High-resolution solid-state n.m.r. studies of temperature-induced phase transitions in silicalite (zeolite ZSM—5)
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[1] J. Klinowski,et al. The origin of 29Si spin–lattice relaxation in zeolites: a means of rapid acquisition of n.m.r. spectra and of probing internal sites in microporous catalysts , 1986 .
[2] K. Unger,et al. Synthesis and structure refinement of ZSM—5 single crystals , 1985 .
[3] D. Hay,et al. Examination of the monoclinic/orthorhombic transition in silicalite using XRD and silicon NMR , 1985 .
[4] G. Engelhardt,et al. Correlation of SiOT (T = Si OR Al) angles and 29Si NMR chemical shifts in silicates and aluminosilicates. Interpretation by semi-empirical quantum-chemical considerations , 1985 .
[5] J. R. Lyerla,et al. The effect of temperature on the 29Si magic angle spinning n.m.r. spectrum of highly siliceous ZSM-5 , 1985 .
[6] D. A. Slack,et al. Investigation of the contributions to the silicon-29 MAS NMR line widths of zeolites and detection of crystallographically inequivalent sites by the study of highly siliceous zeolites , 1984 .
[7] G. Engelhardt,et al. A semi-empirical quantum-chemical rationalization of the correlation between SiOSi angles and 29Si NMR chemical shifts of silica polymorphs and framework aluminosilicates (zeolites) , 1984 .
[8] G. Gobbi,et al. Investigation of the conversion (dealumination) of ZSM-5 into silicalite by high-resolution solid-state silicon-29 and aluminum-27 MAS NMR spectroscopy , 1984 .
[9] J. Klinowski,et al. A simple correlation between isotropic 29Si-NMR chemical shifts and T–O–T angles in zeolite frameworks , 1984, Nature.
[10] D. A. Slack,et al. CHEMICAL SHIFT DISPERSION DUE TO CRYSTALLOGRAPHIC INEQUIVALENCE AND IMPLICATIONS REGARDING THE INTERPRETATION OF THE HIGH-RESOLUTION 29Si MAS NMR SPECTRA OF ZEOLITES , 1984 .
[11] J. Klinowski. Nuclear magnetic resonance studies of zeolites , 1984 .
[12] D. Hay,et al. Orthorhombic-monoclinic phase changes in ZSM-5 zeolite/silicalite , 1984 .
[13] G. T. Kokotailo,et al. Investigation of the dealumination of high silica zeolite A (ZK-4) by 29Si magic-angle-spinning n.m.r. spectroscopy , 1984 .
[14] Gw West. The Effect of Sorbates on the High-Resolution 29Si N.M.R. Spectra of Silicalite , 1984 .
[15] J. Klinowski,et al. The evaluation of non-equivalent tetrahedral sites from 29Si NMR chemical shifts in zeolites and related aluminosilicates , 1983 .
[16] J. Klinowski,et al. ON THE SIMILARITY OF THE HIGH-RESOLUTION SOLID-STATE 29Si AND 27Al SPECTRA OF SILICALITE AND DEALUMINATED ZEOLITE ZSM-5 , 1983 .
[17] D. A. Slack,et al. INVESTIGATION OF THE FACTORS AFFECTING THE 29Si MAS NMR LINEWIDTHS OF ZEOLITES , 1983 .
[18] G. Gobbi,et al. INVESTIGATION OF THE DEALUMINATION OF ZEOLITE ZSM-5 BY SOLID-STATE MAGIC-ANGLE SPINNING NMR , 1983 .
[19] J. Nagy,et al. Position and configuration of the guest organic molecules within the framework of the ZSM-5 and ZSM-11 zeolites , 1983 .
[20] J. Klinowski,et al. Resolving crystallographically distinct tetrahedral sites in silicalite and ZSM-5 by solid-state NMR , 1982, Nature.
[21] G. R. Hays,et al. An investigation into the structure and position of organic bases in ZSM-5-type zeolites by high-resolution solid-state 13C n.m.r. spectroscopy , 1982 .
[22] J. Klinowski,et al. A re-examination of Si, Al ordering in zeolites NaX and NaY , 1982 .
[23] W. M. Meier,et al. Crystal structure and structure-related properties of ZSM-5 , 1981 .
[24] É. Lippmaa,et al. Investigation of the structure of zeolites by solid-state high-resolution silicon-29 NMR spectroscopy , 1981 .
[25] G. D. Price,et al. Crystal structure of tetrapropylammonium fluoride-silicalite , 1981, Nature.
[26] NakamotoHiromi,et al. CRYSTAL SYMMETRY CHANGE OF ZSM-5 BY VARIOUS TREATMENTS , 1981 .
[27] É. Lippmaa,et al. Structural studies of silicates by solid-state high-resolution silicon-29 NMR , 1980 .
[28] D. Olson,et al. ZSM-5-type materials. Factors affecting crystal symmetry , 1979 .
[29] J. Smith,et al. Silicalite, a new hydrophobic crystalline silica molecular sieve , 1978, Nature.