RU2748421C1 - Mesoporous adsorption material for separation of saturated and unsaturated hydrocarbons - Google Patents

Abstract

FIELD: adsorption materials.SUBSTANCE: mesoporous adsorption material for the separation of saturated and unsaturated hydrocarbons is described, which is a family of five isostructural organometallic coordination polymers with the general formula [Zn12(iph)6(glycol)6(dabco)3], where iph2-is an isophthalate, dabco is 1,4-diase[2.2.2]bicyclooctane, glycol is deprotonated polyatomic alcohol: ethylene glycol, 1,2-propanediol, 1,2-butanediol, 1,2-pentanediol, glycerin.EFFECT: invention is aimed at producing materials that are selective to saturated hydrocarbons.1 cl, 2 dwg, 4 tbl

Description

The invention relates to the chemical industry, in particular to adsorption technologies designed to separate saturated (ethane) and unsaturated (ethylene, acetylene) hydrocarbons, including can be used in the production of high-purity ethylene for the polymer industry by purifying it from ethane, as well as for storage of gases and their separation.

Organometallic coordination polymers (MOCPs), composed of metal ions and bridging organic ligands, have attracted a lot of attention in recent decades due to their structural properties, such as large specific surface area, customizable pore architecture and permanent porosity, favorable for many topical applications such as , like storage of gases and their separation.

Ethylene is an important raw material for the chemical industry, producing millions of tons annually. It is usually obtained by steam cracking and thermal decomposition of naphtha or ethane, followed by distillation purification, primarily from ethane. Separation of C ₂ H ₆ / C ₂ H ₄ can potentially be carried out using adsorption technologies, which have several advantages over conventional distillation. The development of porous materials with both high adsorption selectivity C ₂ H ₆ / C ₂ H ₄ and high sorption capacity for ethane is of great practical importance.

Most of the MOCFs synthesized to date have a microporous structure, i.e. the pore size is less than 2 nm, which significantly narrows the possible fields of application of these compounds. The number of mesoporous MOCFs, i.e. having a pore size greater than 2 nm, significantly less. At the same time, such MOCFs look very promising due to the increased surface area and facilitated mass transfer of substrate molecules through the pores, which improves their catalytic and adsorption properties.

We have published (AA Lysova, D G. Samsonenko, PV Dorovatovskii, VA Lazarenko, VN Khrustalev, KA Kovalenko, DN Dybtsev, VP Fedin, J. Am. Chem. Soc. 2019, 141, 17260-17269) a series of five isostructural three-dimensional (3D) MOCP [Zn ₁₂ (tdc) ₆ (glycol) ₆ (dabco) ₃ ] (tdc ^2- = thiophene-2,5-dicarboxylate; glycol = deprotonated polyhydric alcohol; dabco = 1,4-diaza [2.2.2 ] bicyclooctane) based on twelve-core wheel-shaped building blocks, referred to below as the NIIC-10 series. The compounds are microporous MOCPs with straight channels of variable size (∅ 4.9–1.8 Å), depending on the length of the polyhydric alcohol residue. The NIIC-10 series has demonstrated several remarkable properties, including excellent adsorption selectivity to hydrocarbons. In particular, these compounds showed a high selectivity of ethane sorption with respect to ethylene or cyclohexane with respect to benzene.

However, the NIIC-10 family belongs to substances with a microporous structure and limited adsorption capacity, therefore, it should be improved.

The objective of the invention is the creation of mesoporous adsorption materials with selectivity to saturated hydrocarbons (ethane) in relation to unsaturated hydrocarbons (ethylene, acetylene).

EFFECT: obtained compounds (NIIC-20) intended for the separation of ethane and ethylene, as well as ethane and acetylene, having a high specific surface area and rarely observed inverse selectivity of sorption of saturated hydrocarbons (ethane) in relation to unsaturated hydrocarbons (ethylene, acetylene) ... The corresponding adsorption factors of selectivity according to IAST (Ideal Adsorption Solution Theory) reach values of 15.4 for C ₂ H ₆ / C ₂ H ₄ and 10.9 for C ₂ H ₆ / C ₂ H ₂ equimolar gas mixtures at room temperature, exceeding the values for any other porous MOCPs described so far and intended for the separation of ethane-ethylene and ethane-acetylene mixtures.

The problem was solved by creating a mesoporous adsorption material representing a family of five isostructural organometallic coordination polymers (MOCP), the general formula [Zn ₁₂ (iph) ₆ (glycol) ₆ (dabco) ₃ ], where iph ^2- = isophthalate, dabco = 1, 4-diaza [2.2.2] bicyclooctane, glycol = deprotonated polyhydric alcohol (ethylene glycol, EtO _2, NIIC-20-Et; 1,2-propanediol, PrO _2, NIIC-20-Pr; 1,2-butanediol, BuO ₂ , NIIC-20-Bu; 1,2-pentanediol, PeO ₂ , NIIC-20-Pe; glycerol, GlO ₂ , NIIC-20-GI).

As well as the NIIC-10 series, the NIIC-20 are based on 12-core {Zn ₁₂ (RCOO) ₁₂ (glycol) ₆ } wheel units and thus inherit the remarkable selectivity of preferred adsorption of ethane to ethylene. Moreover, the mesoporous NIIC-20 exhibits a higher adsorption capacity with respect to gases. With record C ₂ H ₆ / C ₂ H ₄ adsorption selectivity and high ethane adsorption capacity, the NIIC-20 series convincingly outperforms porous MOCBs known today for ethylene purification applications.

Synthesis and description of the structure.

Colorless crystals of compounds of the NIIC-20 series were obtained by heating a mixture of Zn (NO ₃ ) ₂ ⋅6H ₂ O, isophthalic acid (H ₂ iph), and 1,4-diaz [2.2.2] bicyclooctane (dabco) in a mixture of N, N -dimethylformamide (DMF) and polyhydric alcohol (ethylene glycol, EtO ₂ H ₂ , for NIIC-20-Et; 1,2-propanediol, PrO ₂ H ₂ , for NIIC-20-Pr; 1,2-butanediol, BuO ₂ H ₂ , for NIIC-20-Bu; 1,2-pentanediol, FeO ₂ H ₂ , for NIIC-20-Pe; or glycerol, GlO ₂ H ₂ , for NIIC-20-Gl) at 130 ° С for 48 h with almost quantitative yields (94-99%). Synthesis details are described below. The chemical and phase purity of the obtained compounds was confirmed by the methods of chemical analysis, powder X-ray diffraction, thermogravimetric analysis, and IR spectroscopy.

Synthesis: A mixture of zinc (II) nitrate hexahydrate Zn (NO ₃ ) ₂ ⋅6H ₂ O (0.160 g, 0.539 mmol), isophthalic acid (H ₂ iph, 0.045 g, 0.271 mmol), 1,4-diaz [2.2.2 .] bicyclooctane (dabco, 0.015 g, 0.134 mmol) and N, N-dimethylformamide (DMF, 2.5 ml) were stirred on a magnetic stirrer for 1 h. Then 0.7 ml of the corresponding polyhydric alcohol (ethylene glycol for NIIC-20-Et , 1,2-propanediol for NIIC-20-Pr, 1,2-butanedtol for NIIC-20-Bu, 1,2-pentanediol for NIIC-20-Pe, and glycerol for NIIC-20-Gl), and the resulting solution heated in a closed vessel at 130 ° C for 2 days. Colorless hexagonal prismatic crystals were isolated, washed with DMF (3 × 3 ml) and air dried.

For NIIC-20-Et: Yield: 0.150 g (94%). Elemental analysis (calculation,%) for [Zn ₁₂ (iph) ₆ (CH ₂ OCH ₂ O) ₆ (dabco) ₃ ] ⋅14.7DMF, C _122.1 H _186.9 N _20.7 O _50.7 Zn ₁₂ : C 41.4, H 5.3, N 8.2; experiment: C 41.0, H 5.6, N 8.5.

For NIIC-20-Pr: Yield: 0.162 g (99%). Elemental analysis (calculation,%) for [Zn ₁₂ (iph) ₆ (CH ₂ OCHOCH ₃ ) ₆ (dabco) ₃ ] 15DMF, C ₁₂₉ H ₂₀₁ N ₂₁ O ₅₁ Zn ₁₂ : C 42.5, H 5.6, N 8.1; experiment: C 42.1, H 5.7, N 8.6.

For NIIC-20-Bu: Yield: 0.153 g (96%). Elemental analysis (calculation,%) for [Zn ₁₂ (tdc) ₆ (CH ₂ OCHOCH ₂ CH ₃ ) ₆ (dabco) ₃ ] ⋅12DMF⋅3H ₂ O, C ₁₂₆ H ₁₉₈ N ₁₈ O ₅₁ Zn ₁₂ : C 42.4, H 5.6, N 7.1; experiment: C 41.9, H 5.1, N 7.4.

For NIIC-20-Pe: Yield: 0.168 g (99%). Elemental analysis (calculation,%) for [Zn ₁₂ (iph) ₆ (CH ₂ OCHO (CH ₂ ) ₂ CH ₃ ) ₆ (dabco) ₃ ] ⋅14DMF⋅2H ₂ O, C ₁₃₈ H ₂₂₂ N ₂₀ O ₅₂ Zn ₁₂ : C 43.9, H 5.9, N 7.4; experiment: C 43.6, H 5.7, N 7.7.

For NIIC-20-G1: Yield: 0.146 g (94%). Elemental analysis (calculation,%) for [Zn ₁₂ (iph) ₆ (CH ₂ OCHOCH ₂ OH) ₆ (dabco) ₃ ] ⋅10.2DMF⋅4.5H ₂ O, C _114.6 H _177.4 N _16.2 O _50.7 Zn ₁₂ : C 39.6 , H 5.1, N 6.5; experiment: C 39.2, H 5.2, N 6.4.

Before carrying out the gas sorption experiment, preliminary activation of the NIIC-20-Et-NIIC-20-Gl compounds was carried out. The required amount of the corresponding MOCP was placed in 10 ml of CH ₂ Cl ₂ for 5 days. Every day the crystals were decanted and a new portion of CH ₂ Cl _{2 was} added. After 5 days, the crystals were decanted and dried under vacuum. The next activation step was carried out in a dynamic vacuum (10 ^-8 bar) at 60 ° C for 6 h.

Single crystal X-ray diffraction analysis of compounds NIIC-20-Et-NIIC-20-Gl showed a series of new MOCPs, similar in structure and composition, thus the crystal structure of only one compound from the series (NIIC-20-Et) will be described in detail here (Fig. 1a, b).

The asymmetric part of the NIIC-20-Et consists of two crystallographically independent Zn ^II centers. The tetrahedral center of Zn ^II binds two oxygen atoms of two iph ^2- anions and two oxygen atoms of two deprotonated polyhydric alcohol molecules. The second plane-pyramidal center of Zn ^II binds two oxygen atoms of two iph ^2- anions, two oxygen atoms of one deprotonated polyhydric alcohol molecule, and one nitrogen atom of the dabco molecule in the apical position. Twelve Zn ^II centers of these two types alternate with each other, forming a twelve-core wheel. Zinc cations bind together by twelve carboxylate groups along the outer arc of the ring and six glycolate dianions along the inner arc of the ring to form a building block {Zn ₁₂ (RCOO) ₁₂ (C ₂ H ₄ O ₂ ) ₆ } with an inner diameter of ~ 5.5 Å (Fig. 1a) ... These blocks bind to each other via two isophthalate ligands and one dabco molecule to form a complex 3D porous structure. It contains large cavities ~ 25 Å in diameter (Fig. 1b), each connected to eight others through portals - wheels {Zn ₁₂ }. In addition to nanocavities, the structure contains intersecting smaller channels 6 × 3.5Å formed by iph ^2- anions and dabco molecules, as well as rectangular windows 3.5 × 3.5Å in size, formed by four benzene rings of iph ^2- anions. The resulting structure possesses an nbo-h topology (Fig. 1c), not previously seen in the published literature.

Both the aperture and the chemical functionalization of the portals that bind the nanocavities depend on the polyhydric alcohol substituents. Longer hydrocarbon residues reduce the channel aperture and increase their hydrophobic nature, while glycerol introduces hydrophilicity due to the presence of a free OH group.

Thus, the functional properties of NIIC-20 mesoporous 3D MOCFs can be purposefully changed by varying the crystal structure.

The largest aperture of the Zn ₁₂ carboxylate wheel (~ 5.5Å) is observed in NIIC-20-Et, which has the smallest ethylene glycol molecules in its structure. The introduction of alkyl-substituted glycols (1,2-propanediol in NIIC-20-Pr, 1,2-butanediol in NIIC-20-Bu, 1,2-pentanediol in NIIC-20-Pe) into the MOCP structure significantly narrows the aperture of Zn wheels ₁₂ to ~ 1.8 Å (for NIIC-20-Pe) and increases their hydrophobic nature. The free space available for the NIIC-20-Et connection is estimated to be 63%. The pores of the newly synthesized compounds are filled with solvent molecules. The chemical composition and phase purity of each crystalline phase [Zn ₁₂ (iph) ₆ (glycol) ₆ (dabco) ₃ ] ⋅xDMF⋅yH ₂ O is confirmed by a set of analytical methods (powder X-ray diffraction, IR spectroscopy, chemical and thermogravimetric analyzes).

Texture characteristics. The textural properties of activated compounds from the NIIC-20 series were investigated by measuring the adsorption isotherms of N ₂ at 77 K. Freshly synthesized crystalline compounds were activated by exchanging guest solvent molecules for CH ₂ Cl ₂ for 5 days, evacuated at room temperature, and heated in a dynamic vacuum. (10 ^-8 bar) at 60 ° C for 6 hours. Powder X-ray diffraction data confirm the preservation of the crystalline phases after activation and their stability in subsequent gas adsorption experiments.

All compounds of this isostructural series showed reversible adsorption of N ₂ at 77 K, which confirms their porous nature. The N ₂ adsorption isotherms for NIIC-20-Et-NIIC-20-Gl can be classified as type IVb isotherms according to the official SHRAC classification, typical of micro / mesoporous materials with narrow mesopores, whose width is below the critical diameter. The pore size distribution was calculated from the adsorption isotherms of N ₂ at 77 K by the Quenched Solid DFT (QSDFT) method. The data confirm the mesoporous nature of NIIC-20-Et-NIIC-20-G1 with the largest pore diameter ~ 2.5 nm, which is consistent with the structural data.

The pore volumes were found from nitrogen adsorption at P / P ₀ = 0.95 and by DFT calculations. The data obtained are in good agreement with each other and with theoretical values estimated from the corresponding crystal structure, which indicates the completeness of the activation of the samples and their stability during adsorption. The specific surface area of the samples was calculated by the BET and DFT methods. The pore volumes and specific external surface area calculated by various methods for the compounds of the NIIC-20 series are presented in Table 1. As can be seen, the pore volumes for these compounds are expected to decrease with increasing length of the alkyl substituent of the glycol. The same trend is observed for the specific outer surface of the samples.

Gas adsorption of C ₂ hydrocarbons. Convinced of the permanent porosity of the NIIC-20 series, it was decided to investigate their adsorption properties with respect to C ₂ hydrocarbons (C ₂ H ₂ , C ₂ H ₄ , C ₂ H ₆ ).

The NIIC-10 microporous series, based on the {Zn ₁₂ } blocks, shows promising potential in the separation of gas mixtures, as the corresponding values of the adsorption selectivity factors C ₂ H ₆ / C ₂ H ₄ calculated according to IAST (Ideal Adsorption Solution Theory), and the sorption capacity of ethane is comparable to the available literature data. In order to find the application of the NIIC-20 for such applications, adsorption isotherms of C ₂ gases were measured at 273 and 298 K for P <800 Torr. All isotherms are completely reversible and belong to type I.

Using isotherm data, sorption capacities at 1 bar were calculated (Table 2). The adsorption capacities for ethane are in the range from 2.8 to 4.5 mmol g ^-1 at 273 K and from 2.1 to 2.5 mmol g ^-1 at 298 K. The average ethane capacity for mesoporous NIIC-20 increased by 50% (273 K) or 15% (298 K), compared to the microporous NIIC-10 series, which has the same decoration of the portals.

On the basis of fundamental thermodynamic data, the adsorption selectivity factors for binary gas mixtures (C ₂ H ₆ + C ₂ H ₄ and C ₂ H ₆ + C ₂ H ₂ ) were calculated by three different methods: i) as the ratio of adsorbed amounts; ii) as the ratio of Henry's constants that correspond to the slope of adsorption isotherms at very low partial pressures, S = K _H2 / K _H1 , and iii) according to IAST, which makes it possible to estimate the selectivity factors of gas mixtures of different compositions and at different total pressures, S = y ₂ ⋅x ₁ / (y ₁ ⋅x ₂ ) = x ₁ ⋅ (1-y ₁ ) / (y ₁ ⋅ (1-x ₁ )), where x _i is the molar fraction of component i in the adsorbed state, y _i is mole fraction of component i in the gas phase. The results of calculations of selectivity factors are summarized in Table 3.

Adsorption data unambiguously indicate the preferred adsorption of ethane over ethylene and acetylene for all compounds of the NIIC-20 series. The selectivity factors С ₂ Н ₆ / С ₂ Н ₄ according to IAST fall into the range S = 5.5 ÷ 18.8 at 273 K and S = 3.5 ÷ 15.4 at 298 K (Table 3) for equimolar gas mixtures. It is important to note that a real industrial mixture C ₂ H ₆ + C ₂ H ₄ , such as cracking gas, contains predominantly ethylene (C ₂ H ₆ / C ₂ H ₄ ≈1: 12 ÷ 1: 15), thus, Calculations of the adsorption selectivity at _yC2H6 = 0.07 will give a more adequate criterion for the potential use of the adsorbent in industry. It is noteworthy that the calculations of IAST for such conditions lead to even better selectivity factors of С ₂ Н ₆ / С ₂ Н ₄ , reaching S = 28.1 at 273 K and S = 24.0 at 298 K. The highest selectivity factor is С ₂ Н ₆ / С ₂ H ₄ is observed for NIIC-20-Bu having 1,2-butanediol in the wheel portal {Zn ₁₂ }. Probably, the ethyl residue leads to an ideal combination of window geometry and sufficient hydrophobicity for the realization of the strongest alkane-alkane intermolecular interactions.

As noted earlier, the reverse adsorption selectivity of C ₂ H ₆ / C ₂ H ₄ is a rarely observed phenomenon. The corresponding selectivity factors for MOCPs mentioned in the literature to date are usually quite low at room temperature (S <3) with one exception: MAF-49 with a noticeable selectivity S = 9.0 (see Table 4).

The best adsorption selectivity C ₂ H ₆ / C ₂ H ₄ obtained for NIIC-20-Bu under similar conditions (S = 15.4) is 1.7 times higher than the selectivity of MAF-49 [PQ Liao, WX Zhang, JP Zhang, XM Chen, Nat. Commun. 2015, 6, 8697] and significantly surpasses most of the other literary results mentioned so far (Table 4). Not only adsorption selectivity, but also sorption capacity is an important adsorbent parameter for gas separation applications. In this regard, a more accurate assessment of porous materials should be made on the basis of a plot of selectivity vs. containers (Fig. 2). It is clear that the NIIC-20 series, with its high C ₂ H ₆ / C ₂ H ₄ selectivity factors and sorption capacities, is the most suitable materials for the purification of ethylene from ethane. Also, it should be noted that the transition from the NIIC-10 series (microporous) to NIIC-20 (mesoporous) not only increased the ethane capacity, but also significantly increased the C ₂ H ₆ / C ₂ H ₄ selectivity, despite the widespread phenomenon of inverse dependence adsorption vs. selectivity for porous materials.

Along with the unusual inverted adsorption of C ₂ H ₆ / C ₂ H ₄ , NIIC-20 compounds preferentially adsorb ethane compared to acetylene with C ₂ H ₆ / C ₂ H ₂ selectivity according to IAST for an equimolar gas mixture S = 5.8 ÷ 10.3 at 273 K and S = 4.6 ÷ 10.9 at 298 K. The highest C ₂ H ₆ / C ₂ H ₂ adsorption selectivity factor at 298 K was observed for NIIC-20-Pe with the longest (n-propyl) alkyl diol residue. This inverted adsorptive preference for alkane over alkyne is very unusual.

According to the literature data, there are no porous materials with adsorption selectivity C ₂ H ₆ / C ₂ H ₂ close to the NIIC-20 series. The adsorptive preference of ethane over unsaturated hydrocarbons may be associated with the special organization of portals decorated with diols, which provide numerous van der Waals interactions between saturated hydrocarbons and the features of the NIIC-20 surface.

Claims (8)

Mesoporous adsorption material for the separation of saturated and unsaturated hydrocarbons, which is a family of five isostructural organometallic coordination polymers of the general formula [Zn ₁₂ (iph) ₆ (glycol) ₆ (dabco) ₃ ], where iph ^2- = isophthalate, dabco = 1,4-diaza [2.2.2] bicyclooctane, glycol = deprotonated polyhydric alcohol: ethylene glycol, EtO ₂ , NIIC-20-Et; 1,2-propanediol, PrO ₂ , NIIC-20-Pr; 1,2-butanediol, BuO ₂ , NIIC-20-Bu; 1,2-pentanediol, FeO ₂ , NIIC-20-Pe; glycerin, GlO ₂ , NIIC-20-Gl.

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