Chem. J. Chinese Universities ›› 2021, Vol. 42 ›› Issue (1): 40.doi: 10.7503/cjcu20200362
Special Issue: 分子筛功能材料 2021年,42卷,第1期
• Review • Previous Articles Next Articles
WANG Binyu1, LI Li1, LI Jing2, JIN Keyan1, ZHANG Shaoqing1, ZHANG Jianan3, YAN Wenfu1()
Received:
2020-06-18
Online:
2021-01-10
Published:
2021-01-12
Contact:
YAN Wenfu
E-mail:yanw@jlu.edu.cn
Supported by:
CLC Number:
TrendMD:
WANG Binyu, LI Li, LI Jing, JIN Keyan, ZHANG Shaoqing, ZHANG Jianan, YAN Wenfu. Recent Progresses on the Synthesis of Zeolites from the Industrial Solid Wastes[J]. Chem. J. Chinese Universities, 2021, 42(1): 40.
Raw material | Elemental composition(%, mass fraction) | Crystal phase | Ref. | |||||
---|---|---|---|---|---|---|---|---|
Fly ash | Al2O3 | SiO2 | CaO | Fe2O3 | K2O | MgO | Mullite, quartz | [ |
(40.26) | (48.97) | (2.29) | (3.07) | (0.49) | (0.4) | |||
MnO | Na2O | P2O5 | SO3 | TiO2 | LOI | |||
(0.02) | (0.11) | (0.3) | (0.27) | (1.52) | (2.26) | |||
Perlite industrial waste | O | Si | Al | K | Na | Fe | Mica, quartz, feldspars | [ |
(71.79) | (19.60) | (4.24) | (2.17) | (1.26) | (0.40) | |||
Ca | Mg | |||||||
(0.39) | (0.17) | |||||||
Coal gangue | SiO2 | TiO2 | Al2O3 | Fe2O3 | MgO | CaO | Kaolinite | [ |
(33.50) | (0.74) | (27.96) | (1.68) | (0.48) | (1.11) | |||
Na2O | K2O | H2O | P2O5 | MnO | LOI | |||
(0.17) | (0.35) | (0.43) | (0.079) | (0.02) | (34.24) | |||
Spent FCC catalyst | SiO2 | Al2O3 | NaO2 | Fe2O3 | TiO2 | La2O3 | FAU(Y) | [ |
(49.5) | (45.1) | (1.4) | (1.7) | (1.0) | (0.5) | |||
P2O5 | Other | |||||||
(0.5) | (0.2) | |||||||
Lithium slag | SiO2 | Al2O3 | SO3 | CaO | Fe2O3 | K2O | Quartz, spodumene | [ |
(71.73) | (25.16) | (1.58) | (0.21) | (0.58) | (0.38) | |||
Na2O | TiO2 | |||||||
(0.06) | (0.03) | |||||||
Bauxite residue | Na2O | MgO | Al2O3 | SiO2 | P2O5 | K2O | Gibbsite, calcite, hematite | [ |
(4.03) | (0.21) | (11.46) | (7.89) | (0.09) | (0.45) | |||
CaO | TiO2 | MnO | Fe2O | |||||
(3.53) | (4.82) | (0.21) | (36.8) | |||||
Waste porcelain | SiO2 | Al2O3 | Na2O | K2O | Fe2O3 | CaO | Mullite, quartz, trydimite | [ |
(65.1) | (23.0) | (4.40) | (1.89) | (1.80) | (1.26) | |||
TiO2 | ZrO2 | MgO | P2O5 | ZnO | BaO | |||
(0.88) | (0.87) | (0.133) | (0.096) | (0.227) | (0.133) | |||
Waste glass | SiO2 | CaO | Fe2O3 | Na2O | MgO | Bi2O3 | Amorphous | [ |
(66.1) | (24.9) | (2.4) | (1.7) | (1.2) | (0.5) | |||
Al2O3 | K2O | TiO2 | ||||||
(1.1) | (0.9) | (0.3) |
Raw material | Elemental composition(%, mass fraction) | Crystal phase | Ref. | |||||
---|---|---|---|---|---|---|---|---|
Fly ash | Al2O3 | SiO2 | CaO | Fe2O3 | K2O | MgO | Mullite, quartz | [ |
(40.26) | (48.97) | (2.29) | (3.07) | (0.49) | (0.4) | |||
MnO | Na2O | P2O5 | SO3 | TiO2 | LOI | |||
(0.02) | (0.11) | (0.3) | (0.27) | (1.52) | (2.26) | |||
Perlite industrial waste | O | Si | Al | K | Na | Fe | Mica, quartz, feldspars | [ |
(71.79) | (19.60) | (4.24) | (2.17) | (1.26) | (0.40) | |||
Ca | Mg | |||||||
(0.39) | (0.17) | |||||||
Coal gangue | SiO2 | TiO2 | Al2O3 | Fe2O3 | MgO | CaO | Kaolinite | [ |
(33.50) | (0.74) | (27.96) | (1.68) | (0.48) | (1.11) | |||
Na2O | K2O | H2O | P2O5 | MnO | LOI | |||
(0.17) | (0.35) | (0.43) | (0.079) | (0.02) | (34.24) | |||
Spent FCC catalyst | SiO2 | Al2O3 | NaO2 | Fe2O3 | TiO2 | La2O3 | FAU(Y) | [ |
(49.5) | (45.1) | (1.4) | (1.7) | (1.0) | (0.5) | |||
P2O5 | Other | |||||||
(0.5) | (0.2) | |||||||
Lithium slag | SiO2 | Al2O3 | SO3 | CaO | Fe2O3 | K2O | Quartz, spodumene | [ |
(71.73) | (25.16) | (1.58) | (0.21) | (0.58) | (0.38) | |||
Na2O | TiO2 | |||||||
(0.06) | (0.03) | |||||||
Bauxite residue | Na2O | MgO | Al2O3 | SiO2 | P2O5 | K2O | Gibbsite, calcite, hematite | [ |
(4.03) | (0.21) | (11.46) | (7.89) | (0.09) | (0.45) | |||
CaO | TiO2 | MnO | Fe2O | |||||
(3.53) | (4.82) | (0.21) | (36.8) | |||||
Waste porcelain | SiO2 | Al2O3 | Na2O | K2O | Fe2O3 | CaO | Mullite, quartz, trydimite | [ |
(65.1) | (23.0) | (4.40) | (1.89) | (1.80) | (1.26) | |||
TiO2 | ZrO2 | MgO | P2O5 | ZnO | BaO | |||
(0.88) | (0.87) | (0.133) | (0.096) | (0.227) | (0.133) | |||
Waste glass | SiO2 | CaO | Fe2O3 | Na2O | MgO | Bi2O3 | Amorphous | [ |
(66.1) | (24.9) | (2.4) | (1.7) | (1.2) | (0.5) | |||
Al2O3 | K2O | TiO2 | ||||||
(1.1) | (0.9) | (0.3) |
Raw material | Pre?treatment method | Crystallization method | Main product | Crystal size/μm | Ref. |
---|---|---|---|---|---|
Fly ash | NaOH solution pretreatment | Microwave hydrothermal | LTA | 2—5 | [ |
crystallization | |||||
Alkali fusion | Hydrothermal crystallization | LTA | 8—10 | [ | |
Alkali fusion | Ultrasonic hydrothermal | FAU(X) | 0.5 | [ | |
crystallization | |||||
Alkali fusion(Na2CO3), acid leaching | Hydrothermal crystallization | GIS | 2.84—5.82 | [ | |
Roasting, alkali fusion, acid leaching | Hydrothermal crystallization | ZSM?5 | 2—3 | [ | |
Acid leaching | Hydrothermal crystallization | ZSM?5 | 5—8 | [ | |
Acid leaching | Hydrothermal crystallization | ZSM?5 | 0.4—0.5 | [ | |
Alkali fusion(KOH) | Hydrothermal crystallization | CHA | 4—8 | [ | |
Alkali fusion(KOH) | Hydrothermal crystallization | CHA | 5—8 | [ | |
Alkali fusion | Hydrothermal crystallization | FAU(Y) | 7—8 | [ | |
Perlite industrial waste | No treatment | Hydrothermal crystallization | Zeolite?Pc | 1 | [ |
No treatment | Hydrothermal crystallization | FAU(X) | 10—25 | [ | |
No treatment | Hydrothermal crystallization | FAU(X) | 1 | [ | |
Coal gangue | Roasting, alkali fusion | Hydrothermal crystallization | LTA | 1.7 | [ |
Roasting | Hydrothermal crystallization | LTA | 1—1.5 | [ | |
Roasting | Hydrothermal crystallization | LTA | 1.5 | [ | |
Roasting | Hydrothermal crystallization | LTA | 1.5—2 | [ | |
Roasting, alkali fusion | Hydrothermal crystallization | FAU(X) | 2.5—3 | [ | |
Alkali fusion | Hydrothermal crystallization | FAU(X) | 12—17 | [ | |
No treatment | Hydrothermal crystallization | CHA | 2—7 | [ | |
No treatment | Ultrasonic hydrothermal | CHA | 1.5—7 | [ | |
crystallization | |||||
Roasting, acid leaching | Hydrothermal crystallization | ZSM?5 | 2—4 | [ | |
Spent FCC catalyst | Alkali fusion(Na2CO3) | Hydrothermal crystallization | LTA | 2 | [ |
Acid leaching | Hydrothermal crystallization | LTA | 1—2.5 | [ | |
Ball milling | Hydrothermal crystallization | FAU(X) | 1 | [ | |
Alkali fusion | Hydrothermal crystallization | FAU(Y) | 0.2 | [ | |
Ammonium sulfate activation method, | Hydrothermal crystallization | FAU(Y) | 0.4—1.2 | [ | |
acid leaching | |||||
Microwave acid treatment | Microwave hydrothermal | FAU(Y) | 0.1—0.3 | [ | |
crystallization | |||||
Lithium slag | No treatment | Dynamic hydrothermal | SOD | 20 | [ |
crystallization | |||||
Alkali fusion | Hydrothermal crystallization | FAU(X) | 1—3 | [ | |
Bauxite residue | Alkali fusion | Hydrothermal crystallization | LTA | 0.2—1 | [ |
Acid leaching, alkali fusion | Hydrothermal crystallization | LTA | 5—10 | [ | |
No treatment | Hydrothermal crystallization | ZSM?5 | 2—5 | [ | |
Alkali fusion | Hydrothermal crystallization | ZSM?5 | 1—2 | [ | |
Alkali fusion, acid leaching | Hydrothermal crystallization | LTA | 1—10 | [ | |
Waste porcelain | Alkali fusion | Hydrothermal crystallization | EMT | 0.3—1 | [ |
Alkali fusion | Hydrothermal crystallization | FAU | 0.5 | [ | |
Alkaline Liquor | Hydrothermal crystallization | LTA | 2—4 | [ | |
Waste glass | Acid leaching | Hydrothermal crystallization | LTA | 2—3 | [ |
NaOH solution pretreatment, | Hydrothermal crystallization | LTA | 2—5 | [ | |
Sodium sulfide treatment | |||||
Roasting | Hydrothermal crystallization | GIS | 2—5 | [ | |
No treatment | Hydrothermal crystallization | ANA | 5—10 | [ |
Raw material | Pre?treatment method | Crystallization method | Main product | Crystal size/μm | Ref. |
---|---|---|---|---|---|
Fly ash | NaOH solution pretreatment | Microwave hydrothermal | LTA | 2—5 | [ |
crystallization | |||||
Alkali fusion | Hydrothermal crystallization | LTA | 8—10 | [ | |
Alkali fusion | Ultrasonic hydrothermal | FAU(X) | 0.5 | [ | |
crystallization | |||||
Alkali fusion(Na2CO3), acid leaching | Hydrothermal crystallization | GIS | 2.84—5.82 | [ | |
Roasting, alkali fusion, acid leaching | Hydrothermal crystallization | ZSM?5 | 2—3 | [ | |
Acid leaching | Hydrothermal crystallization | ZSM?5 | 5—8 | [ | |
Acid leaching | Hydrothermal crystallization | ZSM?5 | 0.4—0.5 | [ | |
Alkali fusion(KOH) | Hydrothermal crystallization | CHA | 4—8 | [ | |
Alkali fusion(KOH) | Hydrothermal crystallization | CHA | 5—8 | [ | |
Alkali fusion | Hydrothermal crystallization | FAU(Y) | 7—8 | [ | |
Perlite industrial waste | No treatment | Hydrothermal crystallization | Zeolite?Pc | 1 | [ |
No treatment | Hydrothermal crystallization | FAU(X) | 10—25 | [ | |
No treatment | Hydrothermal crystallization | FAU(X) | 1 | [ | |
Coal gangue | Roasting, alkali fusion | Hydrothermal crystallization | LTA | 1.7 | [ |
Roasting | Hydrothermal crystallization | LTA | 1—1.5 | [ | |
Roasting | Hydrothermal crystallization | LTA | 1.5 | [ | |
Roasting | Hydrothermal crystallization | LTA | 1.5—2 | [ | |
Roasting, alkali fusion | Hydrothermal crystallization | FAU(X) | 2.5—3 | [ | |
Alkali fusion | Hydrothermal crystallization | FAU(X) | 12—17 | [ | |
No treatment | Hydrothermal crystallization | CHA | 2—7 | [ | |
No treatment | Ultrasonic hydrothermal | CHA | 1.5—7 | [ | |
crystallization | |||||
Roasting, acid leaching | Hydrothermal crystallization | ZSM?5 | 2—4 | [ | |
Spent FCC catalyst | Alkali fusion(Na2CO3) | Hydrothermal crystallization | LTA | 2 | [ |
Acid leaching | Hydrothermal crystallization | LTA | 1—2.5 | [ | |
Ball milling | Hydrothermal crystallization | FAU(X) | 1 | [ | |
Alkali fusion | Hydrothermal crystallization | FAU(Y) | 0.2 | [ | |
Ammonium sulfate activation method, | Hydrothermal crystallization | FAU(Y) | 0.4—1.2 | [ | |
acid leaching | |||||
Microwave acid treatment | Microwave hydrothermal | FAU(Y) | 0.1—0.3 | [ | |
crystallization | |||||
Lithium slag | No treatment | Dynamic hydrothermal | SOD | 20 | [ |
crystallization | |||||
Alkali fusion | Hydrothermal crystallization | FAU(X) | 1—3 | [ | |
Bauxite residue | Alkali fusion | Hydrothermal crystallization | LTA | 0.2—1 | [ |
Acid leaching, alkali fusion | Hydrothermal crystallization | LTA | 5—10 | [ | |
No treatment | Hydrothermal crystallization | ZSM?5 | 2—5 | [ | |
Alkali fusion | Hydrothermal crystallization | ZSM?5 | 1—2 | [ | |
Alkali fusion, acid leaching | Hydrothermal crystallization | LTA | 1—10 | [ | |
Waste porcelain | Alkali fusion | Hydrothermal crystallization | EMT | 0.3—1 | [ |
Alkali fusion | Hydrothermal crystallization | FAU | 0.5 | [ | |
Alkaline Liquor | Hydrothermal crystallization | LTA | 2—4 | [ | |
Waste glass | Acid leaching | Hydrothermal crystallization | LTA | 2—3 | [ |
NaOH solution pretreatment, | Hydrothermal crystallization | LTA | 2—5 | [ | |
Sodium sulfide treatment | |||||
Roasting | Hydrothermal crystallization | GIS | 2—5 | [ | |
No treatment | Hydrothermal crystallization | ANA | 5—10 | [ |
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