*Faujasite | ||||
Bergerhoff, G., Baur, W.H. and Nowacki, W. Über die Kristallstrukturen des Faujasits N. Jb. Miner. Mh., , 193-200 (1958) |
[Al58Si134O384]-FAU | |||
[Ga-Ge-O]-FAU | ||||
Barrer, R.M., Baynham, J.W., Bultitude, F.W. and Meier, W.M. Hydrothermal chemistry of the silicates. Part VIII. Low-temperature crystal growth of aluminosilicates, and of some gallium and germanium analogues J. Chem. Soc., , 195-208 (1959) |
[Ga - Ge - O]-FAU | |||
[Al-Ge-O]-FAU | ||||
Barrer, R.M., Baynham, J.W., Bultitude, F.W. and Meier, W.M. Hydrothermal chemistry of the silicates. Part VIII. Low-temperature crystal growth of aluminosilicates, and of some gallium and germanium analogues J. Chem. Soc., , 195-208 (1959) |
[Ge - Al - O]-FAU | |||
Zeolite X (Linde X) | ||||
Milton, R.M. U.S. Patent 2,882,244, , (1959) |
[Al - Si - O]-FAU | |||
Faujasite | ||||
Baur, W.H. On the cation and water positions in faujasite Am. Mineral., 49, 697-704 (1964) |
|(Ca,Mg,Na2)29 (H2O)240 | [Al58Si134O384]-FAU | |||
Zeolite Y (Linde Y) | ||||
Breck, D.W. U.S. Patent 3,130,007, , (1964) |
[Al - Si - O]-FAU | |||
Na-X, hydrated | ||||
Olson, D.H. A reinvestigation of the crystal structure of the zeolite hydrated NaX J. Phys. Chem., 74, 2758-2764 (1970) |
[Al88Si104O384]-FAU | |||
ZSM-3 (EMT-FAU structural intermediate) | ||||
Kokotailo, G.T. and Ciric, J. Synthesis and Structural Features of Zeolite ZSM-3 Adv. Chem. Ser. , 101, 109-121 (1971) |
[Al - Si - O]-FAU | |||
Zeolite Y (Linde Y) | ||||
Costenoble, M.L., Mortier, W.J. and Uytterhoeven, J.B. Location of cations in synthetic zeolites X and Y. Part 4. Exchange limiting factors for Ca2+ in zeolite Y J. Chem. Soc., Faraday Trans. I, 72, 1877-1883 (1976) |
[Al56.9Si135.1O384]-FAU | |||
Zeolite Y (Linde Y) | ||||
Costenoble, M.L., Mortier, W.J. and Uytterhoeven, J.B. Location of cations in synthetic zeolites X and Y. Part 4. Exchange limiting factors for Ca2+ in zeolite Y J. Chem. Soc., Faraday Trans. I, 72, 1877-1883 (1976) |
[Al54.7Si137.3O384]-FAU | |||
CSZ-1 (EMT-FAU structural intermediate) | ||||
Barrett, M.G. and Vaughan, D.E.W. UK Patent GB 2,076,793 A, , (1981) |
[Al - Si - O]-FAU | |||
CSZ-3 | ||||
Vaughan, D.E.W. and Barrett, M.G. High silica faujasite polymorph CSZ-3 and method of synthesizing U.S. Patent 4,333,859, , (1982) |
[AlxSi192-xO384]-FAU (x=42-54) | |||
Zeolite Y, dealuminated | ||||
Klinowski, J., Thomas, J.M., Fyfe, C.A., Gobbi, G.C., Hartman, J.S. A Highly Siliceous Structural Analogue of Zeolite Y: High-Resolution Solid-State 29Si and 27Al NMR Studies Inorg. Chem., 22, 63-66 (1983) DOI: 10.1021/ic00143a016 |
[Si - O]-FAU | |||
SAPO-37 | ||||
Lok, B.M., Messina, C.A., Patton, R.L., Gajek, R.T., Cannan, T.R. and Flanigen, E.M. Silicoaluminophosphate molecular sieves: another new class of microporous crystalline inorganic solids J. Am. Chem. Soc., 106, 6092-6093 (1984) |
[Al - Si - P - O]-FAU | |||
Ultrastable Y, dealuminated, dehydrated | ||||
Parise, J.B., Corbin, D.R., Abrams, L. and Cox, D.E. Structure of dealuminated Linde Y zeolite - Si139.7Al52.3O384 and Si173.1Al118.9O384 - presence of non-framework Al species Acta Crystallogr., C40, 1493-1497 (1984) |
[Si139.7Al52.3O384]-FAU | |||
US-Y, dehydrated | ||||
Parise, J.B., Corbin, D.R., Abrams, L. and Cox, D.E. Structure of dealuminated Linde Y zeolite - Si139.7Al52.3O384 and Si173.1Al118.9O384 - presence of non-framework Al species Acta Crystallogr., C40, 1493-1497 (1984) |
[Si173.1Al18.9O384]-FAU | |||
LZ-210 | ||||
Breck, D.W. and Skeels, G.W. Silicon substituted zeolite compositions and process for preparing same U.S. Patent 4,503,023, , (1985) |
[Al - Si - O]-FAU | |||
ECR-30 (EMT-FAU structural intermediate) | ||||
Vaughan, D.E.W. E. Patent 0,351,461, , (1989) |
[Al - Si - O]-FAU | |||
ZSM-20 (EMT-FAU structural intermediate) | ||||
Newsam, J.M., Treacy, M.M.J., Vaughan, D.E.W., Strohmaier, K.G. and Mortier, W.J. The structure of zeolite ZSM-20: mixed cubic and hexagonal stackings of faujasite sheets Chem. Commun., , 493-495 (1989) |
[Al - Si - O]-FAU (Si/Al = 4.2) | |||
Zincophosphate X | ||||
Harrison, W.T.A., Gier, T.E., Moran, K.L., Nicol, J.M., Eckert, H. and Stucky, G.D. Structures and Properties of New Zeolite X-Type Zincophosphate and Beryllophosphate Molecular Sieves Chem. Mater., 3, 27-29 (1991) |
[Zn96P96O384]-FAU | |||
Beryllophosphate X | ||||
Harrison, W.T.A., Gier, T.E., Moran, K.L., Nicol, J.M., Eckert, H. and Stucky, G.D. Structures and Properties of New Zeolite X-Type Zincophosphate and Beryllophosphate Molecular Sieves Chem. Mater., 3, 27-29 (1991) |
[Be96P96O384]-FAU | |||
Beryllophosphate X | ||||
Gier, T.E. and Stucky, G.D. Structural characterization of a dehydrated magnesium/sodium beryllophosphate faujasite phase Zeolites, 12, 770-775 (1992) |
[Be96P96O384]-FAU | |||
Na-Y, siliceous | ||||
Hriljac, J.J., Eddy, M.M., Cheetham, A.K., Donohue, J.A. and Ray, G.J. Powder Neutron Diffraction and Si-29 MAS NMR Studies of Siliceous Zeolite-Y J. Solid State Chem., 106, 66-72 (1993) |
[Al - Si - O]-FAU | |||
Na-X, dehydrated | ||||
Olson, D.H. The crystal structure of dehydrated NaX Zeolites, 15, 439-443 (1995) |
[Si104Al88O384]-FAU | |||
[Co-Al-P-O]-FAU | ||||
Feng, P., Bu, X. and Stucky, G.D. Hydrothermal syntheses and structural characterization of zeolite analogue compounds based on cobalt phosphate Nature, 388, 735-741 (1997) |
[Co31.68Al64.32P96O384]-FAU | |||
Li-LSX-1.25 | ||||
Feuerstein, M. and Lobo, R.F. Characterization of Li Cations in Zeolite LiX by Solid-State NMR Spectroscopy and Neutron Diffraction Chem. Mater., , 2197-2204 (1998) |
[Si106Al86O384]-FAU | |||
Li-LSX | ||||
Feuerstein, M. and Lobo, R.F. Characterization of Li Cations in Zeolite LiX by Solid-State NMR Spectroscopy and Neutron Diffraction Chem. Mater., , 2197-2204 (1998) |
[Si96Al96O384]-FAU | |||
[Al-Ge-O]-FAU | ||||
Johnson, G.M., Lee, Y.J., Tripathi, A. and Parise, J.B. Structural studies of hydrated germanium X type zeolite via Rietveld analysis of synchrotron powder X-ray diffraction data Microporous Mesoporous Mat., 31, 195-204 (1999) |
[Al96Ge96O384]-FAU | |||
[Ga-Al-Si-O]-FAU | ||||
Occelli, M.L., Schweizer, A.E., Fild, C., Schwering, G., Eckert, H. and Auroux, A. Gallioaluminosilicate molecular sieves with the faujasite structure J. Catal., 192, 119-127 (2000) |
[Ga - Al - Si - O]-FAU | |||
[Ga-Si-O]-FAU | ||||
Occelli, M.L., Schwering, G., Fild, C., Eckert, H., Auroux, A. and Iyer, P.S. Galliosilicate molecular sieves with the faujasite structure Microporous Mesoporous Mat., 34, 15-22 (2000) |
[Ga - Si - O]-FAU (Si/Ga ~ 7.5) | |||
NaX, hydrated | ||||
Greiser, S., Hunger, M., Jäger, C. 29Si{27Al} TRAPDOR MAS NMR to distinguish Qn(mAl) sites in aluminosilicates. Test case: Faujasite-type zeolites Solid State Nucl. Magn. Reson., 79, 6-10 (2016) DOI: 10.1016/j.ssnmr.2016.10.004 |
|Na - H2O| [Si108.5Al83.5O384]-FAU | |||
Na,H-USY, hydrated | ||||
Schroeder, C., Hansen, M.R., Koller, H. Ultrastabilization of Zeolite Y Transforms Brønsted-Brønsted Acid Pairs into Brønsted-Lewis Acid Pairs Angew. Chem. Int. Ed., 57, 14281-14285 (2018) DOI: 10.1002/anie.201808395 |
|Na16.9(H2O)x| [Al38.4Si153.6O384]-FAU | |||
NaY, hydrated | ||||
Schroeder, C., Hansen, M.R., Koller, H. Ultrastabilization of Zeolite Y Transforms Brønsted-Brønsted Acid Pairs into Brønsted-Lewis Acid Pairs Angew. Chem. Int. Ed., 57, 14281-14285 (2018) DOI: 10.1002/anie.201808395 |
|Na53.7(H2O)x| [Si140.1Al51.9O384]-FAU |
* | An asterisk (*) in front of the material name indicates that it is the Type Material |