Transformation of LEV-type zeolite into less dense CHA-type zeolite

被引:83
作者
Goto, Ikuhiro [1 ]
Itakura, Masaya [1 ]
Shibata, Syohei [1 ]
Honda, Koutaro [1 ]
Ide, Yusuke [1 ]
Sadakane, Masahiro [1 ]
Sano, Tsuneji [1 ]
机构
[1] Hiroshima Univ, Grad Sch Engn, Dept Appl Chem, Higashihiroshima 7398527, Japan
来源
MICROPOROUS AND MESOPOROUS MATERIALS | 2012年 / 158卷
关键词
Hydrothermal conversion; Interzeolite conversion; LEV-type zeolite; CHA-type zeolite; Less dense zeolite; INTERZEOLITE CONVERSION METHOD; TEMPLATE-FREE SYNTHESIS; HYDROTHERMAL CONVERSION; FAU ZEOLITE; SILICA ZEOLITES; CRYSTALLIZATION; ALUMINUM; ZSM-5; BETA; CHABAZITE;
D O I
10.1016/j.micromeso.2012.03.032
中图分类号
O69 [应用化学];
学科分类号
081704 ;
摘要
Hydrothermal conversion of LEV-type zeolite into CHA-type zeolite occurred in the absence of both an organic structure-directing agent and a seed crystal. The LEV-CHA transformation proceeds from a more dense zeolite (LEV) to a less dense one (CHA). When amorphous aluminosilicate hydrogels were used as starting materials, the CHA-type zeolite was not obtained under the present hydrothermal synthesis conditions. From the fact that the LEV-CHA transformation proceeded at lower alkalinity conditions, it was suggested that locally ordered aluminosilicate species (nanoparts) produced by decomposition/dissolution of the starting LEV-type zeolite contribute to the transformation process. On the other hand, at higher alkalinity than that used for the CHA-type zeolite synthesis, LEV-LTA transformation occurred effectively and selectively. These results suggest that there is a large difference in the structures of nanoparts generated by decomposition/dissolution of the starting zeolite in the LEV-CHA and LEV-LTA transformations. (C) 2012 Elsevier Inc. All rights reserved.
引用
收藏
页码:117 / 122
页数:6
相关论文
共 38 条
[1]   Aluminum distribution in chabazite: An experimental and computational study [J].
Akporiaye, DE ;
Dahl, IM ;
Mostad, HB ;
Wendelbo, R .
JOURNAL OF PHYSICAL CHEMISTRY, 1996, 100 (10) :4148-4153
[2]   INTERACTION OF ACETYLACETONE WITH HZSM-5 - VISUALIZATION OF NMR INVISIBLE ALUMINUM [J].
ALEXANDER, SM ;
BIBBY, DM ;
HOWE, RF ;
MEINHOLD, RH .
ZEOLITES, 1993, 13 (06) :441-447
[3]   THE HYDROTHERMAL CHEMISTRY OF SILICATES .3. REACTIONS OF ANALCITE AND LEUCITE [J].
BARRER, RM ;
HINDS, L ;
WHITE, EA .
JOURNAL OF THE CHEMICAL SOCIETY, 1953, (MAY) :1466-&
[4]   DISSOLUTION OF HIGH-SILICA ZEOLITES IN ALKALINE-SOLUTIONS .1. DISSOLUTION OF SILICALITE-1 AND ZSM-5 WITH DIFFERENT ALUMINUM CONTENT [J].
CIZMEK, A ;
SUBOTIC, B ;
AIELLO, R ;
CREA, F ;
NASTRO, A ;
TUOTO, C .
MICROPOROUS MATERIALS, 1995, 4 (2-3) :159-168
[5]   ZEOLITE AND MOLECULAR-SIEVE SYNTHESIS [J].
DAVIS, ME ;
LOBO, RF .
CHEMISTRY OF MATERIALS, 1992, 4 (04) :756-768
[6]   Capturing Ultrasmall EMT Zeolite from Template-Free Systems [J].
Eng-Poh Ng ;
Chateigner, Daniel ;
Bein, Thomas ;
Valtchev, Valentin ;
Mintova, Svetlana .
SCIENCE, 2012, 335 (6064) :70-73
[7]   MECHANISM OF CRYSTALLIZATION OF ZEOLITE X [J].
FREUND, EF .
JOURNAL OF CRYSTAL GROWTH, 1976, 34 (01) :11-23
[8]   SYNTHESIS AND CHARACTERIZATION OF ZSM-5 TYPE ZEOLITES .3. A CRITICAL-EVALUATION OF THE ROLE OF ALKALI AND AMMONIUM CATIONS [J].
GABELICA, Z ;
BLOM, N ;
DEROUANE, EG .
APPLIED CATALYSIS, 1983, 5 (02) :227-248
[9]   THE EFFECTS OF THE SILICA SOURCE ON THE CRYSTALLIZATION OF ZEOLITE NAX [J].
HAMILTON, KE ;
COKER, EN ;
SACCO, A ;
DIXON, AG ;
THOMPSON, RW .
ZEOLITES, 1993, 13 (08) :645-653
[10]   THEORETICAL CALCULATIONS ON SILICA FRAMEWORKS AND THEIR CORRELATION WITH EXPERIMENT [J].
HENSON, NJ ;
CHEETHAM, AK ;
GALE, JD .
CHEMISTRY OF MATERIALS, 1994, 6 (10) :1647-1650
1234