A Challenge toward Novel Quaternary Sulfides SrLnCuS3 (Ln = La, Nd, Tm): Unraveling Synthetic Pathways, Structures and Properties
Abstract
:1. Introduction
2. Results and Discussion
3. Materials and Methods
3.1. Materials
3.2. Methods
3.3. Synthesis
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
References
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SrLaCuS3 a | SrNdCuS3 a | SrNdCuS3 a | SrYCuS3 a | SrTmCuS3 a | SrScCuS3 a | |
---|---|---|---|---|---|---|
Space group | Pnma | Pnma | Pnma | Pnma | Cmcm | Cmcm |
Structural type | Ba2MnS3 | BaLaCuS3 | Eu2CuS3 | Eu2CuS3 | KZrCuS3 | KZrCuS3 |
a (Å) | 8.1682(6) | 11.0663(8) | 10.5693(7) | 10.1845(7) | 3.9163(3) | 3.8316(3) |
b (Å) | 4.0748(3) | 4.0886(3) | 4.0072(3) | 3.9378(3) | 12.9520(9) | 12.8504(9) |
c (Å) | 16.0394(11) | 11.4625(8) | 12.8905(9) | 12.9426(9) | 10.0642(7) | 9.7153(7) |
V (Å3) | 533.85(7) | 518.63(2) | 545.96(3) | 519.06(2) | 510.50(6) | 478.36(2) |
Z | 4 | 4 | 4 | 4 | 4 | 4 |
ρ (g cm−3) | 4.806 | 5.015 | 4.764 | 4.303 | 5.416 | 4.059 |
μ (mm−1) | 22.76 | 25.20 | 23.94 | 26.41 | 32.81 | 18.01 |
Collected reflection | 13821 | 7074 | 10117 | 8491 | 2756 | 4498 |
Unique reflections | 846 | 678 | 738 | 734 | 340 | 351 |
Rint | 0.0653 | 0.068 | 0.137 | 0.075 | 0.0678 | 0.055 |
R1(all) | 0.0217 | 0.032 | 0.043 | 0.029 | 0.0248 | 0.017 |
wR2(all) | 0.0382 | 0.054 | 0.080 | 0.033 | 0.0426 | 0.032 |
S | 1.022 | 1.059 | 1.004 | 0.941 | 1.007 | 1.031 |
Reference | This work | [46] | [46] | [47] | This work | [47] |
SrLaCuS3 a | SrLaCuS3 b | SrCeCuS3 a | SrCeCuS3 c | SrPrCuS3 a | SrNdCuS3 d | SrSmCuS3 a | |
---|---|---|---|---|---|---|---|
Space group | Pnma | Pnma | Pnma | Pnma | Pnma | Pnma | Pnma |
Structural type | BaLaCuS3 | Ba2MnS3 | BaLaCuS3 | Ba2MnS3 | BaLaCuS3 | BaLaCuS3 | Eu2CuS3 |
a (Å) | 11.2415(1) | 8.1746(3) | 11.1626(2) | 8.1393(3) | 11.1171(1) | 11.0815(2) | 10.4285(2) |
b (Å) | 4.11053(6) | 4.0727(2) | 4.0970(2) | 4.0587(2) | 4.09492(6) | 4.0849(1) | 3.98640(7) |
c (Å) | 11.5990(1) | 16.0473(8) | 11.5307(1) | 15.9661(2) | 11.5069(2) | 11.4684(2) | 12.9325(2) |
V (Å3) | 535.97(1) | 534.26(4) | 527.33(1) | 527.44(2) | 523.84(1) | 519.14(1) | 537.63(2) |
RDDM (%) | 5.25 | 5.73 | 4.52 | 6.61 | 5.03 | 4.00 | 4.94 |
RF (%) | 1.53 | 1.1 | 2.87 | 3.78 | 1.80 | 3.7 | 2.09 |
Impurity | – | 2.6% SrS | – | – | – | 5.2% SrS 1.3% NdCuSO | 2.6% SmCuS2 1.6% Sm2SO2 |
Reference | [43] | This work | [44] | [44] | [43] | This work | [22] |
SrGdCuS3 a | SrHoCuS3 c | SrErCuS3 a | SrErCuS3 c | SrTmCuS3 e | SrYbCuS3 c | SrLuCuS3 a | |
Space group | Pnma | Pnma | Cmcm | Cmcm | Cmcm | Cmcm | Cmcm |
Structural type | Eu2CuS3 | Eu2CuS3 | KZrCuS3 | KZrCuS3 | KZrCuS3 | KZrCuS3 | KZrCuS3 |
a (Å) | 10.3288(2) | 10.1487(1) | 3.92672(5) | 3.93128(3) | 3.9210(1) | 3.91448(4) | 3.91105(4) |
b (Å) | 3.96271(7) | 3.9332(1) | 12.9632(2) | 12.9709(1)) | 12.9523(5) | 12.9554(1) | 12.9504(1) |
c (Å) | 12.9397(2) | 12.9524(2) | 10.0974(1) | 10.1161(1) | 10.0687(4) | 10.0332(1) | 10.0206(1) |
V (Å3) | 529.62(2) | 517.02(2) | 513.99(1) | 515.843(9) | 511.34(3) | 508.842(8) | 507.540(8) |
RDDM (%) | 4.41 | 4.29 | 5.67 | 3.73 | 4.80 | 3.56 | 5.27 |
RF (%) | 2.18 | 1.91 | 2.60 | 2.06 | 2.60 | 1.48 | 1.27 |
Impurity | 3.6% GdCuS2 2.5% SrS 0.8% Gd2SO2 | 2.6% SrS | 6.3% ErxCuyS2 3.5% SrS | 9.5% Er2SO2 1.2% SrS 0.5% Er5S(SiO4)3 | 5.1% Tm2SO2 1.2% SrS | 2.2% Yb2SO2 1.8% Yb5S(SiO4)3 1.2% SrS | 1.6% SrS 1.1% Lu2SO2 |
Reference | [22] | [36] | [22] | [45] | This work | [45] | [22] |
Atom | x | y | z | Occupancy | x | y | z | Occupancy |
---|---|---|---|---|---|---|---|---|
SrLaCuS3 (single crystal) | SrLaCuS3 (powdered sample) | |||||||
Sr1 | 0.09058(3) | 1/4 | 0.785319(17) | 0.502(5) | 0.09026(6) | 1/4 | 0.785177(28) | 0.5453(46) |
La1 | 0.09058(3) | 1/4 | 0.785319(17) | 0.498(5) | 0.09026(6) | 1/4 | 0.785177(28) | 0.4547(46) |
Sr2 | 0.25439(3) | 1/4 | 0.038345(17) | 0.489(6) | 0.25446(6) | 1/4 | 0.038210(26) | 0.4550(43) |
La2 | 0.25439(3) | 1/4 | 0.038345(17) | 0.511(6) | 0.25446(6) | 1/4 | 0.038210(26) | 0.5450(43) |
Cu | 0.11864(6) | 1/4 | 0.36655(3) | 1 | 0.11857(11) | 1/4 | 0.36652(6) | 1 |
S1 | 0.17928(12) | 1/4 | 0.22120(6) | 1 | 0.17956(18) | 1/4 | 0.22114(9) | 1 |
S2 | 0.38083(12) | 1/4 | 0.42864(6) | 1 | 0.38097(19) | 1/4 | 0.42837(10) | 1 |
S3 | 0.01190(12) | 1/4 | 0.60039(6) | 1 | 0.01197(18) | 1/4 | 0.60006(10) | 1 |
SrNdCuS3 (single crystal) [46] | SrNdCuS3 (powdered sample) | |||||||
Sr1 | 0.31732(6) | 1/4 | 0.49523(6) | 1 | 0.31752(15) | 1/4 | 0.49500(17) | 0.886(5) |
Nd1 | 0.48946(3) | 1/4 | 0.81684(4) | 1 | 0.31752(15) | 1/4 | 0.49500(17) | 0.114(5) |
Sr2 | – | – | – | – | 0.48947(13) | 1/4 | 0.81683(11) | 0.114(5) |
Nd2 | – | – | – | – | 0.48947(13) | 1/4 | 0.81683(11) | 0.886(5) |
Cu | 0.24480(8) | 1/4 | 0.21334(9) | 1 | 0.2447(2) | 1/4 | 0.2133(3) | 1 |
S1 | 0.22363(17) | 1/4 | 0.80669(16) | 1 | 0.2250(5) | 1/4 | 0.8076(4) | 1 |
S2 | 0.04818(16) | 1/4 | 0.14176(17) | 1 | 0.0487(4) | 1/4 | 0.1406(4) | 1 |
S3 | 0.38733(17) | 1/4 | 0.05848(17) | 1 | 0.3872(4) | 1/4 | 0.0571(4) | 1 |
SrTmCuS3 (single crystal) | SrTmCuS3 (powdered sample) | |||||||
Sr | 0 | 0.74817(7) | 1/4 | 1 | 0 | 0.74800(12) | 1/4 | 1 |
Tm | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 1 |
Cu | 0 | 0.47124(9) | 1/4 | 1 | 0 | 0.47147(17) | 1/4 | 1 |
S1 | 0 | 0.36340(13) | 0.06401(14) | 1 | 0 | 0.3634(2) | 0.0644(2) | 1 |
S2 | 0 | 0.07621(18) | 1/4 | 1 | 0 | 0.0761(3) | 1/4 | 1 |
SrLaCuS3 (Single Crystal/Powdered Sample) | |||||
---|---|---|---|---|---|
Sr1/La1–S1 | 2.957(1)/2.9569(11) | Sr2/La2–S1 | 2.996(1)/2.9988(16) | Cu–S1 | 2.383(1)/2.3857(18) |
Sr1/La1–S1i | 2.957(1)/2.9569(11) | Sr2/La2–S2iv | 2.910(1)/2.9119(12) | Cu–S2x | 2.362(1)/2.3636(18) |
Sr1/La1–S1ii | 3.003(1)/3.0036(11) | Sr2/La2–S2v | 2.910(1)/2.9119(12) | Cu–S3vi | 2.360(1)/2.3607(9) |
Sr1/La1–S1iii | 3.003(1)/3.0036(11) | Sr2/La2–S2vi | 3.097(1)/3.0999(17) | Cu–S3ix | 2.360(1)/2.3607(9) |
Sr1/La1–S2 | 3.081(1)/3.0793(13) | Sr2/La2–S3 | 2.964(1)/2.9627(11) | ||
Sr1/La1–S2i | 3.081(1)/3.0793(13) | Sr2/La2–S3vii | 2.964(1)/2.9627(11) | ||
Sr1/La1–S3 | 3.035(1)/3.0387(16) | Sr2/La2–S3viii | 3.062(1)/3.0585(16) | ||
SrNdCuS3 (Single Crystal/Powdered Sample) | |||||
Sr1/Nd1–S1 | 3.009(2)/3.002(4) | Sr2/Nd2–S1 | 2.944(2)/2.933(5) | Cu–S1 | 2.334(1)/2.335(3) |
Sr1/Nd1–S1i | 3.009(2)/3.002(4) | Sr2/Nd2–S1v | 2.953(2)/2.974(5) | Cu–S1i | 2.334(1)/2.335(3) |
Sr1/Nd1–S2ii | 3.036(2)/3.026(4) | Sr2/Nd2–S2 | 2.895(1)/2.904(4) | Cu–S2 | 2.325(2)/2.327(5) |
Sr1/Nd1–S2iii | 3.036(2)/3.026(4) | Sr2/Nd2–S2vi | 2.895(1)/2.904(4) | Cu–S3 | 2.375(2)/2.388(5) |
Sr1/Nd1–S2iv | 2.999(2)/2.997(5) | Sr2/Nd2–S3ii | 2.992(2)/2.980(5) | ||
Sr1/Nd1–S3ii | 3.136(2)/3.135(4) | Sr2/Nd2–S3v | 2.843(1)/2.851(3) | ||
Sr1/Nd1–S3iii | 3.136(2)/3.135(4) | Sr2/Nd2–S3vii | 2.843(1)/2.851(3) | ||
SrTmCuS3 (Single Crystal/Powdered Sample) | |||||
Sr–S1ii | 3.093(1)/3.093(2) | Tm–S1 | 2.717(1)/2.719(2) | Cu–S1 | 2.336(2)/2.335(3) |
Sr–S1v | 3.093(1)/3.093(2) | Tm–S1i | 2.717(1)/2.719(2) | Cu–S1viii | 2.336(2)/2.335(3) |
Sr–S1vi | 3.093(1)/3.093(2) | Tm–S1iii | 2.717(1)/2.719(2) | Cu–S2 | 2.384(2)/2.383(3) |
Sr–S1vii | 3.093(1)/3.093(2) | Tm–S1iv | 2.717(1)/2.719(2) | Cu–S2i | 2.384(2)/2.383(3) |
Sr–S2 | 2.966(2)/2.966(3) | Tm–S2 | 2.703(1)/2.703(2) | ||
Sr–S2i | 2.966(2)/2.966(3) | Tm–S2ii | 2.703(1)/2.703(2) |
SrNdCuS3 | SrTmCuS3 | |
---|---|---|
Space group | Pnma | Cmcm |
Structural type | Ba2MnS3 | KZrCuS3 |
Calculated μ (μB) | 3.618 | 7.561 |
Experimental μ296 K (μB) | 3.611 | 7.378 |
Experimental μ20–300 K (μB) | 3.52 | 7.57 |
Calculated C (K m3 kmol−1) | 0.02057 | 0.08983 |
Experimental C20–300 K (K m3 kmol−1) | 0.0195 | 0.0901 |
Experimental θ20–300 K (K) | −18 | −12 |
Compound (Mass) | Calculated (%) | Found (%) | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
Sr | Ln | Cu | S | O | Sr | Ln | Cu | S | O | |
SrLaCuS3 (386.25) | 22.68 | 35.96 | 16.45 | 24.90 | – | 23.23 | 35.82 | 16.06 | 24.89 | – |
97.4% SrLaCuS3 + 2.6% SrS | 23.10 | 35.67 | 16.32 | 24.92 | – | |||||
SrNdCuS3 (391.59) | 22.38 | 36.83 | 16.23 | 24.56 | – | 24.68 | 35.18 | 15.52 | 24.54 | 0.08 |
93.5% SrNdCuS3 + 5.2% SrS + 1.3% NdCuSO | 23.02 | 36.40 | 16.04 | 24.49 | 0.06 | |||||
SrTmCuS3 (416.28) | 21.05 | 40.58 | 15.27 | 23.10 | – | 20.53 | 42.51 | 14.25 | 22.30 | 0.41 |
93.7% SrTmCuS3 + 1.2% SrS + 5.1% Tm2SO2 | 20.18 | 42.60 | 14.45 | 22.36 | 0.40 |
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Ruseikina, A.V.; Grigoriev, M.V.; Solovyov, L.A.; Chernyshev, V.A.; Aleksandrovsky, A.S.; Krylov, A.S.; Krylova, S.N.; Shestakov, N.P.; Velikanov, D.A.; Garmonov, A.A.; et al. A Challenge toward Novel Quaternary Sulfides SrLnCuS3 (Ln = La, Nd, Tm): Unraveling Synthetic Pathways, Structures and Properties. Int. J. Mol. Sci. 2022, 23, 12438. https://doi.org/10.3390/ijms232012438
Ruseikina AV, Grigoriev MV, Solovyov LA, Chernyshev VA, Aleksandrovsky AS, Krylov AS, Krylova SN, Shestakov NP, Velikanov DA, Garmonov AA, et al. A Challenge toward Novel Quaternary Sulfides SrLnCuS3 (Ln = La, Nd, Tm): Unraveling Synthetic Pathways, Structures and Properties. International Journal of Molecular Sciences. 2022; 23(20):12438. https://doi.org/10.3390/ijms232012438
Chicago/Turabian StyleRuseikina, Anna V., Maxim V. Grigoriev, Leonid A. Solovyov, Vladimir A. Chernyshev, Aleksandr S. Aleksandrovsky, Alexander S. Krylov, Svetlana N. Krylova, Nikolai P. Shestakov, Dmitriy A. Velikanov, Alexander A. Garmonov, and et al. 2022. "A Challenge toward Novel Quaternary Sulfides SrLnCuS3 (Ln = La, Nd, Tm): Unraveling Synthetic Pathways, Structures and Properties" International Journal of Molecular Sciences 23, no. 20: 12438. https://doi.org/10.3390/ijms232012438
APA StyleRuseikina, A. V., Grigoriev, M. V., Solovyov, L. A., Chernyshev, V. A., Aleksandrovsky, A. S., Krylov, A. S., Krylova, S. N., Shestakov, N. P., Velikanov, D. A., Garmonov, A. A., Matigorov, A. V., Eberle, M. A., Schleid, T., & Safin, D. A. (2022). A Challenge toward Novel Quaternary Sulfides SrLnCuS3 (Ln = La, Nd, Tm): Unraveling Synthetic Pathways, Structures and Properties. International Journal of Molecular Sciences, 23(20), 12438. https://doi.org/10.3390/ijms232012438