METHOD OF FABRICATING ORGANIC STRUCTURE DIRECTING AGENT-FREE CHA TYPE ZEOLITE MEMBRANE AND MEMBRANE FABRICATED THEREBY

Abstract

The present invention relates to a method of fabricating an organic structure directing agent-free CHA type zeolite membrane and a membrane fabricated thereby, and more particularly to a method of fabricating a continuous CHA type zeolite membrane, which exhibits CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 separation performances comparable with those of conventional membranes, in a cost-effective manner without a calcination process by hydrothermal synthesis using an alkali metal hydroxide without using an organic structure directing agent, and to a membrane fabricated thereby.

Claims

1. An organic structure directing agent-free CHA type zeolite membrane which is fabricated by the method comprising: (a) preparing particles having a CHA structure; (b) forming a seed layer by depositing the particles having the CHA structure on a support; and (c) fabricating a CHA type zeolite membrane by conducting hydrothermal synthesis on the seed layer using a synthetic precursor solution containing an alkali metal and silica, and having a molar ratio of Si to Al of 45-55 at a temperature of 100-250° C. for 24-48 hours, wherein the organic structure directing agent is added to step (a), and is not added to steps (b) and (c).

2. The organic structure directing agent-free CHA type zeolite membrane of claim 1, wherein an alkali metal in the alkali metal hydroxide is selected from the group consisting of Li, Na, K and mixtures thereof.

3. The organic structure directing agent-free CHA type zeolite membrane of claim 1, further comprising a step of drying after hydrothermally synthesizing in step of (c).

4. The organic structure directing agent-free CHA type zeolite membrane of claim 1, wherein the support is one or more selected from the group consisting of alumina, polyimide, silica, glass, gamma alumina, mullite, zirconia, titania, yttria, ceria, vanadia, silicone, stainless steel and carbon.

5. The organic structure directing agent-free CHA type zeolite membrane of claim 1, wherein the molar ratio of Si to Al is 50, and the hydrothermal synthesis is conducted at 175° C.

6. A method of separating CO.sub.2 from a mixture containing CO.sub.2 and a molecule selected from the group consisting of CH.sub.4, N.sub.2, O.sub.2, C.sub.2H.sub.4, C.sub.2H.sub.6, C.sub.3H.sub.6 and C.sub.3H.sub.8, by using the CHA type zeolite membrane of claim 1.

7. The method of claim 6, wherein the method is performed at a temperature of 30-200° C. under dry conditions, and at a temperature of 75-200° C. under wet conditions.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] FIG. 1 is a schematic view showing a method of synthesizing a CHA type zeolite membrane by seed growth without an OSDA according to an example of the present invention.

[0017] FIG. 2 depicts SEM images of CHA type zeolite particles obtained by seed growth according to an example of the present invention.

[0018] FIG. 3 is a graph showing the XRD patterns of CHA type zeolite particles obtained by seed growth according to an example of the present invention.

[0019] FIG. 4 depicts graphs showing the N.sub.2 adsorption isotherms of CHA type zeolite particles obtained by seed growth according to an example of the present invention.

[0020] FIG. 5 depicts SEM images and XRD pattern graphs, which show the effect of the Si/Al ratio on the formation of continuous CHA type zeolite membranes according to an example of the present invention.

[0021] FIG. 6 depicts graphs showing the CO.sub.2/N.sub.2 separation performance of continuous CHA type zeolite membranes according to an example of the present invention.

[0022] FIG. 7 depicts SEM images and XRD pattern graphs, which show the effect of hydrothermal reaction time on the formation of continuous CHA type zeolite membranes according to an example of the present invention.

[0023] FIG. 8 depicts graphs which show the CO.sub.2/N.sub.2 separation performance of continuous CHA type zeolite membranes according to an example of the present invention.

[0024] FIG. 9 depicts FCOM images of continuous CHA type zeolite membranes according to an example of the present invention.

[0025] FIG. 10 depicts graphs showing the CO.sub.2/N.sub.2 separation performance of continuous CHA type zeolite membranes according to an example of the present invention.

[0026] FIG. 11 depicts graphs showing a comparison of the CO.sub.2/N.sub.2 separation performance of continuous CHA type zeolite membranes according to an example of the present invention with literature data.

[0027] FIG. 12 depicts graphs showing stability of continuous CHA type zeolite membranes according to an example of the present invention.

[0028] FIG. 13 shows SEM images and XRD patterns of C-SSZ-13 seed particles and a C-SSZ-13 seed layer according to an example of the present invention.

[0029] FIG. 14 shows XRD patterns of C-SSZ-13 seed particles and OSDA-free particles according to an example of the present invention.

[0030] FIG. 15 shows an XRD pattern of C-SSZ-13 seed particles according to an example of the present invention.

[0031] FIG. 16 shows XRD patterns of OSDA-free particles (P_20_1d) according to an example of the present invention.

[0032] FIGS. 16, 17 and 18 shows XRD patterns of OSDA-free particles (P_20_2d) according to an example of the present invention.

[0033] FIG. 18 shows XRD patterns of OSDA-free particles (P_50_1d) according to an example of the present invention.

[0034] FIG. 19 shows cross-sectional SEM images and EDX-based Si and Al profiles of continuous CHA type zeolite membranes according to an example of the present invention.

[0035] FIG. 20 shows SEM and FCOM images of continuous CHA type zeolite membranes according to an example of the present invention.

[0036] FIG. 21 depicts graphs showing a comparison of the performance of a continuous CHA type zeolite membrane of the present invention with those of conventional membranes.

BEST MODE FOR CARRYING OUT THE INVENTION

[0037] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present disclosure belongs. In general, the nomenclature used herein is well known and commonly used in the art.

[0038] A conventional method for synthesizing a zeolite membrane, which uses an expensive organic structure directing agent and obtains a final zeolite membrane through a calcination process, has problems in that cost competitiveness and commercialization are decreased due to high synthesis costs and complex fabrication steps. To overcome these problems, in the present invention, a continuous CHA type zeolite membrane was fabricated in a cost-effective manner without a calcination process by preparing a CHA type zeolite membrane by use of an alkali metal hydroxide without using an organic structure directing agent.

[0039] Therefore, in one aspect, the present invention is directed to a method of fabricating an organic structure directing agent-free CHA type zeolite membrane, comprising: (a) forming a seed layer by depositing particles having a CHA structure on a support; and (b) fabricating a CHA type zeolite membrane by hydrothermally synthesizing the support on which the seed layer is formed in a synthetic precursor solution containing an alkali metal hydroxide (MOH wherein M is an alkali metal) and silica.

[0040] FIG. 1 shows a method of synthesizing a CHA type zeolite membrane through hydrothermal growth of seed particles and a seed layer by use of an alkali metal hydroxide without using an OSDA according to the present invention.

[0041] Microporous CHA type zeolite is very promising for carbon dioxide capture because of its appropriate pores with molecular dimensions for the preferential adsorption of carbon dioxide molecules. CHA type zeolite particles and membranes may be prepared by using a seeded growth method in the absence of an organic structure directing agent (OSDA) or template. Very cheap inorganic reagents (KOH, NaOH, and NaAlO.sub.2) were used as SDAs instead of the conventional OSDA, TMAdaOH, and thus a calcination step could be omitted. From an example performed to find appropriate and reliable conditions for obtaining continuous CHA type zeolite membranes, it was recognized that the formation of these membranes is a highly sensitive function of the Si/Al ratio in the synthetic precursor. Using an appropriate Si/Al ratio of ˜50, OSDA-free CHA type zeolite membranes can be manufactured with high reproducibility.

[0042] In the present invention, the synthetic precursor solution may be composed at a molar ratio of SiO.sub.2:NaAlO.sub.2:MOH:H.sub.2O=100:0 to 5:1 to 500:1000 to 100000, more preferably SiO.sub.2:NaAlO.sub.2:MOH:H.sub.2O=100:1 to 3:1 to 100:5000 to 15000, most preferably SiO.sub.2:NaAlO.sub.2:MOH:H.sub.2O=100:2:88:10000.

[0043] Herein, when NaOH and KOH are used simultaneously, the SiO.sub.2:NaAlO.sub.2:NaOH:KOH:H.sub.2O molar ratio of the synthetic precursor solution may be 100:0 to 5:10 to 500:1 to 100:1000 to 100000, more preferably 100:1 to 3:50 to 100:1 to 50:5000 to 15000, most preferably 100:2:70:18:10000.

[0044] Herein, the Si:Al molar ratio of the synthetic precursor solution may be 25 to 95, preferably 40 to 60, more preferably 45 to 55, most preferably 50.

[0045] In the present invention, examples of a silica precursor contained in the synthetic precursor solution includes monomer silica, tetraalkylorthosilicate, silica sol, silica gel, sodium silicate, fumed silica, and colloidal silica. Preferably, fumed silica may be used as the silica precursor, but is not particularly limited thereto and all the silica precursors commonly used in the art to which the present invention pertains can be used.

[0046] In addition, examples of an aluminum precursor include sodium aluminate (NaAlO.sub.2), aluminum isoproxide, aluminum nitrate hydrate, aluminum sulfate hydrate, and aluminum hydroxide. Preferably, sodium aluminate may be used as the aluminum precursor, but is not particularly limited thereto and all the aluminum precursors commonly used in the art to which the present invention pertains can be used.

[0047] An alkali metal in the alkali metal hydroxide may be selected from the group consisting of Li, Na, K, and mixtures thereof. Preferably, Na and/or K are/is used as alkali metal, and most preferably, Na and K are used simultaneously as alkali metal, but the scope of the present invention is not limited thereto.

[0048] In the present invention, the method may further include, after the hydrothermal synthesis of step (b), a step of drying the support.

[0049] In the present invention, the support may be one or more selected from the group consisting of alumina, polypropylene, polyethylene, polytetrafluoroethylene, polysulfone, polyimide, silica, glass, gamma alumina, mullite, zirconia, titania, yttria, ceria, vanadia, silicon, stainless steel, and carbon.

[0050] In the present invention, step (b) may be performed at a temperature of 100-250° C. for 12-120 hours, preferably 175° C. for 24-36 hours.

[0051] In the OSDA-free synthesis of particles in the present invention, an Si/Al ratio lower than or equal to ˜50 and a reaction time of ˜1 d make it possible to obtain high-purity CHA type zeolites. In contrast, a lower Al content and prolonged hydrothermal reaction time can lead to formation of undesired MOR type zeolite. In addition, synthetic conditions similar to those employed for particle synthesis may be directly extended to the intergrowth of an SSZ-13 seed layer in order to obtain OSDA-free CHA type zeolite membranes.

[0052] Further, it was found that a CHA type zeolite membrane having conventional performances through an inexpensive synthesis method without using an organic structure directing agent can obtained in the present invention.

[0053] The fabricated OSDA-free CHA type zeolite membranes showed maximum CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 separation factors of about 12.5±3.8 and about 28.8±6.9, respectively, with a moderate CO.sub.2 permeance of about 1×10.sup.−7 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1. Notably, under more realistic wet conditions (i.e., in the presence of H.sub.2O vapor), the separation performance at temperatures above 75° C. was comparable to that obtained under dry conditions, although permeation was hindered below 50° C., apparently due to the strong adsorption of H.sub.2O vapor.

[0054] Therefore, in another aspect, the present invention is directed to a CHA type zeolite membrane which is fabricated by the above-described method, is free of an organic structure directing agent, and has a continuous plane.

[0055] In still another aspect, the present invention is directed to a method of separating CO.sub.2 from a mixture containing CO.sub.2 and a small molecule, selected from the group consisting of CH.sub.4, N.sub.2, O.sub.2, C.sub.2H.sub.4, C.sub.2H.sub.6, C.sub.3H.sub.6 and C.sub.3H.sub.8, by using the above-described CHA type zeolite membrane.

[0056] In the present invention, the method of separating CO.sub.2 may be performed at 30-200° C. under dry conditions, and at 75-200° C. under moisture conditions.

[0057] The CO.sub.2 separation performance of M_50_1d is comparable with that of conventional CHA membranes obtained using OSDAs. Although no permeate was detected below −50° C., apparently due to inhibition by H.sub.2O under wet conditions, high CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 separation performances were achieved at a higher temperature of −75° C., where the strength of adsorption of H.sub.2O vapor was less pronounced. The CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 separation performances under wet conditions were well maintained up to ˜125 to 150° C. Long-term stability tests for the separation of CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 mixtures at 100° C. under wet conditions showed no noticeable degradation, supporting the high structural robustness of the OSDA-free CHA type zeolite membranes.

[0058] The OSDA-free CHA type zeolite membrane according to the present invention can be applied to CO.sub.2 (0.33 nm)/N.sub.2 (0.364 nm) separation necessary for post-combustion carbon capture. In particular, the OSDA-free CHA type zeolite membrane has an effect in that it can be applied to a continuous separation process as retaining the CO.sub.2/N.sub.2 separation performance although water is present in an exhaust gas after combustion. In addition, it can also be applied to CO.sub.2 (0.33 nm)/CH.sub.4 (0.38 nm) separation for obtaining selectively methane from a bio-gas or natural gas field. When benzene and hydrogen are produced by a direct conversion reaction of methane, hydrogen can be selectively separated to ensure a high methane conversion rate. Additionally, because the OSDA-free CHA type zeolite membrane can also be applied to the reduction of NOx in the exhaust gas of automobiles, it is expected to be highly likely to be applied to the atmosphere purification technologies.

[0059] Hereinafter, the present invention will be described in further detail with reference to examples. It will be obvious to a person having ordinary skill in the art that these examples are for illustrative purposes only and are not to be construed to limit the scope of the present invention.

Preparation Example 1: Synthesis of Conventional CHA Type Zeolite Particles (SSZ-13)

[0060] SSZ-13 seed particles were synthesized according to a conventional literature method by employing TMAdaOH (N,N,N-trimethyl-1-adamantammonium hydroxide) as an OSDA (H. Kalipcilar et al., Chem. Mater. 14 (2002) 3458-3464, U.S. Pat. No. 4,544,538).

[0061] Specifically, certain amounts of TMAdaOH (SACHEM Inc.), NaOH (Sigma-Aldrich), Al(OH).sub.3 (Sigma-Aldrich), and fumed silica (Cab-O-Sil M5, Cabot) were sequentially added to deionized water. The final molar composition was 20 NaOH: 5 Al(OH).sub.3: 100 SiO.sub.2: 4400 H.sub.2O: 20 TMAdaOH. This precursor was thoroughly mixed in a shaking machine overnight and then poured into a Teflon liner. The Teflon liner was placed in a stainless steel autoclave. The hydrothermal reaction was carried out at 160° C. for 4 days under rotation in a forced convection oven. After completing the hydrothermal reaction, the resulting solid particles were recovered by a combination of centrifugation, decanting, and washing with fresh deionized water. Calcination was performed at 550° C. at a ramp rate of 1° C./min under air flow at 200 cc/min. These SSZ-13 particles were used as seeds in the synthesis of OSDA-free CHA type zeolite particles and membranes. For convenience, conventional SSZ-13 particles, obtained using TMAdaOH as an OSDA, were used as a reference and are hereinafter denoted as C-SSZ-13 particles.

Preparation Example 2: Synthesis of OSDA-Free CHA Type Zeolite Particles

[0062] Along with the C-SSZ-13 particles, the present inventors synthesized OSDA-free CHA type zeolite particles via the seeded growth method. Here, the C-SSZ-13 particles played the role of nuclei, while the alkali metal cations (Na.sup.+ and K.sup.+) were used as inorganic SDAs to grow the CHA type zeolite particles from the seed particles. Specifically, the C-SSZ-13 particles were added to a synthetic precursor with a molar composition of x NaAlO.sub.2 (Sigma-Aldrich, Al (50-56 wt %): Na (40-45 wt %)): 70 NaOH (Sigma-Aldrich): 18 KOH (Sigma-Aldrich): 10000 H.sub.2O (x=0, 1, 2, and 5, corresponding to nominal Si/Al ratios of ∞, 100, 50, and 20, respectively). For preparation of the synthetic precursor, certain amounts of NaOH (pellet form), KOH (pellet form), NaAlO.sub.2, and fumed silica (Cab-O-Sil M5, Cabot) were added to deionized water. To form a homogeneous precursor, the mixture was further blended on a shaking machine for 2 days. After the mixture became homogeneous and almost translucent, about 0.1 g of the C-SSZ-13 particles was added to 30 g of the synthetic precursor, followed by additional mixing with the shaking machine for 1 day. The final mixture was poured into a Teflon liner and the Teflon liner was moved to a stainless steel autoclave for reaction. The hydrothermal reaction was carried out at 175° C. for different times (1, 2, and 3 days) under rotation in a forced convection oven. After completing the hydrothermal reaction by quenching with tap water, the solid particles, synthesized in the absence of OSDAs, were recovered by repeated centrifugation, decanting, and washing with deionized water. For convenience, the resulting particles are referred to as P_x_yd, where P represents the OSDA-free particles and x and y indicate the nominal Si/Al ratio and hydrothermal reaction time (in days), respectively.

Preparation Example 3: Synthesis of OSDA-Free CHA Type Zeolite Membranes

[0063] Porous α-alumina discs with a thickness of about 2 mm and a diameter of about 22 mm were prepared according to a method reported in other study (J. Choi, et al., Adsorption 12 (2006) 339-360) and were used as supports for the OSDA-free CHA type zeolite membranes. The C-SSZ-13 particles prepared in Preparation Example 1 were deposited on α-alumina discs via dip-coating. Prior to dip coating, a seed suspension was prepared by adding about 0.05 g of the C-SSZ-13 particles to about 40 ml of ethanol, followed by sonication for about 20 minutes. One side of the α-alumina disc, which was previously polished with a sand paper, was brought into contact with the seed suspension for 30 seconds, and the disc was withdrawn from the seed suspension and dried for 30 seconds under ambient conditions. This dip-coating procedure was repeated four times in order to cover the disc surface. The C-SSZ-13 particles deposited on the α-alumina disc were calcined at 450° C. for 4 hours at a ramp rate of 1° C./min under air flow at 100 cc/min. For secondary growth, a synthetic precursor was prepared using the same procedure used for synthesis of the OSDA-free particles in Preparation Example 2. Accordingly, the synthetic precursor included 100 silica: 70 NaOH: 18 KOH: x NaAlO.sub.2 (x=0, 1, 2, and 5): 10000 H.sub.2O by mole. The α-alumina disc with the seeded side facing down was placed in a tilted position in a Teflon liner, and the prepared synthetic precursor was then added. The Teflon liner was mounted in an autoclave. The hydrothermal reaction for secondary growth was carried out at 175° C. for a certain period under static conditions; the oven temperature was increased from room temperature to the target temperature (175° C.) at a rate of about 5° C./min. The final reaction duration includes the time for heat ramping. After a fixed hydrothermal reaction time, the reaction was quenched by immersing the autoclave under tap water. The recovered membrane samples were washed with deionized water, and then soaked in deionized water overnight to remove undesired impurities. Subsequently, the membrane samples were slowly dried at room temperature over 3 days and further dried at 100° C. in an oven before performing the gas permeation experiment. For convenience, the resulting membrane samples are referred to as M_x_yd, similar to the nomenclature adopted for the particle samples in Preparation Example 2.

Example 1: Analysis of Morphology of OSDA-Free CHA Type Zeolite Particles

[0064] Scanning electron microscope (SEM) images were obtained using a Hitachi S-4300 instrument, and the surfaces of all the particle and membrane samples were Pt-coated at 15 mA for 100 seconds. X-ray diffraction (XRD) patterns were obtained using a Rigaku Model D/Max-2500V/PC diffractometer (Japan) with Cu K.sub.α radiation (λ=0.154 nm). The simulated XRD patterns of CHA and MOR zeolites were obtained using the Mercury software (available from the Cambridge Crystallographic Data Centre; CCDC) with a crystallographic information file (CIF) that was downloaded from the International Zeolite Association (IZA). N.sub.2 adsorption isotherms of some particle samples were obtained at 77 K by use of an ASAP 2020 instrument (Micromeritics Inc.). Fluorescent confocal optical microscopy (FCOM) analysis was performed according to the method described in the literature, except for the use of a solid state laser with a wavelength of 488 nm as a source (E. Kim et al., J. Mater. Chem. A 5 (2017) 11246-11254). For structural analysis of the CHA type zeolites, X-ray diffraction data were collected in reflection mode using a Rigaku Model D/MAX Ultima III instrument (Japan) with Cu K.sub.α radiation (λ=0.154 nm). The accelerating voltage and current were 40 kV and 40 mA, respectively. Data for the sample were obtained at room temperature in flat-plate mode with a step size of 0.02° for a scan time of 10 seconds per step over the 2θ range of 2 to 100°. The diffraction patterns were indexed using the DICVOLO6 program implemented in the FullProf program suite (A. Boultif et al., J. Appl. Cryst. 37 (2004) 724-731; J. Rodriguez-Carvajal, Physica B 192 (1993) 55-69). The initial structure of the framework of the CHA type zeolite, acquired from the Database (http://www.iza-structure.org/databases/) of Zeolite Structures, was utilized for Le Bail refinement to determine lattice parameters (A. Le Bail, Powder Diffr. 20 (2005) 316-326). Le Bail refinement was performed using the Rietveld method in the JANA2006 package (V. Petřiček et al., Z. Kristallogr. 229 (2014) 345-352). The low angle XRD diffraction data below 5° was excluded for the Le Bail refinement owing to the large background component. Separation of CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 mixtures by using the OSDA-free CHA type zeolite membranes was conducted using a home-made permeation system in the Wicke-Kallenbach mode; the total pressure of both the feed and permeate sides was held at about 1 atm. The partial pressures of CO.sub.2 and N.sub.2 (or CH.sub.4) in the CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 mixtures used for the permeation tests under dry feed conditions were 50.5 kPa and 50.5 kPa, respectively (referred to as DRY CO.sub.2/N.sub.2 or DRY CO.sub.2/CH.sub.4, respectively), while the partial pressures of CO.sub.2, N.sub.2 (or CH.sub.4), and H.sub.2O used for the CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 separation tests under wet feed conditions were 49 kPa, 49 kPa, and 3 kPa, respectively (referred to as WET CO.sub.2/N.sub.2 or WET CO.sub.2/CH.sub.4, respectively). The flow rate of the feed mixture and the He sweep was maintained at about 100 mL.Math.min.sup.−1. As an internal standard for reliable gas chromatographic analysis, about 5 mL.Math.min.sup.−1 of CH.sub.4 for the CO.sub.2/N.sub.2 mixtures and of H.sub.2 for the CO.sub.2/CH.sub.4 mixtures were added to the permeate stream carried to a gas chromatograph (GC) column by the He sweep gas. A GC (YL 6100 GC system, YOUNG LIN, South Korea) equipped with a packed column (6 ft×⅛″ Porapak T) and a thermal conductivity detector (TCD) was used for on-line detection of the CO.sub.2/N.sub.2 permeates, whereas a GC (YL Instrument, 6500 GC System) equipped with a capillary column (30 m×0.320 mm GS-GasPro) and a pulsed discharge ionization detector (PDD) was used for on-line detection of the CO.sub.2/CH.sub.4 permeates.

[0065] FIG. 2 shows SEM images of the particles obtained using the seeded growth method in the absence of TMAdaOH as an OSDA; the Si/Al ratios and reaction times were varied. FIG. 2 shows SEM images of P_20 (1.sup.st row), P_50 (2.sup.nd row), P_100 (3.sup.rd row), and P_∞ (4.sup.th row) for various synthesis times of 1 (1.sup.st column), 2 (2.sup.nd column), and 3 d (3.sup.rd column). Yellow arrows are used to indicate particles of other phases. Blue dashed lines are used to designate the different morphologies of the obtained particles shown in (c2), (c3), and (d3). All scale bars represent 5 μm.

[0066] FIG. 13 shows SEM images of (a) C-SSZ-13 seed particles and (b) a seed layer obtained by applying a dip coating method to the particles shown in (a). The smaller particles (<about 700 nm) in (a) were selectively deposited on supports because bulkier particles were allowed to precipitate from a suspension. In FIG. 13(c), the simulated XRD pattern of all-silica CHA type zeolite is shown, and the asterisk (*) indicates the peak of the α-Al.sub.2O.sub.3 disc.

[0067] In all cases, the morphologies and sizes of the OSDA-free particles were different from those of the C-SSZ-13 particles (FIG. 13), which were added to serve as seeds for the seeded growth. This difference suggests that the C-SSZ-13 seed particles underwent decomposition during the seeded growth. For the 1-day seeded growth, while P_20_1d was mainly composed of aggregated plate-like particles ((a1) in FIG. 2), P_x_1d (x=50, 100, and ∞) was composed of small, irregular-shaped grains ((b1) to (d1) in FIG. 2). For a longer duration of 2 days, P_20_2d and P_50_2d ((a2)-(b2) in FIG. 2) had small, irregular-shaped grains, similar to P_x_1d (x=50, 100, and ∞). On the contrary, P_100_2d was composed of sharp, plate-like particles with minor needle-like particles ((c2) in FIG. 2), similar to the morphology of MOR zeolites reported in the prior art (P. Sharma et al., J. Colloid Interf. Sci. 325 (2008) 547-557), whereas P_∞_2d was still comprised of small, irregular-shaped grains (similar to P_∞_1d), though some undefined, large particles were observed, as indicated by the yellow arrow in (d2) of FIG. 2. A longer duration of 3 days resulted in a pronounced change in the morphology of the resulting particles ((b3)-(d3) of FIG. 2). Specifically, P_x_3d (x=100 and ∞) was likely to grow into larger particles with a more defined morphology, while the particles of P_20_3d still had the small, irregular shape, and P_50_3d contained some larger particles (indicated by yellow arrows in (b3) of FIG. 2). The estimated yields of all the syntheses are summarized in Table 1 below. The yields for the syntheses with nominal Si/Al ratios of 100 and ∞ suggest little or no seeded growth after 1 day, whereas a longer duration led to larger particles with sharp edges (see (c1)-(c3) and (d1)-(d3) of FIG. 2). This change in the particle morphology might suggest a gradual change toward another zeolite phase. In contrast, in the syntheses with lower nominal Si/Al ratios (i.e., 20 and 50), the irregular-shaped morphology was preserved for up to 3 days and the corresponding yields increased monotonically (see (a1)-(a3) or (b1)-(b3) of FIG. 2). This suggests preservation of the original zeolite phase and enhanced synthesis with time, though some impurities were co-generated, as indicated by the yellow arrows in (b3) of FIG. 2.

TABLE-US-00001 TABLE 1 Yields and zeolite structure types of P_20_xd, P_50_xd, P_100_xd, and P_∞_xd (x = 1, 2, and 3) Hydrothermal reaction time (days) 1 2 3 Yield Yield Yield (%).sup.a Phase (%).sup.a Phase (%).sup.a Phase P_20 15 CHA 19.1 CHA 33 CHA P_50 2.1 CHA 7.4 CHA + MOR.sup.d 37 CHA + MOR.sup.d P_100 N/A.sup.b CHA.sup.c 4.9 MOR 30 MOR P_∞ N/A.sup.b CHA.sup.c N/A.sup.b CHA.sup.c + MOR.sup.d N/A.sup.b MOR .sup.aYield: (increased weight after drying − seed amount)/silica amount in the precursor. .sup.bThe amount of particles recovered was less than the given seed amount (herein, 0.1 g) in the precursor. .sup.cA CHA phase seemingly resulted from the dissolution of the C-SSZ-13 seed particles during seeded growth. .sup.dA minor portion of MOR zeolite was present in the mixture of MOR and CHA type zeolite particles.

Example 2: Phase Evaluation of OSDA-Free Particles

[0068] FIG. 3 shows XRD patterns of the particles shown in FIG. 2; P_20, P_50, P_100, and P_∞ particles obtained at various synthesis times of (a) 1 day, (b) 2 days, and (c) 3 days. XRD pattern of C-SSZ-13 particles used as seeds is included in (a). The simulated XRD pattern of all-silica CHA type zeolite is included in (a)-(c), and the XRD pattern simulated for MOR zeolite is included in (b)-(c) for comparison. The arrows indicate the peak of MOR zeolite as a minor phase in P_50_2d, P_50_3d, and P_∞_2 d. The samples that contained the MOR zeolite as a major phase are indicated by MOR in parentheses next to the sample name. Gray dashed lines that indicate the XRD peaks of the (101) and (311) planes in the simulated XRD pattern of CHA type zeolites are included.

[0069] The 1-day seeded growth gave rise to pure CHA type zeolites (FIG. 3(a)) irrespective of the Si/Al ratio (i.e., P_x_1d; x=20, 50, 100 and ∞). The XRD pattern of P_100_1d showed a low signal-to-noise ratio, as compared with the patterns of P_20_1d and P_50_1d, indicating unfavorable growth of the zeolite in the former.

[0070] Furthermore, the XRD pattern of P_∞_1d indicated a lower degree of crystallization of the CHA type zeolite. For the cases of P_100_1d and P_∞_1d, the XRD patterns, as well as the very low yields, indicate that the C-SSZ-13 particles, which are supposed to serve as the seeds, were partially dissolved and/or collapsed instead of proceeding to crystal growth. Thus, the corresponding SEM image in FIG. 2(d1) reveals a morphology comprising dissolved and/or collapsed C-SSZ-13 seed particles. For the 2-day seeded growth, the present inventors found that P_20_2d had the pure CHA type zeolite, whereas P_100_2d and P_x_2d (x=50 and ∞) contained MOR zeolite as the major phase and a very small quantity of the MOR phase, respectively. After the longer reaction time of 3 days, the MOR zeolite phases were pronounced in P_x_3d (x=100 and ∞), whereas the phases of P_x_3d (x=20 and 50) were still comparable to those of P_x_2d (x=20 and 50). From the SEM images in FIG. 2, it can be concluded that some particles with a different morphology (indicated by yellow arrows in FIGS. 2(b3) and 2(d2)) were associated with the MOR zeolite particles and the particles with a more defined morphology shown in FIGS. 2(c2), 2(c3) and 2(d3) were MOR zeolite particles. From the various synthesis results, it appears that given the duration of seeded growth, a lower but finite Al content in the synthetic precursor favored transformation of the CHA structure into the MOR structure (i.e., P_100 series), indicating the important role of Al atoms in the synthesis of CHA type zeolite during OSDA-free synthesis. In addition, a longer reaction time resulted in phase transformation from CHA to MOR zeolites in the cases of P_50, P_100, and P_∞, though among them P_50 exhibited the lowest degree for phase transformation, also supporting the importance of Al content. This phase transformation may be correlated with the aforementioned pronounced morphological change observed in the SEM images (FIGS. 2(c1)-(c3) and 2(d1)-(d3)). This phase transformation is in good agreement with the previous report that a prolonged reaction time resulted in the synthesis of the undesired MOR type zeolite (H. Imai et al., Microporous Mesoporous Mater. 196 (2014) 341-348). From the SEM and XRD characterizations, the OSDA-free synthesis with nominal Si/Al ratios of less than and equal to ˜50 was appropriate for obtaining CHA type zeolite particles as the major phase using a reaction time of up to 3 days.

Example 3: Structural Properties of OSDA-Free CHA Particles

[0071] Among the synthesized particles, the present inventors chose three representative OSDA-free CHA particles (P_20_1d, P_20_2d, and P_50_1d) and further measured their N.sub.2 adsorption isotherms at 77 K, along with that of the C-SSZ-13 seed particles as a reference (FIG. 4). FIG. 4 shows N.sub.2 adsorption isotherms of (a) C-SSZ-13 seed particles, (b) P_20_1d, (c) P_20_2d, and (d) P_50_1d at 77 K. The filled and vacant symbols represent adsorption and desorption points, respectively.

[0072] The BET surface area of the SSZ-13 particles (740±3.8 m.sup.2.Math.g.sup.−1) was comparable to the reported values (611-775 m.sup.2.Math.g.sup.−1) (L. Sommer et al., J. Phys. Chem. C 115 (2011) 6521-6530). However, the BET surface areas of P_20_1d, P_20_2d, and P_50_1d were found to be lower at 557±2.0, 491±1.7, and 397±2.2 m.sup.2.Math.g.sup.−1, respectively. It appears that the OSDA-free synthesis led to a reduction of the effective pore size of the resulting particles, which could in turn be attributed to the cations (R. Zhou et al., Microporous Mesoporous Mater. 179 (2013) 128-135) present in the CHA type zeolite framework because of the low Si/Al ratio. Indeed, it was reported that the OSDA-free particles of small pore zeolites such as CHA, RHO and KFI tend to have a low Si/Al ratio (generally, Si/Al≤˜10)(M. Moliner et al., Chem. Mater. 26 (2014) 246-258; Y. Ji et al., Microporous Mesoporous Mater. 232 (2016) 126-137), and accordingly, contain a large amount of cations. Moreover, the N.sub.2 adsorption amounts of the OSDA-free CHA particles are lower than those of the CHA type zeolite and zeotype (SAPO-34) particles synthesized with organic templates (H. Imai et al., Microporous Mesoporous Mater. 196 (2014) 341-348; H. Shi et al., RSC Adv. 5 (2015) 38330-38333). Similarly, the three OSDA-free CHA type zeolite particles synthesized in the present invention also had low Si/Al ratios of about 4.1-4.2 and about 5.5 (Table 2) compared with their nominal Si/Al ratios of 20 and 50, respectively. Thus, it is reasonable to consider that cations compensating the charge balance of Al.sup.3+ in the framework were present inside the framework.

TABLE-US-00002 TABLE 2 Structural parameters of C-SSZ-13 particles, P_20_1d, P_20_2d, and P_50_1d estimated via the Le Bail Refinement and EDX data. BET Surface area Structural parameters EDX analysis (atomic %) (m.sup.2/g) a/{acute over (Å)} c/{acute over (Å)} V/{acute over (Å)}.sup.3 Na/Al K/Al Si/Al (Na + K)/(Si + Al) C-SSZ-13 740 ± 3.8 13.5920 (10) 14.7532 (15) 2360.4 (3) 0.45 — 23 0.02 particles P_20_1d 557 ± 2.0 13.776 (2) 14.894 (4) 2447.9 (9) 0.35 0.81 4.1 0.23 P_20_2d 491 ± 1.7 13.7580 (15) 14.859 (2) 2435.8 (5) 0.27 0.81 4.2 0.21 P_50_1d 397 ± 2.2 13.7670 (9) 14.8597 (12) 2439.1 (3) 0.49 0.90 5.5 0.21

[0073] The values of R.sub.P (profile factor) in the Le Bail Refinement for C-SSZ-13 seed particles, P_20_1d, P_20_2d, and P_50_1d were 4.31, 4.84, 5.45, and 4.83, respectively, while the GOF (Goodness of Fit) values in the same order were 7.18, 6.44, 7.33, and 5.91, respectively.

[0074] Furthermore, the changes in the cell parameters of the three OSDA-free CHA particles were also elucidated in an effort to comprehend their lower BET surface areas. The XRD peaks of the OSDA-free particles were generally shifted to lower 2θ values (FIGS. 3(a) and 3(b), and 14), indicating an expansion of the unit cell parameters.

[0075] FIG. 14 shows XRD patterns of C-SSZ-13 seed particles and three OSDA-free particles (i.e., P_20_1d, P_20_2d, and P_50_1d). The locations of XRD peaks of C-SSZ-13 particles are almost identical to those in the simulated XRD pattern (as indicated by red dashed lines), whereas those of the three OSDA-free particles shifted to lower 2θ values (as indicated by blue dashed lines).

[0076] A previous study (H. Imai et al., Microporous Mesoporous Mater. 196 (2014) 341-348) also reported a left shift of the XRD peaks of template-free CHA particles, though such phenomenon was not addressed or discussed. In the present invention, the present inventors further attempted to estimate the cell parameters of P_20_1d, P_20_2 d, and P_50_1d by using the Le bail refinement. This refinement revealed that all three particles had slightly longer lattice parameters in terms of the a (or b) axis and c axis than those of the C-SSZ-13 particles. This increase was presumably due to framework expansion, which in turn originated from electrostatic repulsion between the alkali cations in the pore structure; the Le bail refinement data for the C-SSZ-13 particles and the template-free CHA particles (P_20_1d, P_20_2d, and P_50_1d) are compared with their respective XRD patterns in FIGS. 15 to 18. The lattice expansion depends on the amount and/or size of cations present inside the zeolite pore structure (M. Martis et al., Phys. Chem. Chem. Phys. 15 (2013) 11766-11774). Given that the OSDA-free particles have lower BET surface areas, the alkali cations (here, Na.sup.+ and K.sup.+), which were presumably present in excess in the CHA type zeolite (Table 2), blocked the micropores and thus inhibited the diffusion of N.sub.2 into the pores (R. Zhou et al., Microporous Mesoporous Mater. 179 (2013) 128-135).

[0077] In general, the present inventors found that the actual Si/Al ratio of the OSDA-free particles determined by energy dispersive X-ray (EDX) analysis was not comparable to the nominal Si/Al ratio of the corresponding synthetic precursors. Instead, the OSDA-free particles were formed with higher Al content (the Si/Al ratios were approximately five times lower than those used for synthesis of the C-SSZ-13 particles). Accordingly, the concentration of cations in the three OSDA-free particles was estimated to be ten times higher than those in the C-SSZ-13 particles, and thus the effective pore size became smaller, resulting in the lower BET surface areas (Table 2). In addition, the insertion of excess cations into the porous structure of the CHA type zeolite was also reflected by the increased lattice parameters (Table 2). This implies that the synthesis of OSDA-free particles that maintain the intrinsic properties of the original SSZ-13 zeolite is quite challenging.

Example 4: Effect of Si/Al Ratio on Formation of OSDA-Free CHA Type Zeolite Membranes

[0078] The selective deposition of SSZ-13 particles with a size of about 700 nm (FIG. 13(a)) on α-alumina supports resulted in the formation of a uniform SSZ-13 seed layer (FIG. 13(b)), which is a pre-requisite for intergrowth to achieve continuous membranes. Among the four nominal Si/Al ratios (20, 50, 100, and ∞) used in the synthesis of the OSDA-free particles (FIGS. 2 and 3), it was recognized that secondary growth for the formation of a continuous membrane occurred only with the Si/Al ratio of 50, strongly supporting the critical role of the Si/Al ratio during seeded (or secondary) growth (FIG. 5). FIG. 5 shows top-view (left) and cross-sectional-view (middle) SEM images of (a1)-(a2) M_20_1d, (b1)-(b2) M_50_1d, (c1)-(c2) M_100_1d, and (d1)-(d2) M_∞_1d along with (a3)-(d3) the corresponding XRD patterns (right). Yellow arrows indicate the bare alumina region, where the seeded particles were not intergrown during secondary growth. The black scale bars represent 20 μm, and the asterisks (*) indicate the XRD peaks from the α-Al.sub.2O.sub.3a disc. Throughout the specification, the terms “seeded” and “secondary growth” are used interchangeably. In the case of M_20_1d, aggregated OSDA-free particles were formed throughout the surface (FIG. 5(a1)) but in a non-continuous way (FIG. 5(a2)). This could possibly be attributed to an overproduction of nuclei, seemingly generated from dissolution of the C-SSZ-13 seed particles under the low Si/Al ratio environment. In the case of M_50_1d, although some cracks were observed in the top-view SEM image (indicated by red arrows in FIG. 5(b1)), at the given SEM resolution, these cracks did not appear to be propagated into the interface between the film and support, as evidenced by the cross-sectional-view SEM image (FIG. 5(b2)). For M_100_1d, long, oval-shaped grains were formed in a non-continuous manner (FIGS. 5(c1) and 5(c2)). Accordingly, the bare α-alumina support was observed, as indicated by yellow arrows. Likewise, isolated thick, disc-like particles were observed in M_∞_1d where the bare α-alumina support was significantly exposed, as indicated by yellow arrows (FIG. 5(d1)). Under the latter two conditions (i.e., the Si/Al ratios of 100 and ∞), where the Al content in the synthetic precursors was apparently insufficient, continuous OSDA-free membranes could not be fabricated after secondary growth. In fact, this trend is consistent with the finding that the use of a lower Al ratio during synthesis of the OSDA-free particles hindered the formation of CHA type zeolite particles (FIGS. 2 and 3). The XRD patterns of the OSDA-free membranes, except for M_∞_1d, confirmed the CHA type zeolite structure (FIG. 5(a3)-5(c3)). In contrast, M_∞_1d included a different phase, namely, the MOR zeolite structure (FIG. 5(d3)), and thus the thick, disc-like particles can be regarded as MOR zeolite grains. This result also indicates that the lower amount of Al facilitated transformation and/or growth of undesired MOR zeolite structures from the C-SSZ-13 seed particles. Therefore, the amount of Al cations, i.e., an appropriate Si/Al ratio, is also a key factor for achieving continuous OSDA-free CHA type zeolite membranes via the secondary growth methodology. From the syntheses using various Si/Al ratios (in FIG. 5), it can be concluded that optimal, but unfortunately narrow-range, conditions are required for the synthesis of well-intergrown OSDA-free CHA type zeolite films; in particular, the conditions used for synthesis for M_50_1d were found to be optimal for the formation of a continuous film.

Example 5: CO.SUB.2./N.SUB.2 .Separation Performance of OSDA-Free CHA Membranes

[0079] The CO.sub.2/N.sub.2 separation performance of the membrane samples shown in FIG. 5 was investigated as a function of the temperature up to about 200° C. under dry conditions (FIG. 6). FIG. 6 shows the CO.sub.2/N.sub.2 separation performance of M_x_1d (x=(a) 20, (b) 50, (c) 100, and (d) ∞) as a function of temperature up to 200° C. under dry conditions. In all graphs, gray dashed lines represent a CO.sub.2/N.sub.2 SF of about 0.8, determined by the Knudsen diffusion. In addition, the red dashed lines, which represent a CO.sub.2/N.sub.2 SF of 10 (ideal selectivity determined from multiplication of permeation selectivity and diffusion selectivity), are included for eye guidance. M_20_1d (FIG. 6(a)) exhibited a maximum (max) CO.sub.2/N.sub.2 separation factor (SF) of about 1; considering a CO.sub.2/N.sub.2 SF of about 0.8 for the bare α-alumina support based on Knudsen diffusion, this performance can be regarded as extremely poor. In contrast, the max CO.sub.2/N.sub.2 SF of M_50_1d was as high as 12.5±3.8 at 75° C. (FIG. 6(b)). Because the max CO.sub.2/N.sub.2 SF was estimated to be about 20 by molecular simulation (S. Li et al., Ind. Eng. Chem. Res. 46 (2007) 3904-3911), the separation performance of M_50_1d indicates the feasibility of the template-free CHA membranes. It is noted that the permeance behavior of the CO.sub.2 and N.sub.2 molecules through M_50_1d was quite unique compared to that through the other CHA type zeolite membranes. In general, CHA type zeolite membranes exhibit a monotonic decrease of both the CO.sub.2 permeance and the corresponding CO.sub.2/N.sub.2 SF with increasing temperature under dry conditions, as adsorption-based separation is likely to be dominant (N. Kosinov et al., J. Mater. Chem. A 2 (2014) 13083-13092; X. Gu et al., Ind. Eng. Chem. Res. 44 (2005) 937-944). In contrast, the max CO.sub.2/N.sub.2 SF for M_50_1d was observed at 75° C., while the CO.sub.2 permeance increased monotonically from 30 to 100° C. This may be because the effective pore size of the OSDA-free CHA type zeolite was smaller than that of the C-SSZ-13 particles (FIG. 4). The additional increase in the nominal Si/Al ratio did not allow for the formation of a continuous membrane in the case of M_100_1d and M_∞_1d (FIG. 5(c1)-5(d1)), and thus neither membranes exhibited any separation ability for the CO.sub.2/N.sub.2 mixtures (FIG. 6(c)-6(d)). The N.sub.2 molecules, which are lighter than CO.sub.2 (N.sub.2 molecular weight (28) vs. CO.sub.2 molecular weight (44)), could permeate both membranes faster with a corresponding CO.sub.2/N.sub.2 SF of ˜0.8, indicative of dominant Knudsen diffusion.

Example 6: Effect of Hydrothermal Reaction Time on Formation of Continuous Membranes

[0080] Using the nominal Si/Al ratio of 50, the present inventors examined the effect of hydrothermal reaction times 0.5 days, 1.5 days and 2 days), since M_50_1d showed marked CO.sub.2/N.sub.2 separation performance (FIG. 6(b)). FIG. 6 shows SEM images of M_50_xd (x=(a) 0.5, (b) 1, (c) 1.5, and (d) 2) along with (e) their XRD patterns as well as the simulated XRD pattern of all-silica CHA type zeolite. Red arrows indicate some observed cracks. The black scale bars represent 10 μm, and the asterisks (*) indicate the XRD peak from the α-Al.sub.2O.sub.3 disc. For fair comparison, the intensity of the XRD peak corresponding to the α-Al.sub.2O.sub.3 disc was used to normalize the XRD patterns of the membrane samples.

[0081] The longer durations of 1.5 days and 2 days also resulted in the synthesis of continuous membranes with surface morphologies that were almost identical to that of M_50_1d (FIG. 7(b)-7(d)). However, the shorter duration of 0.5 days was not sufficient to complete the intergrowth of the seed particles, leading to the co-existence of string- and plate-like particles on the top surface (FIG. 7(a)). It appears that the plate-like particles were initially formed, along with a majority of string-like particles (FIG. 6(a)); further intergrowth formed continuous membranes (FIG. 7(b)-7(d)). Intriguingly, the string-like particles were observed irrespective of the secondary growth time (FIG. 7(a)-7(d)). In addition, some cracks, indicated by red arrows in FIG. 7(c)-7(d), were also found for M_50_xd (x=1.5 and 2). The corresponding XRD patterns shown in FIG. 7(e) confirm that all membranes obtained after secondary growth for 1-2 days had the pure CHA type zeolite structure with a minor left-shift of the XRD peaks, as previously observed in the XRD patterns of OSDA-free particles (FIG. 3 and Table 2).

[0082] Furthermore, the CO.sub.2/N.sub.2 separation performance of the series of samples obtained at different secondary growth times (M_50_xd; x=0.5, 1.5, and 2) was evaluated under dry conditions (FIG. 8). FIG. 8 shows CO.sub.2/N.sub.2 separation performance for M_50_xd (x=(a) 0.5 (b) 1, (c) 1.5, and (d) 2) under dry conditions. In all graphs, the gray dashed lines represent a CO.sub.2/N.sub.2 SF of about 0.8, determined from Knudsen diffusion, and red dashed lines, which represent a CO.sub.2/N.sub.2 SF of 10 (the ideal permeation selectivity determined from multiplication of the sorption selectivity and the diffusion selectivity), are included for eye guidance.

[0083] As expected from the similarity of the morphologies in the top-view SEM images (FIG. 7(b)-7(d)), the CO.sub.2/N.sub.2 separation performance of M_50_1.5d and M_50_2d were comparable to that of M_50_1d with the minor difference being the decreased permeance of CO.sub.2 and N.sub.2 molecules through the membranes. The reduction in the permeance observed in FIG. 8(b)-8(d) can be associated with the thicker membrane obtained with the increased synthesis time (FIG. 19). FIG. 19 shows cross-sectional-view SEM images and EDX-based Si and Al profiles of M_50_xd (x=(a1)-(a2) 0.5, (b1)-(b2) 1, (c1)-(c2) 1.5, and (d1)-(d2) 2). In (a1)-(d1) of FIG. 19, the estimated membrane thicknesses are given, and in (a2)-(d2), the Si and Al profiles were obtained along with the yellow lines.

[0084] Along with the SEM characterization (FIG. 7(a)), the constant CO.sub.2/N.sub.2 SF of about 0.8 for M_50_0.5d over the evaluated temperature range up to 200° C. also supports the incomplete intergrowth of the seed layer (FIG. 8(a)). From these multiple attempts, the present inventors could conclude that the secondary growth of the SSZ-13 seed layer with a synthetic precursor (with a nominal Si/Al ratio of about 50) for the duration of about 1 day is optimal for the fabrication of high-quality OSDA-free CHA membranes in a reproducible manner. Notably, synthesis of the OSDA-free CHA membranes requires a duration of about 1-1.5 days, which is comparable to about 2 days needed to acquire conventional SSZ-13 membranes using TMAdaOH as an OSDA (Y. Zheng et al., J. Membr. Sci. 475 (2015) 303-310). Despite the drawback that the smaller effective pore size of the template- or OSDA-free zeolite membranes results in lowered permeance (M. Pan et al., Microporous Mesoporous Mater. 43 (2001) 319-327), this simpler process based on template-free secondary growth is considerably beneficial for the realization of large-scale zeolite membrane manufacturing.

Example 7: Elucidation of Non-Zeolitic, Defective Structures

[0085] The present inventors investigated the structure of defects such as cracks and grain-boundary defects in the high-performance OSDA- or template-free membranes (here, M_50_1d) by using FCOM analysis.

[0086] FIG. 9(a)-9(e) show cross-sectional-view FCOM images of M_50_1d, and FIG. 9(f)-9(g) show top-view FCOM images of M_50_1d. The top-view FCOM images of FIG. 9(f)-9(g) were acquired from portions indicated by a yellow line of FIG. 9(a)-9(e). The cross-sectional-view FCOM images of FIG. 9(a)-9(e) were acquired from portions indicated by five yellowish green dashed lines of FIG. 9(f)-9(g).

[0087] Despite the lack of a calcination step, M_50_1d obviously had defects, mainly cracks, throughout the membrane surface as shown in FIG. 9, implying that the formation of defects could not be avoided. This suggests that the formation of defects was presumably due to insufficient intergrowth among the polycrystalline grains during the hydrothermal secondary growth (Z. Chen et al., J. Membr. Sci. 369 (2011) 506-513). The cross-sectional-view FCOM images reveal that two types of defects were present; (1) one type defect that propagated fully down to the interface between M_50_1d and the α-alumina support; and (2) the other type defect that existed near the surface, as respectively indicated by yellow and red arrows in FIG. 9. Although the defects that propagated fully down to the interface would deteriorate the membrane separation performance, the density of these defects was significantly lower than that of the defects present near the surface (indicated by the smaller number of yellow arrows in FIG. 9) and almost comparable to that in the high CO.sub.2 perm-selective DDR membrane (E. Kim et al., J. Mater. Chem. A 5 (2017) 11246-11254). Further analysis showed that most of the defect-free portions seemingly consisted of about 10-40 grains, as estimated from FIG. 20(a)-20(b). Desirably, almost no grain-boundary defects were observed around the individual grains in M_50_1d, as compared to the ˜10-30 μm thick MFI type zeolite membrane, which showed poor molecular sieving ability (M. A. Snyder et al., Microporous Mesoporous Mater. 76 (2004) 29-33). Moreover, the OSDA-free synthetic protocol allowed for the formation of well-intergrown membrane constituents (FIG. 30(c)-30(d)). In combination, these features indicate that the approach employing OSDA-free secondary growth is effective for avoiding the considerable generation of defects that serve as non-selective pathways along the membrane thickness. Thus, a continuous CHA membrane (here, M_50_1d) with good performance was obtained via the OSDA-free secondary growth method (FIG. 5(b1)-5(b3)), which should afford good-quality molecular sieving (FIG. 6(b)) primarily through the dominant zeolitic part.

Example 8: CO.SUB.2./N.SUB.2 .and CO.SUB.2./CH.SUB.4 .Separation Performances

[0088] Encouraged by the high CO.sub.2/N.sub.2 separation performance, the present inventors further examined the CO.sub.2/N.sub.2 separation performance of M_50_1d under wet conditions (FIG. 10(b)), as H.sub.2O vapor is the 3.sup.rd largest component in the flue gas stream generated from fossil fuel-fired power plants (D. M. D'Alessandro et al., Angew. Chem.-Int. Edit. 49 (2010) 6058-6082). FIG. 10 shows the CO.sub.2/N.sub.2 (upper; (a)-(b)) and CO.sub.2/CH.sub.4 (lower; (c)-(d)) separation performance of M_50_1d under dry (left) and wet (right) conditions as a function of temperature up to 200° C. Red dashed lines, which represent the CO.sub.2/N.sub.2 SF of 10 in (a)-(b) and CO.sub.2/CH.sub.4 SF of 17 in (c)-(d) (the ideal permeation selectivities determined from multiplication of the sorption selectivity and the diffusion selectivity), are included for eye guidance. Under wet conditions, no permeation of CO.sub.2, N.sub.2, and CH.sub.4 molecules could be detected (below the dark pink dashed line; detection limit) at the temperature lower than and equal to 50° C. (left side of the blue dashed line) in (b) and (d).

[0089] Considering that the removal of H.sub.2O vapor prior to membrane-based separation is energy-intensive (M. T. Snider et al., Microporous Mesoporous Mater. 192 (2014) 3-7), robust CO.sub.2-selective separation capacity of zeolite membranes, especially at about 50 to 75° C., is highly desirable. At moderate temperatures of 30 to 50° C., no permeation through M_50_1d was detectable at the limit of the TCD detector (estimated to be as low as about 1×10.sup.−9 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1), mainly due to strong inhibition by H.sub.2O vapor. Because of the prominent hydrophilic portion of M_50_1d, as supported by the EDX data in FIG. 19(b2), H.sub.2O vapor was preferentially adsorbed inside the CHA type zeolite and reduced the effective pore size, similar to the permeation behavior of NaY membranes under wet conditions (X. Gu et al., Ind. Eng. Chem. Res. 44 (2005) 937-944). Despite the negligible permeances up to about ° C., above 75° C., the capacity to separate CO.sub.2/N.sub.2 mixtures for WET CO.sub.2/N.sub.2 was recovered as the affinity for H.sub.2O adsorption was weakened. Notably, the max CO.sub.2/N.sub.2 SF of M_50_1d was as high as 10.0±1.0 at 125° C. with a corresponding CO.sub.2 permeance of 7.5×10.sup.−8 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1. Although the OSDA-free membrane would not be useful at low temperatures such as flue gas temperatures, this membrane can still be applied to CO.sub.2 separation under high temperature and wet feed conditions (R. Bredesen et al., Chem. Eng. Process. 43 (2004) 1129-1158; M. Ostwal et al., J. Membr. Sci. 369 (2011) 139-147). In fact, the representative temperature range of about 50 to 75° C. for the flue gas stream originates from the desulfurization process, which usually requires copious amounts of water for cooling (H. Zhai et al., Environ. Sci. Technol. 45 (2011) 2479-2485). Therefore, the CO.sub.2 perm-selective membrane (M_50_1d) can potentially be applied to CO.sub.2/N.sub.2 separation at higher temperatures (up to 150° C. as shown in FIG. 10(b)) prior to the desulfurization process.

[0090] In addition to the good CO.sub.2/N.sub.2 separation performance, M_50_1d showed a max CO.sub.2/CH.sub.4 SF as high as 28.8±6.9 at 30° C. under DRY CO.sub.2/CH.sub.4 (FIG. 10(c)). This value is larger than the max CO.sub.2/N.sub.2 SF (12.5), apparently due to the larger molecular size of CH.sub.4 (0.38 nm) relative to that of N.sub.2 (0.364 nm). Although the permeance of CO.sub.2 would be more strongly inhibited by the larger CH.sub.4, the present inventors found that for the CO.sub.2/N.sub.2 (FIG. 10(a)) and CO.sub.2/CH.sub.4 mixtures (FIG. 10(c)), the permeance of CO.sub.2 through the membrane was comparable, indicating the weak interaction of CO.sub.2 with CH.sub.4. However, it was noted that the CO.sub.2 permeance under WET CO.sub.2/CH.sub.4 was lower than that under WET CO.sub.2/N.sub.2, indicating that CO.sub.2 molecules are obviously more strongly inhibited by the larger CH.sub.4 molecules in the presence of H.sub.2O, as evident from FIG. 9(c)-9(d). As observed from the wet CO.sub.2/N.sub.2 permeation test, no permeance of CO.sub.2 and CH.sub.4 molecules was detected below 50° C. under wet conditions (the corresponding detection limit was approximated as 2×10.sup.−10 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1). Nevertheless, both molecules permeated the membrane above 75° C. (FIG. 10(d)). For WET CO.sub.2/CH.sub.4, the max CO.sub.2/CH.sub.4 SF and CO.sub.2 permeance were 11.3±2.4 and 6.2×10.sup.−9 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1 at 75° C., respectively. Considering the representative temperature of about 40 to 70° C. and water content of 3 to 6 vol % in the biogas stream (E. Favre et al., J. Membr. Sci. 328 (2009) 11-14), a slight increase of the feed temperature (for example, to 100-125° C.) is needed to secure modest CO.sub.2 permeance (6.2×10.sup.−8 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1 at 125° C.) with a marked CO.sub.2/CH.sub.4 SF (8.8) under wet conditions.

[0091] Comparison of Separation Performance with Literature Data

[0092] FIG. 11(a) shows CO.sub.2/N.sub.2 separation factor or selectivity vs. CO.sub.2 permeance for M_50_1d along with that of other zeolite membranes (SAPO-34, NaY, CVD-treated CHA, and SSZ-13) under both dry and wet conditions at 100-110° C. FIG. 11(b) shows the CO.sub.2/CH.sub.4 SF vs. CO.sub.2 permeance of M_50_1d along with those of other zeolite membranes (SAPO-34, SSZ-13, DDR); permeation tests were conducted at 20-30° C. and 100° C. under dry and wet conditions. In (a), the red dashed line, which represents a CO.sub.2/N.sub.2 SF of 10, is included for eye guidance, while in (b), the red dashed lines represent CO.sub.2/CH.sub.4 SFs of 10 and 20. In (a), the solid arrows indicate the change in the separation performance from those under dry conditions to those under wet conditions. In (b), the dashed arrows indicate the temperatures during separation performance measurement from low (20-30° C.) to high (100° C.).

[0093] FIG. 11(a) presents a comparison of the CO.sub.2/N.sub.2 separation performance of M_50_1d with those of documented zeolite membranes under both dry and wet conditions. In coal-fired power plants, the operation spans a wide temperature range from the coal-fired boiler temperature (about 1100-1600° C.) to the stack gas temperature (about 50-75° C.) (R. Quinn et al., Ind. Eng. Chem. Res. 51 (2012) 9320-9327). Herein, the membrane performance was evaluated in the range of 100 to 110° C., which corresponds to that expected prior to the flue gas desulfurization process. As mentioned above, at the selected temperatures, M_50_1d showed marked CO.sub.2 perm-selectivity under WET CO.sub.2/N.sub.2. In this temperature range, FAU (X. Gu et al., Ind. Eng. Chem. Res. 44 (2005) 937-944) and CVD-treated CHA (E. Kim et al., Environ. Sci. Technol. 48 (2014) 14828-14836) zeolite membranes had a trade-off between the separation performance under dry and wet conditions, exhibiting high CO.sub.2 permeance and low CO.sub.2/N.sub.2 SF under dry conditions vs. low CO.sub.2 permeance and high CO.sub.2/N.sub.2 SF under wet conditions. This suggests that at the high temperature of about 100° C., H.sub.2O molecules could still be adsorbed in the membranes and hamper the permeation of CO.sub.2. More importantly, the permeance of the larger N.sub.2 molecule was further decreased, mainly due to inhibition by the adsorbed H.sub.2O molecules. This difference in the degree of inhibition by the adsorbed H.sub.2O molecules led to an increase in the CO.sub.2/N.sub.2 SF under wet conditions. In contrast, M_50_1d, as well as SAPO-34 (S. Li et al., Ind. Eng. Chem. Res. 49 (2010) 4399-4404) and SSZ-13 (N. Kosinov et al., J. Mater. Chem. A 2 (2014) 13083-13092) membranes, exhibited different permeation behavior, in which the CO.sub.2/N.sub.2 SFs were comparable under both dry and wet conditions, whereas under wet conditions, the CO.sub.2 and N.sub.2 permeance both decreased to a similar extent relative to the corresponding values under dry conditions. The fact that the CO.sub.2/N.sub.2 SF (about 8.8) of M_50_1d at about 100° C. under dry conditions was almost twice as large as those of the FAU and CVD-treated CHA type zeolite membranes suggests a lower degree of non-zeolitic defects. Notably, the CO.sub.2/N.sub.2 separation performance of M_50_1d was comparable to that of the SAPO-34 membrane obtained by using TEAOH and dipropylamine as OSDAs (S. Li et al., Ind. Eng. Chem. Res. (2010) 4399-4404), making it promising for practical use under harsh conditions.

[0094] The present inventors further compared the CO.sub.2/CH.sub.4 separation performance of M_50_1d with those of other membranes (SSZ-13 (H. Kalipcilar et al., Chem. Mater. 14 (2002) 3458-3464; N. Kosinov et al., J. Mater. Chem. A 2 (2014) 13083-13092), DDR(S. Himeno et al., Ind. Eng. Chem. Res. 46 (2007) 6989-6997), and SSZ-13 membranes (S. Li et al., J. Membr. Sci. 241 (2004) 121-135)) (FIG. 11(b)). For FIG. 11(b), the present inventors considered the CO.sub.2/CH.sub.4 separation performance at 20-30° C. and 100° C. It was noted that both M_50_1d and other CHA and DDR membranes showed good CO.sub.2/CH.sub.4 separation performance under dry conditions. When the feed temperature was increased from 20-30° C. to 100° C., the CO.sub.2/CH.sub.4 SF and the CO.sub.2 permeance of the SSZ-13, SAPO-34, and DDR membranes concomitantly decreased; specifically, the CO.sub.2/CH.sub.4 SFs were decreased by almost half. On the contrary, M_50_1d showed a different behavior, whereby the CO.sub.2 permeance increased without any noticeable degradation of the CO.sub.2/CH.sub.4 SF.

[0095] The CO.sub.2/CH.sub.4 separation performance of M_50_1d under the wet condition was inferior to that of the other SSZ-13 membrane at about 100° C., mainly because of the above-mentioned significant hindrance by the adsorbed H.sub.2O molecules. The degree of degradation of the membrane performance under WET CO.sub.2/CH.sub.4 was much higher for M_50_1d, for which the Si/Al ratio was presumably lower than that of others. Nevertheless, at the higher temperature of 100° C., where the adsorption of H.sub.2O molecules is weakened, the membrane exhibited good separation performance under WET CO.sub.2/CH.sub.4 with a CO.sub.2/CH.sub.4 SF as high as about 10 at 100° C. To be attractive for large-scale use, the reduced CO.sub.2 permeance of M_50_1 under WET CO.sub.2/CH.sub.4 could be increased by adopting high-flux, asymmetric supports (J. Hedlund et al., Microporous Mesoporous Mater. 52 (2002) 179-189).

[0096] In addition, the performance was compared with those of conventional membranes by use of the Robeson upper bound as shown in FIG. 21. The membrane according to the present invention showed high CO.sub.2 permeability and high separation factor even in the presence of CO.sub.2/N.sub.2, and showed separation performance above the Robeson upper bound even in the presence of CO.sub.2/CH.sub.4.

Example 9: Long-Term Stability of OSDA-Free CHA Membranes

[0097] The long-term stability of M_50_1d was evaluated at 100° C. under the wet condition for a sufficiently long duration (3 days) under laboratory settings (FIG. 12(a)) to ensure its robust use of CO.sub.2/N.sub.2 separation. FIG. 12 shows the results of evaluating the long-term stability of M_50_1d for the separation of (a) CO.sub.2/N.sub.2 and (b) CO.sub.2/CH.sub.4 binary mixtures under the wet condition at 100° C. for 72 hours.

[0098] During the continuous measurements, the CO.sub.2/N.sub.2 separation performance was well maintained without any pronounced degradation, suggesting preservation of the structural integrity of the CHA type zeolite in the presence of H.sub.2O. Specifically, the average CO.sub.2/N.sub.2 SF at 100° C. was 10.9±0.3 and the average CO.sub.2 permeance was 6.3×10.sup.−8 mol.Math.m.sup.−2.Math.s.sup.−1.Math.Pa.sup.−1. Furthermore, a long-term stability test of M_50_1d up to 3 days, carried out in order to evaluate the reliability of the CO.sub.2/CH.sub.4 separation ability at 100° C. under the wet condition, did not indicate any significant degradation, also supporting the high structural robustness of M_50_1d (FIG. 12(b)). Here, the present inventors emphasize that the high long-term stability of M_50_1d supports the effectiveness of the approach based on the template- or OSDA-free secondary growth as observed for other membranes that showed stabilities for water/ethanol separation (Y. Hasegawa et al., J. Membr. Sci. 347 (2010) 193-196; R. Zhou et al., Microporous Mesoporous Mater. 179 (2013) 128-135) and CO.sub.2/CH.sub.4 separation (H. Shi et al., RSC Adv. 5 (2015) 38330-38333).

INDUSTRIAL APPLICABILITY

[0099] According to the present invention, when membranes are synthesized using CHA type zeolite particles suitable for carbon dioxide separation without using organic structure directing agents, CHA type zeolite membranes can be fabricated in a cost-effective manner without a calcination process using an inexpensive alkali metal hydroxide instead of an organic structure directing agent.

[0100] In addition, CHA type zeolite membranes can be synthesized without using an organic structure directing agent depending on optimal synthesis conditions according to various synthesis conditions and reaction times. The CHA type zeolite membrane free of an organic structure directing agent, synthesized under the optimal synthesis conditions, has an effect of exhibiting CO.sub.2/N.sub.2 and CO.sub.2/CH.sub.4 separation performances similar to those of conventional CHA separation membranes.

[0101] Although the present invention has been described in detail with reference to the specific features, it will be apparent to those skilled in the art that this description is only for a preferred embodiment and does not limit the scope of the present invention. Thus, the substantial scope of the present invention will be defined by the appended claims and equivalents thereof.