The development of technology for production of zeolites from fly-ash from Troitskaya power plant


Chimica Techno Acta LETTER 
published by Ural Federal University 2021, vol. 8(1), № 20218111 

journal homepage: chimicatechnoacta.ru DOI: 10.15826/chimtech.2021.8.1.11 

1 of 5 

The development of technology for production of zeolites 
from fly-ash from Troitskaya power plant 

V.A. Snegirev, V.M. Yurk
*
 

Chemical-technological institute, Ural Federal University, Mira str., 28, Ekaterinburg, Russia 

* Corresponding author: v.yurk@yandex.ru 

This short communication (letter) belongs to the MOSM2020 Special Issue. 

© 2021, The Authors. This article is published in open access form under the terms and conditions of the Creative 
Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). 

 

Abstract 

The study examines the technology of processing fly ash from 

Troitskaya power plant for the production of zeolite. The paper pre-

sents the results of laboratory studies evaluating the suitability of fly 

ash from Troitskaya power plant for the production of zeolites and 

the development of the zeolite production process. Fly ash contains a 

small amount of heavy metals that can complicate processing, but 

contains a large amount of silicon oxide. The technology consists of 

high-temperature alkaline activation of fly ash and hydrochemical 

synthesis. The resulting powder has a specific surface area of 

89.7 m
2
/g, determined by the BET method, and an average pore di-

ameter of 0.345 μm. The static exchange capacity was 220 mg/g. 

Keywords 
fly ash 

metals 

zeolites 

waste treatment 

thermal power plant residues 

Received: 03.11.2020 

Revised: 25.12.2020 

Accepted: 25.12.2020 

Available online: 16.04.2021 

 

1. Introduction 

Thermal power plant residues are divided into the fly ash, 

collected on electrostatic air cleaner, and slag formed un-

der the combuster. Due to physical and chemical proper-

ties (small powdery particles of spherical shape, often 

hollow), fly ash is widely used in the production zeolites. 

However, their use may be limited by the high content of 

toxic metals [1]. 

The chemical and mineral-phase components of the fly-

ash depend on the composition of the mineral part of the 

fuel, its calorific value, the combustion mode, the method 

of their capture and removal, and the place of selection 

from dumps. But, despite this, in the composition of all 

ashes, the same set of mineral components is observed. 

The main components of fly ash are silicon oxides, alumi-

num, iron, calcium, potassium, sodium and titanium, the 

main content of which in all ash is 50-60% SiO2, 20-30% 

Al2O3, 5-10% Fe2O3 [2,3]. Such composition makes the ash 

an attractive raw material for the production of sorption 

materials such as zeolites. 

The issue of obtaining zeolites from ash is not new and 

has long been studied by various researchers. It is possible 

to obtain zeolites of NaX, NaY, NaA, and phillipsite modifi-

cations from fly ash. One of the methods of zeolite synthe-

sis is the separation of fly ash into components – silicon 

oxide and aluminum oxide – by multi-stage leaching of the 

ash and then their crystallization in alkaline solutions in 

autoclaves at high pressures [4]. 

The purpose of this work is to determine the possibility 

of using the ash of Troitskaya power station for the pro-

duction of zeolites, taking into account the toxic effect of 

metals. 

2. Experimental 

Fly ash from Troitskaya state district power station is cap-

tured by eight electrostatic air cleaner and mixed. The 

granulometric composition was determined by the sieve 

method (State Standard 2093-82). The density determina-

tion was carried out by hydrostatic weighing (State Stand-

ard 2160-2015). The phase analysis was performed using 

an XRD-7000 X-ray diffractometer (Shimadzu, Japan) in 

filtered copper radiation. The survey was carried out in 

the range of Bragg angles 2Θ = 3-80° at a speed of 

0.5 °/min., U = 40 kV, I = 30 mA. A semi-quantitative as-

sessment of the content of mineral phases in the sample 

was performed. Chemical analysis of ash was performed 

in "VUKHIN" Corp. (State Standard 10538-87). The metal 

concentration was determined by atomic absorption 

method (AAS) using a double beam atomic absorption 

spectrometer AA-7000 (Shimadzu, Japan) (State Standard 

32977-2014) and inductively coupled plasma mass spec-

trometry (ICP-MS).  

Zeolite was obtained by hydrochemical method with 

preliminary high-temperature activation. A heated mag-

netic stirrer, Heidolph MR Hei-Standard, was used for de-

silting. High-temperature activation of fly ash was per-

formed in a laboratory electric furnace SNOL 6,7/1300 at a 

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Chimica Techno Acta 2021, vol. 8(1), № 20218111 LETTER 

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temperature of 550 °C. At all stages of the process, a sodi-

um hydroxide (HC) reagent was used. Zeolite crystalliza-

tion took place in a liquid thermostat LOIP LT-316b with 

an accuracy of maintaining the temperature of ±0.1 °C.  

The total pore volume was measured by mercury 

porometry using a modernized pore meter PA-3mV at a 

pressure range of 0.1-200 GPA, which corresponded to 

pore radii from 6520 to 3.75 nm. The morphology of the 

resulting product was studied by scanning electron mi-

croscopy using a JSM 6490 (Jeol, Japan) scanning electron 

microscope. 

The static exchange capacity for Ca
2+

 ions, converted to 

CaO, was determined by the following method: a solution 

containing a calcium salt was added to 1 g of the sorbent, 

mixed and kept for 24 h. Next, 10 cm
3
 of the solution was 

selected over the sorbent, the content of calcium ions was 

determined by complexometric titration. The ion exchange 

capacity of the zeolite was calculated by CaO. 

3. Results and Discussion 

The X-ray diffraction (XRD) pattern of Troitskaya ash is 

shown in Fig. 1. The main components of the ash are 

quartz, mullite and magnetite, typical for this type of raw 

material. The amorphous phase is about 37% (calculated 

with respect to the ratio of the halos of the 1st and 2nd 

orders to the total scattered density in the range of angles 

2Θ = 15-60°). The density of the ash is 1.85 kg/m
3
. The 

results of the chemical analysis of the ash components are 

presented in Table 1. 

The total content of silicon oxide in ash is 55.2%, and 

of aluminum oxide - 26.8%, based on which, the ash can 

be classified as high-silica. This also suggests that the 

main part of alumina is most likely represented in the 

composition of mullite, while the amorphous phase con-

sists mainly of silica. The presence of any additional mac-

roscopic inclusions and minerals in the composition of the 

studied ash was not found. The obtained results are in 

good agreement with the data of [5]. 

The initial fly ash contains a large amount of the crys-

talline phase represented by the minerals mullite and 

quartz. The optimal technology for producing zeolite from 

ash of this composition is high-temperature activation 

with solid alkali and subsequent hydrochemical synthesis 

[6-8]. 

The data shown in Table 2 provide an indication of the 

potential toxicity of fly ash and its processed products. In 

addition, metal ions can reduce the adsorption capacity of 

zeolites [9,10]. However, the content of any metal does 

not exceed the established standards [11]. 

The content of silicon oxide in the ash is significantly 

more than required to obtain alkaline sodium hydroalumi-

nate, so it was decided to conduct a pre-procedure of fly 

ash. The fly ash was leached in a solution of sodium hy-

droxide under constant stirring and heated to 90 °C to 

isolate excess silicon oxide of an amorphous phase. Silica 

is dissolved in an alkaline solution. Process parameters 

such as the alkali concentration, the liquid-to-solid ratio, 

and the duration of desilicization varied to achieve the 

maximum value for removing excess SiO2. The results of 

the experiments are shown in Table 3. 

The table shows that the main influence on the process 

is the amount of alkali, respectively: the more alkali, the 

higher the result. This is because the amorphous silica 

interacts better with concentrated solutions to form sodi-

um silicate. The average maximum extraction value is 

25%, which corresponds to the dissolution of most of the 

amorphous phase. 

Based on the research conducted, the optimal process 

conditions were: NaOH concentration – 5 mol/l, liquid-to-

solid ratio – 10, process duration – 5 h. The selected tech-

nological parameters allow achieving the maximum re-

producible extraction of silica without additional time and 

material costs. The resulting filtrate was analyzed for 

aluminum content. It was found that, under the selected 

conditions, aluminum oxide practically does not pass into 

the solution, concentrating in the composition of the 

treated material. 

 
Fig. 1 XRD pattern of the initial Troitskaya ash 

Table 1 Granulometric composition of fly ash from Troitskaya 
thermal power plant 

Particle 
size, μm 

1–
0.5 

0.5–
0.25 

0.25–
0.125 

0.125–
0.063 

0.063–
0.04 

0.04 

% 2.0 13.4 30.6 34.8 12.2 7.0 

 

Table 2 Trace element content of fly ash from Troitskaya thermal power plant 

Method for determining the concentration 
Metal content, mass. % 

Be Cr Cu Mn Ni Pb V Zn 

AAS - 0.001 0.010 0.155 0.001 0.001 0.010 0.008 
ICP-MS - 0.001 0.008 0.162 0.001 0.002 0.011 0.007 



Chimica Techno Acta 2021, vol. 8(1), № 20218111 LETTER 

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Table 3 Results of the silicon removal experiment 

№ NaOH concentration, mol/l solid-to-liquid ratio t, h removal, % 

1 2 8 3 16 
2 2.5 8 3 20 
3 3 6 4 16 

4 3 8 3 22 
5 4 8 4 24 
6 5 10 4 23 

7 5 10 5 26 
8 8 10 7 32 
9 8 8 3 26 

10 8 10 10 28 

 

The next stage of processing was opening the mineral 

phase of the ash and converting it into soluble compounds. 

We have chosen a method of temperature activation with 

alkali that does not require high pressure and ultrahigh 

temperatures, and is widely used by many researchers. 

High-temperature activation of the fly ash was carried 

out by sintering with solid sodium hydroxide. The process 

took place at a temperature of up to 550 °C for 2 h. The 

essence of this activation is the dissolution of quartz and 

mullite minerals with alkali, which under normal condi-

tions does not occur as a result of this process, sodium 

silicate and aluminate are formed. The resulting sinter 

was then ground, dissolved in water, and the zeolite was 

crystallized. To confirm the need for pretreatment of ash, 

high-temperature activation was performed for both un-

treated and desilicized materials. 

The ratio of reacting components required for the dis-

solution of the crystal phase and the production of zeolite 

was determined experimentally. Based on the data from 

[6-8], the first experiments selected a mass ratio of 

NaOH/ash from 1 to 2.5. the result of sintering and subse-

quent repulpation of sinters obtained from both desilicat-

ed and untreated ash were powders containing a large 

amount of mullite and quartz, which indicates an insuffi-

cient amount of alkali for their dissolution. Zeolite was not 

found in these samples. 

In subsequent experiments, the alkali content was in-

creased. The required amount of NaOH was calculated 

from stoichiometric equivalent ratios required for mineral 

dissolution. The experiments were carried out at a NaOH / 

fly ash ratio equal to their stoichiometric amounts and 

with a one-and-a-half excess of hydroxide. Under the se-

lected activation conditions, the specks of both types of 

ash had a uniform laurel-green color, without obvious 

signs of underburning of the fly ash. They were character-

ized by high strength, and therefore they had to be ground 

in a wet mortar. 

As a result, after performing the repulpation and crys-

tallization stages, zeolite powders with a pale beige color 

were obtained. 

XRD patterns of zeolite powders obtained with a 1.5 

excess of alkali from desilicated and untreated ash are 

shown in Fig. 2. The powders in both samples do not con-

tain the original ash minerals. The zeolite composition in 

both cases can be characterized by the formula 

Na1.84Al2Si2.88O9.68 (PDF 00-048-0731). Such composition is 

difficult to attribute to any particular type of zeolite; most 

likely, a mixture of them was obtained. The closest in 

composition are the zeolites NaX and NaY. The powder 

obtained from desilicized ash (Fig. 2b) has a higher crys-

tallinity than the sample synthesized from raw materials 

(Fig. 2a), which also indicates a smaller amount of the 

amorphous phase in the powder composition. Increased 

crystallinity has a beneficial effect on the functional prop-

erties of the material. It can be concluded that the pre-

treatment of ash, namely the desilicization stage, is a nec-

essary stage in the process of processing ash into zeolite 

from the ash of the Troitskaya power plant. 

Fig. 3 shows the morphology of zeolite powder parti-

cles obtained by high-temperature activation of desilicized 

fly ash in the presence of 1.5 excess of alkali. The average 

 

a 

 

b 

Fig. 2 XRD patterns of the zeolite obtained from:  
a – non desilicated ash, b –desilicated ash 



Chimica Techno Acta 2021, vol. 8(1), № 20218111 LETTER 

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a 

 

b 

 

c 

 
Fig. 3 SEM images of the obtained zeolite 

size of the powder particles is about 70 μm in length and 

40 μm in width (Fig. 3b). The powder also contains parti-

cles with smaller sizes, up to 10 μm in length (Fig. 3a). 

Fig. 3c shows the surface morphology of one of these par-

ticles. They are cubic microcrystallites of zeolite sur-

rounded by a structureless mass of the amorphous phase. 

Zeolite crystallizes in a cubic phase, with a rib length of 

about 1 μm. 

The specific surface of obtained zeolite, determined by 

the BET method, is 89.7 m
2
/g. For comparison, the values 

of this parameter for zeolites synthesized from fly ash in 

other researchers range from 62.01 m
2
/g [12] to 

213.2 m
2
/g [13]. As shown by the results of mercury 

porometry, the surface of zeolite particles is characterized 

by the presence of a large number of micropores. The vol-

ume fraction of pores with a diameter from 0.1 to 5 μm is 

84.89%. The total pore volume of the sample was 

17.67 cm
3
/g, and their average diameter was 0.345 μm. 

Synthesized from fly ash zeolites are used in the purifi-

cation of water from metal ions. The main parameter that 

characterizes the material for adsorption purposes is the 

ion exchange capacity. The ion exchange capacity of zeo-

lite for the sorption of Ca
2+

 ions in terms of CaO was 

220 mg/g. The obtained value shows the applicability of 

the synthesized zeolite for sorption of heavy metal ions 

from an aqueous medium. 

The synthesized zeolite is not soluble in dilute solu-

tions of hydrochloric and sulfuric acids, as well as in con-

centrated sulfuric acid. It is half dissolved in concentrated 

hydrochloric acid. 

As a result of the research, a technology for processing 

fly ash from Troitskaya GRES into zeolite was developed. 

The processing technology consists of operations for ex-

tracting excess silicon from ash, high-temperature activa-

tion, and hydrochemical crystallization, which require the 

use of available reagents and easy-to-use equipment. 

Prospective technology for processing fly ash from 

Troitskaya power plant into zeolite consists of operations 

for extracting excess silicon from ash, high-temperature 

activation, and hydrochemical crystallization, which re-

quire the use of available reagents and easy-to-use equip-

ment. 

By its structure, the resulting zeolite can be attributed 

to a mixture of zeolites of the NaA and NaX types. The zeo-

lite also has good ion exchange properties, typical of this 

material, which makes it attractive for use as a sorbent for 

wastewater treatment (removal of metal ions). 

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