1. Introduction
Currently, recycling industrial waste to produce high-tech materials with specific properties attracts great attention. Coal fly ash, the major byproduct (60–95%) from pulverized coal combustion [
1,
2], contains hollow aluminosilicate spherical particles, cenospheres, which can be useful in many industrial applications due to their unique properties, such as low bulk and apparent density, high thermal resistance, chemical stability, compressive strength, and low thermal conductivity [
3,
4,
5,
6]. Of the promising directions for the use of cenospheres that have been considered recently, the following can be noted: low-density ceramic [
7,
8] and metal syntactic foams [
9,
10], porous mullite ceramics [
11], polymer–matrix composites [
12], catalysts and carriers [
13,
14], composite materials for biomedical applications [
15], and lightweight cement concrete [
16].
The potential of the application of fly ash cenospheres for the production of functional and composite materials is associated with the possibility to stabilize their composition and properties as a consequence of various physical characteristics of individual globules (density, size, and magnetic properties). Increasing attention being is paid to the separation of cenosphere concentrates into narrow fractions with specific physicochemical properties; the systematic study of their composition and structure, including individual globules; and the identification of promising areas for further application [
17,
18,
19]. The criterion for the suitability of cenosphere fractions in each specific case is the fulfillment of stringent requirements for the composition and structure of the glass–crystalline shell of globules. On the basis of well-characterized narrow fractions of cenospheres due to a definite composition and morphology of globules, new functional materials with predictable and reproducible properties have been obtained. Among such materials are highly selective membranes for helium capture [
20,
21].
The global cenospheres market is predicted to rise by an average of 11.9% by 2029 [
22], which will allow the development of new areas for their application, one of which is the production of membrane materials. Membrane technology is a simple and efficient gas separation method with less energy consumption than traditional processes, such as pressure swing adsorption or liquefaction through compression and cooling. The separation and purification of light inert gases, helium and neon, play an important role in modern science and technology [
23]. However, existing membrane materials (polymers, MOFs, zeolites, etc.) have an extremely low selectivity for He-Ne mixtures; for example, the most selective of them is polysulfone, which has an αHe/Ne value of no more than 5 [
24].
At present, membrane gas separation is entering the stage of the directional design of new effective, highly selective, and highly permeable membrane materials characterized by an improved microstructure, chemical resistance, strength, and stability at elevated temperatures. Intensive research aims to develop carbon-based [
25,
26], organic-framework [
27], mixed-matrix [
28,
29], and inorganic membranes [
30,
31].
A promising material for creating highly selective gas separation membranes is nonporous silicate glass [
32,
33]. Even at high temperatures, the αHe/Ne value of silica glass is significantly higher than that of polymer membranes, 150 at 400 °C [
34], but the helium permeability is insufficient for industrial use [
32,
34]. A low-density silica structure (expanded silica glass) can have a higher helium permeability compared with ordinary silica glass and maintain a high selectivity for He-Ne mixture separation [
35].
The gas transport properties of silicate glass depend on the composition and structure of the glass phase, which determine the gas migration in the interstitial space of the glass structural network formed by (SiO
4)-tetrahedra. Modifier ions K
+, Na
+, Ba
2+, Mg
2+, Ca
2+, etc., occupy interstitial voids in the structural network, thus preventing gas penetration [
36,
37]. In aluminosilicate glasses, aluminum cations, depending on the coordination, can act as glass formers (four- and five-coordinated) or modifiers (six-coordinated); after annealing at high temperatures, the six-fold coordination of aluminum becomes predominant, and Al-cations are randomly located in the space between silicon and oxygen tetrahedra [
38,
39,
40]. The structure of aluminosilicate glass, when aluminum acts as a glass former, consists of separate Si-O and Al-O subnetworks. This different ordering of Al and Si atoms leads to microphase separation in the glass, causing the Al-O-rich network to leak through the Si-O network in a peculiar manner. The interweaving of networks leads to the formation of Al-rich areas, which serve as nucleation channels for the subsequent formation of needle-shaped crystallites of the mullite phase during crystallization [
41,
42]. Thus, crystallization in silicate and aluminosilicate glasses can have a significant effect on permeability since it promotes the displacement of modifier ions from the glass phase and changes the material structure.
There are practically no systematic data on the gas transport properties of nonporous silicate glass–crystalline composites in the literature. Investigating the relationship between the composition, structure, and gas permeability of these composite materials is important, especially when considering their potential applications as separation membranes. Such studies will fill the knowledge gap in the field of membrane materials science.
Coal fly ash cenospheres are promising for studying the gas transport properties of glass–crystalline materials in a wide range of compositions [
20,
21]. It was shown that the helium permeability of the glass phase of cenospheres significantly exceeds the analogous values for silicate glasses; in terms of density, the glass phase of cenospheres containing 10 mol % of modifier ions corresponds to silica glass, in which there are no modifier ions [
21]. These studies concerned morphologically homogeneous narrow fractions of cenospheres containing single-ring-structure globules. Another morphological type of cenosphere is foamy globules with a network structure [
20,
43]; their diffusion properties relative to He and Ne have not yet been considered. The development of new membrane materials for the separation and purification of He and Ne based on microspherical components of fly ash from the industrial pulverized combustion of coal is a very urgent task. Solving this problem involves establishing the relationship “composition—structure—properties” for cenospheres of different types and identifying patterns of the formation of new functional materials with specific properties based on technogenic raw materials.
This paper is devoted to the characterization of silicate glass–mullite (SiG/M) composites based on narrow fractions of fly ash cenospheres with different globule structures as effective gas separation membranes. The research included the production of composite membranes, the study of their composition and structure, and the determination of gas transport properties to He and Ne. The expected unique combination of high permeability and selectivity along with the strength of the glass–crystalline shell of cenospheres makes these materials promising for effective helium–neon mixture separation and the production of high-purity gases.
2. Materials and Methods
2.1. Preparation of SiG/M Composites
SiG/M composite membranes based on narrow fractions of fly ash cenospheres were prepared by applying a previously developed technique, including the separation of cenosphere concentrates into narrow fractions [
17,
18,
19] and the high-temperature treatment of cenosphere narrow fractions [
20].
Concentrates of fly ash cenospheres produced after the industrial pulverized combustion of coal were used as a feedstock for obtaining narrow fractions of cenospheres with the maximum content of globules with a single-ring or network structure. The separation of cenosphere concentrates into narrow fractions was performed according to the technological scheme [
17,
18,
19] including stages of aerodynamic classification and magnetic and grain-size separation. To obtain homogeneous fractions of cenospheres with reproducible physical and chemical characteristics, a unique technological complex of equipment was used, including an ATP 50 centrifugal laboratory aerodynamic classifier and an ALPINE e200 LS air-sieve screening unit (Hosokawa Alpine, Augsburg, Germany). The separation of cenospheres by magnetic properties was carried out at a magnetic field strength of 10.55 KOe.
As a result, a nonmagnetic narrow fraction with a size of −0.063 + 0.05 mm (series M) was isolated from the concentrate of fly ash cenospheres from the combustion of Kuznetsk coal at the Moscow Thermal Power Plant (flame kernel temperature of 1650 °C). From the concentrate of fly ash cenospheres after the combustion of Ekibastuz coal at the Reftinskaya TPP (flame kernel temperature of 1550 °C), a fraction −0.25 + 0.2 mm in size (series R) was obtained. The decisive factor in the choice of these fractions was the morphology of their globules. A cenosphere narrow fraction with a size of −0.063 + 0.05 mm is completely represented by spheres of a single-ring structure with a thin solid or low-porosity shell; a cenosphere narrow fraction with a size of −0.25 + 0.2 mm contains predominantly foamy particles with cavities of various sizes and globules with a highly porous shell (
Figure 1). The chemical and phase compositions of the narrow fractions are summarized in
Table 1 and
Table 2; SEM images are shown in
Figure 1c,d and
Figure 2.
Narrow fractions of cenospheres M −0.063 + 0.05 and R −0.25 + 0.2 were subjected to heat treatment at 1000 and 1100 °C, respectively, in an oxidizing atmosphere for 3 h. This temperature regime was chosen according to the results of the thermal analysis (DSC-TG), which was performed using a Jupiter STA 449C synchronous thermal analysis unit (Netzsch, Selb, Germany). The crystallization temperatures of the phases were determined according to the observed specific exothermic effects. It was found that the phase crystallization occurred in the temperature range of 980–1100 °C. After the high-temperature treatment, the destroyed and thoroughly perforated globules were removed using the hydrostatic method with preliminary vacuuming.
2.2. Characterization of SiG/M Composites
For SiG/M composites, we determined the following physicochemical characteristics: bulk density, chemical and phase compositions, particle size distribution, average diameter of the globules, apparent thickness of the glass–crystalline shells, absolute density and composition of the glass phase, and content of the globules related in structure to a certain morphological type. The methods for determining these parameters are described in detail in [
18,
19,
20,
24].
The bulk density was measured using an automated Autotap density analyzer (Quantachrome Instruments, Boynton Beach, FL, USA) and the particle size distribution was measured using a MicroTec 22 laser particle sizer (Fritsch, GmbH, Idar-Oberstein, Germany).
The chemical composition, including the content of silicon, aluminum, iron, calcium, magnesium, and potassium oxides, was determined using chemical analysis according to the State Standard GOST 5382-2019 [
44], which specifies the methods for component identification. The standard error of repeatability (S
n) and the discrepancy between the results of the parallel determinations (R
max) for each component, depending on its content, did not exceed what was accepted according to GOST 5382-2019.
The phase composition and structural parameters of the crystal phases (crystallite size and lattice parameters) were determined using quantitative X-ray powder diffraction analysis with the full-profile Rietveld method and the derivative difference minimization according to the procedure in [
18]. The X-ray diffraction data were obtained on an X’Pert Pro MPD powder diffractometer (PANalytical, Almelo, The Netherlands) with a PIXcel solid-state detector using Cu Kα radiation (2θ range 12–120°). The weight percent of the X-ray amorphous component was determined through the external standard method with corundum used as the standard. The absorption coefficients of the samples were calculated from the total elemental composition according to the chemical analysis data. The composition of the glass phase was calculated using the set of data obtained through the chemical analysis and the quantitative X-ray phase analysis.
Figure 3 shows the experimental and calculated XRD patterns and their difference from those for the original narrow fractions of cenospheres and the SiG/M composites obtained on their basis. The halo at 2θ~30–40° (line 3) indicates the presence of an X-ray amorphous phase in the sample.
The helium pycnometer method was used to determine the absolute density of the glass–crystalline shell of the cenospheres. The volume of a preliminarily ground cenosphere sample was measured using the difference in the helium pressure in a static volumetric measuring cell of an ASAP 2020C-MP (Micromeritics, Norcross, GA, USA) automated sorption analyzer.
The morphology of globules was studied using an Axioscop Imager D1 optical microscope equipped with an AxioCam MRc5 color digital camera (Zeiss, Carl-Zeiss-Stiftung, Oberkochen, Germany). The contents of globules of different morphological types were determined using the specially developed computer program “Msphere” for the processing of digital optical images of at least 5000 globules in each fraction [
19].
The structure of the cenosphere shells was studied using TM-3000 and TM-4000 scanning electron microscopes (High Technologies Corporation, Hitachi, Tokyo, Japan). The composition of the single globules and their local areas were studied using the SEM-EDS method with a TM-3000 (SEM) equipped with a Quantax 70 microanalysis system and a Bruker XFlash 430H energy-dispersive X-ray spectrometer (EDS) (Bruker Corporation, Billerica, MA, USA) at a magnification of × and an accelerating voltage of . Using polished sections of cenospheres in the elemental mapping mode, we analyzed the heterogeneity of the shells of individual globules. The data acquisition time was at least 10 min, which enabled the quantitative processing of the spectra. For single globules and their local areas, the gross composition, including the elemental content of Si, Al, Fe, Ca, Mg, Na, K, and Ti, was determined. The root mean square error (%) in determining the content of elements was O 1.4–3.1; Si 0.3–0.7; Al 0.2–0.6; Ca, Mg < 0.2; Na, K < 0.1; and Ti, Fe < 0.03. The elemental composition was converted to oxides and normalized to 100%.
2.3. Investigation of Gas Transport in SiG/M Composites
The pure gas (He, Ne) permeability of SiG/M composites was measured on a vacuum static installation (
Figure 4) in the mode of gas diffusion from the reactor volume into the internal cavities of the cenospheres.
Gas transport through SiG/M composites is provided by the difference in partial pressures of the He or Ne outside and inside the globules. The measurements were carried out in the temperature range of 25–360 °C for helium and 280–500 °C for neon. The technique, including the determination of the He and Ne permeability coefficients, ideal αHe/Ne selectivity, and diffusion activation energy, is described in detail in [
20]. The relative standard error of permeability determination did not exceed 10%.
4. Conclusions
This work reports new silicate glass–mullite composites produced from narrow fractions of fly ash cenospheres with a size of −0.063 + 0.05 mm and −0.25 + 0.2 mm after heat treatment at 1000 and 1100 °C, respectively. The resulting composites are characterized by a predominant content of globules with a single-ring or network structure; they consist of a silicate glass matrix and defective phases of mullite, quartz, cristobalite, and anorthite. The SEM-EDS study showed that the cenosphere shells, regardless of their globules’ morphology, have a fragmentary structure, are heterogeneous in chemical composition, and contain areas enriched in SiO2 without modifier oxides. Needle-shaped crystallites of mullite are formed on the outer and inner surfaces of globules with a single-ring structure; for cenospheres with a network structure, the volumetric crystallization of the shell is observed, which gives them increased strength. The promising performance of silicate glass–mullite composites based on coal fly ash cenospheres for effective helium–neon mixture separation was demonstrated. The permeability coefficients He and Ne exceed similar values for silicate glasses; the selectivity corresponds to a high level, αHe/Ne 22 and 174 at 280 °C, which is significantly higher than that for polymer membrane materials. The results obtained can be used in the development of new, highly selective membrane materials with improved microstructure and gas transport characteristics for energy-efficient membrane technology for separating helium, hydrogen, and neon from gas mixtures, and for purifying helium concentrate from impurities.