Using the mineral component of building refuse in heavy metals sorption from their mixture


Chimica Techno Acta LETTER 
published by Ural Federal University 2021, vol. 8(1), № 20218112 

journal homepage: chimicatechnoacta.ru DOI: 10.15826/chimtech.2021.8.1.12 

1 of 5 

Using the mineral component of building refuse  
in heavy metals sorption from their mixture 

V.M. Yurk
ab

, O.B. Zaytsev
b
, A.V. Zaytseva

b
, N.A. Malahova

a
 

a: Ural Federal University named after the first President of Russia B.N. Yeltsin,  

Institute of Chemical Engineering, 620002, 19 Mira st., Ekaterinburg, Russia 
b: Ecology development of business (Ekologiia Razvitiia Biznesa (ERBi LLC)),  

620144, 195 Moskovskaya st., 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 sorption properties of the sand-breakstone mixture based on the 

mineral component of building refuse of the 0-10 mm fraction with 

respect to Pb
2+

, Zn
2+

, Cu
2+

, Ni
2+

, Cd
2+

 and Hg
2+

 ions were studied us-

ing atomic absorption spectroscopy. The mechanisms of accumula-

tion of heavy metal ions on the surface of the mixture particles are 

described. It was found that after washing the contaminated material 

distilled water, the residual concentration of metals in the filtrate 

does not exceed the established sanitary and hygienic standards. The 

practical value of the work lies in the possibility of applying the re-

sults in reclamation of technogenic formations or production of ma-

terials for the technical stage of reclamation using technogenic soils. 

Keywords 
contamination 

heavy metal 

building refuse 

soil pollution 

Received: 03.11.2020 

Revised: 25.12.2020 

Accepted: 25.12.2020 

Available online: 16.04.2021 

 

1. Introduction 

The heavy metal pollution of the environment is a serious 

problem nowadays. Soils nearby to plant facilities and 

industrial dumping sites are the most intensively affected 

by this type of exposure. The forming of geochemical bar-

riers is a prospective way to prevent heavy metal migra-

tion in polluted soils and to protect ground water. In ac-

cordance with contemporary conceptions a geochemical 

barrier is an open, non-equilibrium, dynamic and self-

organizing system with a quantity of factors conditioning 

a contaminant fixation [1,2]. Thus, the investigation, de-

scription and modelling of geochemical barriers is really 

important. 

Various materials are used to create artificial geochem-

ical barriers. A choice of its components depends on pollu-

tant properties and economic feasibility. At present, min-

ing waste [3], organoclay [4], farm waste [5,6] have been 

proposed as basic materials for artificial geochemical bar-

riers. However, the use of mineral part of the building 

refuse for that is of interest of soils tilling from heavy 

metals. The ability of building refuse to sorb heavy metal 

ions has been proved by a lot of studies. Such barriers be-

long to physicochemical ones because ions fixation gener-

ally arises from coordination bond formation between 

metals and functional groups of barrier particles surface. 

Also, it was reported [7] that basic properties of building 

refuse which cause a high receptivity are capillary pores 

and silicon and calcium minerals in the composition.  

The adsorption capacity of calcium-containing materi-

als (concrete, foam concrete or brickbats) under dynamic 

conditions reaches 2.3 mg/g [8]. Recent studies have 

shown that the dynamic capacity of building refuse is 

comparable to the capacity of most synthetic sorbents 

[9,10]. So, this type of waste is more attractive for geo-

chemical barriers formation because of abundance and 

availability at low cost. Also, calcium-containing materials 

have an alkaline reaction in water solution; therefore they 

can be used for soils disoxidation or neutralization of acid-

ic tails. For example, calcium aluminate cement is good for 

reliable encapsulation and effective sorption of Pb
2+

, Zn
2+

 

and Cu
2+

 [11] and Cd
2+

, Mn
2+

, Ni
2+

, Fe
2+

, Cr
2+

 [12]. Con-

crete has great geoecoprotective properties for protection 

of soil from radionuclides [13] and sulfide-rich tailings [3]. 

In [14], a concrete geoprotective embankment along the 

railroads to prevent contamination of adjacent soils with 

iron was proposed, and the paper [9] presents the recom-

mendation to use of shungite-containing crushed stone 

waste for these purposes. The authors of [15,16] developed 

a model of a multilayer geochemical barrier based on 

flask, clay, and kaolin accumulating Hg, Pb, Fe, and Cs 

ions, as well as Zn, Cd, and Cu. 

Thus, the analysis of the literature data allows us to 

conclude that the use of building refuse as a raw material 

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Chimica Techno Acta 2021, vol. 8(1), № 20218112 LETTER 

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for the production of a geochemical barrier to the migra-

tion of heavy metal ions is promising. However, most of 

the adsorption studies have considered fixation of only 

one type of metal ions at once. Actually, one has to deal 

with media containing more than one pollutant. The avail-

able information does not allow to estimate the geoprotec-

tive potential of the building refuse in multicomponent 

systems, which soils are. The results of our statistical 

study of soil contamination in the Sverdlovsk region of 

Russian Federation [17] showed that four-five metals can 

be observed in contaminated soil at the same time. The 

present work belongs to the series of our studies on the 

development of a geochemical barrier based on building 

refuse for the reclaiming of industrial lands. The article 

presents the results of sorption studies of heavy metal 

ions from their mixture. 

2. Experimental 

2.1. Materials 

The building refuse used in this study was composed of 

cement, concrete, firebrick, sand, hardened building mor-

tar and other building materials. Cement and concrete 

composed a big part of this mixture. Before we examined 

this building refuse, it had been prepared at first. Utiliza-

ble components such as metal and wood ones were re-

moved. After that, it was ground on a crusher. The basis of 

the derived sand-breakstone compound was a sand frac-

tion with a particle size of up to 10 mm, the grain-size 

composition of which are shown in Fig. 1. 

2.2. Sorption batch experiment 

The model solutions contained ions of heavy metals: lead, 

cadmium, zinc, copper, mercury and nickel. Sorption of 

heavy metals from their nitrate solution was studied in 

static conditions. A 30 g of sand-breakstone mixture was 

put into a 250 ml cylindrical glass funnel and filled up by 

30 ml of a model solution. This suspension was kept for 

seven days at 25 °C. After that the supernatant was fil-

tered to analyze metal ions concentration. To determine  

 
Fig. 1 The grain-size composition of sand-breakstone compound 
based on building refuse 

residual metals (Pb, Zn, Cu, Ni, Hg and Cd) concentrations, 

the atomic absorption spectrometry (AAS) was used. 

For determination of capability of sand-breakstone 

mixture to hold fixed metal ions on a surface of its parti-

cles, the batch experiment was carried out in dynamic 

conditions. Distilled water was leaked through a layer of 

building refuse mixture saturated by heavy metals. Eluates 

were collected at every 100 ml and the residual metals 

concentrations were determined by AAS (AA-7000, Shi-

madzu, Japan). 

3. Results and Discussion 

The laboratory studies of the sorption properties of the 

sand-gravel mixture were carried out in an aqueous medi-

um. This approach allows us to evaluate the full adsorp-

tion capacity of the material and its geoprotective proper-

ties. Moreover, moisture is always present in the soil and 

the migration of heavy metal ions occurs with its active 

participation. Therefore, the obtained data can be success-

fully adapted for use in soils. 

Determining the initial concentration of metals in 

model solutions, we used the statistical data on soil pollu-

tion obtained by analyzing the ecological engineering sur-

veys of capital construction objects in which ERBi LLC 

took part for 2015-2018. The sampling was carried out 

mainly on sites in Yekaterinburg and the Sverdlovsk re-

gion and included soils with the “extremely dangerous” 

category of pollution. These soils must not be used in any 

way and have to be neutralized. 

The model solution of the experiment 1 contained a 

concentration of metal ions, which corresponds to their 

maximum content in contaminated soils of the “extremely 

dangerous” category, discovered during engineering sur-

veys of various sites for construction projects in Yekate-

rinburg. 

One should bear in mind that soils in industrial areas 

can be exposed to increased anthropogenic pollution, as a 

result of which the heavy metals concentrations in them 

can exceed the values being detected during engineering 

surveys. Such soils are also classified as “extremely dan-

gerous” and must be utilized. The ability of a sand-

breakstone mixture to exhibit geoprotective properties 

under these conditions were estimated in the experi-

ment 2. 

Also, as a result of various emergency situations, spills 

of reagents containing metal compounds on the soil may 

occur, contributing to their extreme pollution. Material 

properties in the conditions of emergency soil contamina-

tion were evaluated during the experiment 3. 

The initial data on the metals concentrations in model 

solutions in accordance with the situations described 

above are presented in Table 1. 

The ability of sand-breakstone mixture to sorb heavy 

metals was assessed in aqueous solutions because due to 

the dissolution processes, the ability to migrate to lower 



Chimica Techno Acta 2021, vol. 8(1), № 20218112 LETTER 

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layers of the soil and further to aquifers increases in mois-

ture medium. So, the most unfavorable environmental 

conditions for each of the considering situations were 

simulated, since in the experiments all metals are in their 

most mobile form, while under natural conditions the pro-

portion of the mobile form of metals is far from 100% of 

the total content. 

The results of the sorption of heavy metals by the stud-

ied building refuse mixture modeling various levels of en-

vironmental pollution are shown in Table 2. 

The experimental results demonstrate a high sorption 

activity of building refuse to all heavy metal ions present-

ed in the model solutions. The sorption efficiency for each 

element in all experiments exceeds 99%. The adsorption 

capacity of cadmium is better because a minimal concen-

tration of it in the filtrate is observed. 

The decrease in the residual concentration of metals in 

the filtrate with an increase in their concentration in the 

model solution has been noticed. This phenomenon can be 

explained by the alkaline reaction of an aqueous solution 

and leaching of calcium ions into the solution. As a result 

of calcium hydrolysis, Ca(OH)2 particles are formed in 

solution. Also, hydrolysis of metal salts occurs in the alka-

line medium and a sol of the corresponding hydroxides is 

formed. The growth of the metals concentrations in the 

model solution increases the amount of hydrosol in the 

solution. Joining to the particles of the material, it pro-

vides additional fixation of free metal ions from the solu-

tion that increases the purification efficiency of the pro-

cess. In addition, Ca(OH)2 and CaO particles act as links 

which are capable to sorb metal hydroxide molecules on 

its surface and to agglomerate it. An indirect confirmation 

of the implementation of such mechanisms is the for-

mation of a loose precipitate over the surface of the stud-

ied material, observed throughout the process. 

The metal hydroxides formation in soils and their tran-

sition from a mobile to a fixed form (hydroxide formation) 

begins at pH > 5.5 for lead and > 7.5 for other metals [18]. 

The pH value in the filtrates after the sorption process in 

all experiments was 11.5-12.0. Therefore, most of the con-

taminants were in the MeOHn form after sorption. The 

mechanisms of metals interaction with the surface of the 

sorbent particles leading to their accumulation can be rep-

resented by the following reactions: 

3СaO∙SiO2 + 2H2O + Me
2+

 →  

→ MeO∙SiO2 + 2Me(OH)n + Ca
2+

 
(1) 

CaO∙SiO2∙H2O + Me
n+

 + H2O →  

→ Me(OH)n + SiO2∙H2O + Ca
2+

 
(2) 

CaO∙SiO2∙H2O + Me
2+

 → MeO∙SiO2∙H2O + Ca
2+

 (3) 

2СaO∙SiO2∙H2O + Me
2+

 + H2O →  

→ MeO∙SiO2∙H2O + Ca(OH)2 + Ca
2+

 
(4) 

2(2СaO∙SiO2∙H2O) + 3Me
2+

 + 2H2O →  

→ MeO∙SiO2∙H2O + СaO∙SiO2∙H2O + 2Me(OH)n + 3Ca
2+

 
(5) 

3СaO∙SiO2 + 2H2O → 2CaO∙SiO2∙H2O + Ca(OH)2 (6) 

The mechanisms of heavy metals sorption demonstrate 

how the geochemical barrier based on the building refuse 

acts to prevent the migration of pollutants into deeper 

soils layers. However, it is necessary to bear in mind that 

soils are dynamic systems there are the processes of sub-

stance migration, such as aqueous solutions of organic 

components and inorganic compounds, continuously oc-

cur. Water influences the migration of many elements and 

since the sorption of metal ions on the surface of silicon, 

calcium and magnesium-containing materials is a reversi-

ble process, (Me
n+

)sol ↔ (Me
n +

)sorb, under corresponding 

conditions it washes out some of the ions being passed by 

the geochemical barrier. 

So, experiments to determine the ability of a sand-

breakstone mixture to retain heavy metal ions adsorbed 

on the surface of its particles in dynamic conditions were 

carried out. The results of the studies for each sample are 

shown in Fig. 2 as a dependence of the total content of 

metal ions in filtrates depending on the volume of water 

having passed through the sorbent layer. Fig. 3 shows sim-

ilar relationships for each metal in the mixture. As can be 

seen from the presented data, a small part of the metals 

was washed out from the surface of the particles. The total 

metal content in the filtrate did not exceed 1 mg/l, at that 

the highest concentration was typical for zinc, lead and 

mercury. The best resistance to leaching was possessed by 

cadmium ions, whose presence in the filtrate was practi-

cally not detected. 

 
Fig. 2 The dynamics of leaching of sorbed metal ions (total) from 
contaminated material 

Table 1 Initial concentrations of metal ions in model solutions 

Experiment № 
Metals concentrations, mg/l 

Pb Zn Cd Cu Ni Hg 

1 1888.17 1965.68 401.83 3773.37 3326.04 32.07 

2 2454.62 2555.38 522.38 4905.38 4323.85 41.69 

3 3191.00 3322.00 679.10 6377.00 5621.00 54.20 



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Table 2 Residual concentrations of heavy metals in filtrate after sorption 

Experiment № 
Concentrations of metal ions in filtrate, mg/l 

Pb Zn Cd Cu Ni Hg 

1 0.57 0.165 0.0017 0.633 0.12 0.006 

2 0.08 0.138 0.0022 0.299 0.13 0.02 

3 0.05 0.041 0.0010 0.074 0.06 0.031 

   

   
Fig. 3 The dynamics of leaching of each sorbed metal ions from contaminated material 

It should be noted that there was no relationship be-

tween the initial concentration of metals in model solu-

tions and the ability of particles of the sand-breakstone 

mixture to retain it. So, we can conclude that the strength 

of the adsorption depends on most of all the nature of the 

sorbent and the degree of affinity of elements to its sur-

face, and to a lesser extent of concentration. It is known 

that sorption of Cd ions on the surface of calcium-

containing materials most often occurs by the mechanism 

of ion exchange [16], which increases the strength of their 

retention. The remaining metals can be bound by the min-

eral part of the building refuse through chemisorption and 

surface deposition. Such bond is less strong, since metals 

in hydrolyzed forms can change back to the mobile form 

when the external conditions of the process change. 

Thus, part of the retained metals can enter the envi-

ronment. Metals are washed out in a mobile form capable 

of the migration. Using the sand-breakstone mixture as a 

geochemical barrier, some of them will be accumulated by 

the organic matter of the soil. In order to assess the possi-

ble contamination of the underlying soils and the effec-

tiveness of the barrier on the basis of the proposed sand-

breakstone mixture, a comparison of the concentrations 

obtained with the sanitary and hygienic standards work-

ing in the Russian Federation was carried out. The maxi-

mum permissible concentration (MPC) values for acid 

soils were taken because of the most stringent values. A 

comparative analysis of the equilibrium concentrations of 

metals in the filtrates after washing the contaminated 

mixture with standard values MPC showed that their con-

tent did not exceed 0.01 part of MPC. Consequently, using 

the sand-breakstone mixture for reclamation of contami-

nated areas or mixed with contaminated soil will prevent 

the migration of pollutants to lower soils and underground 

horizons. 

4. Conclusions 

Thus, the present study shows the possibility of using the 

sand-breakstone mixture based on building refuse as geo-

chemical barriers for the reclamation of technogenic for-

mations, quarries, planning the territory. An analysis of 

the results showed a high sorption activity of the material 

to a mixture of heavy metals containing ions of lead, cad-

mium, nickel, zinc, copper and mercury both under static 

sorption conditions and in dynamic modeling conditions 

for soil filtration by surface runoff. The material studied 

in the work can be used during reclamation independently, 

or as a geochemical barrier preventing the migration of 

metal ions in a mixture with contaminated soil of the “ex-

tremely dangerous” category. 



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