Thiostannate
Sulfidostannates, or thiostannates are chemical compounds containing anions composed of tin linked with sulfur. They can be considered as stannates with sulfur substituting for oxygen. Related compounds include the thiosilicates, and thiogermanates, and by varying the chalcogen: selenostannates, and tellurostannates. Oxothiostannates have oxygen in addition to sulfur.[1] Thiostannates can be classed as chalcogenidometalates, thiometallates, chalcogenidotetrelates, thiotetrelates, and chalcogenidostannates. Tin is almost always in the +4 oxidation state in thiostannates, although a couple of mixed sulfides in the +2 state are known,
Some thiostannate minerals are known. In nature the tin can be partly replaced by arsenic, germanium, antimony or indium. Many thiostannate minerals contain copper, silver or lead. In the field of mineralogy, these compound can be termed sulfostannates or sulphostannates.
Different cluster anions are known: [SnS4]4–, [SnS3]2–, [Sn2S5]2–, [Sn2S6]4–, [Sn2S7]6–, [Sn2S8]2–, [Sn3S7]2–, [Sn4S9]2–, [Sn5S12]4–, or [Sn4S10]4–.[2]
The number of sulfur atoms coordinated around the tin atom is most commonly four. However there are also complexes with five or six sulfur atoms surrounding the tin. The behaviour for selenium and tellurium differs as only five selenium or four tellurium atoms can bind to a tin atom. The smaller germanium atom can only accommodate four sulfur atoms. For lead it is hard for it to be in the +4 oxidation state. The SnSn polyhedrons can be standalone in strongly alkaline conditions, or at higher concentrations or less alkaline can condense together. Polyhedra shapes are tetrahedron for four, trigonal bipyramid for five, and octahedron for six sulfur atoms. The polyhedra can be connected at a vertex (corner), or at an edge. Where connected at an edge, four membered rings of -SnSSnS- with internal angles close to 90°.[3] [Sn2S7]6– is corner bridged. Tetrahedra linked by at the corner by a disulfur bridge are unknown.[3]
Sn10O4S208- is a supertetrahedron made from 1, 3 and 6 tin atoms connected by oxygen on the interior and sulfur on the surface.[3]
For anions with formula SnxSy the condensation ratio c is given by x⁄y. It can vary from 1⁄4 to just below 1/2.[3]
Synthesis
The first human production of a thiostannate heated tin oxide with sodium carbonate and sulfur:[4]
2SnO2 + 2Na2CO3 + 9S → 2Na2SnS3 + 2CO2 + 3SO2
Transition metal complexes may be prepared by crystallisation from the ligand solvent.[4]
Copper(II) is normally reduced by sulfide S2- in thiostannates to copper(I).[5]
Anions
formula | name | coordination | dimensionality | description |
---|---|---|---|---|
[SnS4]4− | 4 | 0 | tetrahedra | |
[Sn2S6]4− | bis(μ-sulfido)-tetrathiolato-di-tin | 4 | 0 | edge shared |
[Sn3S9]6− | 1,3,5,2,4,6-trithiatristanninane-2,2,4,4,6,6-hexakis(thiolate) | 4 | 0 | 6 membered ring |
[Sn4S10]4- | 4 | 0 | tetrameric adamantane-like : tetrahedron of tetrahedra, 6 bridging sulfur, 4 terminal sulfur | |
Reactions
Some hydrates are unstable, where water reacts with the sulfide to make hydrogen sulfide gas.
List
formula | system | space group | unit cell Å | volume | density | comment | |
---|---|---|---|---|---|---|---|
Li4SnS4 | orthorhombic | Pnma | a=13.812 b=7.962 c=6.370 | [6] | |||
[Li8(H2O)29][Sn10O4S20]·2H2O | triclinic | P1 | a = 11.232, b = 13.097, c = 23.735, α = 102.73°, β = 90.43°, γ = 93.44°, Z = 2 | 3399 | oxothiostannate | [7] | |
(NH4)4Sn2S6·3H2O | orthorhombic | P41212 | a =8.56294 b =8.56294 c= 22.7703 | [8] | |||
(NH4)6Sn3S9·1.3H2O | monoclinic | C2 | a 16.9872 b 10.54777 c 21.0871 β 108.0389° | 3592.6 | 2.154 | colourless | [9] |
[(CH3)3NH]2Sn3S7 | [3] | ||||||
[(CH3)4N]2Sn3S7·H2O | [3] | ||||||
[(CH3)4N]4Sn4S10 | [8] | ||||||
[(CH3CH2)4N]2Sn3S7 | [3] | ||||||
[(CH3CH2CH2)4N]2Sn4S9 | [3] | ||||||
[(CH3CH2CH2CH2)4N]2Sn4S9 | [3] | ||||||
[(CH3CH2CH2)4N][(CH3)3NH]Sn4S9 | [3] | ||||||
(C12H25NH3)4Sn2S6 ·2H2O | [3] | ||||||
[dabcoH]2Sn3S7 | [3] | ||||||
(Et4N)2Sn(S4)3 | [3] | ||||||
(Et4N)2Sn(S4)2(S6) | [3] | ||||||
((CH3C(NH2)2)8Sn2S6SnS4 | monoclinic | C 1 2/m 1 | a=23.7739 b=16.0647 c=11.8936 β=99.029 Z=4 | 4486.1 | 1.702 | colourless | [9] |
((CH3)2NH2)(NH4)SnS3 dimethylammonium ammonium | orthorhombic | P212121 | a=5.9393 b=12.1816 c=12.4709 Z=4 | 902.26 | 2.054 | colourless | [9] |
(DBNH)2Sn3S6 DBN=1,5-diazabicyclo[4.3.0]non-7-ene | Sn(II) and Sn(IV) | [10] | |||||
(1AEP)2Sn3S7 1AEP = 1-(2-aminoethyl) piperidine | orthorhombic | P212121 | a=13.2299 b= 22.2673 c=9.0772 Z=4 | 2674.1 | pale yellow | [11] | |
SnS2·en | monoclinic | C2/c | a 15.317 b 10.443 c 12.754, β 93.62° | [12] | |||
[enH]4[Sn2S6]·en | triclinic | P1 | a 9.8770 b 9.9340 c 15.4230, α 72.630° β 86.220° γ 81.380° | [12] | |||
Na2SnS3 | R3m | a=3.834 c=19.876 Z=2 | 253 | 3.43 | [4][13] | ||
Na4SnS4 | tetragonal | P421c | a=7.837 c=6.950 | 427 | 2.64 | [13] | |
Na4Sn2S6 | [3] | ||||||
Na4Sn2S6·14H2O | triclinic | P1 | a=10.114 b=7.027 c=9.801 α=108.30 β=92.18 γ=91.11 Z=1 | 663 | 1.95 | [2] | |
Na4SnS4·14H2O | monoclinic | C2/c | a=8.622 b=23.534 c=11.347 β=110.53 Z=4 | 2156 | 1.82 | [13] | |
Na4Sn3S8 | [3] | ||||||
Na5[SnS4]Cl·13H2O | monoclinic | P21/m | a=8.4335 b=11.4958 c=11.5609 β=91.066 Z=2 | 1120.63 | 1.872 | [2] | |
Na4Sn2S6·5H2O | [3] | ||||||
Na6Sn2S7 | C2/c | a=9.395 b=10.719 c=15.671 β=109.97 Z=4 | 1483 | 2.69 | [13] | ||
Mg2SnS4 | orthorhombic | Pnma | a=12.93 b=7.52 c=6.16 Z=4 | 599 | 3.28 | [13] | |
Na2MgSnS4 | R3m | a 3.7496 b 3.7496 c 19.9130 | [14] | ||||
(Ph4P)2Sn(S4)3 | [3] | ||||||
K2SnS3 ·2H2O | [3] | ||||||
K2SnS3·2H2O | orthorhombic | Pnma | a=6.429 b=15.621 c=10.569 Z=4 | 1061 | 2.06 | [13] | |
K2Sn2S5 | [3] | ||||||
K2Sn3S7 ·H2O | [3] | ||||||
[K4(H2O)4][SnS4] | [15] | ||||||
Ca2SnS4 | orthorhombic | Pnma | a=13.74 b=8.23 c=6.44 Z=4 | 728 | 2.99 | [13] | |
[H2tepa][VIII(tepa)(μ-Sn2Q6)]2 | orthorhombic | Abm2 | a =7.7486 b =40.410 c =16.745 | [16] | |||
Mn2SnS4 | tetragonal | I41/a | a=7.408 c=10.41 Z=8 | 571 | 4.15 | [13] | |
[Mn(en)3]2[Sn2S6] | monoclinic | C2/c | a=15.138 b=10.6533 c=23.586 β=118.42 Z=4 | 3345.2 | 1.787 | colourless | [5][17] |
[Mn(en)3]2Sn2S6·2H2O | monoclinic | P21/c | a=10.129, b=15.746, c=11.524, β=102.36° Z=2 | 1795.5 | 1.732 | [18] | |
[Mn(en)2]2(μ-en)[Sn2S6] | triclinic | a=9.0017 b=9.7735 c=10.8421 α=60.38° β=67.23° γ=70.25° | 752.38 | [16] | |||
[Mn(dien)2]2Sn2S6 | monoclinic | P21/c | a=12.48 12, b= 9.3760, c=17.7617, β=121.752°, Z=2, | 1767.5 | 1.789 | [18] | |
[Mn(tren)]2Sn2S6 | triclinic | P1 | a 7.653 b 8.088 c 12.200, α 97.27° β 104.06° γ 108.80° Z=1 | 676.0 | 2.044 | yellow | [5][19] |
[Mn(tren)(H2O)][Mn(baen)]3Mn4Sn6S20∙9H2O | orthorhombic | P213 | a =21.404 b =21.404 c= 21.404 | super tetrahedron | [20] | ||
{Mn(tepa)}2(μ-Sn2S6) | tetragonal | I41/a | a=25.977 c=10.041 Z=8 | 6775 | 1.800 | yellow | [19] |
{[Mn(trien)]2[SnS4]} | [5] | ||||||
{[Mn(C6H18N4)]2SnS4}·4H2O | monoclinic | P21/c | a 10.8446 b 20.974 c 13.2746 β 113.487° | [21] | |||
{[Mn(phen)2]2(μ2-Sn2S6)} | monoclinic | P21/n | a =10.8230 b=9.8940 c=24.811 β=91.356° | [22] | |||
{[Mn(phen)2]2(μ2-Sn2S6)}·phen | triclinic | P1 | a=10.0642 b=10.6249 c=13.693, α=71.700° β=81.458° γ=84.346° | [22] | |||
{[Mn(phen)2]2[Sn2S6]}·phen·H2O phen = 1,10-phenanthroline | triclinic | P1 | a=11.3203 b=12.1436 c=12.7586, α=113.200° β=90.908° γ=110.974° | [5][22] | |||
[Mn(phen)]2(SnS4)·H2O | monoclinic | C2/m | a=16.146 b=19.262 c=9.938 β=124.970 Z=4 | 2532.6 | 1.928 | red chain | [23] |
{[Mn(phen)2]2[μ-η2-η2-SnS4]2[Mn(phen)]2}·H2O | triclinic | P1 | a=10.8703 b=12.5183 c=14.9644, α=103.381° β=108.390° γ=101.636° | [22] | |||
{[Mn(2,2′-bipy)2]2[Sn2S6]} | [24] | ||||||
(1,4-dabH)2MnSnS4 1,4-dab = 1,4-diaminobutane | orthorhombic | Fdd2 | a = 22.812, b = 24.789, c = 6.4153, Z = 8 | 3627.8 | [25] | ||
Li4MnSn2Se7 | monoclinic | Cc | a=18.126 b=7.2209 c=10.740 β=93.43 Z=4 | 1403.2 | 4.132 | orange | [26] |
Fe2SnS4 | tetragonal | I41/a | a=7.308 c=10.338 Z=4 | 552 | 4.32 | [13] | |
{[Fe(tepa)]2[Sn2S6]} | tetragonal | I41/a | [5][27] | ||||
{[Fe(1,2-dach)2][Sn2S6]}·2(1,2-dachH) | [5] | ||||||
{[Fe(phen)2]2[Sn2S6]}·phen·H2O | [5] | ||||||
[Co(en)3]2[Sn2S6] | orthorhombic | Pbca | a=15.640 b=11.564 c=18.742 Z=4 | 2289.7 | 1.779 | yellow | [5][17] |
[Co(dien)2]2[Sn2S6] | [5] | ||||||
[Co2(cyclam)2Sn2S6]·2H2O | [28] | ||||||
[Co(tren)]2Sn2S6 | monoclinic | C2/c | a=12.228 b=9.7528 c=23.285 β=102.90 | 2706.8 | [5][16] | ||
{[Co(cyclam)]2[Sn2S6]}n·2nH2O cyclam = 1,4,8,11-tetraazacyclotetradecane | [5] | ||||||
{[Co(tepa)]2[Sn2S6]} tepa=tetraethylenepentamine | tetragonal | I41/a | a=25.742 c=9.898 | 6558 | [5][27][16] | ||
{[Co(phen)2]2[Sn2S6]}·phen·H2O | [5] | ||||||
[Co(2-(aminomethyl)pyridine)3]2Sn2S6·10H2O (2amp) | monoclinic | P21/c | a=10.1443 b=14.6124 c=18.8842 β=90.601° Z=2 | 2799.1 | 1.633 | yellow | [29] |
[Co(trans-1,2-diaminocyclohexane)3]2Sn2S6·8H2O (dach) | monoclinic | P21/n | a=12.6521 b=11.7187 c=20.4386 β=91.262° Z=2 | 3029.6 | 1.509 | red | [29] |
Ni6SnS2 Butianite | tetragonal | I4/mmm | a = 3.650, c = 18.141 Z=2 | 241.7 | 7.62 | opaque | [30] |
[Ni(en)3]2[Sn2S6] | [5] | ||||||
[Ni(dap)3]2[Sn2S6]·2H2O dap=1,2-diaminopropane | triclinic | P1 | a=9.9046 b=10.527 c=11.319 α =72.13° β =85.19° γ =63.63° | 1004.5 | [5][16] | ||
[Ni(1,2-dach)3]2[Sn2S6]·4H2O 1,2-dach = 1,2-diaminocyclohexane | [5] | ||||||
[Ni(dien)2]2[Sn2S6] | [5] | ||||||
{[Ni(cyclen)]6[Sn6S12O2(OH)6]}·2(ClO4)·19H2O
cyclen = 1,4,7,10-tetraazacyclododecane |
[31] | ||||||
[Ni(cyclen)(H2O)2]4[Sn10S20O4]·~13H2O | [31] | ||||||
{[Ni(cyclen)]6[Sn6S12O2(OH)6]}·2(ClO4)·19H2O | monoclinic | C2/c | a=25.7223 b=15.6522 c=29.070 β=105.879 Z=4 | 11257 | 1.863 | oxothiostannate | [32] |
[Ni(2amp)3]2[Sn2S6]·9.5H2O 2amp = 2-(aminomethyl)pyridine | monoclinic | P21/n | a=18.7021 b=14.6141 c=20.2591 β=97.696 Z=4 | 5487.2 | 1.655 | purple | [4] |
[Ni(aepa)2]2[Sn2S6] aepa=N-2-aminoethyl-1,3-propandiamine | [5] | ||||||
[Ni(tren)]2Sn2S6 | monoclinic | C2/c | a=23.371 b=8.231 c=14.274 β =107.230 Z=4 | 2622.6 | 2.127 | [5][33] | |
[Ni(tren)2]2[Sn2S6]·8H2O | orthorhombic | P42/n | a=26.1885 b=26.1885 c=11.1122 | [5][34] | |||
[Ni(tren)(2amp)]2[Sn2S6] | triclinic | P1 | a =10.2878 b =11.1100 c =11.4206, α =84.740° β =84.395° γ =79.093° | [5][34] | |||
[Ni(tren)(2amp)]2[Sn2S6]·10H2O | monoclinic | P21/n | a =12.1933 b =13.4025 c =14.8920 β= 103.090° | [35] | |||
[Ni(tren)(en)]2[Sn2S6]·2H2O | monoclinic | P21/n | a 12.7041 b 9.8000 c 15.3989, β 108.843° | [35] | |||
[Ni(tren)(en)]2[Sn2S6]·6H2O | monoclinic | P21/n | a 12.5580 b 9.7089 c 16.0359, β 91.827° | [35] | |||
[Ni(tren)(1,2-dach)]2[Sn2S6]·3H2O | triclinic | P1 | a 9.8121 b 10.0080 c 12.422, α 86.38° β 79.65° γ 65.72° | [35] | |||
[Ni(tren)(1,2-dach)]2[Sn2S6]·4H2O | monoclinic | P21/n | a 10.7119 b 19.0797 c 11.1005, β 104.803° | [35] | |||
{[Ni(cyclam)]2[Sn2S6]}·2H2O | [5] | ||||||
{[Ni(tepa)]2[Sn2S6]} | monoclinic | P21/n | [5][27] | ||||
{[Ni(phen)2]2[Sn2S6]}·2,2′-bipy | monoclinic | P21/n | a=10.5715 b=9.9086 c=24.9960 β=92.800 Z=2 | 2615.17 | 1.809 | deep red | [5][36] |
{[Ni(phen)2]2Sn2S6}·4,4′-bipy·½H2O 4,4′-bipy = 4,4′-bipyridine | monoclinic | C2/c | a=18.3431 b=19.4475 c=15.0835 β=95.556 Z=4 | 5355.4 | 1.789 | dark red-brown | [36] |
{[Ni(phen)2]2[Sn2S6]}·phen·H2O | [24] | ||||||
[Ni(L1)][Ni(L1)Sn2S6]n·2H2O L1 = 1,8-dimethyl-1,3,6,8,10,13-hexaazacyclotetradecane | monoclinic | P21/c | [37] | ||||
[Ni(L2)]2[Sn2S6]·4H2O L2 = 1,8-diethyl-1,3,6,8,10,13-hexaazacyclotetradecane | triclinic | P1 | [37] | ||||
[Ni(tren)(ma)(H2O)]2[Sn2S6]·4H2O ma = methylamine | monoclinic | P21/n | a=11.1715 b=10.5384 c=15.8594 Z=2 | 1827.45 | 1.835 | [33] | |
[Ni(tren)(1,2-dap)]2[Sn2S6]·2H2O | monoclinic | P21/n | a=12.9264 b=10.1627 c=15.6585 Z=2 | 1889.8 | 1.799 | [33] | |
[Ni(tren)(1,2-dap)]2[Sn2S6]·4H2O | monoclinic | C2/c | a =14.3925 b=15.1550 c=18.9307, β=99.108° | [35] | |||
[Ni(2amp)3]2[Sn2S6]·9.5H2O 2amp = 2-(aminomethyl)pyridine | monoclinic | P21/n | a=18.7021 b=14.6141 c=20.2591 Z=4 | 5487.23 | 1.655 | purple | [4] |
Cu2SnS3 Mohite | monoclinic | a=23.10 b=6.25 c=6.25 β=101.0° | 4.69 | greenish grey | [13][38] | ||
Cu3SnS4 Kuramite | tetragonal | I42m | a = 5.445, c = 10.75, Z = 2 | 318.72 | 4.56 | [39] | |
Cu4SnS4 | orthorhombic | Pnma | a=13.70 b=7.750 c=6.454 Z=4 | 685 | 4.96 | [13] | |
Cu4SnS6 Erazoite | rhombohedral | R3m | a = 3.739, c = 32.941, Z = 2 | 4.53 | black | [40] | |
Cu4Sn7S16 | monoclinic | a=12.75 b=7.34 c=12.71 β=109.5 Z=2 | 1121 | 4.74 | [13] | ||
(DBUH)CuSnS3 DBU = 1,8-diazabicyclo[5.4.0]undec-7-ene | monoclinic | P21/n | a=9.254 b=8.6190 c=18.135, β=92.80° | [41] | |||
(1,4-dabH2)Cu2SnS4 1,4-dab = 1,4-diaminobutane | tetragonal | P42/n | a=14.539 c=11.478 | [42] | |||
(enH)6Cu40Sn15S60 en=ethylenediamine | cubic | Pn3n | a=25.260 Z=4 | 16119 | 2.727 | black | [43] |
(enH)3Cu7Sn4S12 | trigonal | R3c | a=13.532 c=28.933 Z=6 | 4588 | 3.23 | red | [43] |
[H2en]2[Cu8Sn3S12] | [5] | ||||||
(trenH3)Cu7Sn4S12 tren = tris(2-aminoethyl)amine) | trigonal | R3c | a=13.1059 c=29.347 Z=6 | 4365.4 | 3.317 | [43] | |
[dienH2][Cu2Sn2S6] | [5] | ||||||
[DBUH][CuSnS3] DBU = 1,8-diazabicyclo[5.4.0]undec-7-ene | [5] | ||||||
[1,4-dabH2][Cu2SnS4] | [5] | ||||||
{[Cu(cyclam)]2[Sn2S6]}·2H2O cyclam=1,4,8,11-tetraazacyclotetradecane | triclinic | P1 | a=9.0580 b=9.9419 c=10.2352, α=97.068° β=94.314° γ=101.514° | [5] | |||
(DBNH)2Cu6Sn2S8 DBN=1,5-diazabicyclo[4.3.0]non-7-ene | [10] | ||||||
[Co(2-(aminomethyl)pyridine)3]2 Sn2S6·10H2O | monoclinic | P21/c | a=10.1443 b=14.6124 c=18.8842 β=90.601° Z=2 | 2799.1 | 1.633 | yellow; unstable | [44] |
[Co(trans-1,2-diaminocyclohexane)3]2Sn2S6·8H2O | monoclinic | P21/n | a=12.6521 b=11.7187 c=20.4386 β=91.262° Z=2 | 3029.6 | 1.509 | red | [44] |
Na4Cu32Sn12S48·4H2O | cubic | Fm3c | a = 17.921 z = 13 | black; absorption edge 2.0 eV | [45] | ||
CuAlSnS4 | cubic | a=10.28 Z=8 | 1074 | 4.17 | [13] | ||
K11Cu32Sn12S48·4H2O | cubic | Fm3c | a = 18.0559 z = 14.75 | black; absorption edge 1.9 eV | [45] | ||
Cu2MnSnS4 | tetragonal | a=5.49 c=10.72 Z=2 | 323 | 4.41 | [13] | ||
Cu2FeSnS4 Stannite Ferrokësterite | tetragonal | I42m | a = 5.4432, c = 10.7299 Z=2 | 317.91 | grey | [46] | |
Cu2FeSn3S8 | tetragonal | I41/a | a=7.29 c=10.31 Z=2 | 548 | 4.82 | [13] | |
Cu6Fe2SnS8 Mawsonite | Tetragonal | P4m2 | a = 7.603, c = 5.358 Z=1 | 309 | 4.65 | brownish orange | [47] |
Cu6FeSn2S8 Chatkalite | Tetragonal | P4m2 | a = 7.61, c = 5.373 Z=1 | 311.1 | 5.00 | [48] | |
Cu2CoSnS4 | Tetragonal | I42m | a=5.402 c=10.805 Z=2 | 315 | 4.56 | [13] | |
Cu2NiSnS4 | a=5.425 Z=1 | 160 | 4.49 | [13] | |||
Cu13VSn3S16 Nekrasovite | isometric | a=10.73 | 1,235 | brown | [49] | ||
[Zn(en)3]2[Sn2S6] | orthorhombic | Pbca | a=15.452 b=11.524 c=18.614 Z=4 | 3315.3 | 1.845 | colourless | [5][17] |
{Zn(tren)}2(μ-Sn2S6) | monoclinic | C2/c | a 12.214 b 9.726 c 23.209 β 102.732° | 2689.3 | 2.107 | light yellow | [19][50] |
Cu2ZnSnS4 Kësterite | tetragonal | I4 | a = 5.427, c = 10.871 Z=2 | 320.18 | 4.55 | greenish black | [51] |
Cu6+Cu22+(Fe2+,Zn)3Sn2S12 Stannoidite | orthorhombic | a = 10.76, b = 5.4, c = 16.09 | 934.9 | 4.68 | brass | [52] | |
Cu3(V,Ge,Sn)S4 Ge-Sn-Sulvanite | 361 | [53] | |||||
SnGeS3 Stangersite | monoclinic | P21/b | a = 7.270, b = 10.197, c = 6.846 β = 105.34° Z=4 | 489 | 3.98 | orange | |
Rb4SnS4 | [3] | ||||||
Rb4Sn2S6 | [3] | ||||||
Rb2Sn3S7·2H2O | [3] | ||||||
Rb2Cu2SnS4 | orthorhombic | Ibam | a=5.528 b=11.418 c=13.700 Z=4 | 865 | 4.185 | band gap 2.08 eV | [54] |
Rb2Cu2Sn2S6 | monoclinic | C2/c | a=11.026 b=11.019 c=20.299 β=97.79 Z=8 | 2444 | 3.956 | band gap 1.44 eV | [54] |
Rb2ZnSn3S8 | [55] | ||||||
[Rb4(H2O)4][SnS4] | [15] | ||||||
Sr3MnSn2S8 | cubic | I43d | a = 14.2287 Z = 8 | 2880.7 | 3.743 | dark green | [56] |
Cu2SrSnS4 | trigonal | P31 | a = 6.29, c = 15.57 Z=3 | 534 | 4.31 | [57][13] | |
Sr6Cu4Sn4S16 | cubic | I43d | a=13.982 | 2734 | 4.295 | yellow | [58] |
Sr6Cu2FeSn4S16 | cubic | I43d | a=14.1349 | band gap 1.53 eV | [59] | ||
SrSnS3 | orthorhombic | Pnma | a=8.264 b=3.867 c=14.116 Z=4 | 451 | 4.45 | [13] | |
[Y2(dien)4(μ-OH)2]Sn2S6 | monoclinic | P21/n | a=11.854 b=11.449 c=13.803 β=97.978 Z=2 | 1855 | 1.888 | light yellow | [60] |
α-Ag8SnS6 | cubic | a=21.43 | 9842 | [13] | |||
β-Ag8SnS6 | cubic | a=10.85 | 1277 | [13] | |||
Ag8SnS6 Canfieldite | orthorhombic | a = 15.298, b = 7.548, c = 10.699 Z=4 | 1,235.4 | 6.311 | metallic | [61] | |
Na3AgSnS4 | monoclinic | P21/c | a 8.109 b 6.483 c 15.941, α 90° β 103.713 | double chain | [62] | ||
AgCrSnS4 | cubic | a=10.74 Z=8 | 1239 | 4.92 | [13] | ||
Ag2MnSnS4 – Agmantinite | orthorhombic | a = 6.632, b = 6.922, c = 8.156 Z=2 | 4.574 | orange | [63] | ||
Ag2ZnSnS4 Pirquitasite | tetragonal | I4 | a = 5.78, c = 10.82 | 361 | black | [64] | |
Ag2(Fe2+,Zn)SnS4 Hocartite | tetragonal | I42m | a = 5.74, c = 10.96 Z=2 | 361 | 4.77 | brownish grey | [65] |
Ag1+(Fe2+0.5Sn4+1.5)S4 Toyohaite | tetragonal | grey | [66] | ||||
[enH][Cu2AgSnS4] | orthorhombic | Pnma | a=19.7256 b=7.8544 c= 6.5083 Z=4 | 1008.3 | 3.577 | red | [67] |
Ag2SrSnS4 | orthorhombic | a=7.127 b=8.117 c=6.854 Z=2 | 397 | 5.02 | [13] | ||
Sr6Ag4Sn4S16 | cubic | I43d | a=14.2219 Z=4 | 2876.6 | 4.491 | yellow | [58] |
Sr6Ag2FeSn4S16 | cubic | I43d | a=14.2766 | band gap 1.87 eV | [59] | ||
[1,4-dabH2][Ag2SnS4] 1,4-dab = 1,4-diaminobutane | tetragonal | P42/n | a = 14.7847, c = 11.9087, Z = 8 | 2603.1 | [5][68] | ||
[H2en][Ag2SnS4] | [5] | ||||||
[CH3NH3]2Ag4SnIV2SnIIS8 | orthorhombic | Pnma | a =19.378 b =7.390 c =13.683 Z=4 | 1959 | 3.756 | Orange Sn(II) | [69] |
[CH3NH3]6Ag12Sn6S21 | monoclinic | P21/c | a =18.8646 b =19.9115 c =14.3125 β 100.117° | [70] | |||
[(Me)2NH2]3[Ag5Sn4Se12] | tetragonal | P421m | a=13.998 c=8.685 Z=2 | 1701.9 | 4.403 | dark red | [71] |
[enH][Cu2AgSnS4] | [5] | ||||||
Cu2CdSnS4 | I42m | a=5.402 c=10.86 Z=2 | 338 | 4.77 | [13] | ||
Ag2CdSnS4 | Cmc21 | a=4.111 b=7.038 c=6.685 Z=1 | 193 | 4.95 | [13] | ||
Cu2(Cd,Zn,Fe)SnS4 Černýite | tetragonal | I42m | a = 5.48, c = 10.828 Z=4 | 326 | 4.76 | metallic | [72] |
CuInSnS4 | a=10.50 Z=8 | 1158 | 4.91 | [13] | |||
AgInSnS4 | a=10.16 Z=8 | 1048 | 4.59 | [13] | |||
(Cu,Fe,Zn,Ag)3(Sn,In)S4 Petrukite | orthorhombic | a = 7.66, b = 6.43, c = 6.26 | 308 | brown | [73] | ||
(Cu,Zn,Fe)3(In,Sn)S4 Sakuraiite | isometric | a = 5.46 Z=1 | 162 | greenish grey | [74] | ||
Sn2S3 | orthorhombic | Pnma | a=8.864 b=3.7471 c=14.020 Z=4 | 466 | 4.76 | [13] | |
Cs4SnS4 | 0d | [3] | |||||
Cs2Sn3S7 ·0.5S8 | 2d | [3] | |||||
Cs4Sn5S12·2H2O | 2d | [3] | |||||
[Cs4(H2O)3][SnS4] | [15] | ||||||
Cs2Sn(S4)2(S6) | [3] | ||||||
Cs8Sn10O4S20·13H2O | [3] | ||||||
[Cs10(H2O)18][Mn4(μ4-S)(SnS4)4] | [15] | ||||||
Cs2ZnSn3S8 | monoclinic | P21/n | a 7.5366 b 17.6947 c 12.4976, β=94.830° Z=4 | 1660.7 | 3.775 | layered, band gap 3. eV | [55] |
[Ba2(H2O)11][SnS4] | [15] | ||||||
Li2Ba6MnSn4S16 | cubic | I43d | a=14.6080 Z=4 | 3117.3 | 4.007 | light yellow | [42] |
Ag2Ba6MnSn4S16 | cubic | I43d | a=14.7064 Z=4 | 3180.7 | 4.349 | yellow | [42] |
Ag2BaSnS4 | orthorhombic | I222 | a =7.127 b =8.117 c =6.854 Z=2 | black | [75] | ||
Ba3Ag2Sn2S8 | [76] | ||||||
BaSnS2 | Sn(II) | [77] | |||||
BaSn2S3 | Sn(II) | [77] | |||||
BaSnS3 | orthorhombic | Pnma | a=8.527 b=3.933 c=14.515 Z=4 | 487 | 4.8 | [13] | |
BaSnS3 | monoclinic | C2/c Cc | a=24.49 b=6.354 c=23.09 β=90.15 Z=28 | 3593 | 4.55 | [13] | |
α-Ba2SnS4 | monoclinic | P21/c | a=8.481 b=8.526 c=12.280 β=112.97 Z=4 | 818 | 4.24 | [13] | |
β-Ba2SnS4 | orthorhombic | Pnma | a=17.823 b=7.359 c=12.613 | 1654 | 4.18 | [13] | |
Ba3Sn2S7 | monoclinic | P21/c | a=11.073 b=6.771 c=18.703 β=100.77 Z=4 | 1378 | 4.21 | [13] | |
K2BaSnS4 | R3c | a 25.419 c 7.497 | band gap 3.09 eV; SHG 0.5×AgGaS2 | [78] | |||
Ba6Cu2FeSn4S16 | cubic | I43d | a=14.5260 | band gap 1.2 eV | [59] | ||
Ba6Cu2NiSn4S16 | cubic | I43d | a=14.511 | band gap 0.82 eV | [59] | ||
Ba6Li2ZnSn4S16 | cubic | I43d | a=14.5924 | [79] | |||
Ba6Ag2ZnSn4S16 | cubic | I43d | a=14.6839 | [79] | |||
BaCdSnS4 | orthorhombic | Fdd2 | a=21.57 b=21.76 c=13.110 Z=32 | 6152 | 4.290 | yellow | [80] |
Ba3CdSn2S8 | cubic | I43d | a=14.723 | [81] | |||
Ba6CdAg2Sn4S16 | cubic | I43d | a=14.725 | [81] | |||
La2SnS5 | orthorhombic | Pbam | a=11.22 b=7.915 c=3.97 Z=2 | 352 | 5.26 | [13] | |
[La(dien)3]2[Sn2S6]Cl2 | band gap 3.25 eV | [82] | |||||
La(peha)(μ–SnS4H) peha=pentaethylenehexamine | triclinic | P1 | a 8.609 b 9.327 c 14.649, α 79.2° β 85.5° γ 63.74° | [83] | |||
BaCeSn2S6 | orthorhombic | Pmc21 | a 4.0665 b 19.859 c 11.873 | [84] | |||
BaPrSn2S6 | orthorhombic | Pmc21 | a 4.0478 b 19.8914 c 11.9303 | [84] | |||
BaNdSn2S6 | orthorhombic | Pmc21 | a 4.0098 b 19.761 c 11.841 | [84] | |||
[Nd2(en)6(μ2-OH)2]Sn2S6 | monoclinic | P21/n | a =10.176, b =11.387, c=15.018, β =97.869° | [85] | |||
Nd(peha)(μ–SnS4H) | triclinic | P1 | a 8.621 b 9.372 c 14.656, α 78.28° β 84.33° γ 63.32° | [83] | |||
{Nd(tepa)(μ–OH)}2(μ–Sn2S6)]·H2O tepa=tetraethylenepentamine | monoclinic | C2/c | a=21.537 b=12.863 c=17.697 β=124.308° | [83] | |||
[Nd(dien)3]2[(Sn2S6)Cl2] dien = diethylenetriamine | monoclinic | P21/n | a = 11.672, b = 15.119, c = 14.157, β = 96.213°, Z = 4 | 2483.6 | [86] | ||
[Nd(dien)3]2[(Sn2S6)(SH)2] | monoclinic | P21/n | a = 11.719, b = 15.217, c = 14.221, β = 95.775°, Z = 4 | 2523.1 | [86] | ||
(tetaH)2[Eu2(teta)2(tren)2(μ-Sn2S6)]Sn2S6 | triclinic | P1 | a=9.886 b=10.371 c=17.442 α=89.78 β=88.00 γ=85.14 Z=1 | 1780.8 | 1.898 | light yellow | [60] |
[Eu2(tepa)2(μ-OH)2(μ-Sn2S6)](tepa)0.5·H2O tepa = tetraethylene-pentamine | monoclinic | C2/c | a=19.803 b=14.998 c=17.800 β=126.57 Z=4 | 4246 | 1.970 | colourless | [60] |
[{Eu(en)3}2(μ-OH)2]Sn2S6 | monoclinic | P21/n | a = 10.116, b = 11.379, c = 14.949, β = 98.209°, Z=2 | 1703.1 | [87] | ||
[{Eu(en)3}2(μ-OH)2]Sn2Se6 | monoclinic | P21/n | a = 10.136, b = 11.771, c = 15.423, β = 99.322°, Z = 2 | 1815.8 | [87] | ||
[Eu(dien)3]2[(Sn2S6)(SH)2] | monoclinic | P21/n | a = 11.656, b = 15.168, c = 14.173, β = 95.682°, Z = 2 | 2493.4 | [87] | ||
(tetaH)2[Sm2(teta)2(tren)2(μ-Sn2S6)]Sn2S6 | triclinic | P1 | a=9.920 b=10.382 c=17.520 α=89.91 β=88.07 γ=85.23 Z=1 | 1797.1 | 1.877 | light yellow | [60] |
{Sm(tepa)(μ–OH)}2(μ–Sn2S6)]·H2O | monoclinic | C2/c | a 21.487 b 12.8199 c 17.716 β 124.675° | [83] | |||
[Sm2(en)6(μ 2-OH)2]Sn2S6 | monoclinic | P21/n | a 10.129 b 11.377 c 14.962, β 98.128° | [88] | |||
[Sm(dien)3]2[(Sn2S6)Cl2] | monoclinic | P21/n | a 11.631 b 15.091 c 14.1420 β 96.202° | [88] | |||
[Sm(dien)3]2[(Sn2S6)(SH)2] | monoclinic | P21/n | a 11.698 b 15.212 c 14.219, β 95.654° | [88] | |||
[Sm(trien)(tren)(Cl)]2Sn2S6 · en | triclinic | P1 | a 10.320 b 10.491 c 13.791, α 100.524° β 91.930° γ 119.083° | [88] | |||
{Gd(tepa)(μ–OH)}2(μ–Sn2S6)]·H2O | monoclinic | C2/c | a 21.455 b 12.804 c 17.735 β 124.81° | [83] | |||
[Gd2(en)6(μ2-OH)2]Sn2S6 | monoclinic | P21/n | a =10.1053 b =11.357 c =14.924, β = 98.346° | [85] | |||
[Gd(dien)3]2[(Sn2S6)Cl2] dien = diethylenetriamine | monoclinic | P21/n | a =11.662, b =15.168. c 14.185, β =95.696° | [85] | |||
{Dy(tepa)(μ–OH)}2(μ–Sn2S6)]·H2O | monoclinic | C2/c | a 21.363 b 12.717 c 17.654 β 124.915° | [83] | |||
[Hen]2[La(en)4(CuSn3S9)]⋅0.5 en | [89] | ||||||
[Hen]2[Ce(en)4(CuSn3S9)]⋅0.5 en | [89] | ||||||
[Hen]4[Nd(en)4]2[Cu6Sn6S20]⋅3 en | [89] | ||||||
[enH]4[Sm(en)4]2[Cu6Sn6S20]·3en | monoclinic | C2/m | a 14.257 b 24.242 c 13.119 β 92.223° | [90] | |||
[Hen]4[Gd(en)4]2[Cu6Sn6S20]⋅3 en | [89] | ||||||
[enH]4[Ho(en)4]2[Cu6Sn6S20]·3en | monoclinic | C2/m | a 14.3859 b 24.361 c 13.175, β 93.526° | [90] | |||
EuCu2SnS4 | orthorhombic | Ama2 | a=10.4793, b=10.3610, c=6.4015, Z=4 | [91][92] | |||
[Hen]4[Er(en)4]2[Cu6Sn6S20]⋅3 en | [89] | ||||||
[Hen]4[Er(en)4]2[Ag6Sn6S20]·3en | monoclinic | C2/m | a 14.557 b 24.397 c 13.412 β 94.42° | [93] | |||
[Hen]4[Tm(en)4]2[Ag6Sn6S20]·3en | monoclinic | C2/m | a 14.517 b 24.380 c 13.422 β 94.46° | [93] | |||
[Hen]4[Yb(en)4]2[Ag6Sn6S20]·3en | monoclinic | C2/m | a 14.536 b 24.397 c 13.397, β 94.63° | [93] | |||
Cu6SnWS8 Kiddcreekite | isometric | F43m | a = 10.8178 Z=4 | 1265.9 | 4.934 | grey | [94] |
PtSnS Bowlesite | orthorhombic | Pca21 | a = 6.12 Å, b = 6.12 Å, c = 6.10 Å Z=4 | 228.47 | 10.06 | metallic | [95] |
(Pd,Pt)5(Cu,Fe)4SnTe2S2 Oulankaite | tetragonal | a = 9.044, c = 4.937 Z=2 | 403.8 | 10.27 | metallic | ||
K2Au2SnS4 | triclinic | P1 | a=8.212 b=11.019 c=7.314 α=97.82° β=111.72° γ=72.00° Z=2 | 483.2 | 4.941 | band gap 2.75 eV | [96][54] |
K2Au2Sn2S6 | tetragonal | P4/mmc | a=7.968 c=19.200 Z=4 | 1219 | 4.914 | band gap 2.30 eV | [96][54] |
Cs2Au2SnS4 | orthorhombic | Fddd | a = 6.143 b = 14.296 c = 24.578 Z = 4 | 2158.4 | [96] | ||
Ba[Au2SnS4] | orthorhombic | C2221 | a=6.6387 b=11.0605 c=10.9676 Z=1 | 805.32 | 6.418 | red; blue-green luminescent | [96] |
K2Hg3Sn2S8 | [97] | ||||||
Cu2HgSnS4 Velikite | tetrahedral | I42m | a = 5.55, c = 10.91 | 336 | 5.450 | dark grey | [98] |
SrHgSnSe4 | [99] | ||||||
BaHgSnSe4 | orthorhombic | Fdd2 | a 22.441 b 22.760 c 13.579 | [99] | |||
EuHgSnS4 | Ama2 | a=10.3730 b=10.4380 c=6.5680 | SHG 1.77×AgGaS2 | [100] | |||
Tl4SnS4 | 0d | ||||||
Tl2SnS3 | 1d | ||||||
Tl2Sn2S5 | 3d | ||||||
Tl4Sn5S12 | 3d | ||||||
PbSnS2 Teallite | orthorhombic | Pnma | a = 4.26, b = 11.41, c = 4.09 | 198.8 | 6.36 | metallic | |
PbSnS3 Suredaite | orthorhombic | Pnma | a=8.738 b=3.792 c=14.052 Z=4 | 466 | 6.01 | metallic | [13] |
(Pb,Sn)12.5Sn5FeAs3S28 Coiraite | monoclinic | a = 5.84, b = 5.86, c = 17.32 β = 94.14° Z=4 | 591 | 5.92 | dark grey | [101] | |
Fe2+(Pb,Sn2+)6Sn4+2Sb2S14 Franckeite | triclinic | P1 | a = 46.9, b = 5.82, c = 17.3 α = 90°, β = 94.66°, γ = 90° Z=8 | 4701 | 5.90 | black | [102] |
Pb25.7Sn8.3Mn3.4Sb6.4S56.2 Ramosite | monoclinic | a = 5.82, b = 5.92, c = 17.65 β = 99.1° | 600 | [103] | |||
Pb3Sn4FeSb2S14 Cylindrite | triclinic | P1 | 5.46 | black | [104] | ||
Pb6Sn3FeSb3S16 Potosíite | triclinic | grey | |||||
(Pb,Ag)4Sn4FeSb2S15 Incaite | monoclinic | [105] | |||||
Pb2Fe2Sn2Sb2S11 Plumbostannite | dark grey | [106] | |||||
Ba5Pb2Sn3S13 | orthorhombic | Pnma | [107] | ||||
Pb2SnInBiS7 Abramovite | triclinic | P1 | a = 23.4, b = 5.77, c = 5.83 α = 89.1°, β = 89.9°, γ = 91.5° | 786.79 | metallic | [108] | |
Pb8Sn7Cu3(Bi,Sb)3S28 Lévyclaudite | triclinic | P1 | 5.71 | grey | [109] |
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