ZEOLITIC 3D SCAFFOLDS WITH TAILORED SURFACE TOPOGRAPHY FOR METHANOL CONVERSION WITH LIGHT OLEFINS SELECTIVITY
20190001311 ยท 2019-01-03
Assignee
Inventors
Cpc classification
C07C1/20
CHEMISTRY; METALLURGY
B01J29/005
PERFORMING OPERATIONS; TRANSPORTING
C07C2529/48
CHEMISTRY; METALLURGY
Y02P20/52
GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
Y02P30/20
GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
B01J29/48
PERFORMING OPERATIONS; TRANSPORTING
C07C2529/40
CHEMISTRY; METALLURGY
B01J21/16
PERFORMING OPERATIONS; TRANSPORTING
B01J2229/42
PERFORMING OPERATIONS; TRANSPORTING
C07C1/20
CHEMISTRY; METALLURGY
B01J29/85
PERFORMING OPERATIONS; TRANSPORTING
B01J35/56
PERFORMING OPERATIONS; TRANSPORTING
B01J29/405
PERFORMING OPERATIONS; TRANSPORTING
Y02P30/40
GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
International classification
B01J29/00
PERFORMING OPERATIONS; TRANSPORTING
B01J29/85
PERFORMING OPERATIONS; TRANSPORTING
B01J21/16
PERFORMING OPERATIONS; TRANSPORTING
B01J29/40
PERFORMING OPERATIONS; TRANSPORTING
B01J29/48
PERFORMING OPERATIONS; TRANSPORTING
Abstract
The present disclosure relates to 3D printed zeolite scaffolds. The zeolite scaffolds can be used as a catalyst for methanol to olefin (MTO) conversion and hydrocarbon cracking processes.
Claims
1. A zeolite coated monolith article comprising an uncoated monolithic support structure including walls having a honeycomb structure comprising ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay; and a porous coating disposed directly upon the uncoated monolithic support structure.
2. The zeolite coated monolith article of claim 1, further comprises an additional component selected from the group consisting of amorphous silica, a plasticizing binder, a metal dopant, and combinations thereof disposed within the uncoated monolithic support structure.
3. The zeolite coated monolith article of claim 2, wherein the metal dopant is selected from the group consisting of Zn, Ce, Cr, Mg, Cu, La, Ga, Y, and combinations thereof.
4. The zeolite coated monolith article of claim 1, wherein the porous coating comprises SAPO-34.
5. The zeolite coated monolith article of claim 1, wherein the zeolite coated monolith has a wall thickness of about 0.2 mm to about 0.9 mm.
6. The zeolite coated monolith article of claim 1, wherein the zeolite coated monolith has a square channel length of about 0.2 mm to about 1.6 mm.
7. The zeolite coated monolith article of claim 1, wherein the zeolite coated monolith has a total pore volume of about 0.2 cm.sup.3/g to about 0.95 cm.sup.3/g.
8. The zeolite coated monolith article of claim 1, wherein the zeolite coated monolith has a mesoporosity of about 0.1 cm.sup.3/g to about 0.95 cm.sup.3/g.
9. A process for converting methanol to one or more light olefins (MTO), the process comprising contacting methanol, under deoxygenation conditions, with a catalyst comprising a zeolite monolith, wherein the zeolite monolith comprises an uncoated monolithic support structure including walls having a honeycomb structure comprising ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay, and a porous coating disposed directly upon the uncoated monolithic support structure.
10. The process of claim 9, wherein the one or more light olefins is selected from the group consisting of ethylene, propylene, butylene, and combinations thereof.
11. The process of claim 9, wherein the process occurs in a tubular reactor.
12. The process of claim 11, wherein the tubular reactor a fixed bed reactor or a fluidized-bed reactor.
13. The process of claim 12 wherein the tubular reactor is a fixed bed reactor.
14. A process for catalytic cracking a hydrocarbon to produce a light olefin, the process comprises contacting the hydrocarbon, under cracking conditions, with a catalyst comprising a zeolite monolith, wherein the zeolite monolith comprises an uncoated monolithic support structure including walls having a honeycomb structure comprising ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay, and a porous coating disposed directly upon the uncoated monolithic support structure.
15. The process of claim 14, wherein the process occurs at a temperature from about 550 C. to about 700 C.
16. The process of claim 14, wherein the process occurs at pressure from about 0.5 bar to about 2 bar.
17. The process of claim 14, wherein the hydrocarbon is selected from the group consisting of ethane, propane, butane, pentane, and hexane.
18. The process of claim 17, wherein the hydrocarbon is n-hexane.
19. The process of claim 14, wherein the light olefin is selected from the group consisting of ethylene, propylene, butylene, and combinations thereof.
20. The process of claim 14, wherein the process occurs in a tubular reactor and the tubular reactor is a fixed bed reactor or a fluidized-bed reactor.
Description
BRIEF DESCRIPTION OF THE FIGURES
[0010] The application file contains at least one drawing executed in color. Copies of this patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
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DETAILED DESCRIPTION OF THE INVENTION
[0039] Applicants have discovered that 3D-printed zeolite monoliths have low fouling rates and extended catalyst lifetime when used as a catalyst in methanol to olefin (MTO) conversion reactions.
[0040] Additional aspects of the invention are described below.
(I) Zeolite Monolith
[0041] One aspect of the present disclosure encompasses a zeolite coated monolith article, comprising an uncoated monolithic support structure including walls having a honeycomb structure comprising ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay; and a porous coating disposed directly upon the uncoated monolithic support structure.
[0042] Other aspects of the invention are described in further detail below.
(a) Composition
[0043] In general, the uncoated monolithic support structure comprises zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay.
[0044] (i) Zeolite Ammonia-ZSM-5 Powder (SiO.sub.2/Al.sub.2O.sub.3)
[0045] In an embodiment, the uncoated monolithic support structure may comprise from about 30 wt. % to about 95 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3). In some embodiments, the uncoated monolithic support structure may comprise from about 30 wt. % to about 95 wt. %, about 40 wt. % to about 90 wt. %, or from about 45 wt. % to about 90 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3).
[0046] In additional embodiments, the uncoated monolithic support structure may comprise from about 40 wt. % to about 50 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3). In other embodiments, the uncoated monolithic support structure may comprise about 40 wt. %, about 41 wt. %, about 42 wt. %, about 43 wt. %, about 44 wt. %, about 45 wt. %, about 46 wt. %, about 47 wt. %, about 48 wt. %, about 49 wt. %, or about 50 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3).
[0047] In additional embodiments, the uncoated monolithic support structure may comprise from about 80 wt. % to about 90 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3). In other embodiments, the uncoated monolithic support structure may comprise about 80 wt. %, about 81 wt. %, about 82 wt. %, about 83 wt. %, about 84 wt. %, about 85 wt. %, about 86 wt. %, about 87 wt. %, about 88 wt. %, about 89 wt. %, or about 90 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3). In an exemplary embodiment, the uncoated monolithic support structure may comprise about 44 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3). In a different exemplary embodiment, the uncoated monolithic support structure may comprise about 88 wt. % zeolite ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3).
[0048] (ii) Bentonite Clay
[0049] In an embodiment, the uncoated monolithic support structure may comprise from about 1 wt. % to about 20 wt. % bentonite clay. In some embodiments, the uncoated monolithic support structure may comprise from 1 wt. % to about 20 wt. %, about 1 wt. % to about 15 wt. %, or from about 5 wt. % to about 15 wt. % bentonite clay. In other embodiments, the uncoated monolithic support structure may comprise about 1 wt. %, about 5 wt. %, about 10 wt. %, about 15 wt. %, or about 20 wt. % bentonite clay. In an exemplary embodiment, uncoated monolithic support structure may comprise about 10 wt. % bentonite clay.
[0050] (iii) Additional Components
[0051] In another embodiment, the uncoated monolithic support structure as described herein above may further comprise amorphous silica, a plasticizing binder, a metal dopant, and combinations thereof.
[0052] (a) Amorphous Silica
[0053] In an embodiment, the uncoated monolithic support structure may comprise from about 1 wt. % to about 95 wt. % amorphous silica. In some embodiments, the uncoated monolithic support structure may comprise from 1 wt. % to about 95 wt. %, from about 10 wt. % to about 95 wt. %, from about 20 wt. % to about 95 wt. %, from about 30 wt. % to about 95 wt. %, from about 40 wt. % to about 90 wt. %, or from about 45 wt. % to about 90 wt. % amorphous silica.
[0054] In additional embodiments, the uncoated monolithic support structure may comprise from about 40 wt. % to about 50 wt. % amorphous silica. In other embodiments, the uncoated monolithic support structure may comprise about 40 wt. %, about 41 wt. %, about 42 wt. %, about 43 wt. %, about 44 wt. %, about 45 wt. %, about 46 wt. %, about 47 wt. %, about 48 wt. %, about 49 wt. %, or about 50 wt. % amorphous silica. In additional embodiments, the uncoated monolithic support structure may comprise from about 80 wt. % to about 90 wt. % amorphous silica. In other embodiments, the uncoated monolithic support structure may comprise about 80 wt. %, about 81 wt. %, about 82 wt. %, about 83 wt. %, about 84 wt. %, about 85 wt. %, about 86 wt. %, about 87 wt. %, about 88 wt. %, about 89 wt. %, or about 80 wt. % amorphous silica. In an exemplary embodiment, the uncoated monolithic support structure may comprise about 44 wt. % amorphous silica. In a different exemplary embodiment, the uncoated monolithic support structure may comprise about 88 wt. % amorphous silica.
[0055] (b) Plasticizing Binders
[0056] Suitable plasticizing binders may include, without limit methyl cellulose and polyvinyl chloride. In an exemplary embodiment, the plasticizing organic binder may be methyl cellulose.
[0057] In an embodiment, the uncoated monolithic support structure may comprise from about 1 wt. % to about 10 wt. % plasticizing organic binder. In other embodiments, the uncoated monolithic support structure may comprise from about 1 wt. % to about 10 wt. %, about 1 wt. % to about 8 wt. %, about 1 wt. % to about 6 wt. %, or about 1 wt. % to about 4 wt. %. In some embodiments, the uncoated monolithic support structure may comprise about 1 wt. %, about 1.5 wt. %, about 2 wt. %, about 2.5 wt. %, about 3 wt. %, about 3.5 wt. %, about 4 wt. %, about 4.5 wt. %, about 5 wt. %, about 5.5 wt. %, about 6 wt. %, about 6.5 wt. %, about 7 wt. %, about 7.5 wt. %, about 8 wt. %, about 8.5 wt. %, about 9 wt. %, about 9.5 wt. %, or about 10 wt. % plasticizing organic binder. In an exemplary embodiment, the uncoated monolithic support structure may comprise about 2.5 wt. % plasticizing organic binder.
[0058] (c) Metal Dopants
[0059] Suitable metal dopants may include, without limit, Zn, Ce, Cr, Mg, Cu, La, Ga, Y, Mo, Ni, and Fe.
[0060] In an exemplary embodiment, the metal dopant may be selected from the group consisting of Zn, Ce, Cr, Mg, Cu, La, Ga, Y, and combinations thereof.
[0061] In an embodiment, the uncoated monolithic support structure may comprise from about 1 wt. % to about 10 wt. % metal dopant. In other embodiments, the uncoated monolithic support structure may comprise from about 1 wt. % to about 10 wt. %, about 1 wt. % to about 9 wt. %, about 2 wt. % to about 8 wt. %, or about 3 wt. % to about 8 wt. %. In some embodiments, the zeolite monolith may comprise about 1 wt. %, about 1.5 wt. %, about 2 wt. %, about 2.5 wt. %, about 3 wt. %, about 3.5 wt. %, about 4 wt. %, about 4.5 wt. %, about 5 wt. %, about 5.5 wt. %, about 6 wt. %, about 6.5 wt. %, about 7 wt. %, about 7.5 wt. %, about 8 wt. %, about 8.5 wt. %, about 9 wt. %, about 9.5 wt. %, or about 10 wt. % metal dopant. In an exemplary embodiment, the uncoated monolithic support structure may comprise about 4.5 wt. % metal dopant. In a different exemplary embodiment, the uncoated monolithic support structure may comprise about 5.5 wt. % metal dopant.
[0062] (iv) Coating
[0063] In an embodiment, the uncoated monolithic support structure may be coated to produce a zeolite coated monolith article.
[0064] Suitable coatings may include, without limit, SAPO-34, SSZ-13 and UZM-9.
[0065] (v) Physical Dimensions
[0066] In an embodiment, the zeolite monolith may have a wall thickness of from about 0.2 mm to about 0.9 mm. In some embodiments, the zeolite monolith may have a wall thickness of from about 0.2 mm to about 0.9 mm, about 0.3 mm to about 0.9 mm, about 0.4 mm to about 0.9 mm, about 0.5 mm to about 0.9, about 0.5 mm to about 0.8 mm, or about 0.5 mm to about 0.8 mm. In other embodiments, the zeolite monolith may have a wall thickness of about 0.2 mm, about 0.25 mm, about 0.3 mm, about 0.35 mm, about 0.4 mm, about 0.45 mm, about 0.5 mm, about 0.55 mm, about 0.6 mm, about 0.65 mm, about 0.7 mm, about 0.75, about 0.8 mm, about 0.85 mm, or about 0.9 mm. In an exemplary embodiment, the zeolite monolith may have a wall thickness of about 0.6 mm.
[0067] In an embodiment, the zeolite monolith may have a square channel length of from about 0.2 mm to about 1.6 mm. In some embodiments, the zeolite monolith may have a square channel length of from about 0.2 mm to about 1.6 mm, about 0.3 mm to about 1.6 mm, about 0.4 mm to about 1.6 mm, about 0.5 mm to about 1.6 mm, about 0.6 mm to about 1.6 mm, about 0.7 mm to about 1.6 mm, about 0.8 mm to about 1.6 mm, about 0.9 mm to about 1.6 mm, about 0.9 mm to about 1.5 mm, about 0.9 mm to about 1.4 mm, about 1.0 mm to about 1.4 mm, or about 1.1 mm to about 1.4 mm. In other embodiments, the zeolite monolith may have a square channel length of about 0.2 mm, about 0.25 mm, about 0.3 mm, about 0.35 mm, about 0.4 mm, about 0.45 mm, about 0.5 mm, about 0.55 mm, about 0.6 mm, about 0.65 mm, about 0.7 mm, about 0.75 mm, about 0.8, about 0.85, about 0.9 mm, about 0.95 mm, about 1.0 mm, about 1.1 mm, about 1.2 mm, about 1.3 mm, about 1.4 mm, about 1.5 mm, or about 1.6 mm. In an exemplary embodiment, the zeolite monolith may have a square channel length of about 1.2 mm.
[0068] In an embodiment, the zeolite monolith may have a total pore volume of from about 0.2 cm.sup.3/g to about 0.95 cm.sup.3/g. In some embodiments, the zeolite monolith may have a total pore volume of about 0.2 cm.sup.3/g, about 0.25 cm.sup.3/g, about 0.3 cm.sup.3/g, about 0.35 cm.sup.3/g, about 0.4 cm.sup.3/g, about 0.45 cm.sup.3/g, about 0.5 cm.sup.3/g, about 0.55 cm.sup.3/g, about 0.6 cm.sup.3/g, about 0.65 cm.sup.3/g, about 0.7 cm.sup.3/g, about 0.75 cm.sup.3/g, about 0.8 cm.sup.3/g, about 0.9 cm.sup.3/g, or about 0.95 cm.sup.3/g.
[0069] In an embodiment, the zeolite monolith may have a mesoporosity of from about 0.1 cm.sup.3/g to about 0.95 cm.sup.3/g. In some embodiments, the zeolite monolith may have a mesoporosity of about 0.1 cm.sup.3/g, about 0.15 cm.sup.3/g, about 0.2 cm.sup.3/g, about 0.25 cm.sup.3/g, about 0.3 cm.sup.3/g, about 0.35 cm.sup.3/g, about 0.4 cm.sup.3/g, about 0.45 cm.sup.3/g, about 0.5 cm.sup.3/g, about 0.55 cm.sup.3/g, about 0.6 cm.sup.3/g, about 0.65 cm.sup.3/g, about 0.7 cm.sup.3/g, about 0.75 cm.sup.3/g, about 0.8 cm.sup.3/g, about 0.9 cm.sup.3/g, or about 0.95 cm.sup.3/g
(b) Manufacture
[0070] Another aspect of the present disclosure encompasses a method of producing a zeolite monolith article, the comprising (a) calcinating the ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) at a temperature from about 500 C. to about 600 C. for about 2 hours to about 8 hours to produce a mixture comprising ZSM-5 zeolite and Y zeolite; (b) mixing the mixture comprising ZSM-5 zeolite and Y zeolite with bentonite clay and water to produce a homogenous slurry; and (c) 3D-printing the homogenous slurry on an alumina substrate to produce the zeolite monolith article.
[0071] Additional aspects of the method will be described in further detail below.
[0072] (i) Calcination Step
[0073] In general, the ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3=50) is calcinated to produce a mixture comprising ZSM-5 zeolite (HZSM-5) and Y zeolite (SiO.sub.2/Al.sub.2O.sub.3=80). The calcination step may be performed using standard techniques known to those of skill in the art.
[0074] In an embodiment, the calcination step may be conducted at a temperature from about 500 C. to about 1100 C. In some embodiments, the calcination step may be conducted at a temperature of about 500 C., about 550 C., about 600 C., about 650 C., about 700 C., about 750 C., about 800 C., about 850 C., about 900 C., about 950 C., about 1000 C., about 1050 C., or about 1100 C. In an exemplary embodiment, the calcination step may be conducted at a temperature of about 550 C.
[0075] In an embodiment, the calcination step may be conducted for about 2 hours to about 8 hours. In some embodiments, the calcination step may be conducted for about 2 hours, about 2.5 hours, about 3 hours, about 3.5 hours, about 4 hours, about 4.5 hours, about 5 hours, about 5.5 hours, about 6 hours, or about 6.5 hours
[0076] (ii) Mixing Step
[0077] In general, the components, as described in Section (I)(a)(i)-(I)(a)(iii), above, of the zeolite monolith article may be combined with water to produce a homogenous slurry using standard techniques known to those of skill in the art.
[0078] (iii) 3D Printing Step
[0079] In general, the homogenous slurry may be 3D-printed on a substrate to generate the zeolite monolith. 3D-printing techniques are known to those of skill in the art.
[0080] In an embodiment, the zeolite monolith article may be printed on an alumina substrate, In an exemplary embodiment, the zeolite monolith may be printed on an alumina substrate.
[0081] In an embodiment, the zeolite monolith article may be printed in any shape known to those of skill in the art. In some embodiments, the zeolite monolith is printed in a circular honeycomb structure or a square honeycomb structure.
[0082] (iv) Coating Step
[0083] The zeolite monolith article may be coated using techniques known to those of skill in the art, for example, see Li, X., Chemical Engineering Journal, 333 (2018) 545-553, which is hereby incorporated by reference in its entirety. Briefly, the 3D printed zeolite monolith article is immersed in a water suspension comprising from about 0.1 wt. % to about 2 wt. % seed particles of a coating. The seeded zeolite monolith article is then subjected to hydrothermal treatment process to grow the coating to produce the coated zeolite monolith.
[0084] SAPO-34 may be prepared according to known procedures, for example, see Li, X., Chemical Engineering Journal, 333 (2018) 545-553, which is hereby incorporated by reference in its entirety. Briefly, aluminum isopropoxide (Al(i-C.sub.3H.sub.7O).sub.3, colloidal silica (40 wt. % SNOWTEX-ZL), tetraethylammonium hydroxide (TEAOH, 40 wt. %), and H.sub.3PO.sub.4 (85 wt. %) are mixed together with a molar ratio of about 0.5 to about 1.5 Al.sub.2O.sub.3: about 0.5 to about 1.5 P.sub.2O.sub.5: about 0.1 to about 1.0 SiO.sub.2: about 1.0 to about 10.0 TEACH: about 100 to about 180H.sub.2O. The SAPO-34 mixture may then be subjected to a hydrothermal treatment process. Recovering SAPO-34 seeds involves centrifuging, washing, and drying.
[0085] The hydrothermal treatment process may be conducted at a temperature of from about 150 C. to about 250 C. In some embodiments, the hydrothermal treatment process is conducted at about 150 C., about 160 C., about 170 C., about 180 C., about 190 C., about 200 C., about 210 C., about 220 C., about 230 C., about 240 C., or about 250 C. In an exemplary embodiment, the hydrothermal process may be conducted at about 180 C. In a different exemplary embodiment, the hydrothermal process may be conducted at about 220 C.
[0086] The hydrothermal process may be conducted for about 1 hour to about 8 hours. In some embodiments, the hydrothermal process may be conducted for about 1 hour, about 1.5 hours, about 2 hours, about 2.5 hours, about 3 hours, about 3.5 hours, about 4 hours, about 4.5 hours, about 5 hours, about 5.5 hours, or about 6 hours.
(II) Methods of Use
(a) Conversion of Methanol to Light Olefins
[0087] Another aspect of the present disclosure encompasses a process for methanol to one or more light olefins (MTO), the process comprising contacting methanol, under deoxygenation conditions, with a catalyst comprising a zeolite monolith, wherein the zeolite monolith comprises an uncoated monolithic support structure including walls having a honeycomb structure comprising ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay, and a porous coating disposed directly upon the uncoated monolithic support structure.
[0088] The zeolite monolith is described in greater detail in Section (I) hereinabove.
[0089] In general, the MTO process is known to those of skill in the art.
[0090] (i) Light Olefins
[0091] Suitable light olefins include, without limit, ethylene, propylene, and butylene. In some embodiments, the light olefin is selected from the group consisting of ethylene, propylene, butylene, and combinations thereof.
[0092] (ii) Conditions
[0093] In an embodiment, the MTO process occurs at a temperature of from about 500 C. to about 1500 C. In some embodiments, MTO process occurs at a temperature of about 500 C., about 525 C., about 550 C., about 575 C., about 600 C., about 625 C., about 650 C., about 675 C., about 700 C., about 725 C., about 750 C., about 775 C., about 800 C., about 825 C., about 850 C., about 875 C., about 900 C., about 925 C., about 950 C., about 975 C., about 1000 C., about 1025 C., about 1050 C., about 1075 C., about 1100 C., about 1125 C., about 1150 C., about 1175 C., about 1200 C., about 1225 C., about 1250 C., about 1275 C., about 1300 C., about 1325 C., about 1350 C., about 1375 C., about 1400 C., about 1425 C., about 1450 C., about 1475 C., or about 1500 C.
[0094] (iii) Selectivity
[0095] In an embodiment, the MTO process has a selectivity towards ethylene and propylene.
[0096] (iv) Reactor
[0097] In an embodiment, the conversion of methanol to one or more light olefins (MTO) process may occur in a tubular reactor.
[0098] In an embodiment, the reactor is a fixed bed reactor or a fluidized-bed reactor. In an exemplary embodiment, the reactor is a fixed bed reactor.
(b) Hydrocarbon Cracking
[0099] An additional aspect of the present disclosure encompasses a method for catalytic cracking a hydrocarbon to produce a light olefin, the process comprises contacting the hydrocarbon, under cracking conditions, with a catalyst comprising a zeolite monolith, wherein the zeolite monolith comprises an uncoated monolithic support structure including walls having a honeycomb structure comprising ammonia-ZSM-5 powder (SiO.sub.2/Al.sub.2O.sub.3) and bentonite clay; and a porous coating disposed directly upon the uncoated monolithic support structure.
[0100] The zeolite monolith is described in greater detail in Section (I) hereinabove.
[0101] In general, the cracking process is known to those of skill in the art.
[0102] (i) Hydrocarbons
[0103] In an embodiment, the hydrocarbon may be a light alkane.
[0104] Suitable light alkanes include, without limit, ethane, propane, butane, pentane, and hexane. In some embodiments, the light alkane is a hexane. In an exemplary embodiment, the light alkane is n-hexane.
[0105] (ii) Light Olefins
[0106] Suitable light olefins include, without limit, ethylene, propylene, and butylene. In some embodiments, the light olefin is selected from the group consisting of ethylene, propylene, butylene, and combinations thereof.
[0107] (iii) Cracking Conditions
[0108] In an embodiment, the catalytic cracking occurs at a temperature of from about 550 C. to about 700 C. In some embodiments, the catalytic cracking occurs at a temperature of about 550 C., about 575 C., about 600 C., about 625 C., about 650 C., about 675 C., or about 700 C.
[0109] In an embodiment, the catalytic cracking occurs at a pressure of from about 0.5 bar to about 2 bar. In some embodiments, the catalytic cracking occurs at a pressure of about 0.5 bar, about 0.75 bar, about 1.0 bar, about 1.25 bar, about 1.5 bar, about 1.75 bar, or about 2.0 bar.
[0110] (iv) Reactor
[0111] In an embodiment, the catalytic cracking process may occur in a tubular reactor.
[0112] In an embodiment, the reactor is a fixed bed reactor or a fluidized-bed reactor.
Definitions
[0113] When introducing elements of the present disclosure or the preferred aspects(s) thereof, the articles a, an, the, and said are intended to mean that there are one or more of the elements. The terms comprising, including, and having are intended to be inclusive and mean that there may be additional elements other than the listed elements.
[0114] As used herein, the following definitions shall apply unless otherwise indicated, For purposes of this invention, the chemical elements are identified in accordance with the Periodic Table of the Elements, CAS version, and the Handbook of Chemistry and Physics, 75.sup.th Ed, 1994. Additionally, general principles of organic chemistry are described in Organic Chemistry, Thomas Sorrell, University Science Books, Sausalito: 1999, and March's Advanced Organic Chemistry, 5.sup.th Ed., Smith, M, B. and March, J., eds. John Wiley & Sons, New York: 2001, the entire contents of which are hereby incorporated by reference.
EXAMPLES
[0115] The following examples are included to demonstrate various embodiments of the present disclosure. It should be appreciated by those of skill in the art that the techniques disclosed in the examples that follow represent techniques discovered by the inventors to function well in the practice of the invention, and thus can be considered to constitute preferred modes for its practice. However, those of skill in the art should, in light of the present disclosure, appreciate that many changes can be made in the specific embodiments which are disclosed and still obtain a like or similar result without departing from the spirit and scope of the invention.
[0116] The following abbreviations are used throughout the Examples: XRD: x-ray crystallography; SEM: scanning electron microscopy; FTIR: Fourier-transform infrared spectroscopy; NH.sub.3-TPD/R: ammonia-temperature programmed desorption/resorption; and MAS NMR: Magic angle spinning (MAS) nuclear magnetic resonance (NMR).
Example 1: Metal-Doped 3D Printed Zeolite Catalyst with High Resistance to Coke Formation for Methanol Deoxygenation
Introduction
[0117] As one of the most significant reaction in C1 chemistry, the methanol-to-olefins (MTO) reaction, provides an alternative approach for producing basic petrochemicals from non-oil resources such as coal and nature gas..sup.1-3 Driven by the increasing demand for ethylene and propylene, which are the primary building blocks for the polymer industry,.sup.4 this process can be a readily implemented by current technologies via synthesis gas, natural gas, biomass and the coal..sup.5-9 MTO reaction is mostly catalyzed on acidic zeolite catalysts. With ZSM-5 and SAPO-34 being the central focus due to their distinct selectivity in generating light olefins..sup.10, 11 high rate of deactivation is usually observed for SAPO-34, which possesses CHA framework with small channels and cages, due to the rapid coke deposition..sup.12, 13 Therefore, ZSM-5 zeolite catalysts are more often compromisingly used despite lower olefin yield..sup.14-17
[0118] Various strategies have been employed to increase the selectivity towards light olefins over ZSM-5 zeolite with MFI framework by optimizing the acidity,.sup.18-20 scaling down the crystal size,.sup.15, 21, 22 altering the pore structure,.sup.23-25 and modifying with heteroatoms..sup.26-28 Essentially, introducing heteroatoms in the zeolite framework modifies the acidity of the catalysts. Efforts have been made to dope ZSM-5 with various metals (including alkali metal,.sup.29 alkaline earth metal,.sup.30 and transition metal.sup.31), nonmetals (mainly phosphorus),.sup.32 and semimetals (mainly boron).sup.33. A facile method to dope ZSM-5 with metals is to incorporate the element into the framework of the zeolite. In the synthesis step, the aluminum atoms in the MFI framework are substituted with atoms such as B, Ga, and Fe and the product is generally known as isomorphously substituted ZSM-5..sup.34, 35 ZSM-5 can also be modified by adding protons and extra-framework cations (mainly metal) to form acid/base or redox sites as a post-treatment step. The most common methods for doping the zeolite with metals are ion-exchange and impregnation techniques..sup.36 However, the preparation of catalysts via these techniques remains quite complex and costly due to the low controllability at micro-scale and sensitivity to pH value of zeolite crystals in the cation solution.
[0119] Recent developments in three-dimensional (3D) printing of various porous materials, such as zeolites,.sup.37, 38 silicoaluminophosphate,.sup.39 aminosilica,.sup.40 and metal-organic frameworks,.sup.41 make it possible to efficiently prepare novel materials with tunable structural, physicochemical and mechanical properties for broad applications. Our recent work.sup.38 demonstrated the feasibility and the advantages of preparing 3D-printed zeolite monolith as a promising catalyst for alkane cracking. The 3D-printed ZSM-5 monoliths showed promoted stability and increased selectivity towards light olefins in n-hexane cracking as a result of the formation of hierarchical pores and moderate acidity. In another investigation Tubo and coworkers.sup.42 synthesized Cu/Al.sub.2O.sub.3 catalytic system with a woodpile porous structure using 3D printing technique. It was proclaimed that active component (Cu) was immobilized in the Al.sub.2O.sub.3 matrix and the leaching of the metal into the reaction medium was avoided. The 3D-printed catalyst also showed good dispersion of the copper and excellent performance in Ullmann reaction.
[0120] Numerous metals have been employed as promoters in ZSM-5 type zeolite for the conversion of methanol to hydrocarbons and the effect of promoter on the product distribution has been shown to vary from metal to metal. Hadi et al..sup.43 reported that Ce is a promising promoter for Mn/H-ZMS-5 in the process of methanol conversion to propylene. The selectivity towards propylene was dramatically enhanced and the propylene/ethylene ratio was increased. Several catalysts comprising zeolite ZSM-5 impregnated with Cu were tested for methanol to hydrocarbons by Conte and coworkers.sup.44 and it was found that Cu/ZSM-5 was selective for C.sub.9-C.sub.11 aromatic products owing to the interaction of the acid sites of the zeolite with the basic sites of the metal oxide at the edge of the zeolite crystals. In another study by Li and coworkers,.sup.45 Cu/ZSM-5 prepared via post-treatment method showed improved catalyst lifetime in methanol conversion reaction. Presented and supported by the work of Bakare et al.,.sup.46 Mg modified ZSM-5 exhibited the most stable activity in the MTO reaction with the highest selectivity to propylene due to the presence of weak Brnsted acid sites. The promoted aromatics production by Zn modified ZSM-5 in methanol conversion was claimed and demonstrated by Xu and coworkers..sup.47 Furthermore, metals such as Cr, La, and Y were also introduced to MFI zeolite as promoters for the production of light olefins via catalytic cracking of various alkanes or the dehydration of ethanol..sup.48-50
[0121] In this study, recently reported 3D-printed zeolite monolith studes.sup.38 were extended to metal-doped zeolite monoliths by introducing various metal dopants via the addition of the precursor into the synthesis paste, aiming at modifying the zeolite monolith properties for enhanced catalytic performance in MTO processes. Guided by the above-mentioned literature, eight metals namely cerium, chromium, copper, gallium, lanthanum, magnesium, yttrium, and zinc were selected for this investigation. The metal-doped 3D-printed monoliths, along with their bare counterpart, were analyzed using various characterization techniques including XRD, SEM, N.sub.2 physisorption, FTIR, and NH.sub.3-TPD/R. These novel materials were tested in the methanol conversion and the effect of each metal dopant on the product distribution was discussed.
Experimental
[0122] Preparation of 3D-Printed M/ZMS-5 Monoliths:
[0123] The bare ZSM-5 monoliths were prepared using the method reported in our previous work..sup.38 The 3D-printed metal-doped zeolite monoliths were prepared by adding metal precursor solution into the zeolite and bentonite clay mixture while making the paste. The metal precursor used were Ce(NO.sub.3).sub.3.6H.sub.2O, Cr(NO.sub.3).sub.3.9H.sub.2O, Cu(NO.sub.3).sub.2.2.5H.sub.2O, Ga(NO.sub.3).sub.3.xH.sub.2O, La(NO.sub.3).sub.3.xH.sub.2O, Mg(NO.sub.3).sub.2.6H.sub.2O, Y(NO.sub.3).sub.3.6H.sub.2O and Zn(NO.sub.3).sub.2.6H.sub.2O purchased from Sigma-Aldrich (St. Louis, Mo.). About 8 wt. % metal precursor were added into the paste and the paste was extruded using our scale printed, as described in our early work..sup.38 All the fresh 3D-printed monoliths were calcined at 823 K for 6 hours in order to decompose and remove the methyl cellulose, enhance the mechanical strengthen and immobilize the metal atoms. Bare HZSM-5 monolith is denoted as ZSM-5 while the samples with metal dopants are denoted as M/ZSM-5 (M=Ce, Cr, Cu. Ga, La, Mg, Y or Zn). All the as-prepared M/ZSM-5 monoliths with diameter of 10 mm are shown in
[0124] Characterizations of the 3D-Printed M/ZSM-5 Monoliths:
[0125] X-ray diffraction (XRD) patterns were recorded on a PANalytical X'Pert multipurpose X-ray diffractometer in the angle (28) range of 5 to 50 with Cu-K1 radiation (40 kV and 40 mA) at a rate of 2.0 min.sup.1. Nitrogen physisorption measurements were performed on a Micromeritics 3Flex surface characterization analyzer at 77 K. Prior to the measurements, all samples were degassed at 573 K for 6 hours. Total surface area was determined by the Brunauer-Emmett-Teller (BET) equation using the relative pressure (P/P.sub.0) in the range of 0.05-0.3. External surface area was calculated using t-plot method and the pore size distribution was estimated using Barrett-Joyner-Halenda (BJH) model. Scanning electron microscopy (SEM) images were captured on a Hitachi S-4700 instrument to investigate the morphology of the materials. Energy-dispersive X-ray spectroscopy (EDS) was carried out to map the presence of various elements in the doped zeolite monoliths. Temperature-programmed desorption of ammonia (NH.sub.3-TPD) was performed to investigate the acid property of the samples. NH.sub.3 adsorption was carried out on the Micromeritics 3Flex analyzer under a flow of 5 vol. % NH.sub.3/He at 373 K. The desorption of NH.sub.3 was measured from 373 to 873 K at a constant heating rate of 10 K min.sup.1. A mass spectroscopy (BELMass) was used to detect the quantity of NH.sub.3 desorption. Temperature-programmed Reduction with hydrogen (H.sub.2-TPR) was also performed from 323 to 1123 K under a flow of 5 vol % H.sub.2/He using the same instrument. To determine the functional groups, FTIR spectra were obtained using a Nicolet-FTIR Model 750 spectrometer. Mechanical testing was also carried out to determine the mechanical integrity of the monoliths using an Instron 3369 (Instron, Norwood, Mass., USA) mechanical testing device with a 500 N load at 2.5 mm/min. Prior to testing, monoliths were polished with the sandpaper to prevent the uncertain surface and to avoid cracks on the surface for achieving effective results. Compressive force was applied until the monolith broke. Thermogravimetric analysis-differential thermal analysis (TGA-DTA) of the spent catalysts was carried out from 303 K to 1173 K using TGA (Model Q500, TA Instruments), at a rate of 10 K/min in a 60 mL min.sup.1 air flow.
[0126] Catalytic Test:
[0127] Catalytic behavior of the 3D-printed monoliths was assessed in a fixed-bed reactor setup. Nitrogen flow saturated with methanol at 303 K was fed to the stainless steel reactor. The feed flow rate was controlled by a mass flow controller (Brooks, 5850). In a typical run, 0.3 g of catalyst was tested under 673 K at 1.01 bar with a weight hourly space velocity (WHSV) of 0.35 h.sup.1. The catalyst was activated in situ at 823 K in nitrogen flow for 2 hours. The products were directly transferred to an on-line gas chromatography (SRI 8610C) and analyzed every hour with a flame ionized detector (GC-FID) connected to mxt-wax/mxt-alumina capillary column. The inlet line to the reactor was kept heated at 383 K whereas the effluent line of the reactor until GC injector was kept at 418 K to avoid potential condensation of hydrocarbons.
Results and Discussion
[0128] Characterization of the 3D-Printed M/ZSM-5 Monoliths:
[0129] The XRD patterns of the 3D-printed ZMS-5 monolith and M/ZSM-5 monoliths are depicted in
[0130]
[0131] The FTIR spectra of the 3D-printed ZSM-5 monolith and its metal-doped counterparts in the range of 400-2000 cm.sup.1 are presented in
[0132]
[0133] N.sub.2 physisorption isotherms of the as-prepared samples are depicted in
[0134] Table 1 summarizes the total surface area, micopore surface area, external surface area, pore volume, and micropore volume derived from different methods. For comparison, the pristine HZSM-5 powder was also measured and the values of which are listed after the notation of ZSM-5_P while its bare monolith counterpart is noted as ZSM-5_M in the table. The surface areas of the bare ZSM-5 powder and monolith were 429 and 373 cm.sup.2 g.sup.1 respectively, suggesting the formulation into monolith reduced the total surface area. This might result from the addition of binder and further calcination of fresh monoliths. However, mesopore volume increased from 0.170 cm.sup.3 g.sup.1 to 0.200 cm.sup.3 g.sup.1, due to the decomposition of the plasticizer. All the investigated metal have effect on the textural properties of the zeolite monolith. Both surface area and pore volume were reduced by metal dopant and the significance of the effect varied from metal to metal. The micropore volume of Ce-, Cu-, Ga-, Y-, and Zn-doped monoliths were found to be 0.096 cm.sup.3 g.sup.1, 0.096 cm.sup.3 g.sup.1, 0.096 cm.sup.3 g.sup.1, 0.090 cm.sup.3 g.sup.1, and 0.090 cm.sup.3 g.sup.1 respectively, within 10% variation from the bare ZSM-5 monoliths with 0.100 cm.sup.3 g.sup.1. It suggests these metals barely entered the micorpores of the zeolite when they were doped in the monolith and they affected the mesopores. Furthermore, Cr- and Mg-doped ZSM-5 monoliths displayed significant decrease in both micopore and mesopore volumes suggesting the existence of the metal dopants in the micropores in addition to mesopores, especially the outstanding low pore volume of Mg/ZSM-5 sample verified the explanation of the FTIR results.
TABLE-US-00001 TABLE 1 Physical properties of the investigated samples obtained from nitrogen physisorption. S.sub.BET.sup.a S.sub.micro.sup.b S.sub.ext V.sub.total.sup.c V.sub.micro V.sub.meso samples (m.sup.2g.sup.1) (m.sup.2g.sup.1) (m.sup.2g.sup.1) (cm.sup.3g.sup.1) (cm.sup.3g.sup.1) (cm.sup.3g.sup.1) ZSM-5_P 429 261 168 0.300 0.130 0.170 ZSM-5_M 373 214 159 0.300 0.100 0.200 Ce/ZSM-5 303 193 110 0.222 0.096 0.126 Cr/ZSM-5 286 180 106 0.219 0.089 0.130 Cu/ZSM-5 297 197 100 0.202 0.096 0.106 Ga/ZSM-5 318 197 121 0.213 0.096 0.117 La/ZSM-5 335 215 120 0.234 0.105 0.129 Mg/ZSM-5 229 178 51 0.177 0.087 0.090 Y/ZSM-5 293 185 108 0.208 0.090 0.118 Zn/ZSM-5 285 185 100 0.227 0.090 0.137
[0135]
[0136] H.sub.2-TPR profiles of the M/ZSM-5 samples are presented in
[0137]
[0138] For the application in catalysis, the mechanical strength of the 3D-printed monolith is an important factor to consider. Compression testing results are depicted in
[0139] Catalytic Test:
[0140] The performance of the zeolite monoliths as the catalyst for MTO process was evaluated at 673 K. The methanol conversion rates (X.sub.MeOH) as a function of time on stream are displayed in
[0141]
[0142] To verify the explanation with more evidence, TGA of the spent catalysts after 24 hours of methanol conversion at 673 K was carried out in the temperature range of 303 to 1173 K in a 60 mL min.sup.1 air flow. Both TGA and corresponding DTA profiles were plotted and displayed in
Conclusion
[0143] The 3D-printed monoliths with various dopants were prepared with a facile and rapid method. All samples retained their MFI framework after doping with metals. Most of the metals including Ga, La, Mg, Y, and Zn were well-dispersed in the zeolite without any measurable oxide crystal found by XRD. The as-prepared M/ZSM-5 monoliths exhibited macro-meso-micorporous network. Our results indicated that among all the 3D-printed monolith samples, Mg/ZSM-5 was the most affected sample, which showed moderate acid sites, occuping space in the micropores with relatively high mesopore volume. All these factors contributed to the high selectivity toward light olefins in the MTO process. The result of this investigation has proven that the Mg/ZSM-5 is a promising 3D-printed ZSM-5 monolith with metal incorporation for MTO process.
REFERENCES
[0144] 1. P. Tian, Y. Wei, M. Ye and Z. Liu, ACS Catalysis, 2015, 5, 1922-1938. [0145] 2. Z. Li, J. Martinez-Triguero, J. Yu and A. Corma, Journal of Catalysis, 2015, 329, 379-388. [0146] 3. X. Sun, S. Mueller, H. Shi, G. L. Haller, M. Sanchez-Sanchez, A. C. van Veen and J. A. Lercher, Journal of Catalysis, 2014, 314, 21-31. [0147] 4. R. Meiers, U. Dingerdissen and W. F. Hlderich, Journal of Catalysis, 1998, 176, 376-386. [0148] 5. N. M. Laurendeau, Progress in Energy and Combustion Science, 1978, 4, 221-270. [0149] 6. D. Sutton, B. Kelleher and J. R. H. Ross, Fuel Process. Technol., 2001, 73, 155-173. [0150] 7. M. Asadullah, S.-i. Ito, K. Kunimori, M. Yamada and K. Tomishige, Journal of Catalysis, 2002, 208, 255-259. [0151] 8. L. Wu, V. Degirmenci, P. C. M. M. Magusin, N. J. H. G. M. Lousberg and E. J. M. Hensen, Journal of Catalysis, 2013, 298, 27-40. [0152] 9. X. Li, A. Kant, Y. He, H. V. Thakkar, M. A. Atanga, F. Rezaei, D. K. Ludlow and A. A. Rownaghi, Catalysis Today, 2016, 276, 62-77. [0153] 10. C. Wang, Y. Chu, A. Zheng, J. Xu, Q. Wang, P. Gao, G. Qi, Y. Gong and F. Deng, ChemistryA European Journal, 2014, 20, 12432-12443. [0154] 11. B. V. Vora, T. L. Marker, P. T. Barger, H. R. Nilsen, S. Kvisle and T. Fuglerud, in Studies in Surface Science and Catalysis, eds. M. de Pontes, R. L. Espinoza, C. P. Nicolaides, J. H. Scholtz and M. S. Scurrell, Elsevier, 1997, vol. 107, pp. 87-98. [0155] 12. G. Qi, Z. Xie, W. Yang, S. Zhong, H. Liu, C. Zhang and Q. Chen, Fuel Process. Technol., 2007, 88, 437-441. [0156] 13. D. Chen, K. Moljord, T. Fuglerud and A. Holmen, Microporous and Mesoporous Materials, 1999, 29, 191-203. [0157] 14. S. Ivanova, E. Vanhaecke, B. Louis, S. Libs, M.-J. Ledoux, S. Rigolet, C. Marichal, C. Pham, F. Luck and C. Pham-Huu, ChemSusChem, 2008, 1, 851-857. [0158] 15. A. A. Rownaghi and J. Hedlund, Industrial & Engineering Chemistry Research, 2011, 50, 11872-11878. [0159] 16. A. A. Rownaghi, F. Rezaei and J. Hedlund, Catalysis Communications, 2011, 14, 37-41. [0160] 17. A. A. Rownaghi, F. Rezaei, M. Stante and J. Hedlund, Applied Catalysis B: Environmental, 2012, 119-120, 56-61. [0161] 18. M. Bjrgen, F. Joensen, M. Spangsberg Holm, U. Olsbye, K.-P. Lillerud and S. Svelle, Applied Catalysis A: General, 2008, 345, 43-50. [0162] 19. P. L. Benito, A. G. Gayubo, A. T. Aguayo, M. Olazar and J. Bilbao, Journal of Chemical Technology & Biotechnology, 1996, 66, 183-191. [0163] 20. A. G. Gayubo, P. L. Benito, A. T. Aguayo, M. Olazar and J. Bilbao, Journal of Chemical Technology & Biotechnology, 1996, 65, 186-192. [0164] 21. M. Firoozi, M. Baghalha and M. Asadi, Catalysis Communications, 2009, 10, 1582-1585. [0165] 22. H.-G. Jang, H.-K. Min, J. K. Lee, S. B. Hong and G. Seo, Applied Catalysis A: General, 2012, 437-438, 120-130. [0166] 23. A. A. Rownaghi, F. Rezaei and J. Hedlund, Microporous and Mesoporous Materials, 2012, 151, 26-33. [0167] 24. S. Ivanova, B. Louis, B. Madani, J. P. Tessonnier, M. J. Ledoux and C. Pham-Huu, The Journal of Physical Chemistry C, 2007, 111, 4368-4374. [0168] 25. U. Olsbye, S. Svelle, M. Bjrgen, P. Beato, T. V. W. Janssens, F. Joensen, S. Bordiga and K. P. Lillerud, Angewandte Chemie International Edition, 2012, 51, 5810-5831. [0169] 26. B. Liu, L. France, C. Wu, Z. Jiang, V. L. Kuznetsov, H. A. Al-Megren, M. Al-Kinany, S. A. Aldrees, T. Xiao and P. P. Edwards, Chemical Science, 2015, 6, 5152-5163. [0170] 27. M. Kaarsholm, F. Joensen, J. Nerlov, R. Cenni, J. Chaouki and G. S. Patience, Chemical Engineering Science, 2007, 62, 5527-5532. [0171] 28. V. R. Choudhary, K. C. Mondal and S. A. R. Mulla, Angewandte Chemie, 2005, 117, 4455-4459. [0172] 29. J.-C. Lin, K.-J. Chao and Y. Wang, Zeolites, 1991, 11, 376-379. [0173] 30. D. Goto, Y. Harada, Y. Furumoto, A. Takahashi, T. Fujitani, Y. Oumi, M. Sadakane and T. Sano, Applied Catalysis A: General, 2010, 383, 89-95. [0174] 31. B. Kaur, M. Tumma and R. Srivastava, Industrial & Engineering Chemistry Research, 2013, 52, 11479-11487. [0175] 32. K. Ramesh, C. Jie, Y.-F. Han and A. Borgna, Industrial & Engineering Chemistry Research, 2010, 49, 4080-4090. [0176] 33. G. Coudurier, A. Auroux, J. C. Vedrine, R. D. Farlee, L. Abrams and R. D. Shannon, Journal of Catalysis, 1987, 108, 1-14. [0177] 34. R. M. Barrer, J. W. Baynham, F. W. Bultitude and W. M. Meier, Journal of the Chemical Society (Resumed), 1959, DOI: 10.1039/J R9590000195, 195-208. [0178] 35. D. W. Breck and J. V. Smith, Scientific American, 1959, 200, 85-96. [0179] 36. G. Kinger, A. Lugstein, R. Swagera, M. Ebel, A. Jentys and H. Vinek, Microporous and Mesoporous Materials, 2000, 39, 307-317. [0180] 37. H. Thakkar, S. Eastman, A. Hajari, A. A. Rownaghi, J. C. Knox and F. Rezaei, ACS Applied Materials & Interfaces, 2016, 8, 27753-27761. [0181] 38. X. Li, W. Li, F. Rezaei and A. Rownaghi, Chemical Engineering Journal, 2018, 333, 545-553. [0182] 39. S. Couck, J. Cousin-Saint-Remi, S. Van der Perre, G. V. Baron, C. Minas, P. Ruch and J. F. M. Denayer, Microporous and Mesoporous Materials, 2018, 255, 185-191. [0183] 40. H. Thakkar, S. Eastman, A. Al-Mamoori, A. Hajari, A. A. Rownaghi and F. Rezaei, ACS Applied Materials & Interfaces, 2017, 9, 7489-7498. [0184] 41. H. Thakkar, S. Eastman, Q. Al-Naddaf, A. A. Rownaghi and F. Rezaei, ACS Applied Materials & Interfaces, 2017, 9, 35908-35916. [0185] 42. C. R. Tubo, J. Azuaje, L. Escalante, A. Coelho, F. Guitin, E. Sotelo and A. Gil, Journal of Catalysis, 2016, 334, 110-115. [0186] 43. N. Hadi, A. Niaei, S. R. Nabavi, M. Navaei Shirazi and R. Alizadeh, Journal of Industrial and Engineering Chemistry, 2015, 29, 52-62. [0187] 44. M. Conte, J. A. Lopez-Sanchez, Q. He, D. J. Morgan, Y. Ryabenkova, J. K. Bartley, A. F. Carley, S. H. Taylor, C. J. Kiely, K. Khalid and G. J. Hutchings, Catalysis Science & Technology, 2012, 2, 105-112. [0188] 45. M. Li, Y. Zhou, I. N. Oduro and Y. Fang, Fuel, 2016, 168, 68-75. [0189] 46. I. A. Bakare, O. Muraza, M. Yoshioka, Z. H. Yamani and T. Yokoi, Catalysis Science & Technology, 2016, 6, 7852-7859. [0190] 47. C. Xu, B. Jiang, Z. Liao, J. Wang, Z. Huang and Y. Yang, RSC Advances, 2017, 7, 10729-10736. [0191] 48. J. Lee, U. G. Hong, S. Hwang, M. H. Youn and I. K. Song, Fuel Process. Technol., 2013, 109, 189-195. [0192] 49. B. Liu, D. Slocombe, M. AlKinany, H. AlMegren, J. Wang, J. Arden, A. Vai, S. Gonzalez-Cortes, T. Xiao, V. Kuznetsov and P. P. Edwards, Applied Petrochemical Research, 2016, 6, 209-215. [0193] 50. A. A. Lappas, C. S. Triantafillidis, Z. A. Tsagrasouli, V. A. Tsiatouras, I. A. Vasalos and N. P. Evmiridis, in Studies in Surface Science and Catalysis, eds. R. Aiello, G. Giordano and F. Testa, Elsevier, 2002, vol. 142, pp. 807-814. [0194] 51. M. Liu, J. Li, W. Jia, M. Qin, Y. Wang, K. Tong, H. Chen and Z. Zhu, RSC Advances, 2015, 5, 9237-9240. [0195] 52. S. Lai, D. Meng, W. Zhan, Y. Guo, Y. Guo, Z. Zhang and G. Lu, RSC Advances, 2015, 5, 90235-90244. [0196] 53. F. Rahmani and M. Haghighi, RSC Advances, 2016, 6, 89551-89563. [0197] 54. S. Meghana, P. Kabra, S. Chakraborty and N. Padmavathy, RSC Advances, 2015, 5, 12293-12299. [0198] 55. N. Mimura, I. Takahara, M. Inaba, M. Okamoto and K. Murata, Catalysis Communications, 2002, 3, 257-262. [0199] 56. F. A. Hasan, P. Xiao, R. K. Singh and P. A. Webley, Chemical Engineering Journal, 2013, 223, 48-58. [0200] 57. D. Liu, W. Zhou and J. Wu, Chemical Engineering Journal, 2016, 284, 862-871. [0201] 58. M. A. Ali, B. Brisdon and W. J. Thomas, Applied Catalysis A: General, 2003, 252, 149-162. [0202] 59. J. C. Jansen, F. J. van der Gaag and H. van Bekkum, Zeolites, 1984, 4, 369-372. [0203] 60. S. Allahyari, M. Haghighi, A. Ebadi and S. Hosseinzadeh, Ultrasonics Sonochemistry, 2014, 21, 663-673. [0204] 61. I. C. L. Barros, V. S. Braga, D. S. Pinto, J. L. de Macedo, G. N. R. Filho, J. A. Dias and S. C. L. Dias, Microporous and Mesoporous Materials, 2008, 109, 485-493. [0205] 62. Z. Liu, Z. Zhang, W. Xing, S. Komarneni, Z. Yan, X. Gao and X. Zhou, Nanoscale Research Letters, 2014, 9, 550. [0206] 63. H. Chen, J. Wydra, X. Zhang, P.-S. Lee, Z. Wang, W. Fan and M. Tsapatsis, Journal of the American Chemical Society, 2011, 133, 12390-12393. [0207] 64. M. Impror-Clerc, P. Davidson and A. Davidson, Journal of the American Chemical Society, 2000, 122, 11925-11933. [0208] 65. R. W. Borry, Y. H. Kim, A. Huffsmith, J. A. Reimer and E. Iglesia, The Journal of Physical Chemistry B, 1999, 103, 5787-5796. [0209] 66. E. Vera-Castaneda, Study of the methanol conversion to ethylene and propylene using small pore size zeolites, Texas A and M Univ., College Station (USA), 1985. [0210] 67. C. H. Collett and J. McGregor, Catalysis Science & Technology, 2016, 6, 363-378.
Example 2: 3D-Printed Zeolite Monoliths with Macro-Meso-Microporosity for Selective Methanol to Light Olefins Reaction
Introduction
[0211] Methanol-to-olefins (MTO) conversion is an important reaction to produce light olefins such as ethylene and propylene. Zeolites are generally the most widely used catalyst for this reaction mainly due to their tunable acidity, unique porosity and designable configuration [1-4]. Among various zeolite, SAPO-34 silico-aluminophosphate (CHA structure) has been proven to be an efficient catalyst that exhibits high selectivity towards light olefins as a result of its proper acid site strength and three-dimensional cage structure with 3.8 3.8 eight-ring channels [5]. However, severe coke formation over this catalyst is usually observed which limits its widespread use [6]. To extend the catalyst lifetime, HZSM-5 zeolite (MFI structure) with larger channels (4.7 4.5 ) has been suggested as an alternative due to its relatively high olefins selectivity [7]. Endeavors have been made to increase olefin yield over HZSM-5 zeolite through two approaches: modification of the catalytic components and change of the catalyst configuration. The realization of the former is usually through introduction of heteroatoms and optimization of SiO.sub.2/Al.sub.2O.sub.3 ratio, while the latter is through alteration of particle size and porosity, and fabrication of structured catalyst [8-14].
[0212] As a major type of structured catalysts, monolith catalysts, a block of structured material which contains various types of interconnected or separated channels, have been mainly applied for environmental applications [15] such as removal of SO.sub.x/NO.sub.x from automotive exhaust gases [16-19] and selective catalytic reduction (SCR) process [20-23]. With low pressure drop, high thermal stability, great mechanical integrity, and good mass transfer characteristics, monolithic catalysts are promising alternative to conventional pellets and beads. More importantly, the diffusion efficiency of catalysts can be remarkably improved [24]. Such structures have been previously utilized in MTO reaction. For instance, Li et al. [25] synthesized ZSM-5 monolith with tetramodel porosity and the catalyst showed good activity and selectivity to propylene. In another study, Ivanova et al. [12] coated ZSM-5 zeolite on -Sic monolith and tested the supported catalyst in the conversion of methanol into light olefins. It was found that structured zeolite packings exhibited higher activity and selectivity than the powdered zeolite prepared under the same synthesis conditions. The comparison between the ZSM-5 monolith foam and its pelletized form by Lee et al. [26] illustrated that structured catalyst displayed higher selectivity to light olefins with enhanced mass transport characteristics.
[0213] Monolithic catalysts are conventionally prepared via extrusion process [27-30]. Unique dies with specific sizes and shapes are dispensable for this approach and thus restrict the diversity of catalyst configuration and enhance total fabrication costs. With the emerging three-dimensional (3D) printing technique and its broad application in fabricating various materials [31-35], the preparation of monolithic catalysts via this method opens new opportunities. Precise fabrication with desired configuration, high productivity and low fabrication cost are the advantages of this technique. Recently, Tubio et al. used 3D-printing technique for preparation of a heterogeneous copper-based catalyst [31]. The structured catalyst showed high mechanical strength, requirement-meeting reactivity and possible recyclability in a model Ullmann reaction. Lefevere et al. prepared an stainless steel support using three dimensional fibre deposition (3DFD) technology and washcoated it with zeolite. The coated structured catalysts showed beneficial effect on the selectivity and activity of the catalyst in the conversion of methanol to light olefins [32]. Rezaei and coworkers successfully prepared monoliths of porous materials like zeolites, aminosilicates and metal-organic frameworks (MOFs) and utilized them for CO.sub.2 adsorption. The monoliths displayed excellent adsorption uptake comparable to that of powder sorbents [33-35]. Considering its significance in catalytic reactions, the study of 3D-printed monolithic zeolite catalyst is scarce.
[0214] Motivated by the facility of 3D printing technique to prepare monolith catalysts, we synthesized HZSM-5 monolith using our lab-scale 3D printer. To improve the catalyst performance, SAPO-34 crystals was grown on the monoliths using secondary growth approach. The characterizations of the 3D-printed monoliths were carried out by various techniques such as XRD, SEM, N.sub.2 physisorption, NH.sub.3-TPD, and compressive test. The catalytic performance of the 3D-printed monoliths were tested in MTO reaction.
Experimental
[0215] Preparation of 3D-Printed Zeolite Monoliths:
[0216] Monoliths of HZSM-5 zeolite (M1) and HZSM-5 diluted with amorphous silica (M2) were synthesized from commercial ammonia-ZSM-5 powder (CBV 5524G, Zeolyst, SiO.sub.2/Al.sub.2O.sub.3=50) and amorphous silica (Tixosil). Ammonia-ZSM-5 was calcined at 823 K for 6 hours to produce parent HZSM-5 powder. The desired amounts of HZSM-5/silica powder were stirred with bentonite clay (Sigma-Aldrich), which was used as a binder [36], using a high-performance agitator (Model IKA-R25). Sufficient distilled water was then added until a homogeneous slurry was obtained. The aqueous paste with extrudable viscosity was obtained after adding methyl cellulose (Thermo Fisher), as a plasticizer, with sufficient stir. The paste was loaded into a 10 mL syringe (Techcon Systems) furnished with a nozzle of 0.60 mm in diameter. The synthesis of the monolith was carried out on a lab-scale 3D printer, prior to which the program of printing paths was designed by AutoCAD software and coded by Slic3r. The paste was dispensed and deposited on an alumina substrate layer-by-layer to form a honeycomb-like monolith. The fresh 3D-printed monoliths were dried overnight and then calcined for 6 hours at 873 K to remove methyl cellulose. The uniform cylindrical monolith possessed 50% infill density leading to a 0.60 mm wall thickness and 1.20 mm.sup.2 channel length. The optical image of the monolith is shown in
TABLE-US-00002 TABLE 2 Composition of the 3D-printed monoliths. Bentonite Methyl HZSM-5 silica Clay Cellulose Loading NO. Sample (wt. %) (wt. %) (wt. %) (wt. %) (wt. %) 1 M1 87.50 10 2.5 2 M2 43.75 43.75 10 2.5 3 M3 87.50 10 2.5 4 SPM1 87.50 10 2.5 4.6% 5 SPM2 43.75 43.75 10 2.5 5.8%
[0217] Growth of SAPO-34 on 3D-Printed Zeolite Monoliths:
[0218] PANalytical X'Pert Multipurpose X-ray Diffractometer was used to obtain the X-ray diffraction (XRD) patterns. It was operated at 40 kV and 40 mA with Cu-K1 monochromatized radiation (=0.154178 nm) and the scanned angle range (2) from 5 to 50 at a rate of 2.0 min.sup.1. Textural properties such as total surface area, external surface area and pore size distributioin (PSD) were measured using Brunauer-Emmett-Teller (BET) equation, t-plot and Barrett-Joyner-Halenda (BJH) methods, respectively, based on the N.sub.2 physisorption analysis carried out by a Micromeritics 3Flex surface characterization analyzer at 77 K. Before the measurements, all samples were degassed at 573 K for 6 hours. Morphology of the materials was analyzed with a field-emission scanning electron microscopy (Hitachi S-4700). Temperature-programmed desorption of ammonia (NH.sub.3-TPD) was carried out to evaluate acid properties. NH.sub.3 adsorption was performed under a flow of 5 vol % NH.sub.3/He. The desorption of NH.sub.3 was measured from 373 K to 873 K at a heating rate of 10 K min.sup.1. A mass spectroscopy (MicrotracBEL, BELMass) was used to detect the quantity of NH.sub.3 desorption. The Brnsted and Lewis acid sites were estimated by ex-situ pyridine-adsorption Fourier-transform infrared spectroscopy (FTIR) using a Bruker Tensor spectrophotometer. The catalysts were firstly activated at 673 K for 4 hours to remove moisture and then cooled down to 313 K for adsorption of pyridine until saturation. Since all monolith samples contained bentonite clay (with high proportion of Al), as a binder, it was not possible to obtain reasonable results with .sup.27Al MAS NMR and therefore this measurement was not included. However, since Si and Al are highly correlated in the zeolite framework, .sup.29Si MAS NMR, can reflect the stability of the samples. Magic angle spinning (MAS) nuclear magnetic resonance (NMR) spectra of .sup.29Si (.sup.29Si MAS NMR) were obtained using a Bruker 400 MHz FT spectrometer. The spectra were collected using a 4 mm probe spinning at 10 kHz. Mechanical testing was performed with an Instron 3369 (Instron, Norwood, Mass., USA) mechanical testing device. Monolith samples were polished with smoothing sandpaper to provide smooth and parallel surfaces. Then they were placed between two metal plates and compressed with a 500 N load cell at 2.5 mm/min while the applied load and displacement of the monolith surfaces were recorded. The spent catalysts after MTO reaction were analyzed by thermogravimetric analysis-differential thermal analysis (TGA-DTA) using a Q500, TA Instruments. The temperature was raised from 303 K to 1173 K, at a rate of 10 K/min in a 60 mL min.sup.1 air flow.
[0219] Catalytic Test:
[0220] The 3D-printed zeolite monoliths and their powder counterparts were tested in MTO reaction. The setup of the fixed-bed reactor is shown in
Results and Discussion
[0221] Characterization of 3D-Printed Zeolite Monoliths:
[0222] The XRD patterns of all the as-synthesized monoliths are shown in
[0223]
[0224] Table 3 shows the physical properties of all monoliths and their parents HZSM-5 and silica powders. Corresponding nitrogen physical sorption isotherms and PSD are displayed in
TABLE-US-00003 TABLE 3 N.sub.2 physisorption data of the bare (M1, M2) and SAPO- coated (SPM1, SPM2) 3D-printed monoliths. S.sub.BET.sup.a S.sub.mic.sup.b S.sub.external V.sub.tot.sup.c V.sub.mic.sup.b V.sub.meso Samples (m.sup.2/g) (m.sup.2/g) (m.sup.2/g) (cm.sup.3/g) (cm.sup.3/g) (cm.sup.3/g) ZP 429 261 168 0.30 0.13 0.17 silica 326 21 305 1.02 0.01 1.01 M1 372 213 159 0.30 0.11 0.19 SPM1 336 206 130 0.27 0.10 0.17 M2 323 119 204 0.60 0.06 0.54 SPM2 269 174 95 0.47 0.09 0.38 .sup.aS.sub.BET was obtained by analyzing nitrogen adsorption data at 77K in a relative vapor pressure ranging from 0.05 to 0.3. .sup.bMicropore area and micropore volume were determined using t-plot method. .sup.cTotal pore volume was estimated based on the volume adsorbed at p/p.sub.0 = 0.99.
[0225] The mechanical strength of all the monolith catalysts was assessed by compression test. The sample size used in this test was 10 mm in diameter with 50% infill density.
[0226] The NH.sub.3-TPD profiles of the zeolite powder, the bare monoliths and SAPO-34 grown monoliths are presented in
TABLE-US-00004 TABLE 4 Acid site distribution of the 3D-printed monoliths. Weak Strong Total L B acid peak acid peak Acid acid acid Amount Amount amount site site T (mmol T (mmol (mmol (mmol (mmol Sample (K) g.sup.1) (K) g.sup.1) g.sup.1) g.sup.1) g.sup.1) ZP 490 0.268 676 0.309 0.577 0.174 0.403 M1 487 0.365 651 0.205 0.570 0.194 0.376 SPM1 481 0.352 654 0.277 0.629 0.220 0.409 M2 479 0.220 666 0.018 0.239 0.119 0.120 SPM2 477 0.202 633 0.161 0.363 0.151 0.212
[0227] Catalyst Testing:
[0228] The catalytic performance of the 3D-printed monolithic catalysts and their parent HZSM-5 powder was tested in the MTO reaction at two temperatures and two contact times for 15 hours of time-on-stream and the methanol conversion (X.sub.MeOH) results are shown in
[0229] Moreover, the selectivity toward light olefins was enhanced over 3D-printed monoliths as shown in
[0230] Besides ethylene and propylene, the products generated from methanol conversion over the zeolite catalysts mainly consisted of butylene, paraffin (C.sub.1-C.sub.4), BTX (benzene, toluene, and xylene) and other hydrocarbons with C.sub.5+, as determined by the GC. The distribution of the products of 5 hours on stream over various catalysts under different conditions are listed in Table 5. It is important to emphasize here that BTX selectivity over HZSM-5 powder was significantly higher than the other byproducts. It has been previously proven that aromatic hydrocarbons such as BTX compounds are the precursors of coke formation in MTO over zeolites [58-60].
TABLE-US-00005 TABLE 5 Hydrocarbon distribution over monolith catalyst and the parent HZMS-powder. Hydrocarbon selectivity (%) Total WHSV T X.sub.MeOH Light C.sub.1-C.sub.4 Sample (h.sup.1) (K) (%) C.sub.2= C.sub.3= C.sub.4= Olefins BTX paraffin Others ZP 0.35 623 91 9.1 8.9 3.7 21.8 19.0 51.6 7.8 673 98 7.7 11.7 4.1 23.5 17.2 53.0 6.5 1.06 623 89 12.7 14.1 11.0 37.7 17.4 40.9 4.9 673 97 12.8 17.0 10.8 40.6 14.9 41.0 4.2 M1 0.35 623 90 17.8 21.7 4.7 44.2 13.0 39.0 4.2 673 95 12.8 24.4 6.2 43.4 15.7 38.0 3.0 1.06 623 89 22.4 36.5 4.5 63.4 8.4 24.2 4.4 673 95 14.9 27.5 5.2 47.6 10.5 38.0 4.2 SPM1 0.35 623 98 21.1 19.0 2.1 42.2 14.7 39.4 3.7 673 100 16.9 18.8 4.2 39.9 9.5 45.0 5.7 1.06 623 94 23.9 23.1 3.6 50.6 11.6 35.0 3.2 673 99 19.5 24.4 4.7 48.6 9.6 38.2 3.8 M2 0.35 623 74 28.8 31.3 4.6 64.7 6.9 24.2 4.0 673 89 16.0 27.5 3.1 46.6 7.0 42.8 4.3 1.06 623 69 35.2 26.6 2.8 64.7 12.6 18.2 4.7 673 85 19.3 31.8 3.2 54.4 11.2 31.0 4.0 SPM2 0.35 623 85 26.9 25.8 2.1 54.8 10.7 36.4 2.8 673 98 13.3 24.3 2.5 40.1 10.8 45.3 4.0 1.06 623 77 33.8 19.7 2.7 56.2 12.4 28.2 4.1 673 95 17.9 24.6 2.7 45.2 11.2 41.0 3.2
[0231] The hydrocarbon-pool mechanism of MTO process over zeolite, which has been proposed by Dahl et al. [61-63], is generally accepted, as shown in
[0232] The .sup.29Si NMR spectra of the fresh and spent catalysts (HZMS-5 powder, M1, and M2) are shown in
Conclusion
[0233] This article described the experimental studies on the synthesis of customized 3D-printed zeolite monoliths with a hierarchical (macro-meso-microporous) pore network. The incorporation of amorphous silica and SAPO-34 crystal growth via secondary growth method were applied to tune the porosity and acidity of the zeolite monoliths. The incorporation of amorphous silica contributed to formation of additional mesopores and reduction in acid sites density. The growth of SAPO-34 caused pore clogging which reduced mesopores volume dramatically, whereas both Brnsted and Lewis acid sites were increased by the SAPO-34 crystals. Evaluation of the zeolite monoliths in MTO reaction indicated that the selectivity toward light olefins was favored by the novel 3D-printed structure as a result of modified acidity and porosity of the catalysts. Due to the reduced Brnsted acid site, the hydrogen transfer route in MTO reaction was mitigated and therefore production of paraffin and aromatic was suppressed and less coke formation was observed. Although slight dealumination was found on 3D-printed monoliths after MTO reaction, it was considered to be a stable structured catalyst due to its prolonged life time. This study provides a foundation for preparation of zeolite monoliths with tunable properties by 3D printing method that can be tailored for specific chemical reactions.
REFERENCES
[0234] 1. J. Cejka, A. Corma, S. Zones, Zeolites and catalysis: synthesis, reactions and applications, John Wiley & Sons, 2010. [0235] 2. M. Stcker, Methanol-to-hydrocarbons: catalytic materials and their behavior, Microporous and Mesoporous Materials, 29 (1999) 3-48. [0236] 3. A. T. Aguayo, A. G. Gayubo, R. Vivanco, M. Olazar, J. Bilbao, Role of acidity and microporous structure in alternative catalysts for the transformation of methanol into olefins, Applied Catalysis A: General, 283 (2005) 197-207. [0237] 4. X. Li, A. Kant, Y. He, H. V. Thakkar, M. A. Atanga, F. Rezaei, D. K. Ludlow, A. A. Rownaghi, Light olefins from renewable resources: Selective catalytic dehydration of bioethanol to propylene over zeolite and transition metal oxide catalysts, Catalysis Today, 276 (2016) 62-77. [0238] 5. C. D. Chang, A. J. Silvestri, The conversion of methanol and other 0-compounds to hydrocarbons over zeolite catalysts, Journal of Catalysis, 47 (1977) 249-259. [0239] 6. B. P. C. Hereijgers, F. Bleken, M. H. Nilsen, S. Svelle, K.-P. Lillerud, M. Bjergen, B. M. Weckhuysen, U. Olsbye, Product shape selectivity dominates the Methanol-to-Olefins (MTO) reaction over H-SAPO-34 catalysts, Journal of Catalysis, 264 (2009) 77-87. [0240] 7. S. Svelle, F. Joensen, J. Nerlov, U. Olsbye, K.-P. Lillerud, S. Kolboe, M. Bjrgen, Conversion of Methanol into Hydrocarbons over Zeolite H-ZSM-5: Ethene Formation Is Mechanistically Separated from the Formation of Higher Alkenes, Journal of the American Chemical Society, 128 (2006) 14770-14771. [0241] 8. A. A. Rownaghi, F. Rezaei, J. Hedlund, Yield of gasoline-range hydrocarbons as a function of uniform ZSM-5 crystal size, Catalysis Communications, 14 (2011) 37-41. [0242] 9. J. C. Vdrine, A. Auroux, P. Dejaifve, V. Ducarme, H. Hoser, S. Zhou, Catalytic and physical properties of phosphorus-modified ZSM-5 zeolite, Journal of Catalysis, 73 (1982) 147-160. [0243] 10. C. Mei, P. Wen, Z. Liu, H. Liu, Y. Wang, W. Yang, Z. Xie, W. Hua, Z. Gao, Selective production of propylene from methanol: Mesoporosity development in high silica HZSM-5, Journal of Catalysis, 258 (2008) 243-249. [0244] 11. A. A. Rownaghi, F. Rezaei, J. Hedlund, Uniform mesoporous ZSM-5 single crystals catalyst with high resistance to coke formation for methanol deoxygenation, Microporous and Mesoporous Materials 151 (2012) 26-33. [0245] 12. S. Ivanova, B. Louis, B. Madani, J. Tessonnier, M. Ledoux, C. Pham-Huu, ZSM-5 coatings on -sic monoliths: possible new structured catalyst for the methanol-to-olefins process, The Journal of Physical Chemistry C, 111 (2007) 4368-4374. [0246] 13. A. A. Rownaghi, J. Hedlund, Methanol to Gasoline-Range Hydrocarbons: Influence of Nanocrystal Size and Mesoporosity on Catalytic Performance and Product Distribution of ZSM-5, Industrial & Engineering Chemistry Research, 50 (2011) 11872-11878. [0247] 14. A. A. Rownaghi, F. Rezaei, M. Stanteo, J. Hedlund, Selective dehydration of methanol to dimethyl ether on ZSM-5 nanocrystals, Applied Catalysis B: Environmental 119 (2011) 56-61. [0248] 15. T. Boger, A. K. Heibel, C. M. Sorensen, Monolithic catalysts for the chemical industry, Industrial & engineering chemistry research, 43 (2004) 4602-4611. [0249] 16. K. C. Taylor, Nitric oxide catalysis in automotive exhaust systems, Catalysis ReviewsScience and Engineering, 35 (1993) 457-481. [0250] 17. H. Gandhi, G. Graham, R. W. McCabe, Automotive exhaust catalysis, Journal of Catalysis, 216 (2003) 433-442. [0251] 18. F. Rezaei, A. A. Rownaghi, S. Monjezi, R. P. Lively, C. W. Jones, SOx/NOx removal from flue gas streams by solid adsorbents: a review of current challenges and future directions, Energy & fuels, 29 (2015) 5467-5486. [0252] 19. G. S. Bugosh, M. P. Harold, Impact of Zeolite Beta on Hydrocarbon Trapping and Light-Off Behavior on Pt/Pd/BEA/Al.sub.2O.sub.3 Monolith Catalysts, Emission Control Science and Technology, (2017) 1-12. [0253] 20. M. A. Buzanowski, R. T. Yang, Simple design of monolith reactor for selective catalytic reduction of NO for power plant emission control, Industrial and Engineering Chemistry Research; (United States), 29 (1990) 2074-2078. [0254] 21. P. S. Metkar, N. Salazar, R. Muncrief, V. Balakotaiah, M. P. Harold, Selective catalytic reduction of NO with NH3 on iron zeolite monolithic catalysts: Steady-state and transient kinetics, Applied Catalysis B: Environmental, 104 (2011) 110-126. [0255] 22. O. Krcher, M. Devadas, M. Elsener, A. Wokaun, N. Sager, M. Pfeifer, Y. Demel, L. Mussmann, Investigation of the selective catalytic reduction of NO by NH3 on Fe-ZSM5 monolith catalysts, Applied Catalysis B: Environmental, 66 (2006) 208-216. [0256] 23. F. Notoya, C. Su, E. Sasaoka, S. Nojima, Effect of SO2 on the low-temperature selective catalytic reduction of nitric oxide with ammonia over TiO2, ZrO2, and Al2O3, Industrial & engineering chemistry research, 40 (2001) 3732-3739. [0257] 24. M. Behl, S. Roy, Experimental investigation of gas-liquid distribution in monolith reactors, Chemical Engineering Science, 62 (2007) 7463-7470. [0258] 25. B. Li, Z. Hu, B. Kong, J. Wang, W. Li, Z. Sun, X. Qian, Y. Yang, W. Shen, H. Xu, D. Zhao, Hierarchically tetramodal-porous zeolite ZSM-5 monoliths with template-free-derived intracrystalline mesopores, Chemical Science, 5 (2014) 1565-1573. [0259] 26. Y.-J. Lee, Y.-W. Kim, K.-W. Jun, N. Viswanadham, J. W. Bae, H.-S. Park, Textural Properties and Catalytic Applications of ZSM-5 Monolith Foam for Methanol Conversion, Catalysis Letters, 129 (2009) 408-415. [0260] 27. J. L. Williams, Monolith structures, materials, properties and uses, Catalysis Today, 69 (2001) 3-9. [0261] 28. J. Freiding, B. Kraushaar-Czarnetzki, Novel extruded fixed-bed MTO catalysts with high olefin selectivity and high resistance against coke deactivation, Applied Catalysis A: General, 391 (2011) 254-260. [0262] 29. M. Menges, B. Kraushaar-Czarnetzki, Kinetics of methanol to olefins over AlPO4-bound ZSM-5 extrudates in a two-stage unit with dimethyl ether pre-reactor, Microporous and Mesoporous Materials, 164 (2012) 172-181. [0263] 30. [30] A. Kant, Y. He, A. Jawad, X. Li, F. Rezaei, J. D. Smith, A. A. Rownaghi, Hydrogenolysis of glycerol over Ni, Cu, Zn, and Zr supported on H-beta, Chemical Engineering Journal, 317 (2017) 1-8. [0264] 31. C. R. Tubo, J. Azuaje, L. Escalante, A. Coelho, F. Guitin, E. Sotelo, A. Gil, 3D printing of a heterogeneous copper-based catalyst, Journal of Catalysis, 334 (2016) 110-115. [0265] 32. J. Lefevere, M. Gysen, S. Mullens, V. Meynen, J. Van Noyen, The benefit of design of support architectures for zeolite coated structured catalysts for methanol-to-olefin conversion, Catalysis Today, 216 (2013) 18-23. [0266] 33. H. Thakkar, S. Eastman, A. Hajari, A. A. Rownaghi, J. C. Knox, F. Rezaei, 3D-Printed Zeolite Monoliths for CO2 Removal from Enclosed Environments, ACS Applied Materials & Interfaces, 8 (2016) 27753-27761. [0267] 34. H. Thakkar, S. Eastman, A. Al-Mamoori, A. Hajari, A. A. Rownaghi, F. Rezaei, Formulation of Aminosilica Adsorbents into 3D-Printed Monoliths and Evaluation of Their CO2 Capture Performance, ACS Applied Materials & Interfaces, 9 (2017) 7489-7498. [0268] 35. H. Thakkar, S. Eastman, Q. Al-Naddaf, A. A. Rownaghi, F. Rezaei, 3D-Printed Metal-Organic Framework Monoliths for Gas Adsorption Processes, ACS Applied Materials & Interfaces, 9 (2017) 35908-35916. [0269] 36. J. Lefevere, L. Protasova, S. Mullens, V. Meynen, 3D-printing of hierarchical porous ZSM-5: The importance of the binder system, Materials & Design, 134 (2017) 331-341. [0270] 37. X. Li, W. Li, F. Rezaei, A. Rownaghi, Catalytic cracking of n-hexane for producing light olefins on 3D-printed monoliths of MFI and FAU zeolites, Chemical Engineering Journal, 333, (2018) 545-553. [0271] 38. K. Ma, H. Yu, G. Feng, C. Wang, Y. Dai, Synthesis of ZSM-5@ ordered mesoporous silica composites by dodecylamine surfactant, Journal of Wuhan University of Technology-Mater. Sci. Ed., 29 (2014) 1124-1128. [0272] 39. R. M. Jacobberger, B. Kiraly, M. Fortin-Deschenes, P. L. Levesque, K. M. McElhinny, G. J. Brady, R. Rojas Delgado, S. Singha Roy, A. Mannix, M. G. Lagally, P. G. Evans, P. Desjardins, R. Martel, M. C. Hersam, N. P. Guisinger, M. S. Arnold, Direct oriented growth of armchair graphene nanoribbons on germanium, Nature Communications, 6 (2015) 8006. [0273] 40. J. K. Das, N. Das, S. Bandyopadhyay, Highly oriented improved SAPO 34 membrane on low cost support for hydrogen gas separation, Journal of Materials Chemistry A, 1 (2013) 4966-4973. [0274] 41. M. A. Carreon, S. Li, J. L. Falconer, R. D. Noble, Alumina-Supported SAPO-34 Membranes for CO2/CH4 Separation, Journal of the American Chemical Society, 130 (2008) 5412-5413. [0275] 42. M. Li, J. Zhang, X. Liu, Y. Wang, C. Liu, D. Hu, G. Zeng, Y. Zhang, W. Wei, Y. Sun, Synthesis of high performance SAPO-34 zeolite membrane by a novel two-step hydrothermal synthesis+dry gel conversion method, Microporous and Mesoporous Materials, 225 (2016) 261-271. [0276] 43. X. Li, F. Rezaei, D. K. Ludlow, A. A. Rownaghi, Synthesis of SAPO-34@ZSM-5 and SAPO-34@Silicalite-1 Core-Shell Zeolite Composites for Ethanol Dehydration, Industrial & Engineering Chemistry Research, 57 (2018) 1446-1453. [0277] 44. M. Hartmann, W. Schwieger, Hierarchically-structured porous materials: from basic understanding to applications, Chemical Society Reviews, 45 (2016) 3311-3312. [0278] 45. M. Hartmann, A. G. Machoke, W. Schwieger, Catalytic test reactions for the evaluation of hierarchical zeolites, Chemical Society Reviews, 45 (2016) 3313-3330. [0279] 46. D. Liu, A. Bhan, M. Tsapatsis, S. Al Hashimi, Catalytic Behavior of Brnsted Acid Sites in MWW and MFI Zeolites with Dual Meso- and Microporosity, ACS Catalysis, 1 (2011) 7-17. [0280] 47. L. Emdadi, Y. Wu, G. Zhu, C.-C. Chang, W. Fan, T. Pham, R. F. Lobo, D. Liu, Dual Template Synthesis of Meso- and Microporous MFI Zeolite Nanosheet Assemblies with Tailored Activity in Catalytic Reactions, Chemistry of Materials, 26 (2014) 1345-1355. [0281] 48. C. A. R. Costa, L. F. Valadares, F. Galembeck, Stober silica particle size effect on the hardness and brittleness of silica monoliths, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 302 (2007) 371-376. [0282] 49. V. S. Marakatti, A. B. Halgeri, Metal ion-exchanged zeolites as highly active solid acid catalysts for the green synthesis of glycerol carbonate from glycerol, RSC Advances, 5 (2015) 14286-14293. [0283] 50. L. Zhang, Y. Huang, New Insights into Formation of Molecular Sieve SAPO-34 for MTO Reactions, The Journal of Physical Chemistry C, 120 (2016) 25945-25957. [0284] 51. S. Mller, Y. Liu, M. Vishnuvarthan, X. Sun, A. C. van Veen, G. L. Haller, M. Sanchez-Sanchez, J. A. Lercher, Coke formation and deactivation pathways on H-ZSM-5 in the conversion of methanol to olefins, Journal of Catalysis, 325 (2015) 48-59. [0285] 52. P. Tian, Y. Wei, M. Ye, Z. Liu, Methanol to Olefins (MTO): From Fundamentals to Commercialization, ACS Catalysis, 5 (2015) 1922-1938. [0286] 53. T. Liang, J. Chen, Z. Qin, J. Li, P. Wang, S. Wang, G. Wang, M. Dong, W. Fan, J. Wang, Conversion of Methanol to Olefins over H-ZSM-5 Zeolite: Reaction Pathway Is Related to the Framework Aluminum Siting, ACS Catalysis, 6 (2016) 7311-7325. [0287] 54. A. Takahashi, W. Xia, I. Nakamura, H. Shimada, T. Fujitani, Effects of added phosphorus on conversion of ethanol to propylene over ZSM-5 catalysts, Applied Catalysis A: General, 423-424 (2012) 162-167. [0288] 55. Y. Gao, B. Zheng, G. Wu, F. Ma, C. Liu, Effect of the Si/AI ratio on the performance of hierarchical ZSM-5 zeolites for methanol aromatization, RSC Advances, 6 (2016) 83581-83588. [0289] 56. B. Liu, D. Slocombe, M. AlKinany, H. AlMegren, J. Wang, J. Arden, A. Vai, S. Gonzalez-Cortes, T. Xiao, V. Kuznetsov, P. P. Edwards, Advances in the study of coke formation over zeolite catalysts in the methanol-to-hydrocarbon process, Applied Petrochemical Research, 6 (2016) 209-215. [0290] 57. M. W. Anderson, B. Sulikowski, P. J. Barrie, J. Klinowski, In situ solid-state NMR studies of the catalytic conversion of methanol on the molecular sieve SAPO-34, The Journal of Physical Chemistry, 94 (1990) 2730-2734. [0291] 58. E. Epelde, J. I. Santos, P. Florian, A. T. Aguayo, A. G. Gayubo, J. Bilbao, P. Castao, Controlling coke deactivation and cracking selectivity of MFI zeolite by H3PO4 or KOH modification, Applied Catalysis A: General, 505 (2015) 105-115. [0292] 59. M. Ibanez, M. Gamero, J. Ruiz-Martinez, B. M. Weckhuysen, A. T. Aguayo, J. Bilbao, P. Castano, Simultaneous coking and dealumination of zeolite H-ZSM-5 during the transformation of chloromethane into olefins, Catalysis Science & Technology, 6 (2016) 296-306. [0293] 60. V. Van Speybroeck, K. De Wispelaere, J. Van der Mynsbrugge, M. Vandichel, K. Hemelsoet, M. Waroquier, First principle chemical kinetics in zeolites: the methanol-to-olefin process as a case study, Chemical Society Reviews, 43 (2014) 7326-7357. [0294] 61. I. M. Dahl, S. Kolboe, On the reaction mechanism for propene formation in the MTO reaction over SAPO-34, Catal Lett, 20 (1993) 329-336. [0295] 62. I. M. Dahl, S. Kolboe, On the reaction mechanism for hydrocarbon formation from methanol over SAPO-34: I: isotopic labeling studies of the co-reaction of ethene and methanol, J Catal, 149 (1994) 458-464. [0296] 63. I. M. Dahl, S. Kolboe, On the Reaction Mechanism for Hydrocarbon Formation from Methanol over SAPO-34: 2. Isotopic Labeling Studies of the Co-reaction of Propene and Methanol, Journal of Catalysis, 161 (1996) 304-309. [0297] 64. S. Mller, Y. Liu, F. M. Kirchberger, M. Tonigold, M. Sanchez-Sanchez, J. A. Lercher, Hydrogen Transfer Pathways during Zeolite Catalyzed Methanol Conversion to Hydrocarbons, Journal of the American Chemical Society, 138 (2016) 15994-16003. [0298] 65. S. Ilias, A. Bhan, Mechanism of the Catalytic Conversion of Methanol to Hydrocarbons, ACS Catalysis, 3 (2013) 18-31. [0299] 66. S. A. Axon, J. Klinowski, Solid-State NMR Studies of Zeolite [Si,B]-ZSM-5 Synthesized by the Fluoride Method, The Journal of Physical Chemistry, 98 (1994) 1929-1932.
[0300] All cited references are herein expressly incorporated by reference in their entirety.
[0301] Whereas particular embodiments have been described above for purposes of illustration, it will be appreciated by those skilled in the art that numerous variations of the details may be made without departing from the disclosure as described in the appended claims.