mg2GesMg2NisMg2Pbs
Mg2SisMg2Si6Al3s1,s2Mg2Sns
Mg2ZnsMg2Zn11sMg2Zn3s
Mg23Ba6sMg3Bi2s1,s2Mg3P2s
Mg3Sb2s1,s2Mg3Si6Al2s1,s2Mg4Si4Al4s
Mg4Si6Als1,s2Mg4Si6Al2sMg4Si7s
Mg4Si8sMg5Ga2sMg5In2s
Mg5Si6s1,s2Mg51Zn20sMg6Si3s
Mg6Si4sMg9Si5sMg9Si7Al3s
Mg9Si7Al5sMg9Si9Al3sMgAl2O4s
MgB2sMgB20sMgB4s
MgB7sMgBe13sMgCo2s
MgGasMgGa2sMgH2s
MgNi2sMgOsMgSis
MgSi2Al2sMgSi6Al4s1,s2MgZn2s1,s2
Mns1-s6,lMn11Si19sMn19Sn6s
Mn2BsMn2CaAl10sMn2Ns
Mn2NisMn2PsMn2Scs
Mn2SnsMn2TisMn2Ti2s
Mn2ZrsMn23C6sMn23Sc6s
Mn3AlCsMn3B4sMn3Cs
Mn3C2sMn3NsMn3Nis
Mn3PsMn3SisMn3Tis
Mn5C2sMn5Si3s1,s2Mn5SiCs
Mn5Sn3sMn6N4sMn6N5s
Mn6SisMn7C3sMn7Mo6s
Mn8Si2CsMn9Si2sMn9Ti2s
MnBsMnB2sMnB4s
MnBe12sMnBe2sMnBe5s
MnCa4Al7sMnNsMnNis
MnNi2sMnNi3sMnOs
MnPsMnSc4sMnSe2s
MnSisMnSn2sMnTis
Mos1-s3,lMo2BsMo2Cs
Mo2Hfs1,s2Mo2ZrsMo23C6s
Mo3B5sMo3Ni11sMo3Ps1,s2
Mo3SisMo4Ni3sMo5Si3s
Mo5Sn3sMoBsMoB2s
MoB4sMoCsMoNs1,s2
MoNi4sMoPsMoSe2s
MoSi2s1,s2MoTe2sMoZn22s
MoZn7sNlNas1-s3,l
Na2C2s1,s2Na2KsNa2LiAlH6s
Na2Os1-s3Na3AlH6s1,s2Na3Ass
Na3BisNa3PsNa3Sbs
Na4BasNaAlH4sNaB15s
NaB6sNaBasNaHs
NaMgH3sNaSisNaZn13s
Nbs,lNb2AlCsNb2B3s
Nb2CsNb2NsNb2Zn3s
Nb3B2sNb3B4sNb3C2s
Nb4FeSisNb5B6sNb5Si3s1,s2
Nb5Sn3sNb6Fe7sNbBs
NbB2sNbNsNbNi8s
NbSe2sNbSn2sNbZns
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
Ni11As8sNi12P5sNi2Bs
Ni2CrsNi2InsNi2In3s
Ni2Mg3AlsNi2MosNi2Ps
Ni2Sis1,s2Ni2TasNi2Tes
Ni2VsNi2YsNi2Y3s
Ni20Te17sNi23C6sNi3Bs
Ni3InsNi3In7sNi3Mos
Ni3PsNi3Sbs1,s2Ni3Sis1,s2
Ni3Si2sNi3Sns1,s2Ni3Sn2s
Ni3TasNi3TisNi3Vs
Ni3YsNi4B3sNi4Ws
Ni4YsNi5AlB4sNi5As2s
Ni5P2sNi5Sb2sNi5Si2s
Ni5Zr4sNi52Te40sNi6P5s
Ni7Sc2sNi7Y2sNi7Zr2s
Ni8AlB11sNi8TasNi8Ys
Ni8Zr3sNiAssNiAs2s1,s2
NiBsNiInsNiOs
NiP2sNiSbsNiSb2s
NiScsNiSe2sNiSis1,s2
NiSi2sNiSns1,s2NiSrs
NiTesNiTe2sNiTi2s1,s2
NiV3sNiWsNiW2s
NiYsNiY3sNiZn8s
NiZrsNiZr2sPs1-s4
Pbs1-s7,lPb10Nd11sPb10Pr11s
Pb2AusPb2DysPb2Nds
Pb2PrsPb2TbsPb2Zrs
Pb3AusPb3DysPb3Dy5s
Pb3NdsPb3Nd5sPb3O4s
Pb3PrsPb3Pr5sPb3Srs
Pb3Sr2sPb3Sr5sPb3Tbs
Pb3Tb5sPb3Zr5sPb4Dy5s
Pb4Nd3sPb4Nd5sPb4Pr3s
Pb4Pr5sPb4Sr5sPb4Tb5s
Pb5Li22sPb5Sr3sPbDys
PbNd3sPbOs1,s2PbO2s
PbPr3sPbSesPbSrs
PbSr2sPbTbsPbTes
PbZr4sPrs1-s4,lPr11Sn10s
Pr13Zn58sPr2AlsPr2Fe17s
Pr2SbsPr2Sn3sPr2Sn5s
Pr2Zn17s1,s2Pr2Zn9Mg5sPr3Als1,s2
Pr3Al11s1,s2Pr3Al50Mg22sPr3Si4s
Pr3SnsPr3Sn5s1,s2Pr3Sn7s
Pr3Zn11sPr3Zn22sPr3Zn30Mg13s
Pr4Sb3sPr5Mg41sPr5Sb3s
Pr5Si3s1,s2Pr5Si4s1,s2Pr5Si9s1,s2
Pr5Sn3s1,s2Pr5Sn4s1,s2Pr6Mn23s
PrAlsPrAl2sPrAl3s
PrCr2Al20sPrCu4Al8sPrFe2Al10s
PrMgsPrMg12sPrMg2s
PrMg3sPrSbsPrSb2s
PrSisPrSi2Al2sPrSns
PrSn2sPrSn3sPrTi2Al20s
PrV2Al20sPrZnsPrZn11s
PrZn12sPrZn2sPrZn2Al2s
PrZn2MgsPrZn3sPrZn5s
Sbs1-s3,lSb2Se3sSb2Sn3s
SbFe2sSbNi2sScs1-s4,l
Sc2Si3sSc5Si3sSc5Si4s1,s2
ScCu4Al8sScSisScV2Al20s
Ses1,s2,lSis1-s7,lSi2Te3s1,s2
Si2VsSi2WsSi2Zr3s
Si3N4sSi3TisSi3Zr5s1,s2
Si4Zr5sSi5V6sSi6Al5s1,s2
SiAssSiAs2sSiCs1-s6
SiO2s1-s8SiPs1,s2SiTa3s
SiTe2s1,s2SiZrsSiZr2s
Sms1-s4,lSm11Sn10sSm13Zn58s
Sm2AlsSm2Fe17sSm2Sbs
Sm2Sn3sSm2Sn5sSm2Zn17s1,s2
Sm2Zn9Mg5sSm3Al11sSm3Si5s
Sm3Sn7sSm3Zn11sSm3Zn22s
Sm3Zn30Mg13sSm4Sb3sSm4Sn3s
Sm5Mg41sSm5Sb3sSm5Si3s
Sm5Si4s1,s2Sm5Sn3sSm5Sn4s
Sm6Mn23sSmAlsSmAl2s
SmAl3sSmCr2Al20sSmCu4Al8s
SmFe2sSmFe2Al10sSmFe3s
SmMgsSmMg2sSmMg3s
SmMg5sSmMn2sSmSbs
SmSb2sSmSisSmSi2s1,s2
SmSi2Al2sSmSn2sSmSn3s
SmTi2Al20sSmV2Al20sSmZns
SmZn11sSmZn12sSmZn2s
SmZn2MgsSmZn3sSmZn5s
Sns1-s5,lSn14Ca12Mg7sSn2Li5s
Sn2NasSn2ZrsSn20Ca31s
Sn23Ca36sSn24Sr14Mg25sSn3Cas
Sn3Ca5sSn3Li7sSn3Li8s
Sn3NasSn3Na4sSn3Srs
Sn3Sr5sSn3SrMg5sSn4As3s
Sn4Li17sSn4NasSn4Na15s
Sn4Na9sSn4SrsSn5Li13s
Sn5Li2sSn5Sr3sSn5Ti6s
Sn6Ca7sSn6NasSnAg3s
SnAssSnCasSnFe2s
SnLisSnMgLi4sSnNas1,s2
SnNa3sSnNi2sSnSes1,s2
SnSe2sSnSrsSnSr2s
SnSrMgsSnTesSnTi2s
SnZr4sSrs1-s3,lSr13Cd58s
Sr18Zn62Mg20sSr2AlH7sSr2Mg17s
Sr2SisSr2Zn43Mg55sSr35Zn21Mg44s
Sr4Al38Mg58sSr5Cd3sSr5Si3s
Sr6Mg23sSr9Mg38sSrAlH5s
SrB6sSrBe13sSrC2s1,s2
SrCdsSrCd11sSrCd2s
SrCd6sSrH2s1,s2SrMg2s
SrSisSrSi2s1,s2SrSi2Al2s
SrZnsSrZn13sSrZn2s
SrZn5s1,s2Tas1,s2,lTa2Cs
Ta2CosTa2NsTa2Sis
Ta4C3sTa5Si3s1-s3TaNs1,s2
TaN3sTbs1-s3,lTb11Sn10s
Tb13Zn58sTb2AlsTb2Fe17s
Tb2Zn17s1,s2Tb3Al2sTb3Si5s
Tb3Sn7s1,s2Tb3Zn11sTb3Zn22s
Tb5Mg24sTb5Si3sTb5Si4s
Tb5Sn3sTb5Sn4sTb6Fe23s
Tb6Mn23sTbAlsTbAl2s
TbAl3sTbAl4MgsTbCr2Al20s
TbCu4Al8sTbFe2sTbFe2Al10s
TbFe3sTbMgsTbMg2s
TbMg3sTbMn12sTbMn2s
TbSisTbSi2sTbSi2Al2s
TbSn2sTbSn3sTbTi2Al20s
TbV2Al20sTbZnsTbZn11s
TbZn12sTbZn2sTbZn2Mgs
TbZn3sTbZn5sTbZn6Mg3s
TbZnMg12sTes1,s2,lTis1-s7,l
Ti2AlCsTi2CsTi2Crs
Ti2HsTi2MnsTi2Ns1,s2
Ti2OsTi2O3s1,s2Ti2Zns
Ti3AlsTi3AlCsTi3AlC2s
Ti3AlSi5sTi3B4sTi3O2s
Ti3SisTi3SnsTi4AlSi7s
Ti5Si3s1,s2Ti5Si4sTi5Sn3s1,s2
TiBsTiB2sTiCs
TiH2sTiNsTiN3s
TiOsTiO2s1,s2TiSis
TiSi2sTiZnsTiZn10s
TiZn15sTiZn2sTiZn3s
TiZn5sTms1-s3,lTm11Sn10s
Tm13Zn58sTm2AlsTm2Fe17s
Tm2Sn5sTm2Zn17s1,s2Tm3Al2s
Tm3Si5sTm3Zn11sTm3Zn22s
Tm5Mg24sTm5Si3sTm5Si4s
Tm5Sn3sTm6Fe23sTm6Mn23s
TmAlsTmAl2sTmAl3s
TmCu4Al8sTmFe2sTmFe2Al10s
TmFe3sTmMgsTmMg2s
TmMn12sTmMn2sTmSis
TmSn2sTmSn3s1,s2TmZns
TmZn11sTmZn12sTmZn2s
TmZn2MgsTmZn3sTmZn5s
TmZn6Mg3sTmZnMg12sVs1-s5,l
V2AlCsV2B3sV2Hfs
V2NsV2Tas1,s2V2Zrs
V23C6sV3B2sV3B4s
V3C2sV3SisV4Zn5s
V5C2sV5Si3s1,s2V7Al45s
VBsVB2sVNs
VSn2sVZn16sVZn3s
Ws1-s3,lW2BsW2B9s
W2ZrsW3C2sW5Si3s1,s2
WBs1,s2WCsWNs1,s2
WSe2sYs1-s4,lY11Sn10s
Y13Zn58sY15Zn70Mg15sY2Fe17s
Y2Mn9Al5sY2Sn5sY2Zn17s1,s2
Y3Si5s1,s2Y3Zn11sY3Zn22s
Y3Zn30Mg13sY5Si3sY5Si4s
Y5Sn3s1,s2Y5Sn4sY6Fe23s
Y6Mn23sYAl2sYbs1-s4,l
Yb13Zn58sYb2Zn17s1,s2Yb3Si5s
Yb3Zn11sYb3Zn22sYb5Si3s
Yb5Si4sYb50Si87sYb8Si11s
YbAl2sYbAl3sYbCr2Al20s
YbCu4Al8sYbFe2Al10sYbMg2s
YbSisYbSi2Al2sYbTi2Al20s
YbV2Al20sYbZnsYbZn11s
YbZn12sYbZn2s1,s2YbZn3s
YbZn5sYCr2Al20sYCu4Al8s
YCuAlsYFe2sYFe2Al10s
YFe3sYMn12sYMn2s
YNi5sYSisYSi2s1,s2
YSi2Al2sYSn2sYSn3s1,s2
YV2Al20sYZnsYZn11s
YZn12sYZn2s1,s2YZn2Mgs
YZn3sYZn5sYZn6Mg3s
YZnMg12sZns1-s9,lZn12Scs
Zn17Sc2s1,s2Zn17Sc3sZn2Lis
Zn2ScsZn2ZrsZn2Zr3s
Zn22Fe2TisZn22ZrsZn3AlLis
Zn3As2s1,s2Zn3Li2sZn3P2s1,s2
Zn3Sb2sZn3Zrs1,s2Zn39Zr5s
Zn4Sb3s1,s2Zn5Li2sZn5Sb3s
Zn58Sc13sZn62Ca8Al30sZn7Li3s
Zn9MnsZnAlLisZnAs2s
ZnOsZnP2s1,s2ZnSbs
ZnScsZnTesZnZrs
ZnZr2sZrs1-s8,lZr2AlCs
Zr3SisZr5Sn3s1,s2ZrBs
ZrB12sZrB2sZrCs
ZrH2sZrNsZrSi2s