BioRisk 17: 379-387 (2022) Pete rag ae ei aca rey
doi: 10.3897/biorisk.| 7.77466 RESEARCH ARTICLE & B lO R IS k

https://biorisk.pensoft.net

Pre-monitoring geochemical research of the river
sediments in the area of Ada Tepe gold mining site
(Eastern Rhodopes)

Dimitar Zhelev', Rumen Penin!

| Department of Landscape Ecology and Environmental Protection, Faculty of Geology and Geography, Sofia
University “St. Kliment Ohridski”, Tsar Osvoboditel Boulevard 15, 1504 Sofia, Bulgaria

Corresponding author: Dimitar Zhelev (zhelev@gea.uni-sofia.bg)

Academic editor: Galina Radeva | Received 1 November 2021 | Accepted 30 December 2021 | Published 21 April 2022

Citation: Zhelev D, Penin R (2022) Pre-monitoring geochemical research of the river sediments in the area of Ada
Tepe gold mining site (Eastern Rhodopes). In: Chankova S, Peneva V, Metcheva R, Beltcheva M, Vassilev K, Radeva G,
Danova K (Eds) Current trends of ecology. BioRisk 17: 379-387. https://doi.org/10.3897/biorisk.17.77466

Abstract

The article depicts the geochemical properties of the landscapes in the Ada Tepe gold mine area before its
launching. The research is conducted by examining the heavy metals (Cu, Pb, Zn, Co, Cr, Mn and Ni)
content in samples of river sediments in the local landscapes. The research aims to analyse the concentra-
tion of heavy metals before the launch of gold mining. The study implements the coefficient of Clarke
concentration. The deviation from the background concentrations is a ratio between the element concen-
tration in the collected environmental samples and the Clarke value of the element. ‘The coefficient has a
scale from 0 to a particular positive value, corresponding to the level of enrichment of the sample in com-
parison to the background Clarke value. The values corresponding to the Clarke concentration are equal
to 1, the lower values are between 0 and 1 (dispersion) and any value higher than 1 is a case of concentra-
tion (enrichment). The obtained results display the researched territory as a natural background area. The
content of heavy metals in the river sediments of the researched area (mg/kg, median value) by chemical
elements is Cu (15), Zn (72), Pb (17), Mn (461), Ni (35), Co (8) and Cr (60). That is the reason it could
be defined as not impacted by human activities and it is not influenced by natural geochemical anomalies.
Heavy metals do not pollute the researched landscapes before mining. This outcome is obtained by the

geochemical content of the investigated heavy metals in the river sediments.

Keywords

Ecogeochemistry, environmental impact, gold mining, landscape assessment, pollution

Copyright Dimitar Zhelev & Rumen Penin. This is an open access article distributed under the terms of the Creative Commons Attribution License
(CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

380 Dimitar Zhelev & Rumen Penin / BioRisk 17: 379-387 (2022)

Introduction

In 2016, the current research was conducted as an environmental pre-monitoring ac-
tivity in the area of the Ada Tepe gold mining site (Eastern Rhodopes, Bulgaria). The
mine itself started exploitation in 2018 after years of delay due to obstructions by local
authorities and non-governmental organisations. The non-supporters of the project
outlined possible environmental damage, such as contamination of rivers with heavy
metals, loss of habitats, air pollution etc., that might be caused by the mine. As a result,
the company Dundee Precious Metals Inc. reshaped its initial business plans to satisfy
the demands of the local community for better environmental security.

In ancient times, the area of Ada Tepe was a well-known place for its metal depos-
its. People used to mine gold thousands of years ago. This activity caused local environ-
mental changes such as deforestation, soil erosion and topographical transformations
(Popov et al. 2015; Nikov 2017; Nikov et al. 2018). Probably, at that time, people
impacted the geochemistry of the area as well.

The study is focused on the concentration of heavy metals (Cu, Pb, Co, Zn, Mn, Ni
and Cr) in the river sediments of particular catchments as a geochemical indicator for
the environmental status of the territory. The obtained results are a baseline for future
monitoring and assessment of contamination with heavy metals and human impact.

Methods

The methodological base of this investigation was the system approach (Perelman
1975; Avesalomova 1987; Kabata-Pendias 2010; Kasimov 2013). We conducted a
study through an analysis of the chemical elements'content in the river sediments. The
sediments naturally absorb the substances transported by rivers and that is why any
anomaly of chemical concentration could be easily detected. This approach allows the
tracking of anomalies, either human activities or natural factors.

The chemical elements'content in the various rocks and soils does not match the
Clarke value of the element (the average chemical element’s content in the lithosphere).
That is why the coefficient of Clarke concentration outlines the abundance or the lack
of particular elements in rocks, soils and river sediments. It is a quantitative proportion
between the chemical element’s content in a natural component such as a rock, soil,
water, plants and the Clarke value of the element.

In the current study, the deviation from the background concentrations is a ratio
between the element concentration in the collected environmental samples of river
sediments and the Clarke value of the element. The coefficient has a scale from 0 to
a particular positive value, corresponding to the level of enrichment of the sample in
comparison to the background Clarke value. The values corresponding to the Clarke
concentration are equal to 1, the lower values are between 0 and 1 (a case of disper-
sion) and any value higher than 1 is a case of concentration (a case of enrichment).

Pre-monitoring geochemical research in the area of Ada Tepe 381

The coefficient allows the implementation of a comparative analysis between particular
areas. Ihe current study compares the area of Ada Tepe to technogenic and natural ter-
ritories in Europe and Bulgaria.

This study analysed 12 samples of river sediments for particular chemical elements
(Cu, Pb, Zn, Ni, Co, Cr and Mn). The samples were collected by a standardised meth-
odology. Every sample (500 g, grain size < 0.5 mm) was collected from the upper layer
(0—5 cm) of the river-dried thalwegs during the summer when all intermittent rivers in the
area dry out. We selected the locations by an analysis of spatial perspective and topograph-
ic accessibility. The locations allow interpreting the geochemical influence of the Ada Tepe
itself and the influence of the tributaries that confluence the main river in that area.

The collected samples were analysed in the Geochemistry Laboratory of Sofia
University. The sediments were dried, quartered, levigated in a porcelain cup, sifted
through a 63 um sieve, burned at 500 °C and dissolved by a mixture of acids (HCIO Fe
HF and HCl). Heavy metals content in the chemical solution was obtained by the
method of atomic-absorption spectrometry (Perkin-Elmer 3030).

Results

River sediments are a geochemical indicator for the environmental status within a
catchment. In recent years, many scientists have applied the basin approach in eval-
uating the natural processes and human impact on the environment (Kasimov and
Penin 1991; Perelman and Kasimov 1999; Kotsev 2003; Kasimov 2013; Zhelev 2016;
Nikolova 2020).

The bedrock, the topography, the vegetation and the climate determine the prop-
erties of the river sediments in the area of Ada Tepe. The impact of ancient people is
still visible in the features of the landscapes with some rock niches and ancient min-
ing topography changes. The precipitation rates (760 mm per year) directly affect the
river sediments'accumulation, transportation and deposition. ‘The precipitations are at
a maximum in autumn and winter. They affect the slope of the streams and the forma-
tion of sediments in the riverbeds of Krumovitsa and its tributaries. Deforested land-
scapes in the area enable active bedrock weathering and enforce lateral erosion, a trig-
gering factor for increasing the solid outflow in the rivers. The numerous gullies and
ravines in the local topography enable the easy accumulation of sediments alongside
the river banks. The local lithology is the primary natural factor that determines the
geochemical content of the river sediments. Different types of rocks specifically prede-
termine the variation in the mechanical and chemical structure of the river sediments.

The results from the investigated locations (Fig. 1) are shown in Table 1. Four
elements significantly vary in different locations: Mn, Ni, Cr and Zn. The obtained
results allow a comparative spatial analysis between particular locations alongside the
river course (absolute values) and the comparison with other areas and norms outside
the catchment (median values).

382 Dimitar Zhelev & Rumen Penin / BioRisk 17: 379-387 (2022)

Se
4 Ae

=

a)”

ay,

Figure |. Locations of collecting samples of river sediments around Ada Tepe.

Table |. Content of heavy metals in river sediments in the Ada Tepe Mining Site area (mg/kg).

No. Location Coordinates Cu Zn Pb Mn Ni Co Cr
1 Krumovitsa River before the confluence of Kesibir River 41°25'18"N, 25°39'21"E 5 61 29 459 4 7 5
2 Krumovitsa River (a large meander south east of Ada Tepe) 41°25'30"N, 25°39'55"E 5 130 19 206 6 5 II
3 Krumovitsa River east of Ada Tepe (before the confluence of Kalach) 41°26'12"N, 25°39'56"E 24 46 10 553 55 16 95
4 Krumovitsa River before the confluence of Byuyuk Dere 41°26'34"N, 25°40'24"E 50 76 13 766 124 25 195
5 Krumovitsa River near the bridge between Ada Tepe and Krumovgrad — 41°28'06"N, 25°39'03"E_ 42 80 10 609 94 21 149
6 Krumovitsa River in Krumovgrad 41°28'21"N, 25°38'54"E_ 45 68 15 92 53 7 88
7 Krumovitsa River north of Krumovgrad 41°28'47"N, 25°38'30"E 13 43 13 438 40 13 102
8 Kesibir River before the confluence in Krumovitsa River 41°25'14"N, 25°38'50"E 8 147 39 2000 12 4 16
9 A nameless left tributary of Kesibir River 41°25'27"N, 25°38'55"E 28 62 16 89 63 10 89
10 An intermittent stream — a small left tributary to Krumovitsa River 41°25'39"N, 25°939'09"E 6 «141 21 250 4 3 7
11 Byuyuk Dere (Golemi Dol) —a right tributary of Krumovitsa River 41°26'39"N, 25°40'44"E 10 54 30 464 30 5 Il
12 Kese Dere —a left tributary of Krumovitsa in Ada Tepe 41°26'29"N, 25°38'54"E 18 155 28 490 13 8 31

Average 21 89 20 535 41 10 67
Median 15 72 17 461 35 8 60
Minimum value 5 48 10 89 4 3 5
Maximum value 50 155 39 2000 124 25 195
Discussion

At first, the content of heavy metals of all sediments in the researched area (median
value) is compared to other territories (Europe, Bulgaria), to lithological data (litho-

Pre-monitoring geochemical research in the area of Ada Tepe 383

sphere, acidic metamorphic rocks in Bulgaria) and to adopted threshold environmen-
tal concentrations and predicted environmental concentrations (Table 2).

The data outline the similarities and differences between the Ada Tepe area and
the compared references. A geochemical spectrum (Fig. 2) visualises the associations
of chemical elements within the river sediments of the Ada Tepe area, Europe, natural
background territories in Bulgaria and technogenic areas in Bulgaria. Several peculiari-
ties are visible on the spectrum. Most of the investigated chemical elements are with a
lower concentration in comparison to the river sediments of Europe. Only nickel has
a higher value than Europe’s: 35 mg/kg in the Ada Tepe area compared to 11 mg/kg in
Europe. Comparing the research area to the natural background territories in Bulgaria
(protected areas with minor human impact) outlines a similar situation. Only nickel
has higher concentrations: 35 mg/kg in the Ada Tepe area and 28 mg/kg as a refer-
ence for a natural background territory in Bulgaria. The scale of this excess is relatively

Table 2. Comparative data for content of heavy metals (mg/kg) in the river sediments.

Area Cu Zn Pb Mn Ni Co Cr
Lithosphere (Vinogradov 1962) 47 83 16 1000 58 18 83
River sediments in Europe (Salminen et al. 2005) 22 120 39 1120 11 353) 95
River sediments in Bulgaria — natural background territories (Penin 2003) 45 94 25 777 28 17 64
River sediments in Bulgaria — industrial (technogenic) territories (Penin 2003) 217. 155 102 972 35 37 #74
River sediments in Ada Tepe Area (Median) 15 72 17 461 = 35 8 60
Soils in Ada Tepe Area (Median) 18 77 19 597 Al 10 «34
Acidic metamorphic rocks in Bulgaria — predominant in the Ada Tepe Area (Kuykin et al. 2001) 20 50 20 287 10 11 8
Threshold environmental concentrations (TEC) (MacDonald and Ingersoll 2002) 32 121 36 460 23 - 43
Predicted environmental concentrations (PEC) (MacDonald and Ingersoll 2002) 149 459 128 1100 49 - 111

bs in

wa

Clarke of concentration

Pb Co Zn Mn Cr Cu Ni

Lithosphere (Clarkevalue of the element)

oes RED Sediments of Europe

=e s os River sediments in natural backround areas of Bulgaria
eee River sediments in technogenic ares in Bulgaria
soneee Rwer sediments in Ada Tepe area

Figure 2. Heavy metals in river sediments in Europe, Bulgaria and Ada Tepe area, based on the Clarke

concentration.

384 Dimitar Zhelev & Rumen Penin / BioRisk 17: 379-387 (2022)

tiny and it demonstrates no anomaly. Nickel has coefficient values of Clarke concen-
tration varying between 0.5 and 0.6 in the three comparable territories in Bulgaria.
In the rivers of Europe, it is more dispersed and has smaller coefficient values (0.2).
The obtained data certify no geochemical anomalies for this territory, either caused by
natural factors or human impact. We published results based on investigated plant tis-
sues about geochemical anomalies in the area (Penin and Zhelev 2020), with the same
outcomes. The investigated heavy metals did not contaminate the catchments in the
Ada Tepe area by 2016.

Another analysis compares the geochemical properties of the local rock formations
of acidic metamorphic rocks in the area (Kuykin et al. 2001) and the investigated river
sediments. The chemical elements, Zn, Mn and Cr, have higher concentrations in the
river sediments than the rocks. The difference is relatively small and it correlates to lo-
cal geochemical variants within the landscape.

We compared the river sediments of the Krumovitsa River (the main river in the
catchment) in different sections of its course to clarify the spatial differentiation of
chemical elements in the area (Fig. 3). The spectrum displays an association of chemi-
cal elements (Co, Cu, Ni and Cr) from the analysed sample, collected before the Ada
Tepe area (Location 1, Fig. 1). Only lead has higher concentration (a Clarke concentra-
tion of 1.8) in this sample. The other chemical elements are dispersed in the sediments.
Four of them (Co, Cu, Ni and Cr) have significantly lower concentrations than the
results of the area where the Krumovitsa River passes near the foothill of Ada Tepe
(Location 4, Fig. 1) and the downstream area after the river passes through the town of
Krumovgrad (Location 7, Fig. 1). The results outline the local geochemical influence
of Ada Tepe’s metallogenic rock formations for chemical elements (Co, Cu, Ni and

2,5

Clarke of concentration

Pb én Mn Co Cu Ni Cr

Lithosphere (C brke value of the element) Krumovitsa River before the Ada Tepehill (p. 1)

= = KrumovitsaRWernearAdaTepe hill(p 4) ssesas Krumovitsa river after Krumovgrad (p. 7)

Figure 3. Heavy metals in the sediments of the Krumovitsa River, based on the Clarke concentration.

Pre-monitoring geochemical research in the area of Ada Tepe 385

Cr). Six elements (Zn, Mn, Co, Cu, Ni and Cr) are with lower concentrations in the
downstream area after the river passes through the town of Krumovgrad, compared to
the area where the Krumovitsa River passes near the foothill of Ada Tepe. This circum-
stance proves that there is no technogenic geochemical anomaly in the river sediments
caused by industrial or urban infrastructure.

Another more detailed analysis of the distribution of heavy metals in the river sedi-
ments alongside the Krumovitsa River focuses on seven locations (Fig. 4). The absolute
values of chemical content in the sediments vary and there is one more specific sample
(Location 4, Fig. 1) where there are increased concentrations of four chemical ele-
ments (Cu, Zn, Ni and Cr). This local anomaly is probably naturally determined and
reflects the local geochemical influence of the ore-rich hill of Ada Tepe. The influence
of Buyuyk Dere (one of the significant tributaries) explains the decrease of concentra-
tions downstream. The values with a lower concentration of chemical elements in the
tributary sediments (Location 11, Fig. 1) prove its impact as a natural disperser.

There are no legally adopted norms for recommended environmental concentra-
tions in the river sediments of metals and metalloids in the European Union, although
there are such norms in the United States of America. The Environmental Protection
Agency (US EPA) institutionalises them. The norms adopted by the US EPA con-
sider two levels of quality for the river sediments (MacDonald and Ingersoll 2002).
The first is the threshold environmental concentration (TEC) and the second is the
predicted environmental concentration (PEC). The threshold environmental concen-
tration highlights the acceptable levels of metals and metalloids, while the predicted
environmental concentration raises awareness for possible negative effects on the wild-
life in the ecosystems where the river sediments are. There is a similar approach in

mg/kg

100 6

Beforetheconfluence of Bg meander south east of East of AdaTepehill (p. 3) Beforetheconfluence of Nea the bridgeof In Krumovegrad (p. 6) After Krumovegrad (p. 7)
Kesibir River (p. 1) Ada Tepe hill (p.2) Byuyuk Dere(p.4) Krumovgrad (p. 5)

eee Age ees Pe a ge flow direction ae

Figure 4. Quantity of microelements in the river sediments of the Krumovitsa River.

386 Dimitar Zhelev & Rumen Penin / BioRisk 17: 379-387 (2022)

the Canadian Province of Ontario, where manganese and iron are chemical elements
used for monitoring (Guidelines for Identifying, Assessing and Managing Contami-
nated Sediments in Ontario: An Integrated Approach 2008). Table 2 applies the norms
for Mn from Ontario, Canada. The concentration of cobalt in river sediments does
not have a standard value neither in the USA nor in Canada. Similar studies use the
application of threshold environmental concentration and predicted environmental
concentrations as a reference for a comparative analysis (Cholakova and Penin 2016).
The obtained results from the Ada Tepe area are analysed under the perspective of
threshold and predicted environmental concentrations for metals and metalloids. The
results show that five of the investigated chemical elements (Cu, Zn, Mn, Co and Pb)
do not exceed the threshold environmental concentrations. Nickel (35 mg/kg) and
chromium (60 mg/kg) exceed the threshold environmental concentrations (23 mg/
kg for Ni; 43 mg/kg for Cr). None of the investigated chemical elements exceeds the

predicted environmental concentration.

Conclusion

The performed study highlights the environmental status of the Ada Tepe area before
the start of the mining activity. There was no contamination with heavy metals of the
investigated river sediments in the Krumovitsa River catchment up to 2016. The geo-
chemical properties of the seven examined chemical elements (Cu, Zn, Pb, Mn, Cr, Co
and Ni) within the local landscapes resemble a natural background territory with no
traces for human impact. Local lithological specifics, but not anthropogenic activity,
determine the geochemical properties of the river sediments in the catchment.

The study is a baseline for future research on the mining impact on landscapes and
ecosystems. An extension of the list of investigated chemical elements is recommended
to encompass the geochemical picture of the area. ‘The effect of the ongoing mining ac-
tivity in Ada Tepe must be a subject of regular independent environmental monitoring.

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