Materials and Reagents

The raw material for the synthesis of 5A zeolites used in this study was commercial PAL supplied by Xuyi Clay R&D Center of Changzhou University in China; the average particle size of the PAL was 75 μm. The chemical composition of the PAL, analyzed by X-ray fluorescence is: SiO₂ (58.78%), Al₂O₃ (5.12%), Na₂O (0.10%), K₂O (1.29%), CaO (7.26%), MnO (0.05%), TiO₂ (1.49%), Fe₂O₃ (4.79%), and MgO (10.09%) (Chen et al. Reference Chen, Wang, He, Chen and Zhang2016).

Sodium silicate, sodium hydroxide (≥98%), anhydrous calcium chloride (≥96%), sodium aluminate (≥98%), isooctane (≥98%), nHEX (≥98%), 2MP (≥98%), and 3MP (≥98%) were purchased from Aladdin Reagent Co. (Shanghai, China) and used without any pre-treatment.

Synthesis of Crystallization Directing Agent

The amorphous CDA, also known as a 'seeding director', plays a role in directing crystallization and crystal-size reduction in the synthesis of zeolite A. The synthesis steps are as follows: the aluminate solution was prepared by dissolving 1.31 g of sodium aluminate and 7.18 g of sodium hydroxide in 25 mL of deionized water under magnetic stirring; the silicate solution was prepared by mixing 2.44 g of sodium silicate and 20 of mL deionized water; then the silicate solution was poured quickly into the aluminate solution with vigorous stirring for 24 h, to produce a milky white sol-gel, with the theoretical molar composition of 12Na₂O:SiO₂:4.5Al₂O₃:350H₂O.

Synthesis of 4A Zeolite (Na-A Zeolite) from PAL

Before preparing the 4A zeolites, the PAL was calcinated at 800°C for 4 h in a muffle furnace, then placed in 1 M HCl solution and stirred for 2 h to remove impurities, washed thoroughly until a pH = 7 was reached. In order to obtain the desired zeolites, a hydrothermal reaction was used. Sodium hydroxide was dissolved in 80 mL of distilled water, then 2.0 g of prepared PAL, 1.0 g of sodium aluminate, and CDA were added gradually to the sodium hydroxide solution. The mixture was stirred vigorously at 70°C for 4 h using a magnetic stirrer, forming aluminosilicate gel. The gel was transferred to a PTFE high-pressure reaction kettle (200 mL) and heated for 4 h at 90°C. The precipitates were separated from the liquid phase by filtration, washed with water until a pH value of < 9 was achieved, and then the materials produced were dried at 100°C.

Synthesis of 5A Zeolite (Ca-A Zeolite) through Ion Exchange

5A zeolite was synthesized by means of calcium ion exchange with the Na-A zeolite using a 1 M calcium chloride solution. With the 4A zeolite/calcium chloride solution ratio of 1:20 (mass/volume), the mixture was stirred in an ion exchange vessel at 95°C for 4 h. The 5A zeolite was separated by filtration and washed with distilled water. Then the product was dried at 100°C and calcined at 550°C for 4 h. This ion-exchange process was repeated once more in order to improve the extent of ion exchange. According to the mass ratio of CDA/deionized water added, three different types of 5A zeolites were obtained: CDA-5%, CDA-7.5%, and CDA-10%.

Characterization

X-ray powder diffraction (XRD) patterns were collected at room temperature using a Rigaku D/MAX-2500PC diffractometer (Rigaku Co., Tokyo, Akishima, Japan) using CuKα₁ radiation (λ = 0.15406 nm) operated at 40 kV and 100 mA. Field-emission scanning electron microscopy (SEM) images of 5A zeolite products were taken at 30 kV using a Supra 55 microscope (ZEISS, Jena, Thuringia, Germany). N₂ adsorption isotherms were measured at 77 K using an ASAP2020 sorption analyzer (Micromeritics, Norcross, Georgia, USA). Prior to each analysis, the samples were outgassed at 150°C for 4 h. The Brunauer-Emmett-Teller (BET) method was utilized to calculate the specific surface areas (S _BET) using adsorption data in a relative pressure range from 0.05 to 0.30. The pore-size distributions and pore volume were derived from the adsorption branches of the isotherms.

Batch Adsorption Experiments

Vapor-phase batch adsorption measurements were performed on an Intelligent Gravimetric Analyzer (Model IGA-100B, Hiden Isochema Instrument, Warrington, Cheshire, UK) with a high sensitivity of 0.1 μg. The instrument has an ultrahigh vacuum system controlled precisely by a computer allowing accurate gravimetric changes to be recorded at gradually increased relative pressure values. The variations with time of the amounts adsorbed were also recorded. Before all measurements, pretreatment of each sample was conducted by degassing overnight at 120°C in a vacuum to remove the physically adsorbed water molecules and other impurities adsorbed in the pores. The batch adsorption experiments were carried out at 25°C.

Dynamic Adsorption Breakthrough Experiments

The dynamic adsorption separation was investigated using breakthrough experiments of binary mixtures of n-hexane/2-methylpentane (nHEX/2MP) or n-hexane/3-methylpentane (nHEX/3MP). To test reproducibility, parallel dynamic experiments were carried out three times. The breakthrough experimental apparatus comprised a feed pump, a stainless steel adsorption column, and a regulating valve at the outlet of a packed bed in order to collect products. The pump used to inject the mixture was a high-pressure, constant-current pump. The stainless steel column (10 cm long, 1.0 cm inner diameter) containing adsorbent (1–2 g) and quartz sand at the bottom was placed in an oven which maintained the temperature of the adsorption experiment at 200°C. The experiments were operated by continuously introducing mixtures of hexane isomers with known composition at a fixed total pressure and adjusted to keep a total flow rate of 0.5 mL·min^–1. When saturation was reached, the composition of each product was analyzed using a Shimadzu GC2010 chromatograph equipped with a flame ionization detector (FID). The mass fractions of inlet mixtures were nHEX:2MP (or 3MP) = 1:1, 1:2, or 1:3, with isooctane (70%) as the solvent. The fixed total pressure was 0.5 MPa, 0.8 MPa, or 1.2 MPa, respectively.

The equilibrium dynamic adsorption capacity (q _c) of the adsorbents was calculated from the breakthrough curves according to the equation as follows:

(1) $q_c=\frac{1}{m}\left(C_{0}u\rho t-C_0{V}^{\prime }\rho -\rho u{\int }_0^t{C}_i\mathrm{dt}\right)$

where C _i and C ₀ are the outlet and inlet mass concentrations (%) of the stream through the fixed bed column, respectively; u (mL·min^–1) is the volume flow rate of the specific hexane isomers; m (g) is the dosage of the adsorbent; V' (mL) is the dead space volume of adsorbent bed voids and around the pipe; and ρ (g·mL^–1) is the density of the binary mixture.

The feed flow rate u of the liquid phase was 0.5 mL·min^–1, controlled by a high-pressure constant-current pump, and the exit flow rate was variable because one component was being adsorbed selectively. The mass of component i retained in the adsorbent bed was equal to the total inlet mass of i minus the total outlet mass of i, also minus the dead space volume of the bed. $\rho u{\int }_0^t{C}_i\mathrm{dt}$ is the total outlet mass of component i by integration of the breakthrough curves measured in terms of outlet concentration as a function of time.

The separation factor, S, for a binary mixture of components i and j, is defined as:

(2) $S=\frac{\left(\frac{q_i}{c_{\mathrm{oi}}}\right)}{\left(\frac{q_j}{c_{\mathrm{oj}}}\right)}$

where q _i and q _j are the dynamic adsorption capacity of components i and j, respectively; c _0i and c _0j are the mass concentrations of the feed.

Synthesis and Characterization

Powder XRD patterns of three as-synthesized 5A zeolite adsorbents based on PAL with various additions of CDA (Fig. 1) showed the characteristic peaks of 5A zeolite at 2θ values by comparing the PXRD patterns with standard simulation patterns from the literature (Treacy & Higgins Reference Treacy and Higgins2001). SEM images (Fig. 2) revealed that the particles of 5A zeolite were submicron crystals with cubic lattice shapes. All crystals of 5A products had an average particle size of 400–800 nm, which is smaller than that reported in the literature; most reports of the particle size of 5A zeolite are >1 μm (Li et al. Reference Li, Kuppler and Zhou2009; Yuan et al. Reference Yuan, Chen, Chang and Li2011). The amounts of CDA evidently control the morphology of 5A zeolites. With an increase in the amount of CDA, the change in the crystal size is not obvious, but the crystal shape of product CDA-10% has irregular cubic edges because of the introduction of an excessive amount of CDA. The system lacked sufficient crystals for nucleation and growth, which resulted in an incomplete reaction (or crystal growth) (Liang et al. Reference Liang, Zhang and Liu2001; Pu et al. Reference Pu, Zhao, Guo and Lv2004).

Fig. 1 PXRD patterns of three 5A zeolites with various additions of CDA.

Fig. 2 SEM images of three 5A zeolites with various additions of CDA

Nitrogen adsorption/desorption isotherms gave the specific surface area and the pore diameters (Table 1). In these products, PAL 5A (CDA-5%) showed the largest BET surface area of 527 m²/g and the micropore volume of 0.42 cm³/g. These values are larger than those for the PAL 5A zeolite (CDA-0%), which had a BET surface area of 482 m²/g and total pore volume of 0.27 cm³/g (Chen et al. Reference Chen, Wang, He, Chen and Zhang2016). The isotherms (Fig. 3) of all PAL 5A zeolite products showed type I Langmuir isotherms at low relative pressures, with a characteristic microporous adsorption. When the relative pressures were >0.8, the uptake increased and a smaller hysteresis loop was visible; this may be due to the properties of unreacted PAL.

Table 1 Pore-structure parameters

Fig. 3 N₂ adsorpton/desorption isotherms of four 5A zeolites with various additions of CDA.

Batch Adsorption Performances

A batch adsorption test using the IGA-100B instrument was conducted to investigate the adsorptive properties and rates of interaction of the 5A materials with nHEX. Batch adsorption curves of pure nHEX, 2MP, and 3MP on PAL 5A materials (Fig. 4) revealed that the quantities of nHEX adsorbed on three PAL 5A zeolites were greater than those of 2MP and 3MP. The PAL 5A (CDA-5%) showed a faster rate of adsorption of nHEX than those of 5A (CDA-7.5%) and 5A (CDA-10%) (Fig. 4a). After 20 min, the adsorption capacity of nHEX on PAL 5A (CDA-5%) reached 80% of the saturation value, while the other two 5A zeolite products only reached 60% and 25%, respectively. Thus, the specific surface area and pore volume of PAL 5A (CDA-5%) are larger than those of PAL 5A (CDA-7.5%) and 5A (CDA-10%) (Table 1), so the adsorption of n-paraffin is expected to complete more easily. Due to the smallest surface area and the pore size of PAL 5A (CDA-10%), the resistance to diffusion of alkane molecules will be greater and entry to the pores will be more difficult, resulting in less adsorption. The optimal mass ratio of CDA/deionized water was ~5%, therefore.

Fig. 4 Batch adsorption rate curves of a nHEX, b 2MP, and c 3MP on PAL 5A zeolites

The sieving radius of 5A zeolite was reported to be close to 0.50 nm (Breck Reference Breck1974), which could be the reason for its efficiency in sieving branched hexane isomers with nHEX being adsorbed. The kinetic diameter of 2MP and 3MP molecules are both 0.50 nm, while nHEX’s kinetic diameter is 0.43 nm. The static kinetic measurements demonstrated that kinetic separation of paraffins is based on the molecular dimensions of the hexane isomers; and small amounts of 2MP or 3MP isomer may be adsorbed under larger diffusional limitations, so the adsorption rate of nHEX is greatest among the hexane isomers.

The one-component isotherms of nHEX, 2MP, and 3MP vapor adsorbed on four PAL 5A zeolites were measured at 25°C (Fig. 5). The static saturation adsorption capacities of nHEX adsorbed on PAL 5A (CDA-0%), 5A (CDA-5%), 5A (CDA-7.5%), and 5A (CDA-10%) were 0.136 g/g, 0.149 g/g, 0.120 g/g, and 0.0780 g/g, respectively (Fig. 5a). The PAL 5A (CDA-5%) was superior to many previously reported commercial 5A zeolite adsorbents synthesized from natural clays, which have the adsorption capacity of nHEX at ~0.08–0.13 g/g (Sun et al. Reference Sun, Shen and Liu2008; Melo et al. Reference Melo, Riella, Kuhnen, Angioletto, Melo, Bernardin, da Rocha and da Silva2012). Meanwhile, 5A (CDA-5%) zeolites synthesized in the present study have greater adsorption capacity for nHEX than commercial Sinopec 5A synthesized from chemical raw materials with the amount of nHEX adsorbed of 0.117 g/g (Sun et al. Reference Sun, Liu, Huang and Shen2006).

Fig. 5 Batch adsorption isotherms of a nHEX, b 2MP, and c 3MP on PAL 5A zeolites.

The saturation adsorption capacities of nHEX on four PAL 5A zeolites were greater than those of 2MP and 3MP. By comparison with the structural features of hexane isomers, the lower adsorption capacity of 2MP and 3MP on 5A can be attributed to their larger kinetic diameters. On the other hand, the static saturation adsorption capacity of 3MP adsorbed on four PAL 5A zeolites was slightly greater than that of 2MP (Fig. 5b and c). For all three adsorbents, product PAL 5A (CDA-5%) exhibited the largest adsorption capacity for nHEX and smallest adsorption capacity for 2MP and 3MP, while product PAL 5A (CDA-10%) displayed the smallest amount of adsorption for nHEX. Product PAL 5A (CDA-5%) displayed better adsorption equilibrium selectivity than those of product PAL 5A (CDA-7.5%) and PAL 5A (CDA-10%) for nHEX/2MP separation. The amount of adsorption increases with increase in pressure (Fig. 5).

Dynamic Adsorption Breakthrough Experiments of Binary Mixture Composition

The PAL 5A (CDA-5%) was investigated further for its dynamic adsorption behavior with hexane isomers. This product was chosen due to its distinct static adsorption performance among the 5A zeolite adsorbents investigated. Two sets of experiments were carried out: (1) the influence of the initial feed concentration at a fixed total pressure and temperature for hexane isomers; and (2) the influence of the total pressure at a fixed feed concentration and temperature for hexane isomers. In accordance with industrial separation conditions (Lu et al. Reference Lu, Du, Yao, Liu, Cui, Wang and Yao2010), the dynamic experiments were performed at 200°C and up to 1.2 MPa in the fixed-bed adsorption experiment column.

Breakthrough curves of nHEX/2MP, nHEX/3MP mixtures on 5A (CDA-5%) with different feed ratios at 200°C and 1.2 MPa were obtained (Fig. 6). After the injection of a mixture of nHEX and 2MP (or 3MP) at the inlet of a column packed with 5A zeolite, the linear chain eluted later than its branched isomer, indicating preferential adsorption of nHEX. The outlet concentration of 2MP (or 3MP) increased rapidly to the feed concentration level within 20 min. When the feed ratios of nHEX/2MP and nHEX/3MP mixtures were 1:2, the longest adsorption equilibrium time occurred after ~30 min (Fig. 6). The dynamic saturated adsorption capacities of nHEX increased with the adsorption equilibrium time being extended. The shape of the breakthrough curves depended mostly on mass transfer kinetics, indicating the impact of feed concentration. The experimental conditions and results are given in Tables 2 and 3.

Fig. 6 Breakthrough curves of nHEX/2MP and nHEX/3MP mixtures on PAL 5A (CDA-5 %) with various feed ratios.

Table 2 Experimental conditions and dynamic adsorption parameters for nHEX/2MP binary breakthrough curves on 5A (CDA-5%).

Table 3 Experimental conditions and dynamic adsorption parameters for nHEX/3MP binary breakthrough curves on 5A (CDA-5%).

The breakthrough curves of binary mixtures (nHEX:2MP = 1:2 and nHEX:3MP = 1:2) at various total pressures on PAL 5A (CDA-5%) were obtained (Fig. 7). Breakthrough curves of nHEX on 5A zeolite indicated that its adsorption is highly favorable at higher total pressure. The dynamic adsorption capacity of nHEX increased with increase in total pressure; the outlet concentration of nHEX adsorbed increased slowly after 5 min, until dynamic equilibrium was reached after 30 min (Fig. 7). The conditions for the largest nHEX/2MP separation selectivity were achieved with a feed concentration ratio of 1:2 at a total pressure of 1.2 MPa (Table 2), while the conditions of the largest separation selectivity of nHEX/3MP were at a feed concentration ratio of 1:3 and a total pressure of 1.2 MPa (Table 3). 5A zeolite synthesized from PAL exhibited significantly better shape selectivity and adsorption capacity toward nHEX than toward 2MP and 3MP under the aforementioned experimental conditions. As a low-cost, natural starting Si/Al source, PAL was proven here to be a potential substitute raw material for the synthesis of 5A zeolite adsorbent.

Fig. 7 Breakthrough curves of nHEX/2MP and nHEX/3MP mixtures at various total pressures on PAL 5A (CDA-5%) (nHEX:2MP = 1:2 and nHEX:3MP = 1:2).