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Structure
Type Prototype
CC Code Space
Group SG
Num. ANX
Form. Wyckoff
Symbol Pearson
Symbol c/a
Min c/a
Max AET
Pearson
Note Description

(Bi7Pb)Pt4 58336 PNMA c3 oP12 2 2.5

(H3O)Yb3F10(H2O) 84661 Fd3-mZ 227 h f2 e2 d cF320

(Mn, Fe)2PO4F 16930 I12/c1 15 f8 mS64 triplite

(NbS)(NbS2) 54267 P21221 18 c8 b a oP20

(NH3)2HI 36569 Pm3-m f a cP10

(NH3)3Ti(O2)F5 201509 Fm3-m j e c b a cF88

(NH3)3Ti(O2)F5 201509 Fm3-m j e c b a cF96

(NH4)8Fe2(CN)12 (H2O)3 30513 Ia3-d h2 g c b a cI600

Aenigmatite 15283 P1- 2 i33 c b aP68

Aerugite 2882 R3-mH 166 h3 e c3 a hR27

Ag16Ca6N 78395 IM3-M h e c a cI46 Ca: 17: NAg12Ca4; Ag1: 12: Ag6Ca6; Ag2: 12: Ag8Ca4; N: octahedron: Ca6 Na16Ba6N, Ag8Ca3, Na16Ba6N, Ca6Ag16N Nested polyhedra units consisting of a central N atom surrounded by a Na6 octahedron, a Na8 cube and a Na12 cuboctahedron; the cubes share corners along the body diagonals.

Ag2O3 15999 PN3-MS d b cP10 Ag: octahedron: O6: O: tetrahedron: Ag4 Mg3P2, SB: D5(5)

Ag2O3 15999 PN3-MS 224 d c cP10 Ag: octahedron: O6: O: tetrahedron: Ag4 Mg3P2, SB: D5(5)

Ag3AsS3 27841 R3CH 161 b2 a hR14 Proustite, Ag3SbS3

Ag3CsS2 1033 C12/m1 12 i6 mS24 .5 .6

Ag3SI 202120 Pm3-m h b a cP5

Ag4K23 863 C12/m1 12 i9 mS36

Ag51Gd14 9085 P6/m 175 l3 k2 j2 h e c hP64

Ag8GeTe6 25 F4-3m h6 g e c a cF60

Ag8SiS6 1054 Pna21 a15 oP60

Ag9GaSe6 15252 F4-3m i h2 e c b a cF64

Ag9GaSe6(P213) 2411 P213 b4 a4 cP64

AgAsS2 18101 R3-H f4 hR24 .6 .72 trechmannite, LiSbS2

AgBiSe2 26519 P3-m1 164 d4 c b a hP12

AgCrSe2 25626 R3MH a4 hR4 5.00 7.20 CuCrSe2, CuCrS2

AgCuS 66580 Cmc21 36 a3 oS12 1.5 2 Stromeyerite

AgErSe2 15302 P212121 a4 oP16 .54 .69

AgFeO2 2786 P63/MMC f c a hP8 3.65 4.3 CuFeO2

AgK2As 1154 C2221 20 c b a oS16

AgPb2Cl3OHF 87757 Fd3-mZ 227 f e2 d cF144

AgSbO3 87786 Fd3-mZ 227 f d c cF72

AgSbO3 87786 Fd3-mZ 227 f d c cF79

AgSbO3 87786 Fd3-mZ 227 f d c cF80

AgSbO3 87786 Fd3-mZ 227 f d c cF96

AgTlTe2 43284 I4-m2 e c a tI8

AgYbS2 27091 I41md 109 a4 tI16

Al10Fe2Yb 151140 Cmcm 63 g2 f2 e d c oS52

Al10V 58202 Fd3-mZ 227 g f d c cF176

Al11La3 57937 Immm 71 l2 i h d a oI28

Al11La3 57937 Immm 71 l2 j g c a oI28

Al12W 58207 Im3- g a cI26

Al18Cr2Mg3 57659 FD3-MS 227 g f d c a cF184

Al18Cr2Mg3 57659 FD3-MS 227 g f d c b cF184 Al18Mn2Mg3

Al2(SO4)3 39003 R3-H 148 f5 c2 hR34 2.4 2.95 millosevichite

Al23Gd4Ni6 370010 C12/m1 12 i16 c mS66

Al2Be3Si6O18 31891 P6/MCC m l2 f c hP58 0.90 1.15 beryl

Al2Ca3Ge2 52616 Immm 71 h g2 b oI14

Al2Ca3Si3O12 31082 IA3-D h d c a cI160 Al: octahedron: O6; Ca: square antiprism: O4+4; Si: tetrahedron: O4; O: tetrahedron: AlCa2Si garnet, grossularite, SB: H3(1)-(S1(4)) Isolated SiO4 terahedra.

Al2CdS4 25634 I4- g c b a tI14 1.558 2.207 Al1, Al2, Cd: tetrahedron: S4; S: copl. triangle: Al2Cd (+6S with S-S= 3.7-4.0) CdGa2S4(alpha), Ag2HgI4(beta), thiogallate, SB: E3 Close packed S layers in c stacking, Cd and Al in tetrahedral voids. AlS4 tetrahedra share corners to form a 3D-framework.

Al2Cu 42518 I4/MCM h a tI12 0.582 0.825 Al: 15: Al11Cu4; Cu: bicapped sq. antiprism: Al8Cu2 CoSn2, NaInS4, Fe2B, SB: C16=C51 IGS of slabs containing infinite columns of CuAl8 square antiprisms.

Al2CuCl8 80107 P121/c1 14 e5 a mP22

Al2CuMg 57693 Cmcm 63 f c2 oS16 1.5 2

Al2CuMg 57693 Cmcm 63 g c2 oS16 1.5 2

Al2Gd3 57869 P42nm 102 c4 b tP20

Al2Li3 57951 R3-mH c2 a hR5 2.8 3.5

Al2MgO4 56116 FD3-MS 227 e c b cF56 Al: octahedron: 6O; Mg: tetrahedron: 4O; O: tetrahedron: Al3Mg MgF2eO4, ZrTi2H4, MgFe2O4, spinel, SB: H1(1) For inverse spinel: 8M(3+) on 8b, 8M(2+) + 8M(3+) on 16c; Other Wyckoff-sequence: e d a (by shift 1/2 1/2 1/2); close packed O layers in c stacking, Mg in tetrahedral, Al in octahedral voids.

Al2MgO4 56116 FD3-MS 227 e d a cF56 Al: octahedron: 6O; Mg: tetrahedron: 4O; O: tetrahedron: Al3Mg MgF2eO4, ZrTi2H4, MgFe2O4, spinel, SB: H1(1) For inverse spinel: 8M(3+) on 8b, 8M(2+) + 8M(3+) on 16c; Other Wyckoff-sequence: e d a (by shift 1/2 1/2 1/2); close packed O layers in c stacking, Mg in tetrahedral, Al in octahedral voids.

Al2MgO4, reduced symmetry 46023 F4-3m e3 c a cF56

Al2Mo3C 42917 P4132 d c a cP24

Al2Mo3C 42917 P4132 d c b cP24

Al2Mo3C 42917 P4332 d c a cP24

Al2Mo3C 42917 P4332 d c b cP24

Al2O3 56085 R3-CH e c hR10 2.30 3.20 Lu2S3, D51

Al2O3 56085 R3-CR e c hR10 Lu2S3, D51

Al2S3 73220 P61 a5 hP30 In2Se3

Al2Zr3 58232 Fdd2 43 b2 a oF40

Al2Zr3(tP20) 58231 P42/mnm 136 j g f d tP20

Al3CuHo 55424 Immm 71 j i a oI10

Al3Fe 57795 C12/m1 12 j6 i12 g d mS101

Al3Ho 57912 R3-MH h2 d c2 b hR20 5.20 7.00

Al3Ho 57912 R3-MH h2 e c2 a hR20 5.20 7.00

Al3Ni2 107713 P3-M1 d2 a hP5 1.10 1.38 D5(13)

Al3Ni2 107713 P3-M1 d2 b hP5 1.10 1.38 D5(13)

Al3Os2 58109 I4/mmm 139 e2 a tI10 4.15 4.7

Al3Pu 58141 P63/mmc 194 k h f b hP24 2.2 2.5

Al3ScC3 62308 P63/mmc 194 f2 d c a hP14

Al3Ti 58189 I4/MMM d b a tI8 1.870 2.650 "All cuboctahedra: Al1.2: Al8Ti4; Ti: Al12" SB: D0(22) Aristotype is Cu; close packed TiAl3 layers (Ti atoms form square mesh) in c stacking.

Al3Y2Si2 75228 C12/m1 12 N2O2P3 i3 a mS14

Al3Zr 107130 I4/MMM e2 d c tI16 3.630 5.142 All cuboctahedra: Al1.2.3: Al8Zr4; Zr: Al12 SB: D0(23) Close packed layers in c stacking. Asistotype is Cu

Al3Zr4 150529 P6- j h f b hP7

Al4C3 52287 R3-MH c3 a hR7 6.8 8.3 YFeO4

Al4C3 52287 R3-MH c3 b hR7 6.8 8.3 YFe2O4, D7(1)

Al4C3 52287 R3-MR c3 a hR7 YFe2O4, D7(1)

Al4Cu9 57670 P4-3m i2 g f e4 cP52

Al4La 57936 Imm2 44 d5 b2 a3 oI30

Al4Mo2Yb 456 I4/MMM h d a tI14 0.70 0.90 ErTi2Ga4

Al4NiY 58077 Cmcm f c3 a oS24

Al4NiY 58077 Cmcm f c3 b oS24

Al4U 107243 Imma 74 h e2 b oI20 3 3.3

Al5Co2 30207 P63/mmc 194 k h2 d a hP28

Al6Mn 57972 Cmcm 63 g f e c oS28

Al7Sr8 58168 P213 b4 a3 cP60

Al8CaCo2 57534 Pbam 55 h5 g5 d a oP44

Al8Cr5 823 R3mH 160 c b6 a2 hR26

Al9Co2 57598 P121/c1 14 e5 a mP22

Al9Co2Sr 57633 P6/mmm 191 m f c a hP12

Al9Na4Ge14 100018 P4-3N i e2 d c a cP54 K4Al3(Ge, Al)20

AlAu4 57498 P213 b a2 cP20

AlB2 52282 P6/MMM d a hP3 0.95 1.20 Al: 18: B12Al6; B: coboctahedron: B6Al6 SB: B32 3D-framework of fused BAl6 trigonal prisms. B atoms form planar hexagon-mesh nets. Close packed Al layers in A stacking, B occupies all trigonal prismatic voids.

AlCe 57551 Cmcm 63 g c a oS16

AlCe 57551 Cmcm 63 g c b oS16

AlCl3(H2O)6 22071 R3-cH 167 f e b hR44

AlCr2C 42918 P63/MMC f c a hP8 4.00 4.90

AlCr2C 42918 P63/MMC f d a hP8 4.00 4.90 BaCeN2, RbScO2, Ti2CS, V2AsC, Zr2CS, Ta3MnN4, TlInS2

AlCu 40332 I12/m1 12 i4 c a mS20

AlCu 40332 I12/m1 12 i4 d a mS20

AlDy 57734 Pbcm 57 d3 c oP16 .85 1.05

AlF3(H2O)3 66691 P4/NZ 85 g c2 b tP26 0.397 0.563 Al: octahedron: F2(F, O)4; F: 2 nonlinear Al; (F, O): 1 Al +(1F 1O 3(F, O); O: 8(F, O) rosenbergite

AlFe2B2 20322 Cmmm j i a oS10

AlLi3N2 25565 Ia3- e d c a cI96

AlLiSi 52630 F4-3M c b a cF12 Al: 10: Si4Li6; Li: 10: Si4Al6; Si: cube: Al4Li4 LiAlSi, CuMgSb, CuMnSb, PtSbY, MgAgAs, SB: C1(b) Aristotype is CaF2-type; close packed As layers in c stacking, Mg and Ag in tetrahedral voids.

AlLiSi 52630 F4-3M d c a cF12 Al: 10: Si4Li6; Li: 10: Si4Al6; Si: cube: Al4Li4 LiAlSi, CuMgSb, CuMnSb, PtSbY, MgAgAs, SB: C1(b) Aristotype is CaF2-type; close packed As layers in c stacking, Mg and Ag in tetrahedral voids.

alluaudite 200238 C12/c1 f8 e3 a mS78

alluaudite 200238 C12/c1 f8 e3 a mS80

alluaudite 200238 C12/c1 f8 e3 b mS75

alluaudite 200238 C12/c1 f8 e3 b mS76

alluaudite 200238 C12/c1 f8 e3 b mS78

alluaudite 200238 C12/c1 f8 e3 b mS79

alluaudite 200238 C12/c1 15 f8 e3 b mS80

alluaudite 200238 C12/c1 15 f8 e3 d mS80

AlNb3Se6 25374 P63/mmc 194 f2 b hP7

AlOOH(diaspore) 77326 Pbnm c3 oP16 .6 .75 diaspore

AlOOH(diaspore) 77326 Pnma c3 oP16 .4 .6 diaspore

ALP3O9 26759 I4-3d e4 c cI208

AlPO4 44880 P3121 c2 b a hP18 2.00 2.50 berlinite

AlTh2H4 43313 I4/mcm NO2P4 l h a tI28

amblygonite 20577 P1- 2 i8 h a aP16 LiAlPO4F

amblygonite 20577 P1- 2 i8 h a aP17 LiAlPO4F

amblygonite 20577 P1- 2 i8 h a aP18

Analcime 1C 2930 Ia3-d h g c b cI208 NaAlSi2O6H2O, S6, Zeolite-ANA

Analcime 1M 40451 I12/a1 15 f22 e2 mS208 .98 1.02

Analcime 1O 34877 Ibca 73 f10 e d c oI208 .98 1.02

Analcime 1Q 34875 I41/acdS 142 g4 f2 e b tI208 .98 1.02

ancylite 95445 Pmcn 62 d c4 oP30

ancylite 95445 Pmcn 62 d c5 oP30

andalusite 24275 Pnnm 58 h g5 e oP32

andalusite 24275 Pnnm 58 h g5 e oP36

andalusite 24275 Pnnm 58 h g5 f oP32

andalusite 24275 Pnnm 58 h g5 f oP36

anthophyllite 30254 Pnma 62 d17 c5 oP164 ortho-amphibole

apophyllite 1O 34881 Pnnm 58 h9 g2 b a oP116

apophyllite 1Q 30259 P4/mnc 128 i4 h g b a tP116

arrojadite 31752 C12/c1 15 f40 e2 b a mS340

As 53794 R3-MH c hR2 2.50 3.10 A7

As 53794 R3-MR c hR2 A7

As4O6 36144 FD3-MS 227 f e cF80 As: octahedron: O3+3 (As-O 2.01 and 2.78); O: tetrahedron: As2+2 (+4O) Sb2O3, arsenolite, senarmontite, SB: D5(4)=D61 As4O6 cage molecules with four As3O3 rings.

AsBr3 24589 P212121 AX3 a4 oP16 SbBr3

atelestite 70112 P121/c1 14 e9 mP40

Au3K2 65113 Immm j h a oI10

Au3NaSi 16462 PA3- d c2 cP40 AuNa3Ge ?? isopointal zu SnI4 ??

Au3Sb4Y3 957 I4-3D c b a cI40

Au4KSn2 58522 I4-c2 120 i e d tI28

Au6Sm 2050 P42/ncm 138 j2 i2 e d tP56

AuBe5 58397 F4-3M e c a cF24 Au: 16: (Be2)12(Be1)4; Be1: 16: (Be2)12Au4; Be2: icosahedron: (Be2)6(Be1)3Au3 Be5Pd, Ni5U, SB: C15(b) Laves-type slabs in c stacking. Frank-Kaspar phase (FKP).

aubertite 8225 P1- 2 i12 g f e aP55 AlCu(SO4)2Cl(H2O)14

AuCaGe 85836 Pnma NOP c9 oP36 .31 .4

AuCd 58409 Pmma f e oP4 0.9 1.15

AuCd 58409 Pmmb f e oP4 1.35 1.75

AuCu 42575 P4/MMM c b tP2 1.20 1.50

AuCu 42575 P4/MMM d a tP2 1.20 1.50 12-b SB: L1(0)-type; aristotype is Cu; isopointal with HgMn-type; close packed CuAu layers in c stacking

AuCu3 42587 PM3-M c a cP4 All cuboctahedra: AL: Cu12; Cu: Al4Cu8 "Al3U, UAl3, Ca3Hg, auricupride, SB: L1(2)" Aristotype is Cu-type, obtained for ordered structure; close packed Cu3Au layers (Au atoms form triangular mesh) in c stacking.

AuCu3 42587 PM3-M d b cP4

Autunite 33193 I4/mmm 139 e3 d a tI97 2.65 3.3 Ca(UO2)2(PO4)2 (H2O)10.5

axinite 4343 P1- 2 i26 aP54

B 972 R3-mH 166 i4 h10 c b hR105

B 972 R3-mH 166 i4 h10 c2 b hR105

B 972 R3-mH 166 i4 h10 c2 b hR106

B 972 R3-mH 166 i5 h11 c3 b hR108

B13C2 23923 R3-mH 166 h2 c b hR15

Ba(IO3)2 23276 C12/c1 f4 e mS36 .6 .7

Ba(IO3)2 23276 I12/a1 15 f4 e mS36 .85 .95

Ba2.4Bi1.6O6 73981 Fm3-m j c b a cF40

Ba2Mn8O16 62096 C12/m1 12 i6 b mS25

Ba2Mn8O16 62096 C12/m1 12 i6 b mS26

Ba2MnS3 26231 Pnma AB2X3 c6 oP24

Ba2Ni(NO2)6 24508 Fm3-m h e c a cF84

Ba2NiTeO6 25005 R3-MH 166 h2 c3 b a hR20

Ba2Zn7O18 40925 P1- 2 i13 b aP27

Ba3CdSn2S8 49028 I4-3d e d c2 b cI116

Ba3FeN3 36502 P63/M h2 c hP14 .62 .8

Ba3FeN3 36502 P63/M h2 d hP14 .62 .8

Ba3Si2Ba18O5 491556 Fd3-mZ 227 g f e d c b a cF224

Ba3Yb4O9 33239 R3H 146 b3 a7 hR16

Ba4OCl6 16026 P63MC c3 a2 hP22

Ba4OCl6 16026 P63MC c3 b2 hP22

Ba4SiAs4 26467 P4-3n i2 e2 d a cP72

Ba5AlIr2O11 67143 Pnma 62 d3 c13 oP76

Ba5Si3 24598 P4/ncc 130 g f c2 tP32

Ba8Y3Pt4O17.5 202817 Pm3-m h g e d c a cP32

BaAlF5 37033 P212121 19 ABX5 a7 oP28

BaBiO3 87326 I12/m1 j i2 c a mS20

BaBiO3 87326 I12/m1 j i2 d a mS20

BaCd11 58644 I41/AMDS 141 i c b a tI48 0.541 0.766

BaCd11 58644 I41/AMDS 141 i d b a tI48 0.541 0.766 "Ba: 22: (Cd1)2(Cd2)4 (Cd3)8+8; Cd1: 14: (Cd2)4(Cd3)8Ba2; Cd2: 12: (Cd1)2(Cd3)10Ba2; Cd3: isosahedron: Cd10Ba2"

BaCdSnS4 10472 Fdd2 43 b13 a2 oF224

BaCl2O6 40285 Fdd2 43 b4 a oF72

BaCu2S2 66656 Pmma 62 AB2X2 c5 oP20 1 1.22

BaFe2S4 23081 I4/M h d a tI14 0.6 0.77

bafertisite 20369 C1m1 b25 a14 mS144

bafertisite(substr.) 20290 P121/m1 11 f4 e7 a mP36

BaHg11 58656 PM3-M j i g c a cP36 CdCd11

BaHg11 58656 PM3-M j i g d b cP36 CdCd11

BaMnFeAl2(OHPO4)3 6207 P121/m1 11 f9 e5 mP52 bjarebyite

BaMnS2 31453 Pnma 62 c4 oP16 1.75 2.2 SrZnO2

BaMo6S8 65775 P1- 2 i7 a aP15

banalsite 4447 Ibam 72 k5 j2 g a oI108

BaNd2NiO5 62627 Immm 71 l i d b a oI18 2.8 3.3

BaNd2NiO5 62627 Immm l j c b a oI18 2.8 3.3

BaNd2NiO5 62627 Immm 71 l j d c a oI18 2.8 3.3

BaNiO3 30661 P63/MMC h c a hP10 0.75 1.00 BaTiS3, BaVS3, CsNiCl3, NaBa3N

BaNiO3 30661 P63/MMC h d a hP10 0.75 1.00 BaTiS3, BaVS3, CsNiCl3, NaBa3N

BaNiSn3 58662 I4MM b a3 tI10 1.905 2.699 "Ba: 17: Ni5Sn12; Ni: 10: Ba5Sn5; Sb1: monocapped sq. antiprism: Ba4NiSn4; Sn2: 12: Ba4Ni2Sn6" BaPtSn3, SrNiSn3

BaP3 23618 C12/m1 12 j i2 mS16

BaPb3 58665 R3-MH g d c b hR12 3.00 4.20

BaPb3 58665 R3-MH h e c a hR12 3.00 4.20

BaPt 55492 P63/MMC c a hP4 .9 1.2

BaPtSb 59186 P6-M2 e c b hP3 0.86 1.10 LiBaSi, SrPbSb, ThAuSi, YbPtP

BaPtSb 59186 P6-M2 f d a hP3 0.86 1.10 LiBaSi, SrPbSb, ThAuSi, YbPtP

BaS3 23637 P4-21m 113 e c a tP8

BaSi2O5 100314 C12/c1 15 f11 e a mS96

BaSiF6 26613 R3-MH 166 h b a hR8 .93 1

BaSO4 31894 PBNM d c4 oP24 0.64 0.85

BaSO4 31894 PBNM d c4 oP40 0.64 0.85

BaSO4 31894 PNMA d c4 oP24 0.73 0.90 KGaH4m, Sb: H2

BaSO4 31894 PNMA d c4 oP40 0.73 0.90

BaSr5Lu2W3O18 37058 R3-MH 166 h3 c5 a hR29

BaTiO3-2H 34619 P63/MMC k h f2 b a hP30 2.3 2.7

BaTiSi3O9 36185 P6-C2 l k2 e c hP28 also benitoite-type

BaUO4 36239 Pmab 57 e d2 c a oP24

BaV10O15 14173 Ccmb 64 g4 f2 e d b a oS104 .79 .96

BaZn5 58684 Cmcm 63 g e c2 oS24 .45 .55

BaZnFe6O11 24575 R3-MH 166 h4 c6 b a hR38

BaZnO2 25559 P3121 c b a hP12 1.1 1.25

Be17Nb2 58724 R3-mH 166 h g e c2 hR19

Be17Ru3 58735 Im3- h g3 f e d cI160

Be2CaGe2 25337 P4/NMMS 129 c3 b a tP10 2.072 2.936 "Ce: 16+5: Be8Ge8(BeCa4); Be1, Ge1: 12: Ca4Be4Ge4; Be2, Ge2: monocapped sq. antiprism: Be2: Ge5Ca4; Ge2: Be5Ca4" BaMg2Pb2

Be2SiO4 36276 R3-R 148 f7 hR42 phenakite, eucryptite, S1(3)=H13

Be3N2 25656 P63/MMC f c b a hP10 2.8 3.8

Be3Nb 58723 R3-MH h c2 b a hR12 4.10 5.30 Ni3Pu

Be7Rh 16030 P6-m2 187 n j i h g2 f d hP18

BeMg2Al6O12 31257 R3-mH 166 h4 d c7 a hR42

BeO 18147 P42/MNM g f tP8

Bi2Cu(SeO3)4 66827 P121/c1 14 e9 a mP38 .7 .86

Bi2CuO4 68813 P4/NCCS 130 g f c tP28 0.573 0.812 Bi: 6: O4+2 (+1Bi); Cu: square: O4 (+2Cu); O: tetrahedron: Bi3Cu kusachiite

Bi2Ni3Se2 1024 C12/m1 12 j i3 h f mS28

Bi2Pb2Se5 30372 P3-m1 164 d3 c a hP9

Bi2Te3 15753 R3-MH c2 a hR5 6.20 8.00 As2Te3, Bi2Se3 isopointal with AgCrSe2

Bi2Te3 15753 R3-MH c2 b hR5 6.20 8.00 As2Te3, Bi2Se3 isopointal with AgCrSe2

Bi2Te3 15753 R3-MR c2 a hR5 1 1

Bi2Te3 15753 R3-MR c2 b hR5 1 1

Bi4(SiO4)3 402349 I4-3d e c a cI76

BiF3/Cu2MnAl 24522 FM3-M c b a cF15

BiF3/Cu2MnAl 24522 FM3-M c b a cF16 Bi: 14: (F2)8(F1)6; F1: 14: (F2)8Bi6; F2: 14: (F1)4Bi4(F2)6 BiF3, Cu2MnAl, Heusler-type, gananite, SB: D0(3), L2(1) Bi atoms form Cu-type substructure, F in all octahedral and tetrahedral voids. 3D-framework of fused BiF8 and FF8 cubes. Sequence along body diagonal: -Bi-F-F-F-. For metallic occupation: Cu2MnAl-type with W as aristotype

BiI 1558 C12/m1 i8 mS32 1.25 1.56

BiI3 36182 R3-H 148 f c hR8

BiIn 58790 P4/nmmZ 129 c a tP4 .66 .98

BiIn(hP1) 58789 P6/MMM a hP1 0.85 1.10

BiIn(hP1) 58789 P6/MMM b hP1 0.85 1.10

Bikitaite 1A 29551 P1 a22 aP26 zeolite-BIK Common (Si, Al)O2-framework in a18 with 18 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

BiO 30361 R3MH 160 a2 hR2 Slightly deformed ZnS(sphalerite)-type. Alpha=59.05 instead of ideal 60 degree.

BiSe 20458 P3-m1 164 d4 c2 hP12

bloedite 20576 P121/a1 14 e8 a mP50 .45 .55

BN 35538 P63/MMC d c hP4

bobfergusonite 63261 P121/n1 14 e39 d a mP156 Na2Mn5FeAl(PO4)6

boggsite 69120 Imma j19 i6 h5 g2 oI699 zeolite-BOG Common (Si, Al)O2-framework in j15 i2 h2 g2 with 288 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

boracite 30616 Pca21 29 a24 oP96

boracite (HT) 30351 F4-3c 219 h e d c b a cF192

botryogen 16938 P121/n1 14 e19 b a mP140

BPO4 26890 I4- g c a tI12

brackebuschite 76869 P121/m1 11 f2 e9 a mP30

brackebuschite 76869 P121/m1 11 f2 e9 a mP31 .8 1.2

brackebuschite 76869 P121/m1 11 f2 e9 a mP32 .8 1.2

brewsterite 15885 P121/m1 11 f12 e5 c mP79 1.1 1.2 zeolite-BRE Common (Si, Al)O2-framework in f12 e4 c with 48 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

brookite 56155 Pbca 61 c3 oP24 TiO2(oP)

C(cF8) 53779 FD3-MS 227 a cF8 Diamond, SB: A4

Ca14AlSb11 33266 I41/acdS 142 g5 f e b a tI208

Ca2Al2FeSi3O12OH 20387 P121/m1 11 f3 e13 c a mP44 epidote

Ca2AlFeO5 27112 Pnma 62 d3 c2 a oP36 .95 1.05 brownmillerite

Ca2MgSi2O7 34805 P4-21M f e3 c a tP24 0.544 0.771 4-a, 8-b; 4-a Ca2ZnSi2O7, melilite, hardystonite Units of two corner-linked SiO4 tetrahedra share corners with MgO4 terahedra to form infinite layers.

Ca3Al2(OH)12 66274 Ia3-d h c a cI232 hydrogarnet Related to garnet structure with (OH)4 instead of SiO4

Ca3Al2SO4 (OH)10(H2O)2 28378 C12/c1 15 f10 e2 mS112

Ca3Ge2As4 16455 P121/c1 14 e9 mP36 .95 1.06

Ca3ZrSi2O9 79453 P121/c1 14 e15 mP60

Ca5(PO4)3Cl 24237 P63/M i h4 f b hP42 .66 .77 also apatite-type (2 types depending on Cl- or F-position

Ca5(PO4)3F 30261 P63/M i h4 f a hP42 .66 .77

Ca5(PO4)3F 30261 P63/M i h4 f a hP43 .66 .77

Ca5(PO4)3F 30261 P63/M i h4 f a hP44 .66 .77

Ca7Ge 43321 FM3-M d b a cF32 CuPt7

Ca7Sn6 54618 Pnma 62 N6O7 d5 c3 oP52

Ca9Zn4Bi9 8157 Pbam 55 h5 g5 d b oP44 .2 .26

CaAl12O19 34394 P63/MMC k3 h f3 e d b a hP64 3.50 5.50 hibonite, magnetoplumbite

CaAl12O19 34394 P63/MMC 194 k3 h f3 e2 c a hP64 3.50 5.50

CaAl12O19 34394 P63/MMC 194 k3 h f3 e2 d a hP64 3.50 5.50

CaAl2Si2O8 23922 P1- 2 i52 aP104 anorthite

CaAl4O7 44519 C12/c1 15 f5 e2 mS48 .37 .48 grossite

CaAlSiO4OH 12127 P212121 a8 oP36 austinite, adelite, vuagnatite

CaB2Si2O8 20590 Pnma 62 d5 c3 oP52 danburite

CaB6 26893 PM3-M NO6, AX6 e b cP7 SB: D2(1)

CaB6 26893 PM3-M f a cP7 Ca: 24: B24; B: tetrag. pyramid: B5 (+4Ca) B6Ca, SB: D2(1) B6 octahedra are interconnected via exo-bonds to form a 3D-framework.

CaBSiO4OH 24667 P121/c1 14 e8 mP32 datolite

CaBSiO4OH 24667 P121/c1 14 e8 mP36 datolite

CaC2 56158 F4/MMM e a tI6 0.001 2.000

CaC2 56158 F4/MMM e b tI6 0.001 2.000 Ca: 10: C2+8; C: 1+5: deformed octahedron: CCa5 SB: C11(a) Isopointal with MoSi2- and CuZr3-type. C-C-dumbbells (C-C= 1.15)

CaC2 56158 I4/MMM e a tI6 1.380 1.956 Ca: 10: C2+8; C: 1+5: deformed octahedron: CCa5 SB: C11(a) Isopointal with MoSi2- and CuZr3-type. C-C-dumbbells (C-C= 1.15)

CaC2 56158 I4/MMM e b tI6 1.380 1.956 Ca: 10: C2+8; C: 1+5: deformed octahedron: CCa5 SB: C11(a) Isopointal with MoSi2- and CuZr3-type. C-C-dumbbells (C-C= 1.15)

CaCl2 26686 Pnnm g a oP6 0.6 0.75

CaClOD 62041 P63MC b2 a hP8 2.3 2.9

CaCO3(hR10) 37241 R3-cH e b a hR10 2.95 4.00 calcite, SB: G1

CaCO3(hR10) 37241 R3-cR e b a hR10 calcite, SB: G1

CaCO3(oP20) 56090 Pmcn ABX3 d c3 oP20 1 1.35 aragonite

CaCO3(oP20) 56090 Pnma ABX3 d c3 oP20 1.2 1.55 aragonite

CaCrF5 10286 C12/c1 15 f2 e2 a mS28

CaCu 58880 P121/m1 11 e10 mP20

CaCu5 58882 P6/MMM f d b hP6 0.72 0.90 CaZn5, ErCo5

CaCu5 58882 P6/MMM g c a hP6 0.72 0.90 CaZn5, ErCo5 D2(d)-type

CaF2 53978 FM3-M c a cF12 Ca: cube: F8; F: 4+6: tetrahdron: Ca4 (+6F) Mg2Si, Li2O, fluorite, anti-fluorite, SB: C1 Includes also the anti-type as Li2O; close packed Ca layers in c stacking, F occupies all tetrahedral voids. 3D-framework of edge-sharing CaF8 cubes.

CaF2 53978 FM3-M c b cF12 Ca: cube: F8; F: 4+6: tetrahdron: Ca4 (+6F) Mg2Si, Li2O, fluorite, anti-fluorite.SB: C1 Includes also the anti-type as Li2O; close packed Ca layers in c stacking, F occupies all tetrahedral voids. 3D-framework of edge-sharing CaF8 cubes.

CaFe2O4 16695 PBNM AB2X4 c7 oP28 0.24 0.35 CaV2O4, BaSm2S4

CaFe2O4 16695 PNAM AB2X4 c7 oP28 0.25 0.40 CaV2O4, BaSm2S4

CaFe2O4 16695 PNMA AB2X4 c7 oP28 1.00 1.30 CaV2O4, BaSm2S4

CaFe3Si2O7OOH 31306 P121/a1 14 e15 mP64 ilvaite

CaGaN 2027 P4/nmmZ 129 c3 tP6

CaGe2Ni4 449 P3121 152 c9 b2 a2 hP63

CaHPO4 38128 P1- 2 i12 aP28 monetite

CaIn2 58906 P63/MMC f a hP6 1.42 1.80

CaIn2 58906 P63/MMC f b hP6 1.42 1.80

CaLiAlF6 25022 P3-1c i d c b hP18 Colquiriite

CaLiSi2 25327 Pnma 62 c4 oP16

CaMg(CO3)2 56091 R3-H f c b a hR10 2.95 4.00 CaSn(BO3)2, dolomite, SB: G11 Aristotype is CaCO3(hR10)

CaMg(CO3)2 56091 R3-R ABC2X6 f c b a hR10 CaSn(BO3)2, dolomite, SB: G11 Aristotype is CaCO3(hR10)

CaMg(SiO3)2 30294 C12/c1 15 f4 e2 mS40 diopside

Cancrinite 44892 P63 c9 b a hP56 zeolite-CAN Common SiAlO4-framework in c6 with 36 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

CaRh2B2 49737 Fddd 70 f e a oF40

carpholite 34520 CccaZ 68 i6 f2 e oS152

carpholite 34520 CccaZ 68 i6 f2 e b oS140

carpholite 34520 CccaZ 68 i7 f2 e b oS139

CaSb2 862 P121/m1 11 e3 mP6 1.8 2.2

CaSi2(hR3) 15632 R3-MH c a hR3 3.75 5

CaSi2(hR6) 52789 R3-MH 166 c3 hR6

CaSiO3 20589 P121/a1 14 e15 mP60 wollastonite

CaSO4 56107 Cmcm 63 g f c2 oS24 anhydrite, ferruccite

CaSO4(H2O)2 27875 I12/c1 15 f3 e2 mS48 gypsum

CaSO4(H2O)2 27875 I12/c1 15 f3 e2 mS52 gypsum

CaTiO3 31865 PM3-M c b a cP5 Ti: octahedron: O6; Ca: cuboctahedron: O12; O: 2+4: colinear Ti2 (+4Ca) CaPdH2, Ca3PbO, CeRh3B, Fe3PtN, LaPd3B, Mn3AlC, perovskite, SB: E2(1) Includes also anti-types as AlFe3C; close packed CaO3 layers (O atoms from Kagome net) in c stacking, Ti in octahedral voids. TiO6 octahedra share corners to form a 3D-framework. Linear PdH2 units in CaPdH2.

CaTiO3 31865 PM3-M c b a cP9 Ti: octahedron: O6; Ca: cuboctahedron: O12; O: 2+4: colinear Ti2 (+4Ca) CaPdH2, Ca3PbO, CeRh3B, Fe3PtN, LaPd3B, Mn3AlC, perovskite, SB: E2(1) Includes also anti-types as AlFe3C; close packed CaO3 layers (O atoms from Kagome net) in c stacking, Ti in octahedral voids. TiO6 octahedra share corners to form a 3D-framework. Linear PdH2 units in CaPdH2.

CaTiO3 31865 PM3-M d b a cP5 Ti: octahedron: O6; Ca: cuboctahedron: O12; O: 2+4: colinear Ti2 (+4Ca) CaPdH2, Ca3PbO, CeRh3B, Fe3PtN, LaPd3B, Mn3AlC, perovskite, SB: E2(1) Includes also anti-types as AlFe3C; close packed CaO3 layers (O atoms from Kagome net) in c stacking, Ti in octahedral voids. TiO6 octahedra share corners to form a 3D-framework. Linear PdH2 units in CaPdH2.

CaTiO3 31865 PM3-M d b a cP9 Ti: octahedron: O6; Ca: cuboctahedron: O12; O: 2+4: colinear Ti2 (+4Ca) CaPdH2, Ca3PbO, CeRh3B, Fe3PtN, LaPd3B, Mn3AlC, perovskite, SB: E2(1) Includes also anti-types as AlFe3C; close packed CaO3 layers (O atoms from Kagome net) in c stacking, Ti in octahedral voids. TiO6 octahedra share corners to form a 3D-framework. Linear PdH2 units in CaPdH2.

CaTlSe2 1573 C1c1 9 a16 mS64

CaWO4 15586 I41/AZ 88 f b a tI24 1.703 2.413 Ca: square antiprism: O8; W: tetrahedron: O4; O: copl. triangle: Ca2W (+7O) scheelite, NaAlH4 Isolated AlH4 tetrahedra in NAlH4.

Cd2Ce 58951 P3-M1 d a hP3 0.60 0.80 EuGe2

Cd2Ce 58951 P3-M1 d b hP3 0.60 0.80 EuGe2

Cd3PCl3 201025 P3- g e d2 b hP14

Cd3PCl3 201025 P3- g f d2 a hP14

Cd45Sm11 2246 F4-3m h6 g f e6 d c b a cF440

Cd45Sm11 2246 F4-3m h6 g f e6 d c b a cF448

Cd4GeS6 26214 C1c1 9 a11 mS44 .9 1.2

Cd58Gd13 58979 P63/MMC l k5 j i h3 g f c b a hP142 0.60 1.10 Gd2Zn9, Gd2Cd9, Pu2Zn9, Gd13Zn58

Cd58Gd13 58979 P63/MMC l k5 j i h3 g f d b a hP142 0.60 1.10 Gd2Zn9, Gd2Cd9, Pu2Zn9, Gd13Zn58

Cd6Y 9148 IM3- h g4 f e d cI168

CdCl2(3R) 30255 R3-MH c a hR3 3.7 5

CdCl2(3R) 30255 R3-MR c a hR3

CdGeO3 23531 I41/AZ 88 f8 e d c b a tI160 0.830 1.176 Cd1: 8: O8; Cd2: 8: O6+2; Cd3: 6: O6; Ge1: 6: O6; Ge2.3: 4: O4; Ge4: 6: O4+2; O1.4.5: 4: Cd3Ge; O3.6: 4: Cd2Ge2; O2: cop garnet Aristotype is Mg3Al2Si3O12

CdI2(18R) 42269 R3-MH 166 c4 a hR9

CdI2(2H) 53983 P3-M1 d a hP3 1.42 1.85 Cd(OH)2, Mg(OH)2, Ta2C, SB: C6

CdI2(2H) 53983 P3-M1 d b hP3 1.45 1.85

CdI2(4H) 38116 P63MC b2 a hP6 2.6 3.5 C27-type, CdI2-family (of stacking variants) Zhdanov-symbol: (2 2) (for iodine layers)

CdI2(hP9) 20745 P3-M1 AX2, NO2 d3 c a hP9 3.5 5

CdIn2Se4 25648 P4-2m 111 n f a tP7

CdMn2O4 24258 I41/AMDS 141 h d a tI28 1.427 2.022 Cd: tetrahedron: O4; Mn: octahedron: O4+2; O: tetrahedron: CdMn2+1 Close packed O layers in c stacking, Mn in octahedral, Cd in tetrahedral voids.

CdP4 25605 P121/c1 14 e2 a mP10

CdTm4Mo3O16 108783 Pn3-NZ 222 i f e d c cP96

Ce2Co7B3 20086 P6/MMM i2 h e d c b a hP24 2.20 2.90

Ce2Cu9In3 102134 Pnnm 58 h2 g9 d a oP56

Ce2CuGe6 76491 Amm2 38 b5 a4 oS18

Ce2Ni17C3 81738 I4/mcm 140 l2 k d a tI56

Ce2Ni22C3 20555 Cmca 64 g9 f7 e b a oS216

Ce2Ni2Sn 55495 Immm j h a oI10 1.9 2.4

Ce2Ni7 102233 P63/MMC k h f3 e a hP36 4.30 6.50

Ce3Ni6Si2 25622 IM3-M h e c cI44

Ce5Co19 102100 R3-mH 166 h2 c5 b a hR24

Ce5Mg41 102220 I4/m 87 i3 h4 f b a tI92

Ce5Ni2Si3 60153 P63/m 176 h6 c b hP40

Ce6Ni2Si3 42100 P63/m 176 h3 c b hP22 .3 .4

CeAgAs2 413723 Pmca 57 e d4 c2 oP32

CeAl2Ga2 57576 I4/MMM e d a tI10 2.212 3.150 Ce: 20: Ga8Al8Ce4; Al: 12: Ga4Al4Ce4; Ga: monocapped sq. antiprism: GaAl4Ce4 ThCr2Si2, Al4Ba, LiCu2P2, ThCr2Ge2, CaAl2Zn2, PrNi.5Ga3.5, SB: D1(3) Infinite layers of interconnected AlGa4 tetrahedra. Ga-Ga dumb-bells. (for deviations see 3rd. ref.)

CeAsS 42432 P121/n1 14 e3 mP12 4 4.8

CeCO3F 27591 P6-2C i h2 g f a hP36 1.20 1.55 bastnaesite

CeCo4B 42101 P6/MMM i d c b a hP12 1.23 1.55 B2-dumbbells, B-B=1.72

CeCo4B4 16193 P42/NMCZ 137 g2 b tP18 1.182 1.674 Ce: 24: Co12B12; Co: 12: B5Co4Ce3; B: 9: BCo5Ce3 Q-Phase B-B-dumbbells (B-B=1.72) and isolated Co4 tetrahedra.

CeCoC2 20827 C1c1 9 a4 mS16

CeCr2B6 16203 Immm 71 l j h a oI18

CeCu6 102127 Pnma 62 NO6 d c5 oP28

CeCu6 102127 Pnma 62 NOP5 d c5 oP28 1.1 1.43

CeF3 4 P3-c1 g f d a hP24 LaF3, Cu3P, HoH3, tysonite

CeMn6Ni5 102223 P4/MBM k j g c a tP24 0.50 0.90 U(Ni.68Si.32)11 tP24, P4/mbm, 1.5-1.9, k j g c a, 102223

CeNi12B6 60771 Cmc21 36 b7 a5 oS76

CeNi3 102230 P63/MMC k f d c b a hP24 2.90 3.80

CeNi5Sn 20350 P63/mmc k f2 d c b a hP28

CeNiC2 20397 Amm2 e b a oS8

CeNiSi2 42711 CMCM 63 c4 oS13 BaCuSn2, SrCuSn2

CeNiSi2 42711 Cmcm 63 c4 oS14 BaCuSn2, SrCuSn2

CeNiSi2 42711 CMCM 63 c4 oS15 BaCuSn2, SrCuSn2

CeNiSi2 42711 CMCM 63 c4 oS16 BaCuSn2, SrCuSn2

CePO4(hP18) 31563 P6222 k d c hP18 0.80 1.05 rhabdophane

CePO4(mP) 27860 P121/a1 e6 mP24 monazite

CePO4(mP) 27860 P121/n1 ABX4 e6 mP24 .9 1.1

chabazite 18197 R3-mH i2 h3 g f hR37 Common (Si, Al)O2-framework in i h2 g f with 36 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules

chabazite 18197 R3-mR 166 i2 h3 g f e c2 hR77 Common (Si, Al)O2-framework in i h2 g f with 36 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules

chapmanite 200068 C1m1 8 b5 a4 mS30 Fe2SbSi2O8OH

chevkinite(mP) 6251 P121/c1 14 e16 d c b mP70 chevkinite(mP), Mg2Nd4Ti3Si4O22

chevkinite(mS) 75471 C12/m1 12 j3 i9 e d b a mS70

Chloritoid 2M 16679 C12/c1 15 f10 e c mS104

Chloritoid 2M 16679 C12/c1 15 f10 e c mS95

Chudobaite 267 P1- 2 i17 a aP57

ClF3 19079 Pnma 62 d c2 oP16

CO 26962 P213 a2 cP8 isolated C-O molecules SB: B?-type; isopointal with FeSi-type

Co(NH3)5NO2ClNO3 39510 Pna21 33 a14 oP116

Co11Ga6Sm26 20824 P4/mbm 127 l2 k2 j h g2 f2 e2 a tP86

Co19Zr5P12 40859 P6-2m 189 k2 j g2 f3 e c hP36

CO2(cP12) 22398 PA3- c a cP12 Isolated linear O=C=O molecules, C-O=1.043 Isopointal to FeS2(cP12)

Co2GaGd6 102430 Immm 71 n m l i h d b oI36 Co2+xIn1-xHo6

Co2GaGd6 102430 Immm 71 n m l j g c a oI35 Co2+xIn1-xHo6

Co2GaGd6 102430 Immm 71 n m l j g c a oI36 Co2+xIn1-xHo6

Co2In4Lu3 102502 P6- 174 k j f d a hP9

Co2InTb 102444 Pmma 51 f e2 b oP8

Co2InTb 102444 Pmma 51 f2 e a oP8

Co2P2O7 2830 B121/c1 e11 mP44

Co2P2O7 2830 P121/c1 A2B2X7 e11 mP44 1.1 1.4

Co2Si 52281 PMNB c3 oP12 1.7 2.2 Ca2Si, Ni2Si, Rh2Ge, SB: C37

Co2Si 52281 PNAM c3 oP12 0.67 0.85 Ca2Si, Ni2Si, Rh2Ge, SB: C37 Differs from MgSrSi-type by slightly different axial ratios

Co2Si 52281 PNMA c3 oP12 1.25 1.66 Ca2Si, Ni2Si, Rh2Ge, SB: C37 Differs from MgSrSi-type by slightly different axial ratios

Co3Ga9Y2 20951 Cmcm 63 h g2 f e c a oS56 Co3Ga9Ho2

Co3Ho4 23191 P63/m 176 h3 d b hP21

Co3Lu2Si5 76349 C12/c1 15 f3 e4 mS40

Co3Nb4Si7 53019 I4/mmm 139 k j i h2 e c tI56

Co3U2Si5 20930 Ibam 72 j3 g b a oI40

Co3V 102718 P6/mmm 191 o i h e hP24

Co3W9C4 16888 P63/MMC k h2 g c hP32 0.90 1.15

Co3W9C4 16888 P63/MMC k h2 g d hP32 0.90 1.15

Co4Fe4Th 102409 R3-mH 166 h f d c2 a hR19

Co4Ge7Zr4 16931 I4/MMM k j2 i h2 e tI60 0.35 0.45 Nb4Co4Si7

Co4Hf2P3 25758 P6-2M k j2 g3 f2 d b hP36 0.26 0.35 Co4Nb2P3

Co4Hf2P3 25758 P6-2M k2 j g2 f3 c a hP36 0.26 0.35 Co4Nb2P3

Co4NdB4 2372 P42/NS 86 g2 a tP18 0.47 0.60 B-B dumbbells, B-B=1.74; edge sharing Co4 tetrahedra

Co4NdB4 2372 P42/NS 86 g2 b tP18 0.454 0.644 Nd: 20: B12Co8 (+2Nd); Co: 13: B5Co6Nd2; B: 9: BCo5Nd3 B-B-dumbbells. B-B=1.74. Infinite chains of edge-sharing Co4 tetrahedra and infinite -Nd- chains.

Co4Sc5Si10 30519 P4/MBM j i2 h2 g a tP38 0.275 0.390 Co: 10: Si5Sc5; Sc1: 16: Si12Co4; Sc2: 15: Si8Co4Sc3; Sc3: 20: Si10Co4Sc6; Si1: 9: SiCo2Sc6; Si2: 12: Co2Si7Sc3; Si3: 12 Co2Sc3Si5 Double infinite columns of base-linked SiSc6 trigonal prisms. Infinite columns of Co(Sc4Si4) square antiprisms.

Co5Cr2Mo3 102320 R3-H 148 f8 c2 b hR53 1.5 2

Co5YP3 40505 Pnma 62 c9 oP36

Co6Ho7Sn23 63511 Pm3-1 164 i4 g d2 b a hP36

Co7Er2 102366 R3-MH h d c4 a hR18 7.00 9.50 Co7Gd2

Co7Er2 102366 R3-MH h e c4 b hR18 7.00 9.50 Co7Gd2

Co7Ho12 610 P121/c1 14 e9 b mP38 1.6 1.7

Co7Ho6Ga21 20260 P4/mbm 127 j3 i3 h2 g2 d a tP68

Co9S8 31753 FM3-M f e c b cF68 Pentlandite, (Fe, Ni)9S8 SB: D8(9)-type

CoAs 15065 Pna21 a2 oP8 .55 .7

CoAs3 38229 IM3- g c cI32 Skutterudite, SB: D2 SB: D0(2)-type

coesite 36261 C12/c1 15 f5 e a mS48 .9 1.11

CoGa3Pr8 20941 P63mc c3 b2 a hP24 .6 .72

CoGa8Ho2 42426 P4/MMM i h g e a tP11 2.30 3.00 tP11, P4/mmm, 2.3-3, i h g e a, 42426

CoGe 43677 C12/m1 12 i3 c a mS16

CoHoGa5 42427 P4/MMM i c b a tP7 1.50 1.68 CoUGa5

CoHoGa5 42427 P4/MMM i d b a tP7 1.50 1.68 CoUGa5

CoHoGa5 42427 P4/MMM i d c a tP7 1.50 1.68 CoUGa5

CoIn3 102500 P4-n2 i f e tP16

combeite(HT) 31245 R3-mH 166 h3 g e d c a hR32 Na4Ca4si6O18

CoMo2S4 2018 C1c1 9 a14 mS56 1 1.15

CoNb3S6 42688 P6322 i f c a hP20 1.80 2.50 MnNb3S6, FeTi3S6

CoNb4Si 43233 P4/MCC m c a tP12 0.70 1.40

CoNbB2 41893 Pnma c4 oP16 1.2 1.5

CoO 53059 I4/MMM b a tI4 1.174 1.664 Co: octahedron: O6; O: octahedron: Co6 Aristotype is NaCl; Close packed layers in c stacking, Co in octahedral voids.

copiapite 23662 P1- 2 i28 a aP99 MgFe4(SO4)6 (OH)2(H2O)20

Cordierite 36248 Cccm 66 m3 l6 k g b oS116 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g b a oS118 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g b a oS125 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g c b a oS121 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g c b a oS124 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g c b a oS129 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g d b a oS129 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g2 c b oS121 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

Cordierite 36248 Cccm 66 m3 l6 k g2 c b oS123 Mg2Al2Si(Al2Si4O18) Channels of (Al2Si4O18)-rings may contain H2O or CO2

CoSb2 43500 P121/c1 14 e3 mP12

CoSeO3(H2O)2 69219 P121/n1 14 e7 mP44 cobaltomenite

CoSn 102671 P6/MMM f d a hP6 0.72 0.90 SB: B35

CoSn 102671 P6/MMM g c b hP6 0.72 0.90 SB: B35

CoUC2 63622 P4/nmmZ 129 c3 tP8

CoUC2 63622 P4/nmmZ 129 c3 a tP8

CoW2B2 16776 Immm h f a oI10 .4 .5 Mo2NiB2

CoYC(tP3) 65818 P4/mmm e d a tP3

CoYC(tP6) 61684 P42/mmc 131 e c b tP6

CoZn13 102736 C12/m1 12 j2 i2 c a mS28

CoZr2Si 2371 C12/m1 12 i5 mS20

Cr(NH3)6CuCl5 22076 Fd3-cZ 228 h g e c b cF992

Cr11Ge8 42123 Pnma 62 d3 c13 oP76

Cr12P7 30547 P63/m 176 h4 a hP19

Cr23C6 43377 FM3-M h f e c a cF116 Cr1: 12: (Cr4)12; Cr2: 16: (Cr3)3(Cr4)12; Cr3: 13: (Cr3)2(Cr3)3 (Cr4)6C3; Cr4: 14: Cr12C2; C: square antiprism: Cr8 C6Cr23, tau-carbide, SB: D8(4) 3D-framework of corner-linked CCr8 square antiprisms, additional Cr atoms in unterstices - or - fused Mn alpha-type nested polyhedra units, additional Cr atoms in interstices.

Cr23C6 43377 FM3-M i f e c b cF116 Cr1: 12: (Cr4)12; Cr2: 16: (Cr3)3(Cr4)12; Cr3: 13: (Cr3)2(Cr3)3 (Cr4)6C3; Cr4: 14: Cr12C2; C: square antiprism: Cr8 C6Cr23, tau-carbide, SB: D8(4) 3D-framework of corner-linked CCr8 square antiprisms, additional Cr atoms in unterstices - or - fused Mn alpha-type nested polyhedra units, additional Cr atoms in interstices.

Cr2Ho2C3 62083 C12/m1 12 i3 c mS14 Dy2Fe2Si2C

Cr2Ho2C3 62083 C12/m1 12 i3 d mS14 Dy2Fe2Si2C

Cr2S3(hP20) 16720 P3-1C i f c b hP20 1.75 2

Cr2S3(hR10) 16721 R3-H 148 f c b a hR10 2.7 3

Cr3AsN 25760 I4/mcm 140 h c b a tI20

Cr3S4 16722 C12/m1 12 i3 a mS14

Cr3Si 16835 PM3-N c a cP8 Cr: 14: Cr2+8Si4; Si: icosahedron: Cr12 W3O, UH3, SB: A15 SiCr12 icosahedra share faces and egdges to form a 3D-framework. Frank-Kaspar phase (FKP).

Cr3Si 16835 PM3-N d a cP8 W3O, UH3, SB: A15 SiCr12 icosahedra share faces and egdges to form a 3D-framework. Frank-Kaspar phase (FKP).

Cr5B3 27124 I4/MCM l h c a tI32 1.637 2.319 9-a, 10-c, 14-b, 16-a Ba5Pb3, SB: D8(l) IGS of U3Si2- and CuAl2 thetatype slabs. One B-B dumb-bell for one single B atom.

Cr5CsS8 2566 C12/m1 12 i6 d a mS28 .45 .52

Cr7C3 87129 Pnma 62 d3 c4 oP40

crandallite 6195 R3-mH 166 h2 d c2 a hR27

crandallite 6195 R3-mH 166 h2 f d c2 hR27 CaAl3PO4PO3OH(OH)6

crandallite 6195 R3-mH 166 i h2 d c2 hR26

CrB4 24353 Immm n a oI10

CrCuS2 100595 R3mH 160 a5 hR4

CrEr2S4 657 Pca21 29 a14 oP56

CrFe 102748 P42/MNM j i2 f a tP30 0.433 0.614 M1.4: 12: M12; M2.5: 15: M15; M3: 14: M14 SB: D8(b)

Cristobalite high 35536 Fd3-mZ 227 c a cF24

CrMoO3 27551 R32H 155 d c hR5

CrNb4Se8 53191 P63/mmc 194 k g f b a hP26

CrSi2 16836 P6222 j d hP9 1.30 1.65 SB: C40

CrU2N3 87244 Immm 71 i2 b a oI12

CrU8S17 1990 C12/m1 12 j3 i6 c a mS52

CrYB4 16171 PBAM h2 g4 oP24 0.50 0.65 FeSmB4

CrYB4 16171 PBAM h4 g2 oP24 0.50 0.65 FeSmB4

CrZrSi2 20554 Pbam 55 i3 h2 g3 e oP48 MnTiSi2, FeScSi2

CrZrSi2 20554 Pbam 55 i3 h3 g2 f oP48

Cs2(Mo3SeO12) 75473 P63 c5 b2 a hP36 1.5 1.86

Cs2CuCl4 36175 Pnma 62 AB2X4 d c5 oP28

Cs2LiCo(CN)6 60538 Fm3-m e2 c b a cF64

Cs2S2O6 200865 P63MC c2 b3 a hP20

Cs2TeO3 59164 P321 g d2 b a hP12 1.05 1.3

Cs2Zn3S4 53242 Ibam 72 k j g b oI36

Cs3Cr2Cl9 16706 P63/MMC k h f2 b hP28 2.3 2.7

Cs3Cr2Cl9 16706 P63/MMC k h f2 e hP28 2.3 2.7

Cs3Ir(NO2)6 28640 Fm3-m h e c b a cF88

Cs3Re3S4I4 88610 Fm3-m f e2 d c cF112

Cs3Re5OsS11 50226 Im3- h2 g f e d cI160

Cs3Tl2Cl9 26657 R3-cH 167 f e2 c hR28 1 1.5

Cs5SiP3 65715 Pnma 62 AB5X3 c9 oP36

CsAlSi2O6 15964 IA3-D h g b cI160 pollucite

CsCd(NO2)3 56431 R3H 146 b3 a2 hR11

CsCl 53847 PM3-M b a cP2 Cs: 14: Cl8Cs6; Cl: 14: Cs8Cl6 ClCs, CuZn, SB: B2 3D-framework of fused CsCl8 (or ClCs8) cubes.

CsCl 53847 PM3-M b a cP6 Cs: 14: Cl8Cs6; Cl: 14: Cs8Cl6 ClCs, SB: B2 3D-framework of fused CsCl8 (or ClCs8) cubes.

CsClO4 31430 Fm3-m f b a cF24

CsCu3S2 23326 P3-M1 e d b hP6

CsCu3S2 23326 P3-M1 f d a hP6

CsFeF4 6043 P4/nmmZ 129 j i d c b tP24

CsFeF4 6043 P4/nmmZ 129 j i e c a tP24

CsI3 27252 Pnma 62 c4 oP16

CsN3 28537 Pm3-m e b a cP4

CsNbN2 72546 Fd3-mZ 227 c b a cF32

CsNd(PO4)4 20154 I4-3d e4 c a cI216

CsSCN 60870 Pnma 62 c4 oP16

Cu 53755 FM3-M a cF4 Cu: cuboctahedron: Cu12 Au, ccp, SB: A1 Close packed layers in c stacking.

Cu15Si4 36254 I4-3d e c a cI76

Cu2(OH)2CO3 30609 P121/a1 14 e8 mP40 .3 .38 malachite

Cu2AsO4OH 1112 P121/c1 14 e8 mP36

Cu2Cl(OH)3 14203 Pnma 62 d c3 a oP36 atacamite

Cu2ErS2 16812 P3- d2 a hP5 1.45 1.80

Cu2FeSnS4 26721 I4-2M i d b a tI16 1.650 2.337 All tetrahedra: Cu, Fe, Sn: S4; S: Cu2FeSn (+12S) stannite, kuramite Close packed S layers in c stacking, cations in tetrahedral voids. Isolated SnS4 tetrahedra. Aristotype is ZnS(cF8)

Cu2HgI4 25591 I4-21m 121 i d a tI14

Cu2Mg 103048 FD3-MS 227 d a cF24 Cu: 12: Cu6Mg6; Mg: 16: Mg4Cu12 Laves-phase-cubic, Friauf-phase-cubic, ZrW2, SB: C15=C39 Frank-Kaspar phase (FKP). Mg(Mg4Cu12) Friauf polyhedra (Mg4 terahedron + Cu12 truncated tetrahedron) share hexagonal faces of the truncated tetrahedra to form a 3D-framework. Binary Laves-type slabs in c stacking.

Cu2Mg 103048 FD3-MZ 227 c b cF24 Cu: 12: Cu6Mg6; Mg: 16: Mg4Cu12 Laves-phase-cubic, Friauf-phase-cubic, ZrW2, SB: C15=C39 Frank-Kaspar phase (FKP). Mg(Mg4Cu12) Friauf polyhedra (Mg4 terahedron + Cu12 truncated tetrahedron) share hexagonal faces of the truncated tetrahedra to form a 3D-framework. Binary Laves-type slabs in c stacking.

Cu2O 31057 Pn3-mS 224 b a cP6 cuprite, Ag2O

Cu2SnSrS4 43131 P3221 c3 b a hP24 2.2 2.8

Cu2SnSrS4(P31) 356 P31 144 a8 hP24 2.2 2.8

Cu2SnZnS4 200419 I4- 82 g d c b a tI16

Cu3As 100149 I4-3d e c cI64

Cu3As(HT) 16840 P3-c1 165 g f d b hP24

Cu3AsS4 26743 Pmn21 31 b2 a4 oP16 .71 .99 Enargite, Li3PO4(LT), H2(5)

Cu3FeS4 100727 P3-M1 d3 c hP8 2.4 3.2

Cu3P 16247 P3-m1 164 d3 c hP8

Cu3Pd 107169 P4/MMM i3 h3 g3 e c a tP28 6.7 7.7

Cu3Pd 107169 P4/MMM i3 h3 g3 f d b tP28 6.7 7.7

Cu3SbS3 31113 I4-3m g e d c cI56

Cu3Ti 107712 PmmnZ 59 f b a oP8 .75 .98

Cu3VS4 36169 P4-3M e c b cP8 Cu3SbS4, SB: H2(4)

Cu3VS4 36169 P4-3M e d a cP8 Cu3SbS4 H2(4)-type

Cu4KS3 23336 P4/mmm 123 i h b a tP8

Cu4Mn3Bi4 58775 Fm3-m f e d c cF88

Cu4NaAs2 59205 R3-mH 166 c3 a hR7 5 6.5

Cu4Zr3Si4 87200 Immm 71 l j i h a oI22

Cu4Zr3Si4 87200 Immm 71 n h f e a oI22

Cu4Zr3Si4 87200 Immm 71 n h f e d oI22

Cu5Zn8 103158 I4-3M g e c2 cI52 gamma-brass, SB: D82

Cu7Tb 9115 P6/MMM g e c a hP6 0.72 0.96

Cu7Tb 9115 P6/MMM g e c a hP7 0.72 0.96

Cu7Tb 9115 P6/MMM g e c a hP8 0.72 0.96

Cu8Rb3Se6 14011 C12/m1 12 i8 b mS34

CuAsS 23826 Pna21 a3 oP12 .3 .37

CuClSe2 68292 P121/c1 14 e4 mP16 1.8 2

CuClSe2 68292 P121/n1 14 e4 mP16 1.3 1.5

CuFe2(AsO4)2 (OH)2(H2O)4 100444 P121/c1 14 e9 a mP58 arthurite

CuFe2S3 29095 Pnma 62 d2 c2 oP24

CuFePt2 53259 P4/MMM e c a tP4 0.80 1.20 12-b Ti3Cu, SrPb3 SB: L6(0)-type; Aristotype is Cu; ordered AuCu-type;

CuFePt2 53259 P4/MMM f d b tP4 0.80 1.20

CuFeS2 30289 I4-2D d b a tI16 1.651 2.340 All tetrahedra: Cu, Fe: S4; S: Cu2Fe2 chalcopyrite, SB: E1(1) Aristotype is ZnS(cF8); close packed S layers in c stacking, Fe and Cu in tetrahedarl voids. 3D-framework of corner-linked FeS4 tetrahedra.

CuHf2Ge4 30733 Cmcm c7 oS28

CuHfSi2 87147 P4/NMMS 129 c2 b a tP8 2 2.65

CuHg2Ti 102972 F4-3M d c b a cF16 All rhombic dodecahedra (8+6): Cu: Hg4Ti4Hg6; Hg1: Hg4Ti4Cu6; Hg2: Cu4Hg4Ti6; Ti: Cu4Hg4Hg6 Li2AgSb, Li2AuSn, Li2CaGe, Li2MgSn, Li2AlRh Sequence along body diagonal: -Li-Li-Ag-Sb-. Aristotype is W

CuLaS2 24375 P121/c1 14 e4 mP16 .8 1.2

CuMg2 103047 Fddd 70 f e2 oF48 Mn2B

CuMg2 103047 Fddd 70 f2 e oF48 Mn2B

CuMg2 103047 Fddd 70 g2 e oF48 Mn2B

CuMg2 103047 Fddd 70 g2 f oF48 Mn2B

CuNa2(CO3)2 10355 P121/c1 14 e5 a mP22

CuNb2Se4 25375 P63/mmc 194 f2 c hP7

CuNb2Se4 25375 P63/mmc 194 f2 d hP7

CuP2 35282 P121/c1 14 e3 mP12

CuPbAsS3 18121 Pmn21 31 b3 a6 oP24 .9 1 seligmannite, CuPbSbS3

CuSO4 16747 Pnma 62 d c3 a oP24 chalcocyanite

CuTi 103128 P4/NMMS 129 c2 tP4 1.70 2.15

CuZr2 103164 I4/MMM e a tI6 3.000 5.000 Cu: 8+6: Zr8Cu4Zr2; Zr: 13: Cu4Zr9 SB: C11(a) Isopointal with MoSi2- and CaC2-type

dachiardite 28316 B112/m 12 j9 i6 f e mS114 Common (Si, Al)O2-framework in j5 i6 f e with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

diadochite 87770 P1- 2 i19 aP64 Fe2PO4SO4OH(H2O)6

Dodecasil 3C 201182 Fd3-mZ 227 h g2 f e2 a cF408 zeolite-MTN Common (Si, Al)O2-framework in h g2 with 144 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

Dodecasil-1H 48153 P6/MMM 191 r O3 n l k j i h c hP102 .75 .87 zeolite-DOH

donnayite-1A 43454 P1 1 a33 aP39 NaCeSr2(CO3)4(H2O)2

donnayite-3R 43453 R3mH 160 c2 b2 a4 hR13

dufrenite 34830 C12/c1 15 f16 e c a mS178 Ca(FeOH)12(PO4)8 (H2O)4

dufrenite 34830 C12/c1 15 f16 e c a mS180 Ca(FeOH)12(PO4)8 (H2O)4

dumortierite 100443 Pnma 62 d11 c7 oP115

dumortierite 100443 Pnma 62 d11 c7 oP121

dumortierite 100443 Pnma 62 d11 c7 oP125

Dy2OS2 36603 Pnma 62 A2XY2 c5 oP20 .39 .5

Dy3Ni2 2334 C12/m1 12 i5 mS20 .8

Dy5Pd2 103347 Fd3-mS f e3 cF96

DyGe2-x 53362 Cmc21 36 a6 oS23

edingtonite 323 P21212 18 c9 b a oP53 zeolite-EDI

ekanite(tI) 64745 I422 97 k3 j c a tI62

ekanite(tP) 2858 P4/mcc 124 n3 m f b a tP63

ekanite(tP) 2858 P4/mcc 124 n3 m f b a tP64

epistilbite 16995 C12/m1 12 j8 i3 h2 g2 f e b mS123

epsomite 16595 P212121 19 a13 oP108 MgSO4(H2O)7

Er2FeC4 42968 Ibam 72 j3 a oI28

Er2Mo2C3 88514 C12/m1 12 i3 a mS14

Er2Ni3B6 65737 Cmmm 65 q i h g d oS22 .4 .5

Er2Pd2Si 35438 Pnnm g5 oP20 .5 .65

Er2RhSi3 53413 P6-2c i h f b hP24

Er3GaS6 2511 Cmc21 36 b3 a4 oS40

Er3Ni2 2150 R3-H e2 d a hr15 1.60 2.20

Er3Ni2 2150 R3-H f2 c b hr15 1.60 2.20

Er3Pd7P4 74936 C12/m1 12 i6 d b mS28

Er3Ru4Si12 62185 Cmca 64 g2 f2 e d2 a oS76

Er4NiB13 20700 P4/MNC i h g b a tP36 0.00 1.15

Er4Rh4Sn13 103302 I41/ACDS 142 g5 f2 e d b tI232 1.80 2.25 Tb4(Tb.5Sn.5)Rh6Sn18, Tb5Rh6Sn17

Er5CSi3 54106 P3-m1 164 j2 i18 h g f e d4 c b a hP162

Er7CSi4 54105 P6-m2 187 o k6 j6 i h g hP48

Er8Rh5C12 74646 C12/m1 12 i12 a mS49

Erionite 31143 P63/mmc 194 l2 k2 j i h2 hP198 1.05 1.25 Common (Si, Al)O2-framework in l2 k2 j i h2 with 108 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules

Erionite 31143 P63/mmc 194 l2 k7 j i h2 f4 b hP208 1.05 1.25 Common (Si, Al)O2-framework in l2 k2 j i h2 with 108 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules

ErIr3B2 44230 C12/m1 12 g f d a mS12

ErIr3B2 44230 C12/m1 12 h e d a mS12

ErNiB4 20894 I4/MMM m l j e d tI48 1.00 1.25

ErRh3Si2 62924 Imma 74 h f e c oI24

ErZn5 103319 P63/mmc 194 k h2 g f a hP36

Eu2CuS3 59157 Pnma 62 AB2X3 c6 oP24

Eu2CuS3 59157 Pnma 62 ABCX3 c6 oP24 0.3 1.5

Eu2Re6S11 30736 R3-cH 167 f2 e c2 hR38 2.5 4

Eu2Zr2O7 108765 Fd3-mZ 227 f d c b a cF88

Eu3As4 8211 Fdd2 43 b3 a oF56

Eu3S9Sb4 26535 Pnma 62 A3B4X9 c16 oP64

EuGa2S4 8053 Fddd 70 h6 e b a oF224

EuGa2S4 8053 Fddd 70 h6 g b a oF224

EuGe2 43274 P3-m1 d a hP3 1 1.35

EuTa2Al20 54445 Fd3-mZ 227 g f d c a cF182

fairfieldite 16017 P1- 2 i7 a aP19 Ca2Mn(PO4)2(H2O)2

faujasite 9355 Fd3-mZ 227 i h g3 e2 cF608 Zeolite-FAU, Linde-Y Common (Si, Al)O2-framework in i h g3 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite 9355 Fd3-mZ 227 i h g3 e2 c cF604 Zeolite-FAU, Linde-Y Common (Si, Al)O2-framework in i h g3 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite 9355 Fd3-mZ 227 i h g3 e2 c cF634 Zeolite-FAU, Linde-Y Common (Si, Al)O2-framework in i h g3 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite 9355 Fd3-mZ 227 i h g3 e4 c cF624 Zeolite-FAU, Linde-Y Common (Si, Al)O2-framework in i h g3 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite 9355 Fd3-mZ 227 i h g4 e5 c cF644 Zeolite-FAU, Linde-Y Common (Si, Al)O2-framework in i h g3 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite 9355 Fd3-mZ 227 i3 h g3 e2 cF664 Zeolite-FAU, Linde-Y Common (Si, Al)O2-framework in i h g3 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite (hex) 92901 P63/MMC 194 l8 k8 j i f hP308 1.50 1.80 zeolite-EMT, EMC-2 Common (Si, Al)O2-framework in l8 k6 j i with 288 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

faujasite Fd3- 6315 Fd3-Z 203 g14 e5 c cF1863 Zeolite-FAU', Linde-X Common (Si, Al)O2-framework in g6 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules. Slight deviation from Fd3-m (Zeolite-FAU), caused by ordering of Al.

faujasite Fd3- 6315 Fd3-Z 203 g14 e6 c cF1180 Zeolite-FAU', Linde-X Common (Si, Al)O2-framework in g6 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules. Slight deviation from Fd3-m (Zeolite-FAU), caused by ordering of Al.

faujasite Fd3- 6315 Fd3-Z 203 g6 e2 c cF622 Zeolite-FAU', Linde-X Common (Si, Al)O2-framework in g6 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules. Slight deviation from Fd3-m (Zeolite-FAU), caused by ordering of Al.

faujasite Fd3- 6315 Fd3-Z 203 g7 e4 c cF678 Zeolite-FAU', Linde-X Common (Si, Al)O2-framework in g6 with 576 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules. Slight deviation from Fd3-m (Zeolite-FAU), caused by ordering of Al.

Fe11RuAs5 43949 R3H 146 b4 a5 hR17

Fe12Zr2P7 25757 P6- k3 j3 e d b hP21 0.35 0.46

Fe12Zr2P7 25757 P6- k3 j3 f c a hP21 0.35 0.46 Mg2(Mg.5Ni.5)3Ni9P7

Fe13Ge3 150584 Pm3-m g d c b a cP14

Fe13Ge3 150584 Pm3-m g d c b a cP16

Fe14Nd2B 44294 P42/MNM k2 j2 g f2 e c tP68 1.25 1.55

Fe14Nd2B 44294 P42/MNM k2 j2 g2 f e c tP68 1.25 1.55

Fe2Ga2S5 32551 R3-MH 166 c4 a hR9 11 13.4

Fe2Ga2S5 32551 R3-MH 166 c4 b hR9 11 13.4

Fe2N-zeta 81732 Pbna 60 d c oP12

Fe2Ni9Se8 15080 I4-m2 119 i3 g f c tI38

Fe2P 70115 P6-2M g f c b hP9 0.49 0.66 SB: C22 InMg2-type has lower c/a

Fe2P 70115 P6-2M g f d a hP9 0.49 0.66 SB: C22 InMg2-type has lower c/a

Fe2Si(HT) 100094 P3-M1 d2 b a hP6 1.10 1.40

Fe2SnS4 1313 I41/AZ 88 f c b tI28 1.25 1.60

Fe2SnS4 1313 I41/AZ 88 f d a tI28 1.25 1.60

Fe2Tb 2351 R3-mH 166 e c b hR6

Fe2TiO5 36183 Cmcm 63 f3 c2 oS32 pseudobrookite

Fe2V18.5S.5O46 (H2O)36 410238 Im3-m k2 j h2 f e2 b a cI352

Fe3(PO4)2(H2O)3 302 Pbna 60 d7 c a oP76

Fe3(PO4)2(H2O)3 302 Pbna 60 d7 c a oP80

Fe3(PO4)2(H2O)3 302 Pbna 60 d7 c a oP81

Fe3(PO4)2(H2O)3 302 Pbna 60 d7 c a oP84

Fe3(PO4)2(H2O)3 302 Pbna 60 d7 c a oP88 phosphoferrite

Fe3(PO4)2(H2O)4 30621 P121/a1 14 e8 a mP50 .8 1

Fe3(SO4)4(H2O)14 15207 P1- 2 i18 a aP65

Fe3B7O13Cl 42496 R3CH b7 a3 hR48 2.20 2.75 congolite

Fe3C 36346 Pbnm NO3 d c2 oP16 1.30 1.65 Cementite, SB: D0(11)

Fe3C 36346 PNMA NO3 d c2 oP16 0.80 1.00 Cementite, SB: D0(11)

Fe3N 80930 P6322 g c hP8 siderazot

Fe3S4 42537 R3-MH c3 b hR7 9.4 10.4

Fe3Sc2Si5 41834 P4/MNC h3 g e d tP40 0.45 0.62 Mn3U2Si5

Fe3Th7 107715 P63MC c3 a hP20 0.55 0.80 Ru7B3, SB: D10(2)

Fe3Th7 107715 P63MC c3 b hP20 0.55 0.80 Ru7B3, SB: D10(2)

Fe3TlTe3 100352 P63/M h2 c hP14 0.40 0.52 Mo3TlSe3

Fe3TlTe3 100352 P63/M h2 d hP14 0.40 0.52 Mo3TlSe3

Fe3W3C 76759 FD3-MS 227 f e d c cF112 Fe1.2: 12: Fe6W6; W: 12: C2Fe6W4; C: octahedron: W6 CFe3W3, eta-carbide, SB: E9(3) Fused gamma brass- and Ti2Ni-type (additional central atom) nested polyhedra units.

Fe4LaP12 1286 IM3- g c a cI34 4-a, 6-a, 20-d LaFe4P12, Skutterudite

Fe4Si2Zr 87172 P42/MNM i g b tP14 0.450 0.638 Fe: 13: Si3+1Fe6Zr3; Si: 11: Fe6+2Zr3; Zr: 18: Si6Fe12 CaCu4P2 Pairs of infinite columns of face-linked Si(Zr2Fe6) trigonal prisms sharing the Zr edge. Infinite strings of edge-linked Fe4 tetrahedra.

Fe6Ga6Sc 103465 Immm k h g f e a oI26 .56 .64

Fe6Ge6Li 41384 P6-2m 191 o k j i h e c b hP39

Fe6Ge6Mg 41796 P6/MMM i e d c a hP13 1.40 1.80 Fe6Ge6Hf, Fe3Mn4Ge6

Fe6Ge6Mg 41796 P6/MMM i e d c b hP13 1.40 1.80 Fe6Ge6Hf, Fe3Mn4Ge6

Fe6W6C 76761 Fd3-mZ 227 f e c b cF84

Fe7W6 103694 R3-MH g c3 a hR13 4 5.50 Co7Mo6, SB: D8(5)

Fe7W6 103694 R3-MH h c3 a hR13 4 5.50 Co7Mo6, SB: D8(5)

FeAl2(SO4)4(H2O)22 96598 P121/c1 14 e45 mP356

FeAs2 41805 Pmnn g a oP6 1.5 2.1

FeAs2 41805 Pnnm g a oP6 0.48 0.67

FeB 30449 PNMA 62 c2 oP8 0.60 0.88 TiB, TiSi, YNi, SB: B27=B15

FeBiO3 28622 R3MH 160 b a2 hR5 1 1.4

FeF3 16671 R3-CR 167 e b hR8

FeGa2S4 100706 P3-M1 d3 a hP7

FeGa2S4 100706 P3-M1 d3 b hP7

FeGa3 103448 P42/mnm j f c tP16 .9 1.15 CoGa3, IrIn3

FeGa3 103448 P42/mnm j g c tP16 .9 1.15

FeGe(OH)6 27650 P42/nS 86 g3 d c tP56 stottite

FeHf2Dx 202351 Fd3-mZ 227 i g2 f e2 d cF229

Felsoebanyaite 85074 P1211 4 a46 mP164 Al4SO4(OH)10(H2O)4

FeNb3Se10 42177 P121/m1 11 e7 mP14 1 1.2

FePS3 27307 C12/m1 12 j i2 g mS20

FePSe3 56890 R3-H f c2 hR10 2.9 3.2

ferrierite 35082 Immm o3 n6 m2 k i g f e2 c oI166 zeolite GIS Common (Si, Al)O2-framework in o3 n3 m2 l k g f with 108 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

ferrierite(oP) 75475 Pmnn 58 h12 g f e oP108 Common (Si, Al)O2-framework in h12 g f e with 108 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

FeS(P6-2c) 53497 P6-2c 190 i h f a hP24

FeS2(cP12) 53935 PA3- c a cP12 Fe: octahedron: S6; S: tetrahedron: SFe3 pyrite, SB: C2 Isopointal to CO2(cP12); S-S-dumbbells: S-S=2.18

FeS2(cP12) 53935 PA3- c b cP12 Fe: octahedron: S6; S: tetrahedron: SFe3 pyrite, SB: C2 Isopointal to CO2(cP12); S-S-dumbbells: S-S=2.18

FeS2(oP6) 26756 PMNN g a oP6 1.20 1.5 marcasite, SB: C18

FeS2(oP6) 26756 Pnnm g a oP6 0.67 0.86 marcasite, SB: C18

FeSb2S4 16908 PNMA 62 AB2X4 c7 oP28 berthierite

FeSi 36188 P213 a2 cP8 13-a Fersilicite, SB: B20=B28 Isopointal with CO-type

FeSi2 24360 P4/mmm h a tP3

FeSi2(oS48) 23408 Cmca 64 g2 f d oS48 .77 .83

FeSiTi 41157 Ima2 46 c2 b4 a oI36

FeSO4(H2O)7 34380 P121/c1 14 e12 d a mP108

FeTi4S8 53534 C12/m1 12 j3 i6 d a mS52 .9 1

FeTiO3 29209 R3-H f c2 hR10 2.40 3.00 ilmenite, SB: E2(2)=G4 aristotype is Al2O3.

FeTiO3 29209 R3-R f c2 hR10 ilmenite, SB: E2(2)=G4

FeU2S5 41899 C12/c1 15 f3 e d mS32 .42 .52

FeYb2S4 23378 Fd3-mZ 227 e d c a cF56

FeZrGa2 103457 Pnma 62 d3 c5 b oP48

Fleischerite 4295 P6-2c i2 h2 f3 a hP70

Ga(CN)3 84969 Pm3-m e a cP7

Ga21Ho4Ni10 103756 C12/m1 12 i17 b mS70

Ga2Gd3 103720 I4/MCM m l h2 g c a tI80 1.15 1.45

Ga2HfNi 412753 I4mm 107 e d4 c3 b a2 tI80

Ga2Mg5 103794 Ibam 72 j2 f b oI28

Ga2S3 34647 C1c1 9 a5 mS20 .55 .65

Ga3Pt5 103927 Cmmm 65 j h e b a oS16

Ga4(Ga, Ge)2O10H.77 39343 Pbnm d c5 a oP34

Ga41V8 1803 R3-H f7 d c b a hR49 0.95 1.20

Ga41V8 1803 R3-H f7 e c b a hR49 .95 1.2

Ga4HfNi2 103737 I23 f5 e2 c3 cI168

Ga4Ni3 103864 Ia3-d g f a cI112

Ga4Ti5 103997 P63/MCM f2 c a hP18 0.60 0.80

Ga4Ti5 103997 P63/MCM g2 d b hP18 0.60 0.80

Ga5Ho2Ni5 103754 P6/MMM l k f d a hP18 0.40 0.60 Al3Ni2Y, Co3Ga2Ce, Co3Ga2Y

Ga5Ho2Ni5 103754 P6/MMM m j g c b hP18 0.40 0.60 Al3Ni2Y, Co3Ga2Ce, Co3Ga2Y

Ga6Pu 103942 P4/NBMS m g c tP14 1.15 1.45

Ga9Mg4Na 103796 P6/mmm q o2 n5 m l j h e2 hP84

Gadolinite 4338 P121/c1 14 e8 a mP34

GaGeLi 25310 P63mc b2 a hP6 1.45 1.80 LiZnSb

gainesite 31199 I41/amdZ 141 h5 e b a tI50

GaMo4S8(HT) 41935 F4-3M e3 a cF52 GaMo4S8: cF52, F4-3m, 8.5-11, e3 a, 41935

GaS 59 P63/mmc 194 f2 hP8

GaSe 73387 P6-m2 187 i2 h g hP8

Gd13Zn58 104155 P63mc 186 d4 c14 b3 a2 hP142

Gd2Si3 44384 Imma 74 e3 oI10

Gd2Si3 44384 Imma 74 e3 oI11 TbSi2-x

Gd2Si3 44384 Imma 74 e3 oI12 TbSi2-x

Gd3Ni8Sn16 104100 Im3- g3 c a cI82

Gd3NiSi2 15534 Pnma c6 oP24

Gd7Ni10Y3 104104 P121/m1 11 e6 mP12 0.45 0.6

GdFeO3 16644 PBNM ABX3 d c2 a oP20 1.30 1.60 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdFeO3 16644 PBNM ABX3 d c2 b oP20 1.30 1.60 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdFeO3 16644 PCMN ABX3 d c2 b oP20 0.92 1.18 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdFeO3 16644 PMCN ABX3 d c2 b oP20 0.64 0.84 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdFeO3 16644 PNAM ABX3 d c2 a oP20 1.20 1.55 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdFeO3 16644 PNMA d c2 a oP20 0.85 1.06 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdFeO3 16644 PNMA d c2 b oP20 0.85 1.06 CaTiO3(orh), YFeO3, SrZrS3, UCrS3 Aristotype is CaTiO3, perovskite

GdSn3 104135 Amm2 38 b4 a4 oS15

GdSn3 104135 Amm2 38 b4 a4 oS16

Ge(HP) 16570 P43212 b a tP12 1.050 1.3

Ge2LaPt2 53666 P1211 a5 mP10

Ge3Rh5 53891 Pbam h2 g c a oP16 .62 .83

Ge4S6(CF3)4 62223 Fd3-mZ 227 g f e2 cF208

GeAs 17033 I4/mmm 107 a2 tI4

GeK 43515 P4-3n i2 e2 cP64

GePbS3 2090 P121/c1 14 e5 mP20

GeRh3Y2 76345 R3-mH 166 d c a hR6

GeS 38165 Pbnm c2 oP8 0.75 0.90 herzenbergite, SnS, SB: B16=B29

GeS 38165 Pcmn c2 oP8 2.25 2.7

GeS 38165 Pmcn c2 oP8 2.60 3.30 herzenbergite, SnS, SB: B16=B29

GeS 38165 Pnam c2 oP8 0.30 0.40 herzenbergite, SnS, SB: B16=B29

GeS 38165 Pnma c2 oP8 0.35 0.50 herzenbergite, SnS, SB: B16=B29

GeTe 56042 R3-mH 166 e d b a hR8

gillespite 27597 P4/nccS 130 g3 f c b tP64

gismondine 6313 I41/amdZ 141 i2 h g f b tI116 .83 1.05 zeolite-P Common (Si, Al)O2-framework in h g f with 48 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

gismondine mcl 27324 P1121/a e19 mP104

gmelinite 33668 P63/mmc 194 l k6 j2 i h f hP148 .7 .78 Common (Si, Al)O2-framework in l k2 j i with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

goetzenite 28002 P1- 2 i14 b a aP32

gonnardite 29522 I4-2d 122 e4 d3 a tI104 0.45 0.54 Tetranatrolite Common (Si, X)O2-framework in e3 d a with 60 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

graphite(2H) 53781 P63/MMC c b hP4

graphite(2H) 53781 P63/MMC d b hP4

graphite(3R) 53780 R3-MR 166 c hR2

H3W12PO40(H2O)6 92217 Pn3-mS 224 k4 h e a cP148

H3W12PO40(H2O)6 92217 Pn3-mS 224 k4 h e a cP149

harmotome 2318 P121/m1 11 f13 e6 d mP87 phillipsite, zeolite-PHI Common (Si, Al)O2-framework in f11 e2 with 48 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

heulandite 25029 C12/m1 12 j13 i6 h2 g d mS185 Ca(Al2O7O18)(H2O)6, clinoptilite Common (Si, Al)O2-framework in j12 i h g with 108 atoms/cell, great variability of additional enclosed counter-cations and absorbed molecules

heulandite 25029 C12/m1 12 j14 i6 h g d a mS181 Ca(Al2O7O18)(H2O)6, clinoptilite Common (Si, Al)O2-framework in j12 i h g with 108 atoms/cell, great variability of additional enclosed counter-cations and absorbed molecules

heulandite Cm 27526 C1m1 8 b30 a15 mS186 zeolite-HEU' Common (Si, Al)O2-framework in b26 a2 with 108 atoms/cell, great variability of additional enclosed counter-cations and absorbed molecules

Hf3Ni2Si3 200067 Cmcm 63 f3 c2 oS32

Hf9Mo4B 23788 P63/MMC k h2 c a hP28 0.85 1.15

HfGa2 103727 I41/amd 141 e3 tI24

HfO2 87456 PMNB 62 c3 oP12

HfO2 87456 PMNB 62 c3 oP12 .4 2.5

Hg 53771 R3-mH 166 a hR1 1.5 2.5

Hg2.9SbF6 35096 I41/amdZ 141 h4 g e b tI40 1.5 1.8

Hg2K 104303 IMMA h e oI12 1.50 2.00 CeCu2

Hg2K 104303 IMMA i e oI12 0.95 1.25 CeCu2

Hg3NbF6 62027 P3-1M k d b a hP10 1.37 1.70

Hg5Mn2 104324 P4/mbm 127 i h d tP14 Li2Sn5, Pd2Hg5, V2Ga5

HgCl 36195 I4/MMM e2 tI8 2.10 2.70 calomel, Hg2Cl2, SB: D31

HgMn 104323 P4/MMM c b tP2 0.90 1.15 TiCu(delta) isopointal with AuCu-type

HgMn 104323 P4/MMM d a tP2 0.90 1.15 14-b TiCu(delta) isopointal with AuCu-type

HgNa 104326 Cmcm 63 g c2 oS16

HgNb6Br16(H2O)18 50174 Fd3-mZ 227 g2 f2 e b cF616

HgO 40316 PNMA c2 oP8 0.51 0.55

HgPbP14 29260 Pnma 62 d5 c6 oP64 .8 .95

HgSO4.H2O 15404 Pnma 62 d c5 oP36

Hilairite 20257 R32H 155 f4 e d c b a hR43

Hilairite 20257 R32H 155 f4 e2 d c b a hR48

Hilairite 20257 R32H 155 f4 e2 d c b a hR49

Ho10In20Ni9 104414 P4/nmmZ 129 j3 i4 h g c2 a tP78

Ho11Ge10 43052 I4/MMM n2 m i h2 e2 d tI84 1.30 1.60 Yb11Sb10, Cr5Sc7Si9

Ho11Ge10 43052 I4/mmm n2 m j h2 e2 d tI84

Ho2Rh12As7 43971 P63/m 176 h3 e d hP21

Ho4C7 83381 P121/c1 14 e5 a mP22

Ho6Mo4Al43 105153 P63/mcm l k3 j i h g2 b hP106

HoAl3Pb2O8 67819 Pn3-mS 224 k f e2 b cP56

HoFe6Sn6 106584 Immm o l2 k j4 i3 h g a oI78

HoFe6Sn6 106584 Immm o n2 k h4 g3 f e a oI78

Hureaulite 10275 C12/c1 f14 e mS156

Hydrotalcite 6296 R3-mH 166 h c2 a hR7 6.5 8.5 Mg4Al2(OH)12 CO3(H2O)3 Variable M(2+)/M(3+) ratio

In 53777 I4/MMM a tI2 1.258 1.783 In: cuboctahedron: In4+8 SB: A6 Aristotype is Cu; Cuboctahedral coordination splitted into 4+8.

In2Mo15Se19 26546 R3-CH f4 e2 c3 hR72 5.20 7.00

In2Mo15Se19 26546 R3-CR f4 e2 c3 hR72 1 1

In2Se3 17008 R3mH 160 a5 hR5 6 8

In2ZnS4(disord.) 78345 R3-MH 166 c3 a hR7 8.0 10, MgAl2Se4, MnIn2Se4

In2ZnS4(hR14) 65725 R3MH a14 hR14 16.00 24.00

In2ZnS4(hR7) 16974 R3MH a7 hR7 8.00 12.00

In3Li13 51963 Fd3-mZ 227 f e d c b a cF128

In3Mo15Se19 26386 P63/m 176 i4 h3 f2 e hP74

In3Te4(HP) 44655 R3-mH c3 a hR7 8.6 10.6

In3Yb8 59575 R3-cH 167 f2 e c3 b hR44 Al3Au8, Hg3Na8

In41K17 106707 Fd3-mZ 227 g4 e2 b a cF464

In5Nd4S13 200616 Pbam h6 g4 c a oP44

In6LaNi3 51955 PmmnS 59 e3 b2 a2 oP20

In9Pt13 59501 C12/m1 12 j2 i4 g f d c mS44

InMg2 51974 P6-2M g f b a hP9 0.35 0.50 SB: C22 Fe2P-type has greater c/a

InMg2 51974 P6-2M g f c b hP9 0.35 0.50 SB: C22 Fe2P-type has greater c/a

InMg3 51976 R3H 146 b4 a4 hR16 4 5.5

InNbS2 74702 P6-m2 187 h b a hP4

InNi2 59437 P63/MMC d c a hP6 1.10 1.55 Ni2Ge(HT), Ni2Si(theta), SB: B8(2)

InPt2Y 59505 P63/MMC f c a hP8 1.75 2.20 GdPt2Sn, CeLi2Ge

InTaS2 74703 P6-m2 187 g d a hP4

Ir3Ge7 53656 IM3-M f e d cI40 Ir3Sn7, Co3Al3Si4, SB: D8(f)

Ir4Sc11 10438 Fm3-m f2 e d b a cF120

Ir4Sc11 10438 Fm3-m f3 d b a cF120

IrTa 104565 Pmma j i f e oP12 .3 .4

IrYGe2 76509 Immm 71 l2 i h2 g oI32 IrNdGe2

IrYGe2 76509 Immm 71 l2 j i2 g oI32 IrNdGe2

jahnsite 6205 P12/a1 13 g15 f e2 d c a mP108 CaFe2Mg2Mn(PO4) 4(OH)2(H2O)8

jarlite 40133 C12/m1 12 j9 i5 d b a mS102 Na2MgSr6AlF32(OH)2

K14Fe4O13 67170 P21/b11 14 e15 d mP62

K19Pb8O4(OH)3 401435 Fm3-m i f e2 b a cF136

K2As2F8O2 9027 P121/n1 14 e7 mP28 2.4 2.8

K2Ca(SO4)2(H2O) 26829 P121/m1 11 f3 e8 mP32 syngenite

K2CuFe(CN)6 28654 F4-3m f2 d c b a cF64

K2GeTeO6 40422 Fd3-mZ 227 f e c cF80

K2GeTeO6 40422 Fd3-mZ 227 f e d cF80

K2Mg(SO4)2(H2O)4 61478 C12/m1 12 j4 i7 g d a mS100 leonite

K2Mg(SO4)2(H2O)4 61478 C12/m1 12 j6 i6 g b a mS100 leonite

K2Mg(SO4)2(H2O)4 61478 C12/m1 j6 i6 g d a mS100

K2Mg(SO4)2(H2O)6 26772 P121/a1 14 e9 a mP62 picromerite

K2Mg(SO4)2(H2O)6 26772 P121/a1 14 e9 a mP78

K2Mg2(SO4)3 16702 P213 b5 a4 cP108 K1: 15: O15; K2: 9+3: O9+3; Mg1.2: octahedra: O6; S: tetrahedron: O4; O1: 5: SMgK3; O2: 3+1: SMgK1+1; O3: 4: SMgK2; O4: langbeinite

K2Mg2(SO4)3 16702 P213 b5 a4 cP76 K1: 15: O15; K2: 9+3: O9+3; Mg1.2: octahedra: O6; S: tetrahedron: O4; O1: 5: SMgK3; O2: 3+1: SMgK1+1; O3: 4: SMgK2; O4: langbeinite

K2MgF4 33519 I4/MMM e2 c a tI14 2.781 3.940 K: 9: F9; Mg: octahedron: F6; F1.2: octahedra: F1: K1+4Mg; F2: Mg2K4 K2NiF4, Ca4Sb2O, Eu4As2O, Na4I2O IGS of NaCl- and CaTiO3-type slabs (1: 1). NiF6 octahedra share edges to form infinite layers.

K2MgF4 33519 I4/MMM e2 c a tI30 2.781 3.940

K2MgF4 33519 I4/MMM e2 c b tI14 2.781 3.940

K2MnF6 76273 P63mc c2 b2 a hP18 1.59 1.68

K2MnS2 65453 Ibam 72 j2 a oI20

K2MnS2 65453 Ibam 72 j2 b oI20

K2Mo3Se18 54262 P1211 4 a23 mP46

K2NaAl3F12 40178 P121/m1 11 f4 e8 d c mP36

K2NaAlF6 6027 FM3-M e c b a cF112 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF30 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF37 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF38 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF39 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF40 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF44 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2NaAlF6 6027 FM3-M e c b a cF88 "K: cuboctahedron: F12; Na, Al: octahedra: F6; F: octahedron: K4NaAl (+4F)" Ba2CaWO6, elpasolite

K2Nb3Se6 44673 P6-m2 187 h g2 f c hP7

K2Ni(CN)4 24099 P121/c1 14 e5 a mP22

K2Pb(SO4)2 76891 R3-mH 166 h c3 a hR13 3.2 4.2 palmierite

K2Pd3S4 41885 Fddd 70 h f2 a oF72

K2PtCl4 23998 P4/MMM j e a tP15 .57 .64

K2PtCl4 23998 P4/MMM j e a tP7 .57 .64

K2PtCl6 36304 FM3-M e c a cF36 Pt: octahedron: Cl6; K: cuboctahedron: Cl12; Cl: tetrag. pyramid: PtK4 (+8Cl) Gd2MnGa6, K2PtH6, K2TeBr6, Sr2IrH5, Sr2RuH6, K2TeBr6(alpha), SB: H61 Isolated PtCl6 octahedra.

K2PtCl6 36304 FM3-M e c a cF68 Pt: octahedron: Cl6; K: cuboctahedron: Cl12; Cl: tetrag. pyramid: PtK4 (+8Cl) Gd2MnGa6, K2PtH6, K2TeBr6, Sr2IrH5, Sr2RuH6, K2TeBr6(alpha), SB: H61 Isolated PtCl6 octahedra.

K2PtS2 26258 Immm h f a oI10

K2S2O6 16661 P321 g3 f e d2 c hP30

K2S3 1263 Cmc21 36 b a3 oS20 .95 1.1

K2SnO3 24131 Pcmn 62 d2 c2 oP24

K2SO3 60762 P3-M1 i d2 b a hP12 1.15 1.35

K2SO4(alpha) 31535 P63/MMC d c a hP14 1.3 1.66

K2SO4(alpha) 31535 P63/MMC k h d c a hP14 1.3 1.66

K2SO4(beta) 56102 Pmcn 62 d c5 oP60 Ba2SiS4, K2ZnH4, (NH4)2WS4

K2SO4(beta) 56102 Pnma 62 AB2X4 d c5 oP28 Ba2SiS4, K2ZnH4, (NH4)2WS4

K2Te3 2453 Pnma 62 d c3 oP20

K2UF6 26193 P6-2M g f d a hP9 .5 .65

K2Zn(CN)4 14368 Fd3-mZ 227 e2 d a cF88

K2ZrSi3O9 24446 P63/M i h2 f b hP30 1.30 1.65 wadeite

K3FeO2 73215 P41212 b2 a2 tP24 1.950 2.763 K1: nonlinear O2 (+K8Fe3); K2: copl. square: O4 (+2K); Fe: linear O2 (+3K); O: octahedron: Fe(K1)(K2)4 Linear O-Fe-O units. Fe-O=1.77

K3Na(SO4)2 26018 P3-M1 i d3 b a hP14

K3Pr2(NO3)9 9319 P4132 e5 d3 c cP164

K3Pr2(NO3)9 9319 P4332 e5 d3 c cP164

K3V5O14 24068 P31M d c4 b2 hP22 0.50 0.65

K3Zn4O(AsO4)3(H2O)4 81373 F4-3c h g e2 d a cF268

K4CdCl6 15923 R3-CH 167 f e b a hR22 1 1.35

K4CdCl6 15923 R3-cR 167 f d b a hR22

K4Si23 26299 PM3-N k i d c a cP52

K4Si23 26299 PM3-N k i d c a cP53

K4Si23 26299 PM3-N k i d c a cP54 Ba4Ga8Si15, Cs2Sn11, Na4Si23, (Cl2)4(H2O)23

K5Sb3Sn 57401 P121/n1 e9 mP36 KNa4Sb3Sn

K6HgS4 47218 P63MC c3 b2 hP22 0.66 0.90

K6LiFe24S26Cl 10398 PM3-M m h g f e b a cP58 djerfisherite

K6Sn2Te6 10109 P121/c1 14 e7 mP28 .95 1.05

K6U4O15 202328 Im3-m e d c b a cI38

K7NbAs4 380109 Pmn21 31 b3 a6 oP24

K8In11 370002 R3-cH 167 f2 e c2 hR38 4.5 5.5

K9NaTl13 54243 Im3- g e c a cI46

K9U6BiO24 66528 Pm3-m h g f e d c b a cP40

KAl(SO4)2(H2O)12 29283 PA3- d3 c2 b a cP192 K, Al: octahedra: K: (O3)6; Al: (O4)6; S: tetrahedron: (O1)(O2)3; O1: S; O2: S +(O3)(O4); O3: K + (O2)(O4); O4: Al +(O2)( alum-type, SB: H42

KAl(SO4)2(H2O)12 29283 PA3- d3 c2 b a cP208 K, Al: octahedra: K: (O3)6; Al: (O4)6; S: tetrahedron: (O1)(O2)3; O1: S; O2: S +(O3)(O4); O3: K + (O2)(O4); O4: Al +(O2)( alum-type, SB: H42

KAl(SO4)2(H2O)12 29283 PA3- d4 c3 b a cP192 K, Al: octahedra: K: (O3)6; Al: (O4)6; S: tetrahedron: (O1)(O2)3; O1: S; O2: S +(O3)(O4); O3: K + (O2)(O4); O4: Al +(O2)( alum-type, SB: H42

KAl(SO4)2(H2O)12 29283 PA3- d5 c4 b a cP192 4-a, 6-a; 1#a alum-type, SB: H42

KAl(SO4)2(H2O)12 29283 PA3- d7 c2 b a cP192 K, Al: octahedra: K: (O3)6; Al: (O4)6; S: tetrahedron: (O1)(O2)3; O1: S; O2: S +(O3)(O4); O3: K + (O2)(O4); O4: Al +(O2)( alum-type, SB: H42

KAl(SO4)2(H2O)12 29283 PA3- d8 c3 b a cP192 K, Al: octahedra: K: (O3)6; Al: (O4)6; S: tetrahedron: (O1)(O2)3; O1: S; O2: S +(O3)(O4); O3: K + (O2)(O4); O4: Al +(O2)( alum-type, SB: H42

KAl3(SO4)2(OH)6 24157 R3-MH h2 d c2 a hR26 2.2 2.8 alunite

KAl3(SO4)2(OH)6 24157 R3-MR h2 d c2 a hR26 1 1 alunite

KAlP2O7 2888 P121/c1 ABC2X7 e11 mP44 1 1.2

KAlSi3O8 36234 C12/m1 12 j5 i2 g mS51

KAlSi3O8 36234 C12/m1 12 j5 i2 g mS52 sanidine

KB3H3 65507 Fm3-m e2 c cF56

KBi6IO9 408652 Ia3-d h g2 f b a cI272

KBO2 16005 R3-CH e4 hR24 NaBS2, F5(13)

KCuO2 15095 Cmcm f c2 oS16 1.0 1.5

KCuZrS3 80624 Cmcm 63 f c3 a oS24

KCuZrS3 80624 Cmcm 63 f c3 b oS24

keatite 34889 P41212 b4 a tP36 1 1.3

keatite 34889 P43212 b4 a tP36 1 1.3

Keggin molecule 413185 Pm3-m m j2 i g e c b a cP113

KFeS2 15557 C12/c1 15 f e2 mS16

KGa3 20664 I4-m2 119 i2 f b a tI24

KH3(SeO3)2 9677 Pbcn d4 c oP48

KMg2Al3(Al2Si10O30) 202732 P6/MCC m3 l f c a hP96 1.25 1.60 osumilite

KMgCl3(H2O)6 9264 Pbnn 52 e14 d4 c oP276 carnallite

KN3 24007 I4/mcm 140 h d a tI16

KNa3Al4Si4O16 27584 P63 c8 b3 a hP56 0.57 0.95 nepheline

Koritnigite 100581 P1- 2 i28 aP80

KOsF6 27664 R3-H f b a hR8 .9 1.5

KOsF6 27664 R3-R f b a hR8

kotoite 24036 Pnnm 58 h g2 f a oP22

KPO3 26148 Pnma 62 d c3 oP20

Krautite 100543 P1211 4 a28 mP80 MnAsO3OHH2O

KSb2BO6 33505 I4-3d e3 c cI160

KSbO3 41203 Pn3-S 201 h g f e c cP60

KSe2V3O12 81231 P63 c5 b2 a hP36 1.45 1.78

KSnAs 40815 P63MC b2 a hP6 2.6 3.5

KTiPO5 6199 Pn21a a16 oP64 .48 .52

KTiPO5 6199 Pna21 a16 oP64 .79 .85

Kyanite 16970 P1- i16 aP32 .75 .81 Al2SiO5(aP32)

La 104657 P63/MMC c a hP4 2.80 3.60 Nd(alpha), SB: A3'

La 104657 P63/MMC d a hP4 2.80 3.60 Nd(alpha), SB: A3'

La2Fe8Ti12O38 100554 R3-H f9 c2 b a hR59 1.80 2.25 davidite

La2Fe8Ti12O38 100554 R3-R f9 c2 b a hR59 davidite

La2Mn22C3 32111 I41/amd 141 i d c b a tI53

La2Mn22C3 32111 I41/amd 141 i d c b a tI54

La2Ni3 450 Cmca 64 f e a oS20

La2Ni5B4 63501 C12/m1 12 j i3 d mS22

La2O3 24693 P3-M1 d2 a hP5 1.38 1.75 Ce2O3, Mg3As2, Mg3Sb2, SB: D52

La2O3 24693 P3-M1 d2 b hP5 1.38 1.75 Ce2O3, Mg3As2, Mg3Sb2, SB: D52

La2S3 15151 Pnma A2X3 c5 oP20 1.85 2.3 Gd2S3, Cr3C2

La2Sb 42733 I4/MMM e2 c tI12 3.280 4.646 La1: cuboctahedron: La4+4Sb4; La2: 13+4: Sb5La8+4; Sb: monocapped sq. antiprism: La9 Ca2As IGS of BaAl4- and W-type slabs.

La2SnS5 2312 Pbam h2 g c a oP16 .31 .4

La3In2O6 21024 Pbam h5 g5 d a oP44

La3InS6 30510 P21212 18 c9 b a oP40

La3MnS6 2072 C1m1 8 b19 a17 mS104

La3NbO7(oS) 10058 Cmcm 63 h g2 c b a oS44

La4Ge3S12 2046 R3CH b6 a hR38 0.35 0.50

La6Ni6P17 2242 I4-3m g e d c a cI58

LaB2C2 23300 P42/MMC m k e tP10 1.90 2.30 YB2C2

labuntsovite 87544 C12/m1 12 j9 i4 h g2 f c mS120 (Na,K)10.7Ti8Mn.4Si16O53 (OH)3(H2O)9

LaCoB5O10 4235 P121/n1 14 e17 mP68 1 1.5

LaF3(P63mc) 27089 P63cm c3 b a hP24

LaI 83678 P63/MMC c a hP4 2 2.8

lamprophyllite 20549 C12/m1 j4 i5 h b a mS61

lamprophyllite 20549 C12/m1 j4 i5 h b a mS62

lamprophyllite 20549 C12/m1 j4 i5 h b a mS63

lamprophyllite 20549 C12/m1 j4 i5 h b a mS64

LaPtSi 27224 I41MD a3 tI12 3.10 3.80

LaRh3B2 61414 P6/mmm 191 j i h g e2 c a hP17

LaRu3Si2 100785 P63/m 176 h f b hP12

LaS2 1435 Pcmn 62 d2 c2 oP24

LaSi 408030 Cmcm f c2 oS16 1.0 1.5

Laueite 23819 P1- 2 i10 g b a aP41 Fe2Mn(PO4)2 (OH)2(H2O)8

Laueite 23819 P1- 2 i10 g c a aP41

Laumontite 63502 C12/m1 12 j10 i4 g mS116 zeolite-LAU

Laumontite Am 16535 A11m 8 b18 a6 mS98 zeolite-LAU'

lavenite 20377 P121/a1 14 e15 mP62

Lawsonite 34066 Cmcm 63 h f3 d c3 oS76

lazulite 26496 P121/c1 14 e7 a mP34 MgAl2(PO4)2(OH)2

leucophosphite 22048 P121/n1 14 e16 mP100 .95 1.05

leucophosphite 22048 P121/n1 14 e16 mP84 K(FePO4)2OH(H2O)2

levyne 4361 R3-mH 166 i2 h7 g f c4 b hR103 Common (Si, Al)O2-framework in i2 h3 g f with 54 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules

Li2Eu5O8 31799 C12/m1 12 i7 b mS30 .22 .3

Li2O2 25530 P63/mmc f c a hP8 2.1 2.80

Li2ThN2 16232 P3- g2 d a hP15 .8 .91

Li3Fe2(PO4)3 62244 P121/c1 14 e20 mP80

Li3N 34280 P6/MMM c b a hP4

Li3Pr2(BO3)3 20217 P121/n1 14 e17 mP68

Li4TeO5 2403 P1- i9 c b aP20

Li4UF8 30338 Pnma 62 d5 c3 oP52

Li5La3Nb2O12 68251 Ia3-d h d c b a cI176

Li5Mo9S12 49564 R3-H 148 f4 c hR17

Li5Tl2 10053 R3-mH 166 c3 b hR7

Li6Ca12Mo4N16O3 83865 I4-3d e2 d c2 b cI164

Li6HoB3O9 2121 P121/c1 14 e19 mP76

Li8IrO6 61217 R3-H f2 c a hR15 2.7 2.9

LiAlCl4 1040 P121/a1 e6 mP24 .5 .6

LiAlCl4 1040 P121/c1 e6 mP24 1.7 2

LiAs 26472 P121/c1 14 e4 mP16

LiBa4Sb3O12 202200 Im3-m e d c b a cI40

LiBaCrF6 6042 P121/c1 AB2X6 e9 mP36 1.45 1.8

LiBaCrF6 6042 P121/c1 14 ABCX6 e9 mP36 1.46 1.78

LiCrS2 26233 P3-M1 d b a hP4 1.7 2.0

LiFeO2-alpha 31149 I41/amdS 141 e b a tI16 2 2.5

LiGaSiO4 65125 R3H 146 b14 hR42 .6 .8 aristotype is Be2SiO4 (phenakite)

LiMnAs 26459 P4/nmmZ 129 c b a tP6 1.35 1.55

LiNbGeO5 40536 Pbnm 62 d c5 a oP32

LiNbO3 28294 R3CH 161 b a2 hR10 1 2.75

Linde-N 20645 Fd3-Z 203 g39 f e9 cF3876 Common (Si, Al)O2-framework in g20 with 640 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules

LiSbF6 23924 R3-H 148 f b a hR8 2.5 3

LiSbF6 23924 R3-R f b a hR8

LiSbO3 24051 Pnna 52 e d c2 oP20

LiSn 104782 P12/m1 10 n m e a mP6 (Nb, Rh)Rh

LiSn 104782 P12/m1 10 n m f a mP6 (Nb, Rh)Rh

LiSr4B3O9 170861 Ia3-d h g2 f b a cI272

LiTiO2 48128 FD3-MS 227 e d c cF64 Li, Ti, O: octahedra: Li: O6; Ti: O6; O: Li3Ti3 Ca2NH, LiZrS2, CuZrS2 Close packed O layers in c stacking, Li and Ti in octahedral voids.

LiTm2Ge4 57075 P1121/m 11 e4 mP7

LiYSn 32041 P63mc c3 b2 a hP24 .72 .9

lomonosovite 34069 P1- 2 i23 aP46 2.45 3

Lu3Co8Sn4 55544 P63mc c4 b2 a hP30

ludwigite 30653 Pbam 55 h3 g5 c b oP36

LuNiSn2 20790 Pnma 62 NOP2 c12 oP48

LuRh4B4 32508 Ccca 68 i6 f a oS108

LuRu4B4 44440 I41/ACDS 142 g2 b tI72 1.693 2.400 Lu: 24: Ru12B12; Ru: 13: B5LuRu7; B: 9: BRu5Lu3 B-B dumb-bells. B-B=1.52. Ru4 tetrahedra are interconnected to form infinite (mutually perpendicular) zigzag chains.

mazzite 6258 P63/MMC 194 l3 k3 j3 i h4 g f e c hP211 .38 .47 zeolite-MAZ

merlionite 100419 Immm 71 o5 n6 m2 l j i h f e c b oI162 zeolite-MER

metasillimanite 92636 Pbnm d c5 a oP32 .92 1.15

metatobernite 20594 P4/nmmZ 129 j2 i2 c7 b a tP82 Cu(UO2)2(PO4)2 (H2O)8

Metavariscite 15834 P121/n1 14 e8 mP48 AlPO4(H2O)2(mP)

Mg 53767 P63/MMC c hP2 1.50 1.90 SB: A3 Ideal c/a=1.633 for hcp; c/a(Zn)=1.86 deviates clearly >from the ideal value

Mg 53767 P63/MMC d hP2 1.50 1.90 SB: A3 Ideal c/a=1.633 for hcp; c/a(Zn)=1.86 deviates clearly >from the ideal value

Mg2PO4F 26970 P121/c1 14 e32 mP128 wagnerite

Mg2PO4F 26970 P121/c1 14 e32 mP144 wagnerite

Mg2SiO4 56114 PBNM AB2X4, ABCX4 d c4 a oP28 1.12 1.42 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg2SiO4 56114 PBNM AB2X4, ABCX4 d c4 b oP28 1.12 1.42 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg2SiO4 56114 PMCN AB2X4, ABCX4 d c4 a oP28 1.52 1.90 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg2SiO4 56114 PMNB AB2X4, ABCX4 d c4 a oP28 0.71 0.88 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg2SiO4 56114 PNAM AB2X4, ABCX4 d c4 a oP28 0.52 0.67 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg2SiO4 56114 PNMA AB2X4, ABCX4 d c4 a oP28 0.39 0.6 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg2SiO4 56114 PNMA AB2X4, ABCX4 d c4 b oP28 0.39 0.6 olivine, Mg2GeS4, Mn2GeS4, BeAl2O4 , SB: S1(2)=H12

Mg3Ca(CO3)4 201729 R32H 155 f e d3 b a hR20 .73 1

Mg3Ca(CO3)4 201729 R32H 155 f e3 d b a hR20 .73 1 huntite

Mg3Si2O5(OH)4 81101 C1m1 8 b5 a4 mS36 1.3 1.5 Lizartite 1M

Mg3Ti(BO3)2O2 30652 Pnma 62 c7 oP28 .3 3.5

Mg5(SiO4)2F2 15180 P121/c1 14 e8 d mP35 Chondrodite

Mg5(SiO4)2F2 15180 P121/c1 14 e8 d mP36 Chondrodite

Mg5(SiO4)2F2 15180 P121/c1 14 e8 d mP37 Chondrodite

Mg5(SiO4)2F2 15180 P121/c1 14 e8 d mP38 Chondrodite

Mg6MnO8 82182 Fm3-m e d c a cF60

Mg9(SiO4)4F2 10300 P21/b11 14 e15 d mP62

Mg9(SiO4)4F2 10300 P21/b11 14 e15 d mP63

Mg9(SiO4)4F2 10300 P21/b11 14 e15 d mP64 Clinohumite

MgCl2(H2O)6 26744 C12/m1 12 j i2 a mS42 bischofite

MgCO3(H2O)3 2758 P121/n1 14 e8 mP56

MgNb2O6 85008 Pbcn d4 c oP36 .30 .42 columbite

MgNi2 104838 P63/MMC h g f2 e hP24 2.90 3.80 Laves-phase 4H, SB: C36

MgSeO3 494 Pnma d c2 a oP20 .75 .98

MgSeO3 494 Pnma 62 d c2 b oP20 .75 .98

MgSiO3 77344 Pbca 61 c10 oP80 .24 .33

MgSn(OH)6 76927 Pn3-Z 201 h c b cP56 schoenfliesite

MgSn(OH)6(Pn3-m) 25824 Pn3-mZ 224 k c b cP56 schoenfliesite

MgSO3(H2O)6 2524 R3H 146 b3 a2 hR23

MgSO4(H2O)4 16579 P121/n1 14 e10 mP72

MgSO4(H2O)5 2776 P1- 2 i10 e a aP42 pentahydrite

MgSO4(H2O)6 16546 C12/c1 15 f11 e a mS192 hexahydrite

MgSO4H2O 15924 C12/c1 15 f2 e2 b mS36

MgSO4H2O 15924 C12/c1 15 f2 e2 c mS36

MgSrSi 42457 Pnam 62 c3 oP12 .49 .65 Differs from Co2Si-type by slightly different axial ratios

MgSrSi 42457 Pnma c3 oP12 1 1.25 Differs from Co2Si-type by slightly different axial ratios

MgV2O5 86102 Cmcm 63 f3 c2 oS32

MgZn2 104897 P63/MMC h f a hP12 1.50 1.80 Laves-phase 2H, Wfe2, SB: C14=C41

MgZn2 distorted 150576 P121/m1 11 e2 a mP6

Mitridatite 1017 A1a1 9 a75 mS372 (CaO)6(FePO4)9 (H2O)9

Mixite 70117 P63/m 176 i2 h6 c hP87 BiCu6(AsO4)3 (OH)6(H2O)3 variable zeolitic water

Mixite 70117 P63/m i3 h5 c hP86 BiCu6(AsO4)3 (OH)6(H2O)3 variable zeolitic water

Mixite 70117 P63/m 176 i3 h5 c hP87 BiCu6(AsO4)3 (OH)6(H2O)3 variable zeolitic water

Mn(cI58) 56133 I4-3M g2 c a cI58 Mn1.2: 16: Mn16; Mn3: 13: Mn13; Mn4: 12: Mn12 Mn(alpha), P4, SB: A12 29-atom nested polyhedra units consisting of a central atom surrounded by a Mn4 tetrahedron, a Mn(1)12 truncated tetrahedron and a Mn(2)12 cuboctahedron.

Mn(cP20) 56134 P4132 d c cP20 Mn1: icosahedron: Mn12; Mn2: 14: Mn12+2 Mn(beta), SB: A13

Mn12Th 104986 I4/MMM j i f a tI26 0.475 0.673 Mn1.3: icosahedra: Mn10Th2; Mn2: 14: Mn13Th; Th: 20: Mn20 SB: D2(b) IGS of CaCu5- and Zr4Al3-type blocks (1: 1)

Mn17Pr2C2 59114 R3-mH 166 h f e d c2 hR19

Mn17Pr2C2 59114 R3-mH 166 h f e d c2 hR20

Mn17Pr2C2 59114 R3-mH 166 h f e d c2 hR21

Mn17Pr2C2 59114 R3-mH 166 h f e d c2 hR22

Mn23Th6 104987 FM3-M f2 d b a cF116 Mn1: cube: Mn8 (+6Th); Mn2.4: icosahedra: Mn2: Th4Mn4; Mn4: Th3Mn9; Mn3: 13: Th3Mn10; Th: 17: Th4Mn12+1 SB: D8(a) Th6 octahedra. IGS of gamma brass-type blocks (centred at Wyckoff position 8(c)) with four additional atoms per cell. IGS of Na16Ba6N- (central atom missing) and W-type blocks, centred at Wyckoff position 4(b) and 4(a).

Mn23Th6 104987 FM3-M f2 e d a cF116 SB: D8(a)

Mn23Th6 104987 FM3-M f2 e d b cF116 Mn1: cube: Mn8 (+6Th); Mn2.4: icosahedra: Mn2: Th4Mn4; Mn4: Th3Mn9; Mn3: 13: Th3Mn10; Th: 17: Th4Mn12+1 SB: D8(a) Th6 octahedra. IGS of gamma brass-type blocks (centred at Wyckoff position 8(c)) with four additional atoms per cell. IGS of Na16Ba6N- (central atom missing) and W-type blocks, centred at Wyckoff position 4(b) and 4(a).

Mn2Nd 54341 P1m1 6 c3 b3 a3 mP12

Mn2O3 52348 IA3- e d a cI80 Mn1.2: octahedra: O6; O: tetrahedron: Mn4 (+4O) Mg3P2, Yb2S3(theta), bixbyite, sesquisulfide T, SB: D5(3) SB: D5(3)-type;

Mn2O3 52348 IA3- e d b cI80 Mn1.2: octahedra: O6; O: tetrahedron: Mn4 (+4O) Mg3P2, Yb2S3(theta), bixbyite, sesquisulfide T, SB: D5(3)

Mn2Y 54374 I41/amdZ 141 d a tI12

Mn34Tb4C5 40783 P63/mmc 194 k j h g f d b hP43

Mn5Si3 33713 P63/MCM g2 d hP16 0.60 0.80 SB: D8(8) D8(8)-type

Mn6Bi(PO4)O8 51441 Fm3-m f2 d b a cF80

Mn7FeCl3O10 69062 Fm3-m h g f e c b a cF168

Mn7SiO12 66976 I41/acdZ 142 g3 f e c b a tI160 1.8 2.2 braunite

MnBi 58806 P2221 d2 c b a oP8 1.25 1.4

MnCoGe 1882 PNMA c3 oP12 1.25 1.66

MnMoO4H2O 61077 P1- 2 i7 aP18

MnNb4S8 42654 P63/MMC k h f b a hP26 1.65 2.10 MnNb4Se8

MnNd4OSe6 391299 P63mc c3 b2 a hP24 .65 .9

MnO2 20227 I4/M h3 tI24 0.244 0.345 Mn: octahedron: O6; O1: npl. triangle: Mn3 (+11O); O2: copl: triangle: Mn3 (+11O)

MnP 30412 PBNM c2 oP8 0.48 0.60 FeAs, NiSi, Sb: B14=B31

MnP 30412 PMCN c2 oP8 1.50 1.85 FeAs, NiSi, Sb: B14=B31

MnP 30412 PNAM c2 oP8 0.54 0.68 FeAs, NiSi, Sb: B14=B31

MnP 30412 PNMA c2 oP8 1.00 1.25 FeAs, NiSi, Sb: B14=B31

MnU6 150486 I4/mcm 140 k h a tI28 .49 .53

Mo2B5 24282 R3-mH 166 c3 b hR7

Mo2BC 23188 Cmcm 63 c4 oS16

Mo3NiS4 42401 R3-H 148 f4 c hR16

Mo3Se4 16316 R3-H f2 c hR14 1.05 1.40

Mo3Se4 16316 R3-R f2 c hR14 1 1

Mo3Y2Si4 76379 P121/c1 14 e4 b mP18

Mo6Ni6C 68119 Fd3-mS 227 f e d a cF104

Mo6Ni6C 68119 Fd3-mS 227 f e d c a cF104

Mo6PbS8 76369 R3-H f2 c a hR15 1.10 1.40 CaMo6S8, GeMo6S8, SnMo6S8

Mo6PbS8 76369 R3-R f2 c a hR15 1 1 CaMo6S8, GeMo6S8, SnMo6S8

MoB 24280 I41/AMDS 141 e2 tI16 5.00 6.00 SB: B(g)

MoC 44987 P63/MMC f2 b a hP12 3.9 5.0

moganite 67669 I12/a1 15 f4 e mS36 1.1 1.4

MoNi 105044 P212121 19 a14 oP56

MoNi4 105047 I4/M h a tI10 0.55 0.70 SB: D1(a)

MoNiP2 76283 P63/mmc 194 f b a hP8

MoO3 30258 Pbnm 62 AX3 c4 oP16

MoP 43331 Cmc21 a3 oS12 1.5 2

MoPt2 105070 Immm 71 g a oI6

mordenite 34891 Cmcm 63 h5 g5 e d c2 b oS152 Common (Si, Al)O2-framework in h5 g5 e d c2 with 144 atoms/cell, great variability of additional enclosed counter-cations and absorbed molecules

MoS2(3R) 40081 R3MH a3 hR3 5 6.50

MoS2(4H) 24000 P63/MMC f c hP6 3.30 4.50 C7-type, MoS2-family (of stacking variants)

MoS2(4H) 24000 P63/MMC f d hP6 3.30 4.50 C7-type, MoS2-family (of stacking variants)

MoSi2 26868 I4/MMM e a tI6 2.064 2.924 Mo, Si: rhombic dodecahedron (10+4): Mo: Si10Mo4; Si: Mo5Si5+4 AlCr2, SB: C11(b) Close packed MoSi2 layers (Mo atoms form triangle mesh), Mo in neigbouring layers are located over and under centres of edges of Si6 hexagons. Isopointal with CaC2- and CuZr3-type.

MoSi2 26868 I4/MMM e b tI6 2.064 2.924 Mo, Si: rhombic dodecahedron (10+4): Mo: Si10Mo4; Si: Mo5Si5+4 AlCr2, SB: C11(b) C11(b)-type; close packed MoSi2 layers (Mo atoms form triangle mesh), Mo in neigbouring layers are located over and under centres of edges of Si6 hexagons. Isopointal with CaC2- and CuZr3-type.

MoUC2 16549 Pnma 62 c4 oP16 1.7 2.28 CrUC2

Muscovite 1M 63123 C12/m1 j3 i2 g d mS41

Muscovite 1M 63123 C12/m1 j3 i2 g d mS42

Muscovite 2M1 30297 C12/c1 15 f9 e mS82

Muscovite 2M1 30297 C12/c1 15 f9 e mS83

Muscovite 2M1 30297 C12/c1 15 f9 e mS84

Muscovite 2M2 4368 C12/c1 15 f9 e mS83

Muscovite 2M2 4368 C12/c1 15 f9 e mS84

Muscovite 3T 9650 P3112 c8 b a2 hP61 5.15 6.35

Muscovite 3T 9650 P3112 c8 b a2 hP63 5.15 6.35

Na1.55Si17 50799 Fd3-mZ 227 g e c b a cF146 Clathrate, framework of tetrahedrally connected Si(or Ge)-atoms (or H2O-molecules) in g e a with 136 atoms/cell. Additional greater atoms or small molecules in cavities of the framework.

Na1.55Si17 50799 Fd3-mZ 227 g e c b a cF160 Clathrate, framework of tetrahedrally connected Si(or Ge)-atoms (or H2O-molecules) in g e a with 136 atoms/cell. Additional greater atoms or small molecules in cavities of the framework.

Na21Zn(SO4)10Cl3 80099 I4-3d e5 d c3 a cI300

Na2CaMn7(PO4)6 100869 R3-H 148 f38 c5 b a hR240 fillowite

Na2HgO2 27409 I4/MMM e2 a tI10 2.8 4.15 Na: tetrag. pyramid: O5; Hg: colinear O2 (+4Hg); O: 6: HgNa5 Sc2BC2, U2IrC2, Na2PdH2 Linear O-Hg-O units, Hg-O=1.97

Na2Mg(CO3)2 9518 R3-H 148 f c2 a hR11 3 3.7 eitelite

Na2Mn3Cl8 1846 R3-MH 166 h d c2 hR13

Na2Mn3Cl8 1846 R3-MH 166 h e c2 hR13

Na2O2 25526 P6-2M h g f e hP12

Na2PtS2 87219 Cmc21 36 a5 oS20

Na2Re3S6 76536 C12/c1 15 f10 e2 mS88

Na2SiF6 16598 P321 g3 f e d a hP27 .52 .59

Na2SnF6 23156 P121/c1 14 e4 a mP18

Na2SO3 4432 P3- g d2 b a hP12 1.1 1.3

Na2SO4 27654 Fddd 70 h f a oF56 thenardite

Na3(CaSrLa)(CO3)5 22349 P63MC d c6 b a hP52 0.55 0.70 burbankite

Na3AlF6 30201 P121/c1 14 e4 b a mP20 1.4 1.5 cryolite

Na3As 26883 P63/MMC f c b hP8 1.55 2.00 Al3Ir, SB: D0(18)

Na3As 26883 P63/MMC f d b hP8 1.55 2.00 Al3Ir, SB: D0(18)

Na3AsS3 645 P213 b a4 cP28 K3SbTe3

Na3AuS2 202329 R3-CH 167 e c b hR12 1.9 2.4

Na3CrCl6 62035 P3-1c i f c a hP20 1.6 2.1

Na3H(SO4)2 8049 P121/c1 14 e12 d a mP56

Na3Mg(CO3)2Cl 4237 Fd3-cZ 203 g f e d c cF208 northupite

Na3MnCO3PO4 200789 P121/m1 11 f2 e9 mP26 sidorenkite

Na3Pt4Ge4 32038 I4-3M c2 b cI22

Na4Al4Si9O24Cl 87538 I4/M i3 h4 a tI82 0.55 0.72 marialite

Na5Al3F14 25618 P4/mnc 128 i h g e c b a tP44 chiolite

Na6(SO4)2ClF 26914 Fm3-m f e c b a cF72

Na6(SO4)2O 411442 Fm3-m f e c a cF68

Na6Fe2(CO3)4SO4 20169 Fd3-Z 203 g f e2 d a cF232 (ferro)tychite

Na6Mg(SO4)4 16607 P121/c1 14 e13 a mP54 vanthoffite

Na6Pb3P4Se16 91168 I4-3d e d2 c2 cI116

Na7(AsO4)2F(H2O)19 34388 Fd3-cZ 228 h6 e d c a cF2400

Na8Al6Si6O24Cl2 30263 P4-3N i e d c a cP46 sodalite, SB: S6(2)

Na8SnSb4 76496 Fd3-mZ 227 f e c a cF104

NaAl3P2O8 (OH)4(H2O)2 6300 P41212 b9 a2 tP112 2.40 3.05 wardite

NaAl3P2O8 (OH)4(H2O)2 6300 P43212 b9 a2 tP112 2.40 3.05 wardite

NaAlCl4 30611 P212121 19 a6 oP24 0.55 1.8

NaAlSi3O8 52343 C1- 2 i13 aP26 albite

NaBaCe2(CO3)4F 68245 P63/MMC k2 f2 e d c a hP42 4.00 5.15 cordylite

NaBaLiNiF6 72211 Fm3-m d c b a cF40

NaBaZrF7 67515 Pnma 62 ABCX7 d3 c4 oP40

nabokoite 68186 P4/ncc 130 g8 d c3 b a tP156

NaCa(Nb2O6)F 24445 FD3-MS 227 f d c a cF88

NaCa(Nb2O6)F 24445 FD3-MS 227 f d c b cF88 (Na, Ca): 8: F2O6; Nb: octahedron: O6; O: tetrahedron: Nb2(Ca, Na)2 (+4O); F: tetrahedron: (Ca, Na)4 (+6O) pyrochlore, SB: E8(1)

NaCl 53815 FM3-M b a cF24 Na: octahedron: Cl6; Cl: octahedron: Na6 ClNa, rocksalt, halite, SB: B1 Close packed Cl layers in c stacking, Na occupies all octahedral voids. NaCl6 octahedra share edges to form a 3D-framework.

NaCl 53815 FM3-M b a cF8 Na: octahedron: Cl6; Cl: octahedron: Na6 ClNa, rocksalt, halite, SB: B1 Close packed Cl layers in c stacking, Na occupies all octahedral voids. NaCl6 octahedra share edges to form a 3D-framework.

NaClO3 22395 P213 b a2 cP20

NaCrS2 15558 R3-MH 166 c b a hR4 4.40 6.25 FeNaO2, NaTiS2, RbBiS2, AgBiSe2, delafossite-3R

NaCrS2 15558 R3-MR c b a hR4 1 1 FeNaO2, NaTiS2, RbBiS2, AgBiSe2, delafossite-3R

NaFeO2(beta) 27804 Pna21 a4 oP16 .85 1.1

NaFeP2O7 37013 P121/c1 ABC2X7 e11 mP44 1.2 1.4

NaKTeO3(H2O)3 24781 P31C c2 b2 a hP30

NaMgOH(SO3)2 61209 P1- 2 i12 f d aP32

NaN3(beta) 24006 R3-MH c b a hR4 3.7 4.6

NaN3(beta) 24006 R3-MR 166 c b a hR4

NaP 14009 P212121 a4 oP16 1.5 1.85 KP

NaPb 105156 I41/ACDS 142 g f e tI64 1.5 1.83

NaSCN 953 Pnma 62 c4 oP16

Nasicon high 20740 R3-CH 167 f2 e2 c hR40 2.42 2.55

Nasicon low 62177 C12/c1 15 f9 e2 d mS80 0.57 0.6

NaSn2 170467 C12/m1 12 j3 i5 g mS48

NaTi4O8 23879 C12/m1 12 i6 a mS26 .48 .57

NaTl 105169 FD3-MS 227 b a cF16 Na, Tl: rhombic dodecahedra (8+6): Na: Na4Tl4+6; Tl: Tl4Na4+6 Rb2Sb(beta), SB: B32 Tl atoms from a tetrahedral 3D-framework. Sequence along body diagonal: -Na-Na-Tl-Tl-. Aristotype is W

natrolite 30278 Fdd2 43 b9 a oF184 .32 .4 zeolote-NAT Common (Si, Al)O2-framework in b7 a with 120 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

NaZn13 105173 FM3-C i b a cF112 Na: 24: (Zn2)24; Zn1: icosahedron: (Zn2)12; Zn2: 10+2: (Zn1)(Zn2)9Na2 SB: D2(3) Centres of ZnZn12 icosahedra and na atoms form a CsCl-type lattice.

Nb2Se3 42981 P121/m1 11 e5 mP10 1.3 1.5

Nb2SnO6 202827 C12/c1 15 f4 e mS36 .3 .37

Nb3PbS6 74694 P6322 182 i f b a hP20

Nb5As3 16417 Pnma 62 c16 oP64

Nb6F15 25769 IM3-M h e b cI42

Nb7P4 41238 C12/m1 12 i10 d a mS44

NbAs 16585 I41md 109 a2 tI8

NbO 14338 PM3-M d c cP6 Nb: copl. square: O4 (+8Nb); O: copl. square: Nb4 (+8O) NbO4 squares share single corners to form a 3D-framework.

NbPt3 54283 P121/m1 11 f2 e4 mP16 TaNi3

NbS2(hP6) 43697 P63/MMC f b hP6 3.20 4.40 TaS2

NbSe3 30002 P121/m1 11 e12 mP24 1.45 1.65

NbTe2 14389 C12/m1 12 i4 a mS18

NbTe4 25770 P4cc 103 d a tP10

Nd(B2O2)3 4236 I12/c1 15 f4 e2 mS40

Nd2CuO4 4203 I4/MMM e d c a tI14 3 3.40

Nd2Fe23B3 44298 I4-3d e3 d2 c2 cI224

Nd3Ni13B2 86374 P6/MMM i h f e d b hP18 2.00 2.50

Nd3Ni13B2 86374 P6/MMM i h g e c a hP18 2.00 2.50

Nd3Ni7P5 67094 P63/m 176 h10 d hP60

Nd6Fe13Si 40059 I4/mcm l3 k f d a tI80

NdAlO3 10333 R3-CH e b a hR10 2.15 2.7

NdAlO3 10333 R3-CR e b a hR10

NdAs2 1730 P121/c1 14 e3 mP12

NdBr3 31590 Ccmm f c2 oS16 0.65 0.8

NdBr3 31590 Cmcm f c2 oS16 2.15 2.8

NdNiGa2 103850 Cmmm 65 j2 i d b oS16

NdRh2Sn4 105285 Pnma c7 oP28 0.35 0.45

NdRh5B3 37031 P6-2M f d b hP6 0.45 0.60

NdRh5B3 37031 P6-2M g c a hP6 0.45 0.60

NdSi2-x 54376 P2212 17 d3 c3 oP11

NdSn2 54292 Cmmm 65 j i c a oS12 ZrGa2, ThGe2

NdSn2 54292 Cmmm 65 j i d b oS12 ZrGa2, ThGe2

NdTe3 23973 Cmcm 63 c4 oS16 AsMn3, D0(d)

NdYbS3 2062 C2221 20 c b a2 oS20

nenadkevichite 39843 C1m1 8 b21 a13 mS110 K2(Nb, Ti)2Si4O12(O, OH)2(H2O)1.6

NH4CdCl3 15616 Pnam 62 c5 oP20

NH4CdCl3 15616 Pnam 62 c5 oP36

NH4NO3(III) 24012 Pbnm AXY3 d c3 oP36 .73 .92

NH4NO3(IV) 24013 PmmnS 59 e b a2 oP18

NH4NO3(IV) 24013 PmmnS 59 f b a2 oP18 nitrammite

Ni12SrB6 100286 R3-MH h2 f b hR19 0.70 0.90

Ni12SrB6 100286 R3-MH h2 g a hR19 0.70 0.90

Ni17Th2 105410 P63/MMC k j g f c b hP38 0.85 1.10 CeNi15Si2

Ni17Th2 105410 P63/MMC k j g f d b hP38 0.85 1.10

Ni19Th2 105411 P63/mmc 194 k2 j3 g f e d c b hP38

Ni20Sc4B10 40443 I41/amd 141 h2 g f e2 c a tI85

Ni20Y6P13 62491 P6- k6 j6 d c a hP39 0.25 0.35 Ni20Zr6P13, Rh20U6P13

Ni20Y6P13 62491 P6- k6 j6 f c a hP39 0.25 0.35 Ni20Zr6P13, Rh20U6P13

Ni2Re5As12 35731 Pnnm 58 g9 a oP38

Ni2Tm 105431 F4-3m h2 g e4 b a cF189

Ni2USi3 9968 I4/mmm 139 g e3 d tI24

Ni3P 54177 I4- g4 tI32 0.44 0.55 Fe3P

Ni3Pb2S2 24176 R3-MH d c b a hR7 2.10 2.80 Ni3Sn2S2

Ni3Pb2S2 24176 R3-MH e c b a hR7 2.10 2.80 Ni3Sn2S2

Ni3Pb2S2 24176 R3-MR d c b a hR7 Ni3Sn2S2

Ni3Pb2S2 24176 R3-MR e c b a hR7 Ni3Sn2S2

Ni3S2 27521 R32H 155 d c hR5 Ni3Se2, heazlewoodite, D5(e)

Ni3S2 27521 R32H 155 e c hR5 Ni3Se2, heazlewoodite, D5(e)

Ni3Sn 105357 P63/MMC h c hP8 0.70 0.90 Mg3Cd, Pt3U, SB: D0(19) Aristotype is Mg

Ni3Sn 105357 P63/MMC h d hP8 0.70 0.90 Mg3Cd, Pt3U, SB: D0(19) Aristotype is Mg

Ni3Sn2 105358 Pnma 62 N2O3 d c3 oP20

Ni3Ti 30216 P63/MMC h g c a hP16 1.45 1.85 Pd3U, SB: D0(24) D0(24)-Type

Ni3Ti 30216 P63/MMC h g d a hP16 1.45 1.85 Pd3U, SB: D0(24)

Ni3Zr2P3 76680 Pnma 62 c8 oP32 .75 .9

Ni4U3Si4 41747 Immm 71 j2 i3 b oI22 U3Ni4Si4

Ni4U3Si4 41747 Immm 71 j3 i2 a oI22 U3Ni4Si4

Ni5P4 43239 P63MC c5 b a2 hP36

Ni5YSi3 23036 Pnma NO3P5 c9 oP36 .31 .4 Ni5USi3

Ni60Yb11C6 39331 Im3-m k j f e2 d b cI154

Ni6PbY12 54614 Im3- g e a cI38

NiAs 31062 P63/MMC c a hP4 1.2 2 As: trig. prism: Ni6; Ni: bicapped octahedron: As6Ni2 AsNi, NiS(LT), PtB, nickeline, niccolite, SB: B8(1) Close packed As layers in h stacking, all octahedral voids occupied by Ni. AsNi6 trigonal prisms share edges to form a 3D-framework.

NiAs 31062 P63/MMC d a hP4 1.2 2 As: trig. prism: Ni6; Ni: bicapped octahedron: As6Ni2 AsNi, NiS(LT), PtB, nickeline, niccolite, SB: B8(1) Close packed As layers in h stacking, all octahedral voids occupied by Ni. AsNi6 trigonal prisms share edges to form a 3D-framework.

NiAs2 24204 Pbca 61 c3 oP24 pararammelsbergite

NiCl2(H2O)6 22284 C12/m1 12 j i2 a mS42 nickelbischofite

NiCl2(NCNH2)4 411553 Im3-m k h2 e b cI138

nigerite 3T 39902 P3-m1 164 i4 e d4 c2 b hP41

nigerite 3T 39902 P3-m1 164 i4 f d4 c2 a hP42

NiS 29312 R3MR 160 b2 hR6

NiSmGe3 60645 Cmmm 65 h2 g3 oS20

NiSmGe3 60645 Cmmm 65 j2 i3 oS20

NiSSb 44606 P213 a3 cP12 ullmannite Aristotype is FeS2(cP12), S-Sb dumbbells, S-Sb=3.25, isopointal with ZrOS

NiTa2Si7 61352 C12/m1 12 i10 mS40 1.3 1.4

NiTi2 105420 FD3-MS 227 f e c cF96

NiTi2 105420 FD3-MS 227 f e d cF96 Ni, Ti1: icosahedra: Ni: Ti9Ni3; Ti1: Ni6Ti6; Ti2: 14: Ni4Ti10

NiWO4 16685 P12/c1 13 g2 f e mP12 wolframite

NiZr6Cl15 71149 Im3-m h e b a cI44

nolanite 16761 P63mc 186 c3 b3 a hP26

offretite 2747 P6-m2 o2 n3 m l3 k3 j i2 h g c b hP86 zeolite-OFF Common (Si, Al)O2-framework in o2 n2 m l k2 b with 54 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

OsGe2 43690 C12/m1 12 i3 mS12

Overite 10406 Pbca 61 c18 oP216 CaMgAl(PO4)2 OH(H2O)4

P2O5 40865 R3CH 161 b4 a2 hR28

Pa 24622 I4/MMM a tI2 0.75 0.90

Paragonite 3T 200224 P3112 c8 b a3 hP60 5 6.2

Paragonite 3T 200224 P3112 c8 b a3 hP61 5 6.2

Paragonite 3T 200224 P3112 c8 b a3 hP63 5 6.2

Paragonite 3T 200224 P3112 c8 b3 a hP63 5 6.2

Pargasite 87849 C12/m1 12 j7 i2 h2 g b a mS80 NaCa2Mg4AlAl2Si6O22 (OH)2

Pargasite 87849 C12/m1 12 j7 i2 h2 g b a mS81 NaCa2Mg4AlAl2Si6O22 (OH)2

Pargasite 87849 C12/m1 12 j7 i2 h2 g b a mS82 NaCa2Mg4AlAl2Si6O22 (OH)2

Pargasite 87849 C12/m1 12 j7 i2 h2 g b a mS83 NaCa2Mg4AlAl2Si6O22 (OH)2

Pargasite 87849 C12/m1 12 j7 i2 h2 g b a mS84 NaCa2Mg4AlAl2Si6O22 (OH)2

paulingite 34452 Im3-m 229 l14 k12 j8 i2 h2 g f3 e3 cI3460 Common (Si, Al)O2-framework in l14 k6 j6 i2 with 2016 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

Pb2Cl2CO3 38358 P4/mbm k j h2 g e tP32 1.05 1.15 phosgenite

Pb2Fe(CN)6 51493 P3- g2 d a hP15 .70 .8

Pb2OSO4 14246 C12/m1 12 j i5 g mS32

Pb3O2Cl2 23521 Pnma 62 d c5 oP28 mendipite

Pb3O4 36253 P42/MBC h2 g d tP28 0.625 0.887 Pb1: octahedron: O6; Pb2: npl. triangle: O3 (+(Pb2)); O1: npl. triangle: (Pb2)2(Pb1) (+(O2)); O2: (3+1) tetrahedron: (Pb

Pb4(Ti3Te)O13 61228 FD3-MZ 227 f d c a cF84

Pb5(AsO3)3Cl 100168 P63/m i h3 f b hP36 .6 .75

Pb5I6S2 25304 C12/m1 12 i6 a mS26

PB6 62748 R3-mH 166 h2 c hR14

Pb7O8Cl2 202630 I4/mmm g e2 b tI17 asisite

PbAgAsS3 26835 P121/a1 e6 mP24 .76 .84 marrite

PbClF 30287 P4/NMMZ 129 c2 a tP6 1.481 2.098 Pb: monocapped antiprism F4Cl5; Cl: tetrag. pyramid: Pb5; F: tetrahedron: Pb4 BiClO, CeFeSi, KAgSe, NaMnP, ZrSiS, ZrSiSe, matlockite, bismoclite, SB: E SB: E0(1)-type; IGS of ternary BaAl4- and W-type slabs. With higher c/a ratio 2D-character appears.

PbClF 30287 P4/NMMZ 129 c2 b tP6 1.481 2.098 matlockite, BiClO, Cu2Sb, SB: E0(1)

PbClOH 27137 Pnma 62 c3 oP16 laurionite

PbO 53927 P4/NMMZ 129 c a tP4 1.065 1.509 Pb: npl. square: O4 (+4Pb); O: tetrahedron: Pb4 (+4O) litharge, Sn(gamma), InBi, FeSe(alpha), BaO(HP), SB: B10 SB: B10-type; planar square-mesh O nets, Pb atoms alternatively over and under the squares. Layer structure with edge-linked (: PbO4) square psi-pyramids. IGS of W- and CaF2-type slabs (1: 1)

PbSbO2Cl 36159 Bmmb 63 e c3 oS20 nadorite

PbTiO3 16621 P4MM c b2 a tP5 0.95 1.20 macedonite

PbU2Se5 66862 P121/c1 14 e8 mP32 1.4 1.65

PbWO4 811 P121/a1 e6 mP24 .37 .45

PbWO4 811 P121/c1 e6 mP24 2.25 2.75

PbZn2(AsO4)2(H2O)2 76617 P1- 2 i6 g f a aP18

PbZn2(AsO4)2(H2O)2 76617 P1- 2 i6 g f a aP19 helmutwinklerite

PbZnVO4OH 40083 Pnma 62 d c5 a oP36 descloizite

PbZnVO4OH 40083 Pnma 62 d c5 b oP36 descloizite

Pd13Tl9 105730 P3-m1 164 i2 f e d b a hP22

Pd17Se15 23907 PM3-M m j i f e d b cP64

Pd2RhTa 105667 P63/mmc 194 k2 h f2 b hP40

Pd2SnU 105698 Pnma 62 NOP2 c4 oP15

Pd3Te2 77902 Cmcm 63 f c2 a oS20 2 2.5

Pd3US4 201796 PM3-N d c a cP16

Pd3US4 201796 PM3-N e c a cP15

Pd3US4 201796 PM3-N e c a cP16 NaPt3O4

Pd3US4 201796 PM3-N e d a cP16 NaPt3O4

Pd4Pu3 2516 R3-H e2 b a hR14 0.38 0.50

Pd4Pu3 2516 R3-H f2 b a hR14 0.38 0.50

Pd5B2 43513 C12/c1 15 f3 e mS28

Pd5Pu3 350 Cmcm 63 g f e c2 oS32 La3In5, U3Ga5, Zr3Ga5, Zr3Rh5

Pd5Th3 105719 P6-2m 189 g f c hP8

Pd5TlAs 23540 P4/MMM i c b a tP7 16.801 2.00 8-a, 11-d, 12-b IGS of Cu3Au- and CaF2-type slabs.

Pd5TlAs 23540 P4/MMM i d b a tP7 16.801 2.00

Pd5TlAs 23540 P4/MMM i d c a tP7 16.801 2.00

Pd8Sb3 77891 R3cH 161 b5 a7 hR44

PdF2(cP12) 100567 PA3- c a cP12 Pd: octahedron: F6; F: copl. triangle: Pd3 (+7F) Isopointal with FeS2(pyrite), but no F-F-dumbbells, 6 F-F=2.84, 1 F-F=2.89

PdF2(cP12) 100567 PA3- c b cP12 Pd: octahedron: F6; F: copl. triangle: Pd3 (+7F) Isopointal with FeS2(pyrite), but no F-F-dumbbells, 6 F-F=2.84, 1 F-F=2.89

PdO 26598 P42/mmc 131 e c tP4

PdO 26598 P42/mmc 131 e d tP4 palladinite

PdSn2 108761 Aba2 41 b2 a2 oS24

PdTa2S6 61004 C12/m1 12 i4 a mS18

pectolite 25786 P1- 2 i15 aP32

Phlogopite 1M 44891 C12/m1 12 j3 i2 h c b mS39

Phlogopite 1M 44891 C12/m1 12 j3 i2 h c b mS40

Phlogopite 1M 44891 C12/m1 12 j3 i2 h c b mS41

Phlogopite 1M 44891 C12/m1 12 j3 i2 h c b mS42

Phlogopite 1M 44891 C12/m1 12 j3 i2 h c b mS43

Phlogopite 1M 44891 C12/m1 12 j3 i2 h c b mS44

Phlogopite 1M 44891 C12/m1 12 j3 i2 h d a mS44

phosphuranylite 40010 Cmcm 63 h9 g5 f5 c3 b oS332 KCa(UO2)7(PO4)4O4 (H2O)8(H3O)3

Phurcalite 1687 Pbca 61 c29 oP328 Ca3(UO2)3(PO4)2 (OH)4(H2O)4

Po(alpha) 76749 PM3-M a cP1 SB: A19

Po(hR1) 43212 R3-mH 166 a hR1 .7 1.4

polyhalite 6303 F1- 2 i13 a aP31 K2Ca2Mg(SO4)4 (H2O)2

Pr(HP) 54388 R3-MH 166 h c hR8 2.3 2.7

Pr2Re3B6 86366 C12/c1 15 f5 e mS44 1 1.25

Pr2Si2O7 14252 P121/c1 e11 mP44 2.5 2.8

Pr3Rh4Sn13 102352 PM3-N k e c a cP40 Yb3Rh4Sn13

Pr3Rh4Sn13 102352 PM3-N k e d a cP40 Pr: 16: Sn12Rh4; Rh: 9: Sn6Pr3; Sn1: icosahedron: Sn12; Sn2: 14: Rh2Sn9Pr3 Yb3Rh4Sn13, phase I RhSn6 trigonal prisms share single corners to form a 3D-framework. Infinite columns of face-sharing PrSn12 cuboctahedra.

Pr7O12 1857 R3-H 148 f3 a hR19

Pr8Sb2S15 20353 I41cd b12 a tI200

PrBN2 72107 R3cH 161 b4 hR24

preisingerite 31179 P1- 2 i15 aP32

PrPS4 201897 I41/acd 142 g2 e b a tI96

Pt(NH3)4Cl(HSO4)2 35147 P121/c1 14 e8 a mP60

Pt3O4 43002 PM3-N e c cP14 Pt: copl. square: O4 (+2Pt); O; copl. triangle: Pt3 (+6O) PtO4 squares share single corners to form a 3D-framework.

Pt3Tl2 105821 P3-1c i f c a hP20 2.1 2.9

PtSn4 105793 Aba2 41 b2 a oS20

PtTe2 105813 P3-m1 d a hP3 1 1.35

PtTe2 105813 P3-m1 d b hP3 1 1.35

PtYAs 44047 P63/MMC f2 b a hP12 3.10 3.90 CaGaGe, Tb1-xNiP

Pu2C3 24620 I4-3D d c cI40 Pu: 9: C9; C: pentag. bipyramid: CPu6 Rb2O3, C3Pu2 SB: D5(c)-type; C-C dumb-bells (C-C=1.40, intermediate between single and double bond).

Pu3Zn22 105879 I41/amd 141 i h3 e d b tI100

Pu5Rh3 105863 P4/NCCS g f c b tP32 0.50 0.65 Nd5Ir3

pumpellyite 29259 C12/m1 12 j4 i13 f mS100 Ca4MgAl5Si6O22 (OH)5H2O

pumpellyite 29259 C12/m1 12 j4 i13 f mS102 Ca4MgAl5Si6O22 (OH)5H2O

quartz, high 31088 P6222 i d hP9

quartz, high 31088 P6222 j c hP9

quartz, high 31088 P6222 k c hP9

quartz, high 31088 P6422 j c hP9

quartz, low 40009 P3121 c a hP9

quartz, low 40009 P3221 c a hP9

Rb18Cu31Cl49 201785 I4-3d e6 d2 c3 a cI385

Rb18Cu31Cl49 201785 I4-3d e6 d2 c3 b cI392

Rb2C2 51529 Pnma 62 AX c4 oP16

Rb3Hg20 240037 PM3-N k e d c a cP46

RbAg3Sm2Se5 91095 Cmcm 63 f4 c3 oS44 3.9 4.3

RbNiCrF6 15649 Fd3-mZ 227 f c b cF72

Re(NCl)F5 62531 P121/m1 11 f2 e4 mP16

Re3B 43662 Cmcm 63 f c2 oS16 2.3 2.9

Re7U4Si6 2471 IM3-M e d c a cI34

ReB2 23871 P63/mmc 194 f c hP6

ReB3 24361 P63/mmc 194 f c a hP8 2.1 2.6

ReBiO4 10481 Cmcm f c3 a oS24

ReBiO4 10481 Cmcm f c3 b oS24

ReO3 16810 PM3-M c b cP4 Re: octahedron: O6; O: colinear Pd2 (+8O) NCu3, Cu3N(antitype), SB: D0(9) RO6 octahedra share corners to form a 3D-framework

ReO3 16810 PM3-M d a cP4 Re: octahedron: O6; O: colinear Pd2 (+8O) NCu3, Cu3N(antitype), SB: D0(9) ReO6 octahedra share corners to form a 3D-framework

ReY2B6 16187 Pbam 55 h3 g6 oP36

ReY2B6 16187 Pbam 55 h6 g3 oP36

ReY3B7 2475 Cmcm 63 f4 c3 oS44 CrEr3B7

Rh13Sc57 105922 Pm3- l2 k3 j3 h g e b a cP140

Rh2S3 15344 Pbcn 60 d2 c oP20 .65 .8

Rh2Y3 337 I4/MCM m2 l2 h2 g f c b a tI140 2.00 2.60 Er3Rh2

Rh2Y3Si2 30725 Pbcm 57 e2 d2 c oP28

Rh3ScSi7 15243 R3-cH 167 f e b a hR22 2.35 2.9

Rh3Y2Sn5 105935 Cmc21 36 a10 oS40

RhBi3 58853 Pnma 62 c4 oP16

Rinkite 28023 P1211 4 a30 mP60

roselite 54882 P121/c1 14 e7 a mP38

rosenbuschite 22334 P1- 2 i28 g c b a aP60

roweite 6172 Pbam 55 i6 h5 g3 c a oP108

Ru2Si3 2344 Pbcn 60 d4 c2 oP40

Ru3UB2 44578 P3- 147 g6 f e d2 b a hP48

Ru4Sn6Y 54354 I4-2m i2 c a tI22 1.4 1.45

RuF5 26670 P121/a1 e12 mP48 .42 .46

RuF5 26670 P121/c1 e12 mP48 2.2 2.35

S3N2O2 15795 C12/c1 15 f3 e mS28

Sb2S3 26751 PBNM c5 oP20 0.30 0.40 Bi3S3, SB: D5(8)

Sb2S3 26751 PCMN c5 oP20 0.90 1.15 Bi3S3, SB: D5(8)

Sb2S3 26751 PMCN c5 oP20 2.70 3.40 Bi3S3, SB: D5(8)

Sb2S3 26751 PNMA c5 oP20 0.90 1.10 Bi3S3, SB: D5(8)

SbO2 24244 Fd3-mZ 227 f d c b a cF96

SbTaO4 25548 Pna21 33 a6 oP24

Sc15C19 42631 P4-21c 114 e7 c2 b a tP68

Sc2O2S 2450 P63/MMC f2 b hP10 3.10 4.10 Pt2Sn3, SB: D5(b)

Sc2S3 22236 Fddd 70 h g2 e oF80

Sc2S3 22236 Fddd 70 h g2 f oF80

Sc2Si2O7 26682 C12/m1 12 j i2 g d mS22 thortveitite, S2(1)

Sc2Si2O7 26682 C12/m1 12 j i2 h a mS22 thortveitite, S2(1)

Sc5Cl8 36403 C12/m1 12 i6 a mS26

Sc7Cl12 36424 R3-H 148 f3 a hR19

Sc7I12C 61265 R3H 146 b6 a2 hR20

ScRhSi2 15248 Pnma 62 c4 oP16 1.45 1.65 YZn3

ScU3S6 612 Pnnm 58 g9 c a oP40 .2 .3

ScU3S6 612 Pnnm 58 g9 c b oP40 .2 .3

ScU3S6 612 Pnnm 58 g9 d b oP40 .2 .3

ScUS3 2239 Cmcm 63 f c2 a oS20

ScUS3 2239 Cmcm 63 f c2 b oS20 2.3 2.5

ScYS3 23422 Pna21 a5 oP20 1.3 1.45

Se 53801 P3121 a hP3 1.10 1.30 SB: A8

seidozerite 30386 P12/c1 13 g13 f2 e2 mP59

seidozerite 30386 P12/c1 13 g13 f2 e2 mP60

seidozerite 30386 P12/c1 13 g13 f2 e2 mP62

SF6 63362 Im3-m e a cI14

Si(HP) 16955 Ia3- c cI16

Si3Cl8 2767 F4-3c h e2 b a cF176

SiC(4H) 24170 P63MC b2 a2 hP8 2.95 3.6 Zhdanov-symbol: (2 2)

SiC(6H) 15325 P63MC b4 a2 hP12 4.4 5.5

sillimanite 25711 Pbnm d c5 a oP32 .68 .9

sillimanite 25711 Pnma d c5 a oP32 .9 1.2

Sm 76031 R3-MH c a hR3 6.50 8.50

Sm 76031 R3-MH c b hR3 6.50 8.50

Sm2F(AuF4)5 66068 P41212 b13 a2 tP112 3 3.3

Sm2O3 34291 C12/m1 12 i7 b mS30 .55 .7

Sm2O3(cI80) 27998 I213 c2 b2 a cI80 Sm1.2.3: octahedra: O6; O1: tetrahedron: Sm4 (+4O); O2: tetrahedron: Sm4 (+5O)

Sm5Ge4 41707 Pnma 62 d3 c3 oP36 .9 1.15 Ba5Sb4

SmSI 2510 R3-MH c3 hR6 6.9 8.9

SmSI 2510 R3-MR c3 hR6

Sn 53790 I41/AMDS 141 a tI4 0.50 0.62 SB: A5

Sn21Cl16(OH)14O6 15581 R32H 155 f7 e d c4 b hR71 abhurite

Sn2S3 97513 Pnma 62 ABX3 c5 oP20

Sn5Ti6 27022 P63 173 c3 b2 a hP23

Sn5Ti6 27022 P63 173 c3 b2 a hP24

Sn5Ti6(P63/mmc) 106088 P63/mmc 194 h2 g c a hP22

Sn7Tb3 54357 Cmmm 65 j4 i2 d b oS20

SnF3 33786 Fm3-m e b a cF32

SnI4 31093 PA3- AX4 d c2 cP40 ?? isopointal zu Au3NaSi ??

SnTaS2 100387 P63/mmc 194 e c a hP8

sodalite 24441 P4-3n 218 i e2 d c cP66 zeolite-SOD

sodalite 24441 P4-3n 218 i e2 d c a cP52 zeolite-SOD

sodalite 24441 P4-3n i e2 d c a cP54 zeolite-SOD

sodalite 24441 P4-3n 218 i e3 d c cP66 zeolite-SOD

Sr2N 69016 R3-mH c a hR3 5.0 6.3

Sr2N 69016 R3-mR c a hR3

Sr2Ta15O32 50513 R3-H 148 f8 c2 b hR49 4 5

Sr3Ti2O7 34629 I4/MMM g e3 b a tI24 4.390 6.219 Sr1: cuboctahedron: O12; Sr2: 9: O9; Ti: octahedron: O6; O: octahedra: O1.2: Sr4Ti2; O3: Sr5Ti IGS of NaCl- and CaTiO3-type slabs (1: 2). TiO6 octahedra share corners to form double slabs.

Sr4(Ga8Ge15)-a 90177 PM3-N k j i c a cP54

Sr4(Ga8Ge15)-b 90182 PM3-N k2 i c a cP54

Sr4Ti3O10 34630 I4/MMM g e5 c a tI34 6.052 8.574 Sr1: cuboctahedron: O12; Sr2: 9: O9; Ti1.2: octahedra: O6; O: octahedra: O1.2.3: Sr4Ti2; O4: Sr5Ti IGS of NaCl- and CaTiO3-type slabs (1: 3). TiO6 octahedra share corners to form triple slabs.

Sr8Rh5H23 74994 Pm3-m h g f e c b a cP36

Sr9B6N12 74915 Im3-m e c b a cI28

SrCa2Lu10O18 9631 P63 c10 b hP62

SrCa2Lu10O18 9631 P63 c10 b a hP62

SrCa2Sc6O12 4127 P63/m 176 h3 c b hP21 .3 .36

SrSi2 2860 P4132 c a cP12

SrSi2 2860 P4332 c a cP12

SrSn4 281669 Cmcm 63 f c2 a oS20 1.45 1.7

SrZnO2 15913 Pnma 62 ABX2 c4 oP16

staurolite 22051 C12/m1 12 j7 i3 h g d c b a mS77

staurolite 22051 C12/m1 12 j7 i3 h g d c b a mS80

staurolite 22051 C12/m1 12 j7 i3 h g d c b a mS81

staurolite 22051 C12/m1 12 j7 i3 h g d c b a mS82

stilbite 28270 C12/m1 12 j12 i2 h g mS210 Common (Si, Al)O2-framework in j12 i h g with 108 atoms/cell, great variability of additional enclosed counter-cations and absorbed molecules

strunzite 100409 P1- 2 i21 aP70 MnFe2(PO4)2 (OH)2(H2O)6

sursassite 30681 P121/m1 11 f3 e13 d b a mP51

Ta3B4 44589 Immm 71 h g2 c oI14 D7(b)

Ta3B4 44589 Immm 71 j2 i a oI14

Ta5N6 29329 P63/mcm k g d hP22 1.9 2.3

Ta6Cl15 26104 Ia3-d 230 h3 g cI336

taramellite 100265 PmmnZ 59 g8 f2 e4 b2 a2 oP96 Ba2FeTiSi4O12(OH)2

TaS2(6R) 52117 R3MH AX2 a6 hR6

TaSe2 26249 P63MC b4 a2 hP12 6.1 8

TbB2C 44141 P42/MBC 135 h3 g tP32 1 1.25

TbFe6Sn6 106583 Cmcm 63 g2 e d c5 oS52

TbP5P14 54085 P121/c1 14 e20 mP80 .6 1.5

Tc2As3 66662 P1- 2 i10 aP20

Te(OH)6 24956 Fd3-cZ 228 h c cF416

TeO2(alpha) 202792 P41212 b a tP12 1.330 1.884 Te: 6+2: O6+2; O: 3+1: Te3+1 (+5O) Aristotype is TiO2(tP6), rutile

Th2S5 35088 Pbcn 60 d3 c oP28

Th2Zn17 20238 R3-MH h f d c2 hR19 1.30 1.65 Nb2Be17, Th2Fe17

Th3N4 14336 R3-MH c3 a hR7 6.8 8.3

Th3N4 14336 R3-MR c3 a hR7

Th3P4 25724 I4-3D c a cI28 Th: cube: P8; P: octahedron: Th6 (+3P) P4Th3, sesquisulfide C, Ce2S3(gamma) SB: D7(3)-type

Th3P4 25724 I4-3D c b cI28 SB: D7(3)

Th6Mn23H16 201431 Fm3-m i f3 e d b a cF181

Th7Se12 26672 P63/m 176 h3 a hP19

ThB2C 68414 R3-mH g d c a hR12

ThB4 24680 P4/MBM i h g e tP20 0.480 0.680 UB4, SB: D1(e)

ThB4 24680 P4/MBM j h g e tP20 0.480 0.680

ThH2 56178 I4/mmm 139 d a tI6 1.1 1.51

ThMoB4 41819 Cmmm p j i h g oS24

ThMoB4 41819 Cmmm 65 q j i h g oS24

Thomsonite 61166 Pncn 52 e18 d2 c2 oP204 Common SiAlO4-framework in e14 d2 with 120 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

Thomsonite(substr.) 20007 Pbmn 53 i6 h4 g f e b oP102 zeolite THO Common (Si, Al)O2-framework in i6 h g e with 60 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

ThSi2 77320 I41/AMDZ 141 e a tI12 2.921 4.138 Th: 12+8: Si12Th8; Si: 9: Si3Th6 SB: C(c)-type

ThSi2 77320 I41/AMDZ 141 e b tI12 2.921 4.138

ThTi2O6 14341 C12/m1 12 i4 a mS18 thorutite

ThTl 106158 Pbcm 57 d4 c2 oP24

ThZr2H7 56180 Fd3-mZ 227 f c b a cF80

ThZr2H7 56180 Fd3-mZ 227 f d b a cF80

Ti2C 77473 Fd3-mZ 227 e c cF48

Ti2C 77473 Fd3-mZ 227 e d cF48

Ti3P 43062 P42/NS 86 g4 tP32 0.421 0.596 Ti1: 14: P2Ti12; Ti2: 14: P4Ti10; Ti3: 13: P3Ti10; P: 9: Ti9 Nb3As, Ta3As, Ta2NbAs Infinite columns of face-sharing Ti4Ti4, resp. Ti4P4, tetrahedron stars (inner tetrahedron whose faces are capped by the atoms of an outer tetrahedron). PTi6 trigonal prisms.

Ti3Zn22 150122 P42/mbc i4 h3 g b tP100

Ti5Te4 15451 I4/M h2 a tI18 0.34 0.42

Ti5Te4 15451 I4/M h2 b tI18 0.34 0.42

TiAs 16773 P63/MMC f c a hP8 3.00 4 MoC(gamma), NbN, TiP, Ti1-xS

TiAs 16773 P63/MMC f d a hP8 3 4 MoC(gamma), NbN, TiP, Ti1-xS

TiB25 1856 P42/nnmS 134 n2 m2 b a tP52

tilasite 56862 C12/c1 15 f2 e3 a mS32 MgCaAsO4F, titanite

tilasite 56862 C12/c1 15 f2 e3 b mS32 MgCaAsO4F, titanite

tilasite 56862 C12/c1 15 f2 e3 c mS31 MgCaAsO4F, titanite

tilasite 56862 C12/c1 15 f2 e3 c mS32 MgCaAsO4F, titanite

tilasite 56862 C12/c1 15 f2 e3 d mS32 titanite

TiO2(tI12) 31064 I41/AMDZ 141 e a tI12 2.110 2.990 Ti: octahedron: O6; O: copl. triangle: Ti3 (+6O) anatase, SB: C5 TiO6 octahedra share edges to form a 3D-framework with zigzag chains of edge-linked octahedra.

TiO2(tI12) 31064 I41/AMDZ 141 e b tI12 2.110 2.990 Ti: octahedron: O6; O: copl. triangle: Ti3 (+6O) anatase, SB: C5 TiO6 octahedra share edges to form a 3D-framework with zigzag chains of edge-linked octahedra.

TiO2(tP6) 53997 P42/MNM f a tP6 0.543 0.770 Ti: octahedron: O6; O: copl. triangle: Ti3 (+11O) rutile, SB: C4 Infinite chains of edge-linked TiO6 octahedra share single corners to form a 3D-framework. O inside Ti3 triangles.

TiO2(tP6) 53997 P42/MNM f b tP6 0.543 0.770 Ti: octahedron: O6; O: copl. triangle: Ti3 (+11O) rutile, SB: C4 Infinite chains of edge-linked TiO6 octahedra share single corners to form a 3D-framework. O inside Ti3 triangles.

TiPbO3 27949 Pmmm h g f d a oP5

TiS3 42072 P121/m1 11 e4 mP8

TiSi2 1089 Fddd 70 e a oF24 C54

TiZn16 150123 Cmcm 63 h2 g f2 c2 a oS68

Tl2S5 1911 P212121 A2X5 a7 oP28

Tl2Se2 30219 I4/MCM h b a tI16 0.733 1.039 Tl1: sq. antiprism: Se8; Tl2: tetrahedron; Se4 (+4Se); Se: cube: (Tl2)2+2(Tl1)4 (+2Se) InTe, SB: B37 Infinite chains of edge-linked TlSe4 tetrahedra and 3D-framework of face- and edge-sharing TlSe8 square antiprisms.

Tl3AsS4 44054 Pnma 62 d2 c4 oP32 .85 1.2 (NH4)3AsS4, Tl3PS4

Tl3AsS4 44054 Pnma 62 d2 c4 oP80 .85 1.2 (NH4)3AsS4, Tl3PS4

Tl3AsSe3 15148 R3mH 160 b2 a hR7

Tl3VS4 16572 I4-3M c b a cI16

Tl5Te3 42674 I4- 82 g3 e b a tI32

Tl7Sb2 52288 Im3-m h f e a cI54

TlI 26761 AMMA c2 oS8 2.20 2.75 AgCa, CrB, B33 CrB contains infinite B-chains

TlI 26761 Bbmm c2 oS8 0.31 0.40 AgCa, CrB, B33

TlI 26761 CMCM c2 oS8 .95 1.32 AgCa, CrB, B33 CrB contains infinite B-chains

TlPd3O4 2276 Fm3-m f d b a cF64

TlV12S16 52203 P63 173 c2 b a hP15

TlV5S8 100374 C121 5 c6 b a mS28 .45 .52

Tm2Fe2Si2C 79394 C12/m1 12 i3 a mS14

Tm2S3 430 P121/m1 11 e10 mP20

TmRuGa3 106748 Pm3-m g d c a cP15

TmRuGa3 106748 Pm3-m g d c b cP15

tomichite 202164 P121/m1 11 f9 e4 mP46 V3FeAsTi3O13OH

topaz 52358 Pbnm 62 d3 c3 oP36 Al2SiO4(OH, F)2

topaz 52358 Pbnm 62 d3 c3 oP37

topaz 52358 Pbnm 62 d3 c3 oP38

Tourmaline 4380 R3MH c5 b6 a2 hR54 0.40 0.55 NaFe3Al6(BO3)3 Si6O18(OH)4

Tourmaline 4380 R3MR c5 b6 a2 hR54 1 1 NaFe3Al6(BO3)3 Si6O18(OH)4

Tremolite 46173 C12/m1 12 j7 i2 h2 g a mS78

Tremolite 46173 C12/m1 12 j7 i2 h2 g a mS79

Tremolite 46173 C12/m1 12 j7 i2 h2 g a mS80 Ca2Mg5Si8O22(OH)2

Tremolite 46173 C12/m1 12 j7 i2 h2 g a mS81 Ca2Mg5Si8O22(OH)2

Tremolite 46173 C12/m1 12 j7 i2 h2 g a mS82 Ca2Mg5Si8O22(OH)2

Tridymite 38126 P63/mmc g f c hP12

troegerite 35348 P4/nccZ 130 g2 c3 b tP84 D(UO2)2AsO4(D2O)4

tsumcorite 34763 C12/m1 12 j i4 f a mS30

tsumcorite 34763 C12/m1 12 j i4 f a mS34

tsumcorite 34763 C12/m1 j i4 f a mS36

tsumcorite 34763 C12/m1 12 j i4 f a mS37

tuhualite 17017 Cmca 64 g9 f3 e2 d oS192

tuhualite 17017 Cmca 64 g9 f3 e2 d oS204

tuhualite 17017 Cmca 64 g9 f4 e2 d oS200

tuhualite 17017 Cmca 64 g9 f4 e2 d oS204

Turquoise 21062 P1- 2 i19 a aP55 CuAl6(PO4)4 (OH)8(H2O)4

U 16056 Cmcm 63 c oS4 1.6 1.85

U3Si 1890 I4/mcm 140 h b a tI16

U3Si2 31626 P4/MBM h g a tP10 0.446 0.633 U1: 12: U8Si4 (+2U); U2: 10: Si6U4 (+5U); Si: 9: SiU8 LiY2Si3, SB: D5(a) Si-Si-dumbbells. Si-Si=2.30. SiU6 trigonal prisms share faces and edges to form a 3D-framework; aditional U atoms in channels (square section).

U3Si2 31626 P4/MBM h g a tP9 0.446 0.633

U4O9-beta 15439 I4-3d e14 d3 c4 b a cI832

U4S3 38354 Pm3-m 221 d c a cP7

U4S3 38354 Pm3-m d c b cP7

U64O143 41014 I4-3d e15 d2 c3 b cI828

UB12 24705 FM3-M i a cF52 ZrB12, SB: D2(f) SB: D2(f)-type

UBC 73828 Cmcm c3 oS12

UCl3 2353 P63/M h c hP14 .5 .63

UCl3 2353 P63/M h c hP8 .5 .63 La(OH)3

UCl3 2353 P63/M h d hP14 .5 .63

UCl3 2353 P63/M h d hP8 .5 .63

UCl4 30648 I41/amZ 141 h a tI20 0.87 0.93

UCl6 31625 P3-M1 i3 d a hP21 .52 .62

UCl6 31625 P3-M1 i3 d b hP21 .52 .62

UD3 40065 Pm3-n c a cP32

UD3 40065 Pm3-n k c a cP32 AuZn3

UF4 14137 C12/c1 15 f6 e2 c mS60

UF4 14137 C12/c1 15 f6 e2 d mS60

UO3 31628 P3-m1 164 d b a hP4 1 1.4

UTe2 26283 Immm 71 j i h oI12

V2Zr3Ga4 104028 Pnma 62 d3 c12 oP72 .75 .9

V3S 26515 I4-2m 121 i2 g f tI32

V4Sb2Si 82564 I4/MCM k h a tI28 .45 .49

V6Si5 15303 Ibam 72 j4 f a oI44

V6Si5 15303 Ibam 72 j4 g a oI44

Variscite 819 Pbca 61 c8 oP96 .8 1.2

vivianite 30645 C12/m1 12 j3 i3 g a mS74 Fe3(PO4)2(H2O)8

VO2 22303 Pbnm 62 c3 oP12

Voltaite 9254 Fd3-cZ 228 h6 g f c b a cF2000

Voltaite 9254 Fd3-cZ 228 h8 g c b a cF2000

W 53800 IM3-M a cI2 W: rhombic dodecahedron: W8+6 bcc, Fe(alpha), SB: A2 Infinite 3D-framework of fused WW8 cubes.

W5Si3 73331 I4/MCM k h b a tI32 0.433 0.614 W1: 15: Si6W9; W2: 12: Si4W10; Si1: 10+2: W10Si2: Si2: bucappled sq. antiprism: W8Si2 SB: D8(m)

Wadalite 62980 I4-3d e d c2 b a cI127

WC 22258 P6-M2 c b hP2 0.86 1.10

WC 22258 P6-M2 d a hP2 0.86 1.10 B(h)-type

WC 22258 P6-M2 e b hP2 0.86 1.10 B(h)-type

WC 22258 P6-M2 f a hP2 0.86 1.10 B(h)-type

WCl3 23129 R3-H f4 hR24 .5 .6

wenkite 2083 P6-2m l5 k2 j2 i3 h2 g2 f b hP90

Whitlockite 1490 R3cH b14 a3 hR90 3.4 3.6

Whitlockite 1490 R3cH 161 b14 a4 hR91

WN2 30364 R3-mH 166 c a hR3 5 6.3

wodginite 56863 C12/c1 15 f5 e2 mS48 .48 .6 MnSnTa2O8

Woehlerite 100158 P1211 4 a30 mP60

wyllieite 6203 P121/n1 14 e20 d mP79 Na2(Mn, Fe)2Al(PO4)3

XeF2 26625 I4/mmm e a tI6 1.45 1.8

XeF4 26626 P121/c1 14 e2 a mP10

Y3Co4Ge13 52992 PM3-N k2 e d a cP40

Y3Ge5 20612 Fdd2 43 b3 a2 oF64

Y3TaO7 10059 C2221 20 c3 b2 a3 oS44

Y5S7 43620 C12/m1 12 i5 d a mS24

Y6Mn23H8.3 86403 Fm3-m f2 e d b cF152

Y6Mn23H8.3 86403 Fm3-m f3 e d b a cF149

Yb3S4 15726 Pnma 62 c7 oP28 .95 1.07

Yb5Sb3 26221 PCMN d2 c4 oP32 1.35 1.70 Ca5Sb3, U3S5

Yb5Sb3 26221 PNMA d2 c4 oP32 0.60 0.75 Ca5Sb3, U3S5

YBa2Cu3O6-x 62919 P4/mmm i h g2 f d a tP12 2.95 3.2

YBa2Cu3O6-x 62919 P4/mmm i h2 g e d a tP12 2.95 3.2

YbCl2 6054 Pbca 61 c3 oP24

YbCrO4OH 72151 P121/c1 14 e14 mP64

YF3 26595 PBNM AX3 d c2 oP16 1.00 1.25

YF3 26595 PNMA AX3 d c2 oP16 0.60 0.80 "isopointal with Fe3C AX3, must contain F, Cl, Br oder I enthalten"

YNbO4(mP) 100176 C12/c1 15 f2 e2 mS24

YTaO4 15352 P121/a1 13 g2 f e mP12 .86 1.25

Yugawaralite 26819 P1c1 7 a29 mP74 zeolite YUG Common (Si, Al)O2-framework in a24 with 48 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zemannite 33638 P63/m 176 i3 h2 f e hP56

zemannite 33638 P63/m 176 i3 h4 f b hP32 Na2Zn2(TeO3)3

zeolite A 26911 Pm3-m 221 m k i h g e cP81 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite A 26911 Pm3-m 221 m k i2 h g cP84 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite A 26911 Pm3-m 221 m k2 i h g2 cP78 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite A 26911 Pm3-m 221 m l2 k i h g3 cP96 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite A 26911 Pm3-m 221 m2 k i h g2 cP116 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite A 26911 Pm3-m 221 m2 k i h g4 f cP83 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite A 26911 Pm3-m 221 m2 k i h2 g5 cP90 Linde-A, zeolite-LTA Common (Si, Al)O2-framework in m k i h with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite AlPO-5 91671 P6cc d6 hP72 Common (P, Al)O2-framework in d6 with 72 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite L 18099 P6/mmm r2 q p o3 n m2 l k2 j2 g e d c b hP180 .37 .46 Linde-L, zeolite-LTL Common (Si, Al)O2-framework in r2 q p o2 m k with 108 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite Theta-1 61178 Cmc21 36 b7 a4 oS72

zeolite TMA-E 31491 P63/mmc 194 l2 k7 j i h f e2 hP230 1.1 1.3 zeolite-EAB, bellbergite Common (Si, Al)O2-framework in l2 k3 j i with 108 atoms/(rhombohedral cell), great variability of additional enclosed counter-cations and adsorbed molecules, cell similar to erionite-cell

zeolite ZK5 22054 Im3-m 229 l2 k2 j i f2 cI612 Common (Si, Al)O2-framework in l k2 j i with 288 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite ZSM-11 30003 I4-m2 j14 i4 h2 g2 tI288 Common (Si, Al)O2-framework in j14 i4 h2 g2 with 288 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite ZSM-5 60674 Pnma 62 d50 c13 oP452 Silicalite(oP) Common (Si, Al)O2-framework in d34 e4 with 288 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite-ABW 6269 Pna21 33 a9 oP39

zeolite-IFR 280740 I12/m1 12 j10 i3 g mS96

zeolite-LOS 20177 P3-1c 159 c16 b3 a2 hP106 .78 .84

zeolite-LTA 24901 Fm3-c 226 j7 i4 g2 a2 cF1319

zeolite-RHO 74367 Im3-m 229 k j i f b cI149 Common (Si, Al)O2-framework in k j i with 144 atoms/cell, great variability of additional enclosed counter-cations and adsorbed molecules

zeolite-RHO-I4-3m 23708 I4-3m 217 h2 g2 cI156

zeolite-RON 31016 I4/mcm 140 m2 l2 k5 j i h tI265 Roggianite

zeolite-RTE 86547 C12/m1 12 j7 i2 h g mS72 RUB-3

zeolite-STF 410595 P1- 2 i24 aP48 SSZ-35, ITQ-9

zeolite-ZON 57129 Pbca 61 c29 oP328 ZAPO-M1

zippeite 81585 C12/c1 15 f16 e2 mS168 K(UO2)2(OH)3SO4H2O

Zn(CN)2 22392 P4-3m e2 b a cP10

Zn(CN)2(disordered) 84968 Pn3-mS 224 e a cP10

Zn3P2 26876 P42/NMCZ 137 g3 f d c tP40 1.30 1.60 Cd3As2, SB: D5(9)

Zn4Ta2O9 49006 C12/c1 15 f14 e a mS120

ZnMn3O7(H2O)3 202700 R3-H 148 f4 c2 hR40 chalcophanite

ZnS(12R) 37374 R3MH 160 a8 hR8 8.8 11 Zhdanov-symbol: (3 1)3

ZnS(15R) 37375 R3MH 160 a10 hR10 11 13.5 Zhdanov-symbol: (3 2)3

ZnS(21R) 37376 R3MH 160 a14 hR14 15.5 19 Zhdanov-symbol: (3 1 1 2)3

ZnS(2H) 31061 P63MC b2 hP4 1.55 1.8 Wurtzite

ZnS(9R) 37373 R3MH 160 a6 hR6 6.6 8.7 Zhdanov-symbol: (2 1)3

ZnS(cF8) 53943 F4-3M c a cF8 All tetrahedra: Zn: S4; S: Zn4 SZn(cF8), sphalerite, zincblende, SB: B3 Close packed S layers in c stacking, Zn in tetrahedral voids (stacking sequence AabbCc). ZnS4 terahedra share single corners to form a 3D-framework.

ZnS(cF8) 53943 F4-3M d a cF8 All tetrahedra: Zn: S4; S: Zn4 SZn(cF8), sphalerite, zincblende, SB: B3 Close packed S layers in c stacking, Zn in tetrahedral voids (stacking sequence AabbCc). ZnS4 terahedra share single corners to form a 3D-framework.

ZnSb2O6 30409 P42/MNM j f e a tP18 1.666 2.360 "Zn, Sb: octahedra: O6; O1: copl. triangle: ZnSb2 (+13O); O2: copl. triangle: ZnSb2 (+12O)" ordenezite, tapiolite

Zoisite 20235 Pnma 62 d4 c13 oP88

Zr(SO4)2(H2O)4 26499 Fddd 70 h3 e a oF184

Zr2NiAs2 68141 P63/MMC f c b a hP10 2.9 3.6

Zr2Rh12P7 77789 P63/m h3 c b hP21 .37 .44

Zr3O 23402 R32H 155 f e d c2 hR16

Zr3PbO4F6 60959 Fm3-m i f e c cF112

Zr5Si4 43214 P41212 b4 a tP36 1.65 2.00 tP36, P31212, 1.65-2, b4 a, 43214

Zr5Zn39 150130 C12/m1 j6 i7 f e c a mS88

ZrBeSi 76123 P63/MMC d c a hP6 1.55 2.05

ZrCr2Hx 20799 Fd3-mZ 227 g d a cF32

ZrCr2Hx 20799 Fd3-mZ 227 g d a cF33

ZrCr2Hx 20799 Fd3-mZ 227 g d a cF34

ZrCr2Hx 20799 Fd3-mZ 227 g d a cF52

ZrGa2 104041 Cmmm 65 h g c a oS12

ZrGa2 104041 Cmmm 65 h g d b oS12

ZrO2(mP) 18190 P121/c1 e3 mP12 .92 1.1 baddeleyite

ZrOS 31721 P213 a3 cP12 Zr: 7: O3S4; O: nopl. triangle: Zr3 (+7S); S: tetrahedron: Zr4 (+7O) IrLaSi, LaIrSi Isopointal with NiSbS. Aristotype is PdF2. No O-S dumbbells

ZrSi2 26758 Cmcm 63 c3 oS12 .92 1.05

ZrSiO4 31130 I41/AMDS 141 h b a tI24 0.756 1.072 Zr: 8: O4+4; Si: tetrahedron: O4; O: copl. triangle: SiZ1+1 (+5O) zircon, SB: S1(1)=H3 Isolated SiO4 tetrahedra.

(NH4)Pb2Br5

Ag2Te-alpha

Ag2ZnP2S6

alpha-cristobalite

alpha-K2SO4

alpha-quartz

Apatite

BaGe2O5 III

BaSi2

BaTiO3-6H

BCr

Bi(IO3)3

Ca11InSb9

CaBe2Ge2

CaCr2Al10

CaCuO2

CaIrO3

CaZrTi2O7

Ce2Li2Ge3

Ce3Al4Si6

CeCu2

Co2Al9

Co2Ge4Tb3

CrB

Cs2(B12H12)

Cs2In3

Cu5Ho7Sb

CuO2

Delafossite

Delafossite-2H

ErFe4Ge2-LT

EuAuGe

EuMg2D6

Fergusonite

Hf Cu Si2

HfCuSi2

HfFe6Ge6

HfRhSn

Hg4Pt

Ho10Ni9In20

Ho3Si4

Hollandite

IrU

K2NiF4

Keggin

KHg

KHg2

La3Rh4Sn13

La4Co2Sn5

La4Ni3Pb4

LaCu0.28Te2

Langasite

Langbeinite

Li2O

LiP

LiTe2Ti

MgAgAs

MgK2(SO4)2(H2O)6

Monazite

NaZr2(PO4)3

PbSb2O6

PbZrO3

Pr5Co19

Pu3Pd5

PuGa6

PuNi3

Pyrochlore

Quartz

Sc3NiSi3

Si2Zr

Sm3CuSe6

SmMn6Sn6

Sr5Nb5O17

TbCu7

Th2Ni17

ThCr2Si2

TiNiSi

Vaterite

Whitlockite-type

Y2AlGe3

Yb2Pt3Sn5

Yb36Sn23

YBaCo4O7

YFe6Sn6

YPd2Si

Zeolite TMA

ZnS

Zr2Ni7

ZrNiAl