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Monitoring heavy metal pollution in foraminifera from the Gulf of Edremit (northeastern Aegean Sea) between Izmir, Balıkesir and Çanakkale (Turkey)
Accepted Manuscript Monitoring heavy metal pollution in foraminifera from the gulf of edremit (northeaster aegean sea) between izmir, balikesir and çanakkale (turkey)
Zeki Ünal Yümün, Melike Önce PII:
S1464-343X(17)30132-2
DOI:
10.1016/j.jafrearsci.2017.03.015
Reference:
AES 2851
To appear in:
Journal of African Earth Sciences
Received Date:
18 February 2017
Revised Date:
09 March 2017
Accepted Date:
17 March 2017
Please cite this article as: Zeki Ünal Yümün, Melike Önce, Monitoring heavy metal pollution in foraminifera from the gulf of edremit (northeaster aegean sea) between izmir, balikesir and çanakkale (turkey), Journal of African Earth Sciences (2017), doi: 10.1016/j.jafrearsci.2017.03.015
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ACCEPTED MANUSCRIPT
HIGHLIGHTS In this study, the populations and abnormal shell structures of Quaternary foraminifera in the sediments of the northeaster Aegean Sea were examined. Examination of the faunal and sedimentological properties of the samples showed that the Gulf of Edremit is completely influenced by the sea and has rich foraminifera and ostracod populations. Scanning electron microscopy was used to perform an elemental analysis of the surfaces of dark yellow-orange foraminifera. The S, Fe and Mn concentrations in the shells were found to be high like in hydrotermal waters.
ACCEPTED MANUSCRIPT 1
MONITORING HEAVY METAL POLLUTION IN FORAMINIFERA
2
FROM THE GULF OF EDREMIT (NORTHEASTER AEGEAN SEA)
3
BETWEEN İZMIR, BALIKESIR AND ÇANAKKALE (TURKEY)
4
Zeki Ünal YÜMÜN1 Melike ÖNCE2
5 6
1Namık
Kemal University, Çorlu Faculty of Engineering, Çorlu, Tekirdağ/TURKEY, [email protected]
7
2Namık
Kemal University, Çorlu Faculty of Engineering, Çorlu, Tekirdağ/TURKEY, [email protected]
8 9
ABSTRACT
10
In this study, the populations and abnormal shell structures of Quaternary foraminifers in the
11
sediments of the North-eastern Aegean Sea were examined. For this purpose, offshore drilling
12
was carried out at three locations, and core samples were collected from 13 locations at
13
Küçükkuyu (Çanakkale), Güre (Edremit-Balıkesir) and Dikili (İzmir). At these points, drilling
14
reached depths ranging from 3.00 to 22.00 m beneath the seafloor; recent sediments were
15
observed, but the bedrock was not reached. Examination of the faunal and sedimentological
16
properties of the samples showed that the Gulf of Edremit is completely influenced by the sea
17
and has rich foraminifers and ostracod populations.
18
The abnormalities observed in the foraminifer shells, as well as the yellow- and/or black-
19
coloured shells seen in both the foraminifer and ostracod populations, are due to natural and
20
anthropogenic ecological pollution. The vertical (chronological) and horizontal (spatial)
21
distributions of heavy metal concentrations in both the core and drill core samples were
22
investigated to determine the causes of the morphological abnormalities observed in the
23
foraminifers. In the present study, pollution index (PI) values were calculated to assess the
1
ACCEPTED MANUSCRIPT 24
degree of heavy metal pollution (Yümün 2017). The current land use status of the coastal areas
25
corresponding to the measured PI values was investigated to identify the sources of the
26
pollution. Especially in the Güre region, a large number of genera and species of benthic
27
foraminifers showed overgrowth in the shell sizes of individuals, and the coloration of the shells
28
is noteworthy.
29
These changes in the shells are a result of thermal sources and agricultural activities in the
30
region. Scanning electron microscopy (SEM) was used to perform an elemental analysis of the
31
surfaces of dark yellow-orange foraminifers (Ammonia compacta and Elphidium crispum). The
32
S, Fe and Mn concentrations in the shells were found to be high, based on the SEM analyses.
33
This is similar to the high S and Fe contents of thermal waters. Thus, the main causes of the
34
coloration of the shells have been accepted to be both thermal waters and fertilizers and
35
pesticides that are used in agricultural activities.
36 37
Keywords: Heavy metals, Pollution Index, Aegean Sea, Edremit, Balıkesir, Çanakkale
38 39
1. INTRODUCTION
40
Seas have been exposed to pollution caused by people for centuries. As technological
41
advancements have increased with time, the quantity and toxic properties of pollution have
42
changed. Before the Industrial Revolution, seas were only polluted with domestic and
43
agricultural wastes; following the Industrial Revolution, the discharge of dangerous chemical
44
wastes into the seas began. Of the wastes created by both industrial and agricultural activities,
45
heavy metals represent the most significant pollutants. Heavy metals dissolve in water; thus,
46
they are the most important pollutants in aquatic ecosystems.
2
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Their persistence in the environment, toxicity at high concentrations, tendency to accumulate
48
in tissues and biomagnification in the food chain pose a threat to people. Therefore, the
49
monitoring and control of heavy metals in aquatic ecosystems have been studied by many
50
researchers (Uluturhan and Küçüksezgin 1998). Because of its geographical location and
51
geological structure, the Gulf of Edremit is a landlocked gulf. In addition, the flow is limited in
52
the study area, so it is rather defenceless against heavy metal pollution. The effect of heavy
53
metals on foraminifers was investigated in the study area, which is an important tourist
54
attraction. Foraminifers are single-celled and usually very small organisms that date back to the
55
beginning of life on earth and that have evolved over time (Meriç, 1983). Recent studies have
56
used foraminifers as biological indicators of heavy metal pollution in seas, and this study
57
adopted the same method.
58
In a study conducted in the Dikili Gulf (in the northeastern Aegean Sea), Meriç et al. (2003)
59
identified three different abnormal benthic foraminifers species (Peneroplis planatus, Rosalina
60
sp. and Elphidium crispum). They reported that the individual benthic foraminifers they
61
observed, which had an abnormal appearance, may have been affected by the thermal sources
62
that have developed due to the presence of active earthquake faults in the region. Meriç et al.
63
(2008) investigated the effects of inner sea sources on the foraminifers and ostracod populations
64
in the Gulf of Saros. In their study, which was titled, “The Effect of Water Resources Containing
65
Thermal Minerals on the Benthic Foraminifers Population in the Coastal Areas of the Eastern
66
Aegean Sea”, Meriç et al. (2009), showed that the coloration and morphological deformities
67
observed in the foraminifers shells at certain locations occurred because the water contained
68
minerals from thermal springs. The present-day planktonic foraminifers species and their
69
spatial distribution were determined by Toker and Yıldız (2002). Avşar (2002) carried out a
70
taxonomic examination by examining the distribution of benthic foraminifers in the North-
71
eastern Aegean Sea. Üstünada et al. (2011) investigated seasonal changes in heavy metals in 3
ACCEPTED MANUSCRIPT 72
the benthic organisms of the species found in the Çanakkale Strait. Yümün et al. (2016) studied
73
the foraminifers, ostracod and mollusc populations in the İzmir Gulf (Karşıyaka, Bayraklı,
74
İnciraltı and Çeşmealtı), and the effects of heavy metals on these organisms. Yümün (2017)
75
investigated the effects of heavy metals on the foraminifers populations found in the Holocene
76
sediments in the western Marmara Sea. In this study, an average value called the “Pollution
77
Index (PI)” was used to summarize the results of geochemical analyses. The relationships
78
between the Pollution Index (PI) and foraminifers numbers, as well as the diversity of genera
79
and species, were assessed in this study.
80
The distribution of heavy metal concentrations in a wide area from Babakale (Çanakkale) to
81
Dikili (İzmir) was investigated, and zones with heavy metal pollution were identified. The
82
drilling data were used to determine the co-occurrence of heavy metals and foraminifers
83
populations over time, while data from the core samples were used to investigate the current
84
status. Approaches to studying the effects of heavy metals on foraminifers and the sources of
85
heavy metal pollution were developed, based on investigation of the samples. A similar study
86
was carried out by Bergin et al. (2006) in the İzmir Gulf. Meriç et al. (2012) studied the effects
87
of oceanographic properties on the benthic foraminifer, ostracod and bryozoan populations in
88
the coastal areas of the Gulf of Edremit (Balıkesir), but that study only focused on a small area
89
and was limited to grab samples, whereas this study used drill and core samples and considered
90
older periods in terms of geochronology.
91
2. MATERIALS AND METHODS
92
The present-day sediment samples were collected from three different locations in the
93
northeastern Aegean Sea, specifically Dikili (İzmir, SK-1), Güre (Balıkesir, SK-2) and
94
Küçükkuyu (Çanakkale, SK-3) (Fig. 1). A modular sea buoy and a drilling machine with a semi-
95
hydraulic rotary system built on the buoy were used for drilling. Furthermore, core samples
96
were collected from 13 different locations in the study area (Burhaniye-Ören, Akçay Körfez, 4
ACCEPTED MANUSCRIPT 97
Güre Fener, Güre Merkez, Dalyan, Babakale, Asos Kamplar, Altınoluk, Gömeç, Cunda Adası,
98
Sarımsaklı, and Altınova). The samples collected transported to the laboratory while protected
99
from the sun in opaque core boxes. A total of 241 samples, including 176 samples from the 3
100
drill cores and 65 samples from the other core samples, were examined (Table 1).
101
102 103
Figure 1: Sample (Bore Hole and Core Samples) location map
104 105
Moreover, sea water samples were collected from 10 locations, and hydrothermal water samples
106
were collected from 2 locations, to determine the relationships between the heavy metal
107
contents of the sea water, the hydrothermal water and the sea sediments (Table 1).
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ACCEPTED MANUSCRIPT Table 1: The properties of the drilling and core samples
108 Sort No of Sample
Sea Water Samples
Dikili BH-1 Güre BH-2 K.Kuyu BH-3 Core-1 Core-2 Core-3 Core-4 Core-5 Core-6 Core-7 Core-8 Core-9 Core-10 Core-11 Core-12 Core-13
Hydrothermal Water Samples
Sample Locations
Dikili/İzmir Güre/Balıkesir K.Kuyu/Çanakkale Burhaniye- Ören Akçay-Balıkesir Güre/Fener-Balıkesir Güre/Merkez-Balıkesir Dalyan/Edremit Babakale-Çanakkale Asos/Çanakkale Altınoluk/Balıkesir Gömeç- Balıkesir Cunda Adası/Balıkesir Ayvalık Sarımsaklı Altınova/ B.Kesir Altınova/Balıkesir Dikili Altınova merker Cunda adası Sarımsaklı ayvalık Gömeç Burhaniye/Ören Dalyan edremit Akçay Güre merkezs Altınoluk ENTUR-Edremit/Balıkesir AFRODİT-Güre/Balıkesir
Geographic Coordinate East (Y) 490060.55 489776.20 466009.22 0493908 0493240 0487550 0489776 0495590 0489830 0448819 0478001 0483063 0472857 0471845 0480092 0485272 490145.45 478615.23 473445.98 471182.99 483322.06 493893.57 495272.12 493302.40 489535.40 477243.35 503670.19 490008.62
North (X) 4324738.74 4381514.27 4377155.44 4371663 4381247 4379549 4381655 4378221 4381641 4372621 4379661 4360373 4355018 4348423 4342318 4332873 4324372.27 4337596.56 4354828.82 4346301.37 4360944.68 4370561.51 4379490.82 4381485.51 4381686.38 4379525.96 4379973.70 4382032.28
Deniz Suyu Derinliği (m)
Numune Derinliği (m)
Numue Botu (m)
13,00 9,20 10,20 11,00 8,00 8,00 9,00 10,50 9,00 3,00 4,50 3,00 2,00 2,50 3,00 3,00 2,00 2,00 3,00 2,50 2,50 2,50 2,00 3,00 3,50 4,50 -
13,0-20,0 9,20-30,0 10,20-31,45 11,75 8,50 8,75 10,00 11,25 9,60 3,50 5,25 3,50 3,00 3,25 3,50 3,60 1,00 1,00 1,00 1,00 1,00 1,00 1,00 1,00 1,00 1,00 -
7,0 20,80 21,25 0,75 0,50 0,75 1,00 0,75 0,60 0,50 0,75 0,50 1,00 0,75 0,50 0,60 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt
109 110
Wet sieve analysis was used to determine the grain-size distribution of the present-day sediment
111
samples. Prior to the sieve analysis, 10% H2O2 was added to 15 grams of each sediment sample.
112
The samples were then stored for 24 hours and washed with water in a 0.125 mm sieve.
113
Following the washing process, the samples were dried for 6 to 8 hours at 75 0C, and the
114
foraminifers and ostracods were identified with a binocular microscope. Microphotographs of
115
the foraminifers genera and species were taken with a scanning electron microscope (SEM)
116
belonging to the Scientific and Technological Research and Application Centre of Namık
117
Kemal University (NABİLTEM). An elemental surface analysis of the foraminifers that
118
showed changes in coloration (Ammonia compacta and Elphidium crispum) was also performed
119
with SEM. A geochemical analysis of the two water samples obtained from the geothermal
6
ACCEPTED MANUSCRIPT 120
water resources on the seashore were carried out to determine the source of the heavy metals
121
observed in the foraminifers shells.
122
For the heavy metal analysis, 15 grams of each sediment sample were simultaneously taken
123
from the same levels as were sampled for palaeontological analyses. Once the samples had been
124
dried at 50°C for 24 hours, they were then pulverized in a mortar. Heavy metal analysis of the
125
pulverized samples was carried out using a SPECTOBLUE model ICP-OS housed at
126
NABILTEM. For sample combustion, 0.5 grams of the pulverized samples was weighed and
127
transferred to combustion tubes. A 12-ml amount of HNO3 and 4 ml of HCl were added to these
128
samples, which were heated at 98°C for 1 hour and at 200°C for 1.5 hours. The tops of the
129
cooled tubes were opened in a fume hood, ultra-pure water was added to the tubes up to 50 ml,
130
and the contents were strained through filter paper.
131 132
The prepared samples were placed in the measurement unit of the ICP-OS device (Smart
133
Analyser Vision) to take readings. The concentrations in parts per million (ppm) of 24 heavy
134
metals (Cd, Fe, Cu, Pb, Zn, Co, Cr, Al, Mn, Ni, As and Hg) were then determined. Using the
135
method proposed by Yümün (2017), the Pollution Index (PI) is obtained by dividing the
136
proportion of the total heavy metal concentrations to their average values by the number of
137
measurements. This is the first study that has applied the Pollution Index method to a study
138
area. This method also separately correlates the PI values with the number of foraminifers
139
individuals and species. For quantitative age determinations, 150 grams of young sediment
140
were sampled from the lowest parts of drill cores BH-1, BH-2, and BH-3, which were collected
141
at Dikili (İzmir) (19.00 to 20.00 m), Güre (Edremit/Balıkesir) (29.00 to 30.00 m) and
142
Küçükkuyu (Çanakkale) (31.00 to 31.45 m), respectively.
143 144
7
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3. RESULTS
146
3.1. Regional Sedimentation
147
The present-day sediments in the Gulf of Edremit showed properties that are specific to the
148
gulf. Since the Gulf of Edremit is a closed basin, the connection between the gulf and the
149
Müsellim Strait and Dikili Channel is quite restricted. Therefore, there is almost no interaction
150
between the bottom sediments in these three regions. The Müsellim rocks to the east of
151
Bababurun and at the narrowest point between Midilli and the Anatolian landmass restricts the
152
connection between the Gulf of Edremit and the open sea. There is a jump from −100 metres
153
to −50 metres in the area where the Gulf of Edremit connects to the Dikili Channel. This
154
bathymetric difference obstructs the transfer of material from the bottom (50 m depth) of the
155
Gulf of Edremit to the Dikili Channel. The flow in this region is also limited (Eryılmaz and
156
Yücesoy-Eryılmaz 1998).
157 158
3.2. Sedimentological Properties of the Investigated Area
159
The investigated area exhibits a lithology that has a considerable thickness on land, and its grain
160
size changes from coarse to fine towards the sea. At the Dikili drilling site, the water depth is
161
13.00 m. Samples taken from the drill core, which penetrated 20 m, were silty clay and low in
162
sand. At the Güre drilling site, there was sea water between 0.00 and 9.20 m; between a depth
163
of 9.20 and 12.20 m, there was a high water content, as well as dark greenish-black shells at
164
low levels and clay that was low in sand (slime); between a depth of 12.20 and 16.00 m, there
165
was a high water content, medium to dark green shells at low levels and clay that was low in
166
sand; between a depth of 16.00 and 18.00 m, there was black-dark green clay that was low in
167
sand, and between a depth of 18.00 and 30.00 m, the sediment was observed to alternate
168
between green, gravelly and sandy clay, and green clay. At the Küçükkuyu drilling site, the
169
water depth was 10.20 m. This site was drilled to a depth of 31.45 m and yielded 21.25 m of 8
ACCEPTED MANUSCRIPT 170
core sample. The core had high water content and was made up of a dark bluish-black slime
171
between 10.20 and 17.0 m; had medium-high water content and a consistent slime that became
172
more condensed between depths of 17.0 and 20.50 m; and contained greyish-black silty clay
173
between the depths of 20.50 and 31.45 m. A radiometric age determination of the detrital
174
materials, which had largely terrestrial origins was carried out, and their sedimentation rates
175
were determined.
176 177
3.3 Radiometric Age and Sedimentation Rate Determination
178
The sediment samples taken from the bottom-most layers of the Dikili, Güre and Küçükkuyu
179
drill cores were sent to a laboratory (Beta Analytic Inc.) for radiocarbon age determination. In
180
the radiocarbon analysis, the sea sediments were analysed using standard AMS (14C) methods
181
(Table 2). The age of the Dikili sample from the bottom-most layer was determined to be
182
5750+/−30 Before Present (BP) with
183
penetrated 7 m deep below the sea bed. The 7 metres of sediment taken from the bottom of the
184
20-m core sample was tested. That 7 m of sedimentation occurred over 5750 years. The
185
sedimentation rate (Vs) was 1.217 mm/year (Table 2). With the
186
determined to be 2770 +/− 30 BP for the bottom-most layer of the core obtained from the Güre
187
drill site.
14C
dating. In the Dikili drill core (SK-1), the drill
14C
method, the age was
188 189
Table 2: The report from the radiocarbon dating analyses (Beta Analytic Inc.) Sample Data Beta - 423881 SAMPLE : EKP_1 (Dikili/İzmir) ANALYSIS : AMS-Standard delivery MATERIAL/PRETREATMENT : (organic sediment): acid washes 2 SIGMA CALIBRATION : Cal BC 4690 to 4520 (Cal BP 6640 to 6470) Beta – 423882 SAMPLE : EKP_2 (Küçükkuyu/Çanakkale) ANALYSIS : AMS-Standard delivery
9
Measured Radiocarbon Age 5750 +/- 30 BP
Conventional Radiocarbon Age(*) 5750 +/- 30 BP
Sedimentation speed (Vs) mm/year 1,217
3710 +/- 30 BP
3700 +/- 30 BP
5.743
ACCEPTED MANUSCRIPT MATERIAL/PRETREATMENT : (organic sediment): acid washes 2 SIGMA CALIBRATION : Cal BC 2195 to 2165 (Cal BP 4145 to 4115) and Cal BC 2150 to 2020 (Cal BP 4100 to 3970) and Cal BC 1990 to 1980 (Cal BP 3940 to 3930) Beta – 423883 SAMPLE : EKP_3 (Güre/Balikesir) ANALYSIS : AMS-Standard delivery MATERIAL/PRETREATMENT : (organic sediment): acid washes 2 SIGMA CALIBRATION : Cal BC 1000 to 835 (Cal BP 2950 to 2785)
2780 +/- 30 BP
2770 +/- 30 BP
7,509
190 191
Drilling at the 30.00-m-deep Güre site was carried out in a water depth of 9.20 m and yielded a
192
20.80 m core sample. The sedimentation rate (Vs) was found to be 7.509 mm/year by dividing
193
the core length by the sedimentation age. A total core length of 21.25 m was obtained from the
194
Küçükkuyu drill site. With the
195
sample taken from the bottom-most layer of the core. According to this, the sedimentation rate
196
in the Küçükkuyu region was determined to be Vs = 5.743 mm/year. The Dikili area is a plain,
197
and the effect of runoff is low; therefore, it had the lowest sedimentation rate
198
(Vs =1.217 mm/year). The relatively high sedimentation rates inferred from Güre
199
(Vs = 7.509 mm/year) and Küçükkuyu (Vs = 5.743 mm/year) were attributed to the relatively
200
steep slopes of the surrounding land.
14C
method, an age of 3700 +/− 30 BP was obtained for the
201 202
3.4 Foraminifer Population
203
3.4.1 The Foraminifer Population in Dikili:
204
In the Dikili SK-1 drill core samples, 15 genera and 19 species were identified. The foraminifers
205
were Adelosina duthiersi (Schlumberger), Adelosina mediterranensis (Le Calvez, J. and Y.),
206
Ammonia compacta (Hofker), Ammonia parkinsoniana (d'Orbigny), Anomalinoides
207
rubiginosus (Cushman), Brizalina spathulata (Williamson), Elphidium advenum (Cushman),
208
Elphidium crispum (Linne), Elphidium macellum (Fichtel and Moll), Fursenkoina acuta
209
(d'Orbigny), Lagena strumosa (Reuss), Lobatula (Walker and Jacob, 1798), Melonis
210
pompilioides (Fichtel & Moll), Nonionella turgida (Williamson), Pygro inornata (d'Orbigny), 10
ACCEPTED MANUSCRIPT 211
Quinqueloculina seminula (Linnaeus), Reusella spinulosa (Reuss), Rosalina bradyi (Cushman)
212
and Spiroloculina excavata (d'Orbigny).
213 214
3.4.2 The Foraminifer Population in Güre and Küççükkuyu:
215
Six genera and 8 species were found in the Güre SK-2 and Küçükkuyu SK-3 drill core. The
216
foraminifers were Adelosina mediterranensis (Le Calvez, J. and Y.), Ammonia compacta
217
(Hofker), Elphidium advenum (Cushman), Elphidium crispum (Linne), Elphidium
218
complanatum (d'Orbigny), Massilina secans (d'Orbigny), Miliolinella subrotunda (Montagu),
219
and Quinqueloculina seminula (Linnaeus).
11
ACCEPTED MANUSCRIPT 220 221
3.4.3 The Foraminifer Population in the Core Samples:
222
Ten genera and 18 species were seen in the core samples.
223
The foraminifers were Adelosina cliarensis, (Heron-Allen and Earland), Adelosina duthiersi
224
(Sclumberger), Adelosina mediterranensis (Le Calvez, J. and Y.), Amphistegina lobifera
225
(Larsen) and A. lessonii (d'Orbigny), Elphidium advenum (Cushman), Elphidium crispum
226
(Linne), Elphidium macellum (Fichtel and Moll), Lobatula (Walker and Jacob), Massilina
227
secans (d'Orbigny), Peneroplis pertusus (Forskål), Peneroplis planatus (Fichtel & Moll),
228
Planorbulina
229
Quinqueloculina
230
Spiroloculina excavata (d'Orbigny), and Vertabralina striata (d'Orbigny). Since the core
231
samples were obtained from a maximum of 1.0 m below the sea bed, they represent the sediment
232
of the present-day period. The numbers of foraminifers individuals, genera and species (Table
233
3) were compared against the heavy metal concentrations of the same samples (in terms of PI).
mediterranensis seminula
(d'Orbigny),
Quinqueloculina
bidentata
(d'Orbigny),
(Linnaeus),
Quinqueloculina
striata
(d'Orbigny),
234 235
Ostracod Populations: Significant numbers of ostracods were obtained from the 13 core
236
samples and 3 drill core samples collected from the area between Dikili and Babakale. The
237
ostracods, which were identified as belonging to 13 genera and 15 species, were
238
Acanthocythereis hystrix (Reuss), Aurila albicans (Ruggieri), Carinocythereis carinata
239
(Roemer), Carinocythereis whitei (Baird), Cytheridea acuminata (Bosquet), Cytherelloidea
240
vulgata (Müller), Cytherelloidea sp., Cytheretta sp., Falunia sp., Loxoconcha eliptica (Brady),
241
Loxoconcha rhomboidea (Fischer), Loxoconcha sp., Neomonoceratina sp., Pontocythere
242
elongata (Brady), Xestoleberis communis (Mueller), Xestoleberis glabrescens (Reuss),
243
Xestoleberis sp., Urocythereis favosa (Roemer), Urocythereis sororcula (Ulıczny), and
244
Urocythereis sp.
12
ACCEPTED MANUSCRIPT 245
As in the case with foraminifers, changes in colour were also observed in the ostracods. The
246
most common coloration change in the ostracods was to orange.
247 248
Table 3: The foraminifer genera and species in the core samples from the Gulf of Edremit
Core-11
Core-12
5 10
2 5
5
1
5 2 5
35
10 5
Core-8
15 11
1
Core-7
5
1
5
8 5 7
Core-10
3
Core-9
3
5
Core-6
Core-3
5 35
Core-5
10
Core-4
Adelosina cliarensis Adelosina duthiersi Adelosina mediterranensis Ammonia compacta Ammonia parkinsoniana Amphistegina lobifera A. lessonii Cribroelphidium poeyanum Cycloforina contorta Cycloforina villafranca Elphidium advenum Elphidium crispum Elphidium complanatum Elphidium macellum Lachlanella variolata Lobatula lobatula Massilina secans Melonis pompilioides Miliolinella subratunda Peneroplis pertusus Peneroplis planatus P. mediterranensis Porosononion granosum Pseudutriloculina oblonga Pseudotriloculina rotunda Quinqueloculina bidentata Quinqueloculina seminula Q. lamarckiana Quinqueloculina striata Sigmoilinita costata Spiroloculina angulosa Spiroloculina excavata Spiroplectinella sagittula Vertabralina striata Textularia bocki Triloculina marioni Triloculina marioni Number of foraminifer genus Number of foraminifer species Pollution Indes
Core-2
Foraminifers
Core-1
Core Sample No
7
35
25 3
1 7
55 7
1 3
4
12
11
7
7
35
36 17
7 4
4
15
2
1 13 5
1 8
2 4
3
7
5
15 11
7 1
35 11
3 1 4
25
5
11
3 7
4
3 5
4
17 7 3 1 3 19 11
7
11
10 7
11
20 15
40 12
15 10 3
7 7
3
10
12
10 4
7 12
2 3 9 3 5
5
5
2
15
11
13
7
9
2
7 5 5
2 3
1 1
7
4 5
12
3
12
8
17
10
6
13
10
8
4
5
13
4
14
9
23
10
7
14
12
12
6
1,18
1,33
1,03
1,06
1,11
0,86
0,65
0,95
1,62
0,67
0,74
1,20
249 250
13
ACCEPTED MANUSCRIPT 251 252
3.4.4 Morphological deformities in the Foraminifers and the geochemical analyses of their shells
253 254
The foraminifers were yellow-orange in the Güre region (Fig. 2), whereas the colour ranged
255
between orange and black in the Küçükkuyu region (Fig. 3). The foraminifers shells obtained
256
in the Dikili region were in the dark grey–black range (Fig. 4). The numbers of twin growths in
257
the shells of Massilina secans from the Güre and Küçükkuyu regions (Fig. 2/3 and 3/1) were
258
quite high. The hydrothermal waters controlling the ambient temperature, and the high Ca
259
concentration in the environment, were among the most important causes of these
260
morphological deformities.
261
262 263
Figure 2: The morphological deformities found in the Güre drill core samples:
264
1. Ammonia compacta (13.70 m) 2. Massilina secans (15.90 m) 3. Massilina secans (15.70 m)
265
14
ACCEPTED MANUSCRIPT
266 267
Figure 3: The morphological deformities in the foraminifers found in the Küçükkuyu drill core
268
samples: 1. Massilina secans (18.00 m) 2. Miliolinella subrotunda (15.80 m) 3. Adelosina
269
mediteranensis (15.10 m).
270 271 272
Geochemical analyses were carried out to determine the causes of the coloration changes
273
observed in shells from the Dikili region (Fig. 5). The microscopic elemental surface analysis
274
of 2 grams of foraminifers shells was carried out using the ICP-OS device to determine the
275
amounts of elements accumulated in the shells (Table 4). As in the Dikili sediments, the Fe, Zn,
276
Mn, As, Cd, Co, Ni, Pb and Pt values in the shells were quite high. These values are 10 times
277
higher than the ICP-OS values of the foraminifer samples obtained from Güre and Küçükkuyu.
278
279
15
ACCEPTED MANUSCRIPT 280
Figure 4: The coloration changes observed in the foraminifers found in the Dikili drill core
281
samples: 1: Elphidium crispum (14.20 to 14.30 m) 2: Elphidium macellum (15.20 to 15.30 m)
282
3: Elphidium advenum (28.00 to 28.50 m) 4: Ammonia parkinsoniana (19.20 to 19.30 m)
283 284
Table 4: The ICP-OS results of the heavy metals accumulated in the shells and foraminifer
285
tests collected at Dikili, Güre and Küçükkuyu Sample ID
Fe ppm
Dikili foraminifer tests Güre foraminifer tests Küçükkuyu foraminifer tests
143973.31 40.26
3799.11
3012.94
Sample ID
Dikili foraminifer tests Güre foraminifer tests Küçükkuyu foraminifer tests
Cu
Zn ppm
As ppm
B ppm
Cd ppm
Co ppm
Cr ppm
2524.83 255.15 0.40
176.31
22.84
3.49
2.00
5.38
6.73
2077.4
64.39
3.77
0.29
19.11
0
0.91
5.85
3.22
1454.85 28.99
3.59
1.77
15.48
0
0.35
2.21
Ni
Al ppm
Pb
Mn ppm
Ag ppm
Pt
Sb
Na
Mg
ppm
ppm
ppm
ppm
ppm
ppm
ppm
25.30
10.52
31.78
6.49
0.00
1023.35 827.65
14.76
4.10
0.28
0.00
0.33
5333.3
5.09
1.04
0.00
0.00
0.00
5571.25 337.42
K ppm
Ca ppm
P ppm
1291.33 442320.24 234.80
2093.08 1036.24 500787.20 1359.97
1080.27 507674.02 55.48
NOTE: Bi, Sn, Se, Hg and Mo = 0
286 287
Furthermore, the significantly elevated concentrations of some heavy metals (Fe, Zn, Mn, As,
288
Cd, Co, Ni, Pb and Pt) in foraminifers such as Elphidium were due to the perforated structure
289
of their shells. Foraminifer shells become mineral deposits at microscopic scales.
290
16
ACCEPTED MANUSCRIPT
291 292
Figure 5: The ICP-OS results of the foraminifer tests collected at Dikili, Güre and Küçükkuyu
293 294
The elemental surface analyses of the Küçükkuyu (Fig. 6/1) and Güre foraminifer shells (Fig.
295
6/2) were carried out using SEM. In the analyses, the S values of the Güre samples were much
296
higher than those of the Küçükkuyu samples. This is because, at Güre, the geothermal waters
297
mix with the sea in large amounts, whereas there are no geothermal resources in Küçükkuyu.
298
Therefore, water samples were taken from the seashore at Edremit and Güre to carry out
299
geochemical analyses.
300
17
ACCEPTED MANUSCRIPT
301
Figure 6: The elemental surface analysis graphs (sample: Güre BH-2, 15.10 m)
302 303
3.5 The Chemical Properties of the Sediment Samples
304 305
The core samples obtained from the Güre, Dikili and Küçükkuyu drill cores were vertically
306
sectioned at 10-cm intervals, and their heavy metal concentrations were determined (Table 5, 6
307
and 7).
308
In the chemical analyses of the drill core from the Dikili region, Fe and Al levels were higher
309
than those of the other drill cores. There is no significant change in the heavy metal
310
concentrations at different depths obtained from the same core. The fact that Hg was zero at all
311
levels is noteworthy.
312
In chemical analyses of the Güre drill core, the elemental concentrations showed sudden
313
increases at three different depths (Table 5). There was no similarity between the elemental
314
concentrations at other depths. Therefore, the evaluations were based on average values. The
315
average values were 1351.5 ppm for Hg, 462.06 ppm for Mn, 70.61 ppm for As, 66.78 ppm for
316
Cd, and these values were substantially higher than those from the Dikili region.
317
18
ACCEPTED MANUSCRIPT Table 5: The heavy metal distribution in the Güre SK-2 drill core samples
318
Derinlik (m) 13.20-13.30 13.30-13.40 13.40-13.50 13.50-13.60 13.60-13.70 13.70-13.80 13.80-13.90 13.90-14.00 14.00-14.10 14.10-14.20 14.20-14.30 14.30-14.40 14.40-14.50 14.50-14.60 14.60-14.70 14.70-14.80 14.80-14.90 14.9-15.00 15.00-15.10 15.10-15.20 15.20-15.30 15.30-15.40 15.40-15.50 15.50-15.60 15.60-15.70 15.70-15.80 15.80-15.90 15.90-16.00 Average Value
Co
Fe
Pb
As
Cr
Cu
Zn
Al
Mn
Ni
Hg
Cd
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppb
14.837 43.124 26.287 9.945 25.034 23.841 25.090 24.179 18.312 24.340 25.272 25.327 26.943 26.475 35.497 24.743 26.126 25.093 24.904 24.752 29.497 26.842 24.766 24.710 24.360 28.370 39.441 32.462
20871.80 43483.20 35806.50 13835.40 32805.30 32872.00 36375.70 32995.10 21643.90 30289.30 35394.50 35186.30 34200.90 36253.50 39254.60 35374.90 32955.90 33656.80 32410.40 34470.00 35612.90 35448.00 34096.10 33443.10 32794.10 36298.30 45622.00 42481.50
1.85 3.65 5.47 0.02 0.00 0.00 1.36 0.00 0.09 0.20 2.11 7.21 0.35 0.00 0.00 0.22 0.05 0.00 0.90 2.09 9.85 0.26 1.02 3.07 1.51 0.11 0.00 0.00
44.2894 83.6967 74.3962 29.4966 76.7601 70.3402 86.8838 66.5548 47.1204 81.25 84.032 68.9589 93.7122 87.1272 74.2573 83.1218 68.6532 71.0684 66.127 77.874 48.5521 55.9327 73.8981 75.3997 55.2406 82.9546 79.1742 70.1492
27.5 1755.6 58.4 16.9 60.6 57.5 65.7 53.9 504.9 53 54.1 46 79.9 58.4 1101.9 54.8 60.5 62.6 59.8 46.1 61.9 54.6 49.7 49.6 60.9 66.8 1094.5 71.7
3.1 40.6 18.3 5.7 13 10.9 17.2 15.2 0.4 6.4 18.4 14.7 12.6 10.4 21.2 13.8 10.9 10 10 12.3 21.2 17.5 9 12.9 10.7 18.6 35.3 25
29.60 56.80 51.80 10.10 67.20 50.90 51.70 51.10 20.20 40.00 52.60 58.90 52.70 51.00 52.40 52.50 51.70 50.80 62.80 50.20 55.70 53.80 46.60 46.70 45.40 55.10 66.70 65.30
9866.50 11909.90 11882.20 7379.90 12711.40 13095.20 11708.80 13474.10 9020.40 11536.70 12370.60 11001.90 13753.60 14890.00 14939.10 13054.60 14153.80 14005.80 11770.90 12026.70 11884.60 14514.50 12506.30 11313.50 12512.40 14071.50 16281.00 16949.00
247.1 638.7 444.1 173.8 419.7 383.5 434.8 421.5 281.5 399.9 470.1 525.1 481.7 418.3 529.8 407.5 433.9 435.4 462.8 460.2 573.2 512.2 469.8 461.6 523.5 527.9 590 810.2
39.5 954.8 84.9 16.9 68.2 66.9 71.8 64.7 273.3 61.3 70.2 70 86.2 70 601 67.5 80.6 75.2 77.3 70.5 95.8 85.7 69.1 69.3 73.4 90.5 643 102.9
822.7 1756.2 1398.1 540.7 1277.0 1315.3 1433.2 1349.3 841.3 1256.3 1436.5 1379.0 1375.3 1466.5 1600.7 1379.7 1328.9 1347.8 1278.9 1383.1 1392.7 1439.7 1370.9 1308.6 1302.9 1432.7 1864.0 1765.3
0.0 295.5 0.0 357.3 0.0 0.0 0.0 0.0 282.0 0.0 0.0 0.0 0.0 0.0 450 0.0 34.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 450.1
26.09
33783.29
1.478
70.61
206.71
14.83
50.01 12663.75
462.06 150.02
1351.5 66.78
319 320
The heavy metal concentrations obtained from the Küçükkuyu drill site are given in Table 7.
321
Here, Cd, As and Pb were high in the upper levels and lower or zero towards the bottom levels.
322
The high levels of these elements in the upper levels were attributed to the agricultural
323
pesticides and fertilizers that have recently been used in olive cultivation.
324 325 326
Table 6: The heavy metal concentrations in samples from the Dikili Drill Core-1 (BH-1) (Hg
327
was determined to be zero at each level) Numune Derinliği
Cd
Cu
Pb
Zn
Co
Cr
As
Mn
Ni
Fe
Al
(m)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
13.00-13.20
0.461
26.23
6.88
52.8
11.86
39.28
19
22.90
331.10
39.59
29722.60
14715.40
ACCEPTED MANUSCRIPT 13.20-13.40
0.831
26.44
7.20
49
10.40
32.78
20.63
363.30
35.32
28742.20
14135.00
13.40-13.60
0.910
26.97
7.37
63.2
10.22
35.85
21.54
281.50
36.01
30858.50
14420.10
13.60-13.80
1.392
28.92
7.12
58.6
11.49
45.28
20.86
238.40
40.52
32080.30
16369.90
13.80-14.00
1.234
29.10
9.15
67
11.94
44.83
18.02
236.10
40.63
32690.20
16124.80
14.00-14.20
0.786
23.21
10.47
52.2
9.84
32.57
21.58
215.00
32.43
27619.30
12596.20
14.20-14.40
0.738
26.71
0.00
58.2
13.86
79.44
22.68
207.70
50.61
34903.20
18310.00
14.40-14.60
1.265
25.81
6.32
46.3
11.67
42.55
24.69
206.30
39.14
28756.20
14815.10
14.60-14.80
1.338
25.23
7.97
50.6
11.31
40.98
20.74
217.70
37.69
29617.80
14619.60
14.80-15.00
1.050
23.41
7.46
62.3
10.90
40.97
17.98
233.50
36.13
30913.80
14361.20
15.00-15.20
1.382
26.33
9.76
47.3
12.26
39.56
35.50
403.70
41.44
30469.70
14760.60
15.20-15.40
1.240
27.12
6.73
54.6
11.74
40.36
36.72
481.80
42.15
32316.40
15791.30
15.40-15.60
1.519
26.08
9.41
51.7
12.28
42.55
31.84
408.00
43.58
32044.70
15352.90
15.60-15.80
1.455
27.65
8.16
64.8
11.89
47.44
28.08
274.40
45.64
36012.10
17496.20
15.80-16.00
0.926
31.62
7.28
66.1
13.51
106.68
24.96
336.50
62.81
37292.10
19291.90
16.00-16.20
0.000
21.08
7.21
51.1
10.73
39.84
21.18
255.60
34.17
31696.00
16735.90
16.20-16.40
0.388
21.60
7.10
46.4
10.58
59.65
19.49
249.30
44.53
30233.50
14885.30
16.40-16.60
1.315
21.76
5.78
58.5
13.35
56.33
28.65
281.50
47.36
34787.30
17268.80
16.60-16.80
1.456
23.86
4.75
58
11.36
46.39
26.68
279.10
42.58
34702.30
17743.80
16.80-17.00
1.424
23.57
7.14
56.3
11.48
47.03
32.05
308.00
43.22
35230.70
17816.80
17.00-17.20
1.192
22.62
7.15
54.3
11.16
44.51
27.03
272.60
38.97
34219.60
17676.10
17.20-17.40
1.241
22.75
7.13
56.8
11.03
44.03
25.12
301.30
38.27
34316.50
17652.10
17.40-17.60
0.961
42.37
7.82
51.4
16.03
394.11
30.82
326.70
232.44
32255.60
14584.00
17.60-17.80
0.659
19.03
6.65
50.1
9.14
37.19
15.58
221.20
32.92
28014.9
15030.80
17.80-18.00
0.937
27.76
6.06
48.5
14.43
542.18
18.80
280.60
289.58
31229.80
14902.00
18.00-18.20
0.809
20.88
6.45
54.2
11.24
44.46
25.37
269.90
37.22
32299.30
16763.60
18.20-18.40
1.373
22.22
7.99
67.4
11.37
45.07
22.32
277.50
37.85
34736.10
17275.80
18.40-18.60
0.267
21.98
6.61
51.4
10.81
43.24
24.40
272.80
37.85
33249.10
16077.00
18.60-18.80
0.499
23.16
0.00
65
15.38
70.43
27.95
257.10
48.26
36261.10
19070.20
18.80-19.00
2.024
31.80
10.04
195.9
12.51
73.57
30.56
319.90
55.31
40800.90
17458.80
19.00-19.20
0.906
20.29
2.47
53.3
10.45
74.66
19.28
225.70
51.81
29387.20
17094.70
19.20-19.40
1.3754 22.55
8.12
59.5
11.68
49.92
25.00
284.20
39.34
34272.20
17689.20
19.40-19.60
2.158
25.33
4.05
61.5
12.03
51.36
21.58
280.00
45.74
35461.60
18560.50
19.60-19.80
0.750
21.87
8.54
50.5
10.61
55.04
25.94
277.60
42.90
31737.40
14447.10
19.80-20.00 Average Value
1.362
21.38
2.05
56.7
13.35
57.53
26.64
274.10
44.01
33845.90
17676.70
1.075
25.10 6.697 59.76 11.826
73.933
24.661
284.277
54.515
32,650.75 16,273.4
328 329
As in the Güre samples, the Hg, Mn, Fe and Al concentrations in the Küçükkuyu samples were
330
high, and the average values of the other elements were similar.
331
Table 7: The heavy metal concentrations in the Küçükkuyu SK-3 drill core samples Depth of Sample 10.40-.10.60 12.50-12.70 12.70-12.90 13.00-13.20
Co
Fe
Pb
ppm ppm ppm 26.964 35954.20 7.44 22.287 29739.70 1.81 24.625 28472.70 3.19 25.071 32095.70 0.13
As ppm 80.5975 73.0552 96.5279 65.963
Cr
Cu
ppm 63.8 49.5 70.4 83
ppm 17.9 13.3 9.2 15.1
20
Zn
Al
Mn
Ni
ppm ppm ppm ppm 58.00 13197.30 497.9 98.7 78.10 11089.40 424.6 67.1 50.70 10044.70 421 71.8 53.70 13548.40 546 82.6
Hg
Cd
ppm ppb 1478.7 0.0 1149.4 101.0 0.0 23.3 1287.0 2575.2
ACCEPTED MANUSCRIPT 13.20-13.40 27.101 35240.90 4.70 13.40-13.60 24.736 33185.80 3.20 13.60-13.80 31.533 38575.90 1.33 13.80-14.00 29.484 32888.60 6.51 14.00-14.20 27.710 37164.80 0.00 14.20-14.40 29.146 37605.80 0.00 14.40-14.60 30.111 41727.40 0.45 14.60-14.80 30.225 35039.60 0.12 14.80.15.00 27.603 37302.90 0.00 15.00-15.20 27.806 37869.50 0.45 15.20-15.40 24.375 34583.30 1.25 15.40-15.60 25.842 36060.50 4.73 15.60-15.80 30.199 42221.50 0.00 15.80-16.00 29.830 40869.10 0.69 16.00-16.20 27.437 30093.90 2.46 16.20-16.40 23.184 31262.60 2.00 16.70-16.90 27.002 38198.80 0.00 16.90-17.10 26.267 37218.00 0.56 17.10-17.30 27.612 31471.40 6.17 17.30-17.50 25.670 30079.00 1.75 17.50-17.70 26.330 29225.70 4.68 17.70-17.90 24.645 33194.40 0.73 17.90-18.00 26.197 34970.70 0.00 18.00-18.20 27.423 37745.00 7.59 18.20-18.40 25.916 36399.80 2.22 18.40-18.60 27.126 31380.30 0.29 18.60-18.80 22.575 33532.60 0.10 18.80-19.00 25.398 34894.70 0.43 19.00-19.20 26.717 29562.00 8.64 19.20-19.40 24.885 32929.90 10.44 22.00-22.20 28.551 41556.00 0.46 22.20-22.40 29.031 37799.70 0.00 25.00-25.20 27.853 38261.30 1.61 25.20-25.40 29.869 39029.10 5.38 28.00-28.20 28.403 39315.30 0.03 28.20-28.40 27.669 32272.90 2.21 31.00-31.20 29.131 41711.30 9.52 31.20-31.40 30.226 40107.10 0.31 16.90-17.10 26.267 37218.00 0.56 17.10-17.30 27.612 31471.40 6.17 17.30-17.50 25.670 30079.00 1.75 17.50-17.70 26.330 29225.70 4.68 17.70-17.90 24.645 33194.40 0.73 17.90-18.00 26.197 34970.70 0.00 18.00-18.20 27.423 37745.00 7.59 18.20-18.40 25.916 36399.80 2.22 18.40-18.60 27.126 31380.30 0.29 18.60-18.80 22.575 33532.60 0.10 18.80-19.00 25.398 34894.70 0.43 19.00-19.20 26.717 29562.00 8.64 19.20-19.40 24.885 32929.90 10.44 22.00-22.20 28.551 41556.00 0.46 22.20-22.40 29.031 37799.70 0.00 25.00-25.20 27.853 38261.30 1.61 25.20-25.40 29.869 39029.10 5.38 28.00-28.20 28.403 39315.30 0.03 28.20-28.40 27.669 32272.90 2.21 31.00-31.20 29.131 41711.30 9.52 31.20-31.40 30.226 40107.10 0.31 35420.1 2.646 Average Value 27.1
92.6923 77.4262 56.8874 64.6729 58.2882 69.9353 115.562 75.8304 77.578 109.057 80.8339 65.6382 101.345 69.4819 84.2383 77.7235 45.5496 32.6499 81.6658 122.758 87.5902 81.2872 68.7409 71.5879 85.5852 76.5604 73.2443 83.2475 117.596 73.5847 91.5897 93.9082 71.8228 74.8619 65.8281 67.5886 71.6013 89.5641 32.6499 81.6658 122.758 87.5902 81.2872 68.7409 71.5879 85.5852 76.5604 73.2443 83.2475 117.596 73.5847 91.5897 93.9082 71.8228 74.8619 65.8281 67.5886 71.6013 89.5641
79.4
60.9 72.4 65.2 69.1 62.1 53.5 56.4 66.4 55.9 59.3 56.4 44.3 66.9 63.3 78.3 62.8 64.6 64.9 65.8 69 81.8 59.5 58.4 59.3 64.9 72 61 74.1 69.2 65.5 72.2 86.3 73 95.5 91.8 87.2 73.1 89.4 64.9 65.8 69 81.8 59.5 58.4 59.3 64.9 72 61 74.1 69.2 65.5 72.2 86.3 73 95.5 91.8 87.2 73.1 89.4
69.7
17.2 17.4 25.8 19.5 25 31.7 28.5 22.3 22.8 23.1 21.7 28.3 28.5 29.7 15.6 12.5 24.6 25.3 18.5 14.8 11.5 13.2 22 29 21.6 14.7 9.2 13.7 14.8 16.3 22.7 22.1 23.9 22.4 20.2 14.3 26 20 25.3 18.5 14.8 11.5 13.2 22 29 21.6 14.7 9.2 13.7 14.8 16.3 22.7 22.1 23.9 22.4 20.2 14.3 26 20
19.7
58.60 46.70 62.70 49.40 62.20 60.40 60.70 53.00 52.50 51.60 54.60 57.90 61.60 62.80 39.10 57.70 58.70 57.90 56.60 42.20 40.50 46.80 60.20 61.90 53.40 43.90 43.20 59.00 47.80 50.00 93.20 79.20 69.20 72.80 63.60 48.80 70.70 77.30 57.90 56.60 42.20 40.50 46.80 60.20 61.90 53.40 43.90 43.20 59.00 47.80 50.00 93.20 79.20 69.20 72.80 63.60 48.80 70.70 77.30
58.21
12449.60 11553.60 14427.40 11234.50 14574.80 15129.00 14041.70 11298.30 13734.50 14037.70 14175.00 12322.20 16176.90 15273.40 10403.60 10926.00 15746.70 14158.10 10901.20 11209.60 10170.30 13445.90 14269.10 13415.40 14583.30 12224.60 14588.40 14104.60 10408.40 11322.50 16649.10 16534.50 14885.00 14576.10 15548.40 12147.40 13157.30 14937.30 14158.10 10901.20 11209.60 10170.30 13445.90 14269.10 13415.40 14583.30 12224.60 14588.40 14104.60 10408.40 11322.50 16649.10 16534.50 14885.00 14576.10 15548.40 12147.40 13157.30 14937.30
13362.8
502.8 448.3 732.7 596.7 614.3 800.1 819 781.4 784.1 732.4 404.2 613.1 745.6 680.6 532.8 565.5 518 548.6 429.8 420.5 427.1 502.7 548.5 553.1 430.7 430.4 445.4 512.3 501.2 496.4 659.9 655.7 586.8 666.7 561 498.5 586.2 513.2 548.6 429.8 420.5 427.1 502.7 548.5 553.1 430.7 430.4 445.4 512.3 501.2 496.4 659.9 655.7 586.8 666.7 561 498.5 586.2 513.2
551
87.2 87.8 105.7 90.9 86.5 78 75.6 79.1 75.7 81.7 76.8 76.5 89.9 95.6 80.4 69.7 90.2 95.7 87.3 77.4 81.2 73.4 71.4 81.5 87.6 85.2 70.5 88.5 88.1 89.2 110.7 113.6 103.8 127.8 123.1 105.6 116.2 112.5 95.7 87.3 77.4 81.2 73.4 71.4 81.5 87.6 85.2 70.5 88.5 88.1 89.2 110.7 113.6 103.8 127.8 123.1 105.6 116.2 112.5
90.9
1438.1 789.5 1291.4 40.5 1569.4 0.0 0.0 25.7 1496.8 0.0 1551.9 0.0 1719.3 621.0 0.0 22.8 1500.2 0.0 1532.7 0.0 1406.2 0.0 1425.3 0.0 1699.1 0.0 1694.0 0.0 0.0 19.6 1238.7 43.8 1557.9 0.0 1439.6 0.0 0.0 21.0 0.0 27.8 0.0 25.4 1285.7 0.0 1429.1 0.0 1508.4 0.0 1482.1 0.0 0.0 29.0 1174.3 0.0 1407.7 0.0 0.0 22.3 1272.0 0.0 1658.3 0.0 1558.9 0.0 1515.3 0.0 1572.3 0.0 1593.6 0.0 0.0 24.1 1634.7 0.0 1604.8 0.0 1439.6 0.0 0.0 21.0 0.0 27.8 0.0 25.4 1285.7 0.0 1429.1 0.0 1508.4 0.0 1482.1 0.0 0.0 29.0 1174.3 0.0 1407.7 0.0 0.0 22.3 1272.0 0.0 1658.3 0.0 1558.9 0.0 1515.3 0.0 1572.3 0.0 1593.6 0.0 0.0 24.1 1634.7 0.0 1604.8 0.0
1106.4 66.2
332
In particular, the high levels of Hg seen at Güre and Küçükkuyu (Güre Hg = 1351.5 ppm and
333
K. Kuyu Hg = 1106.4 ppm) result from hydrothermal mineral deposits that are in contact with
334
carbonate rock formations in the Kaz Mountains. Table 8 shows the heavy metal concentrations
21
ACCEPTED MANUSCRIPT 335
of the core samples. In addition, the average heavy metal concentrations and Pollution Index
336
values of the core and drill core samples were calculated (Fig. 7).
337
338 339
Figure 7: The average values of the heavy metal concentrations in the drilling and core
340
samples
341
The average values of all core samples were calculated by using the average values obtained
342
for each core sample (Table 8 and Fig. 8). The ratio of each elemental concentration in the core
343
samples to the average value (the Pollution Index) was calculated. Here, a PI value of 1 (PI= 1)
344
was taken as the pollution threshold; PI values lower than 1 (PI<1) were taken to indicate non-
345
polluted environments, whereas PI values higher than 1 (PI>1) were taken to indicate polluted
346
environments (Table 9).
347
22
ACCEPTED MANUSCRIPT
348 349
Figure 8: A plot showing the Pollution Index (PI) values (red: PI>1; green: PI<1; blue: PI=1)
23
Table 8: The average values of the core and drill core samples and the calculated index values
350
ore No
Fe
Zn
Al
Mn
As
B
Cd
Co
Cr
Cu
Ni
Pb
Pt
Sb
Na
Mg
K
Ca
P
Pullotion Indeks (PI)
Core-1
29405.6
6055.5
13072.7
244.2
12
18
0.8
9.3
24
32
24
16.6
0.15
0.647
5644.2
3285.9
9206.2
8748.8
661.1
1.179
Core-2
37166.5
3413.8
15104.3
327.5
10.48
24.9
1.28
14.7
81.6
31.8
81
18.1
0.27
0.219
5474.9
6662.1
8150.4
16522.5
542.7
1.325
Core-3
36313
2783.7
15231.2
318.5
2.21
17.8
0.95
11.6
38.9
29.7
28.1
3.44
0.23
0.331
5375.4
4721.7
7875.1
17761.8
625.9
1.025
Core-4
30264.6
4806.1
12911.4
234
10.51
23.1
0.84
10.5
49.6
28.1
45.6
12.8
0.09
0.148
4860.6
4960.9
6545
14105.8
473.1
1.059
Core-5
35548.3
2440
16504.4
285.8
13.44
24.9
0.89
12.5
40.7
44.2
30.9
20.5
0.03
0
9963.5
4367.5
11648.1
7223.9
568.3
1.113
Core-6
26687.2
81.2
6506.4
385.7
5
10.8
1.3
7.7
11.5
10.5
7.6
11.5
0.84
0
3504.9
1595.9
3596.6
25335.1
786.2
0.855
Core-7
15571.3
21.5
6503.3
381.3
12.2
19.4
0.49
4.94
28.4
6.4
22.3
10.7
0.15
0
4210.6
3088.4
4286.8
24151.7
231.3
0.649
Core-8
27051.9
97.9
12459.3
280.4
5.5
15
0.8
9.5
51.3
39.5
41.9
22.5
0.16
0.3
3908.1
3582
4437.8
23921.8
485.8
0.945
Core-9
43598.7
82
12757.4
406.9
27.5
44.9
1.9
15.9
61.2
9
63
14.5
0.79
1.3
7899.5
4968
9085.6
21554.7
379.5
1.616
Core-10
13402.3
95
8085.6
118.9
5.6
51
0.28
2.5
10.6
13.7
7.4
14.3
0
0.279
8221.6
1577.8
5536.9
36467.5
118.7
0.672
Core-11
24791.2
169
11078.4
135.3
15.4
31.5
0.63
5.8
12.8
18.9
9.2
4.9
0.04
0.332
9825.7
1968.8
5804.2
23854
134.9
0.744
Core-12
25637.4
63.9
11265.4
300
4.9
19.9
0.62
12.4
294.6
19.8
178.4
6.9
0
0.132
6052.7
3338.3
8640.4
9204.5
729.3
1.198
Core-13
23948.6
47.8
9400.2
211.5
7.2
22.6
0.69
8.5
22.7
7.7
13.4
5
0.09
0
4660.8
2761.9
5072.5
7797.6
693.9
0.616
CORE SAMPLE AVERAGE
28414.4
1550.57
11606.15
279.2
10.15
24.9
0.88
9.68
55.99
22.41
42.52
12.4
0.22
0.284
6123.27
3606.1
6914.28
18203.8
494.6 7
1
DİKİLİ BH-1 AVERAGE
32,650.8
59.757
16,273.4 11
284.28
24.66
-
1.075
11.83
73.9
25.11
54.52
6.697
-
-
-
-
-
-
-
GÜRE BH-2 AVERAGE
33783.29
50.01
12663.75
462.06
70.61
-
66.78
26.09
206.7
14.83
150.0 2
1.478
-
-
-
-
-
-
-
KÜÇÜKKUYU BH-3 AVERAGE
35420.1
58.21
13362.8
551
79.4
-
66.2
27.1
69.7
19.7
90.9
2.646
-
-
-
-
-
-
-
24
ACCEPTED MANUSCRIPT 352 353
In Table 9, the locations at which PI was higher than 1 (PI>1) are the areas where olive
354
cultivation and industrial activities are currently intense; the locations at which PI was lower
355
than 1 (PI<1) usually correspond to areas used as beaches and tourist attractions. In the locations
356
with high pollution levels, the number of foraminifer individuals was low, and changes in
357
coloration and morphological deformities were commonly observed. In the locations where
358
PI<1, the number of fossil individuals was high, but no colour changes or morphological
359
deformities were observed. This finding – which was first reached in this study – was viewed
360
as evidence of how much foraminifers and other organisms are affected by the pollution in their
361
environment. Instead of attributing the low numbers of foraminifers individuals to changes in
362
coloration and to the morphological deformities to one element or a few elements, the
363
evaluations were based on the PI value proposed by Yümün (2017) to describe the pollution in
364
the environment.
365
A numeric PI map was developed to visually highlight the pollution of the Gulf of Edremit (Fig.
366
9). In the Pollution Index map, areas with PI>1 are red and areas with PI<1 are green. The
367
pollution distribution values seen in the map correspond to the current land use of the region
368
shown in Table 9.
369
25
ACCEPTED MANUSCRIPT
370 371
Figure 9: A map of the Pollution Index (PI) of the investigated area
372
Table 9: The Pollution Index values (PI) for each core sample STATION NO
STATION NAME
STATION-1
Burhaniye- Ören
STATION-2
Akçay-Balıkesir
STATION-3
Güre/Fener-Balıkesir
STATION-4
Güre/Merkez-Balıkesir
STATION-5
Dalyan/Edremit-Balıkesir
STATION-6
Babakale-Çanakkale
STATION-7
Asos/Kamplar-Çanakkale
STATION-8
Altınoluk/Balıkesir
STATION-9
Gömeç- Balıkesir
STATION-10
Cunda Adası/Balıkesir
STATION-11
Ayvalık Sarımsaklı
STATION-12
Altınova/ B.Kesir
STATION-13
Altınova/Balıkesir
Kirlilik İndeksleri (PI) 1.179 1.325 1.025 1.059 1.113 0.855 0.649 0.945 1.616 0.672 0.744 1.198 0.616
26
PI değerlendirmesi
Açıklama Bölgenin Güncel Durumu
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI>1: Kirli Ortam
Zeytin Tarımı ve Jeotermal
PI>1: Kirli Ortam
Zeytin Tarımı ve Jeotermal
PI>1: Kirli Ortam
Zeytin Tarımı ve Jeotermal
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI<1: Temiz Ortam
Turizm Alanı
PI<1: Temiz Ortam
Turizm Alanı
PI<1: Temiz Ortam
Turizm Alanı
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI<1: Temiz Ortam
Turizm Alanı
PI<1: Temiz Ortam
Turizm Alanı
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI<1: Temiz Ortam
Turizm Alanı ve Plaj
ACCEPTED MANUSCRIPT 373 374
3.6 The Geochemical Properties of the Sea Water and Hydrothermal Waters
375
Geochemical analyses of hydrothermal water from two locations and sea water from ten
376
locations were carried out to determine the relationships among the heavy metal contents (Table
377
10 and Table 11). In Table 10, the geothermal analyses of the Entur and Afrodit hydrothermal
378
waters were examined together. Although the concentration of the element As in Güre was
379
14.57 ppm, it was 3.018 ppm in Entur. The high level of As, which has a toxic effect, is
380
noteworthy. The levels of Ca, S and Al in Entur were 27.938 ppm, 110.850 ppm and
381
35.326 ppm, respectively, and these values are much higher than those seen at Güre. The levels
382
of the other elements were approximately equal to each other. The water in both locations was
383
alkaline, which is expected to lead to large carbonate shells in the foraminifers. In the
384
geochemical analyses of the sea water samples from the Gulf of Edremit, the levels of As, Co,
385
Cr, Pb, Sb, Sn and Se were equal to zero. Although the levels of the elements that are released
386
into the sea by the geothermal facilities operating at the sea shore, such as As, Pb, Sb, Sn and
387
Se, were zero in the sea water, they were high in the foraminifer shells and sediments given in
388
Table 10. The sources of these elements were the coastal, hydrothermally generated mineral
389
operations and agricultural activities. The source of the sulphur (S) noted in the sediment and
390
foraminifer shells in the Güre region was geothermal water (Table 10).
391 392 393 394 395 396
27
ACCEPTED MANUSCRIPT 397
Table 10: The data from geochemical analysis of the hydrothermal waters of Entur
398
(Edremit/Balıkesir) and Afrodit (Güre/Balıkesir)
399 Element
GÜRE/AF RODİT
Na (ppm) Mg (ppm) K (ppm) Ca (ppm) S (ppm) As (ppb) Al (ppb) B (ppm) Bi (ppb) Cd (ppb)
225.110 0.990 3.317 7.667 93.347 14.578 0 2.255 8.109 1.521
EDREMİT/ENTUR
Element
GÜRE/AFRODİT
EDREMİT/ENTUR
235.013 Co (ppb) 2.122 0.923 Cr (ppb) 1.515 3.087 Cu (ppb) 1.714 27.938 Fe (ppb) 0.991 110.850 Mn (ppb) 1.972 3.018 Mo (ppb) 7.970 35.326 Pt (ppb) 1.637 1.200 Sb (ppb) 3.597 8.378 pH 8.80 1.612 EC 8.58 Not: Ag, Ni, P, Pb, Se, Sn, Ti, W, Zn, and Hg= 0
1.530 1.444 1.317 0 2.143 7.706 1.659 2.839 12,88 15,41
400 401
Table 11: The heavy metal concentrations of the sea water samples (ppm) SAMPLE LOCATİON Burhaniye Ören Liman 1 Akçay Dikili Güre Merkezs Dalyan Edremit Sarımsaklı Ayvalık Gömeç Altınoluk Cunda Adası Altınova Merker SAMPLE LOCATİON Burhaniye Ören Liman 1 Akçay Dikili Güre Merkezs Dalyan Edremit Sarımsaklı Ayvalık Gömeç Altınoluk Cunda Adası Altınova Merker
Fe
Zn
Al
Mn
Ag
B
Bi
Cd
Cu
10,436
0
576,357
5,251
32,264
3,368
40,965
1,516
4,849
15,075
2,856
794,424
7,884
28,640
3,145
0
1,436
3,097
4,737 35,743
3,866 0
733,022 447,644
3,594 4,302
37,008 32,867
3,109 3,189
0 0
4,046 0
2,542 2,314
14,788 14,490 135,699
0 0 0
716,435 601,590 563,554
2,819 4,034 7,377
33,641 29,070 33,773
3,089 3,294 3,156
0 0 0
0 0 0
1,997 2,295 11,016
14,152 14,366 6,216
0 0 0
856,393 812,480 1081.21
5,083 3,269 4,224
32,113 33,192 18,177
3,217 3,264 3,143
0 0 0
1,105 1,182 1,193
1,035 2,547 1,441
Mo 16,921
Ni 0
Pt 1,662
Hg 0.297
Na 12603.1
Mg 534.7
K 140.4
Ca 331,832
P 4,752
16,773
2,670
1,507
2,370
13144.1
532.2
216.7
307,658
9,195
15,727
2,489
4,234
0.800
13852.7
548.4
257.1
306,285
4,192
17,377
2,690
1,106
1,426
13327.7
582.2
279
304,256
9,012
16,805
1,124
0
0.736
13265.4
562.2
252.3
301,910
4,430
18,475
2,437
0
1,397
12196.0
520.3
187
298,783
9,213
17,244
3,242
0
0
12473.9
541.7
202.1
312,721 12,672
16,877
2,323
1,221
0
12575.2
542.5
188.4
303,924
4,028
16,866
2,268
1,097
2,720
12250.3
570.2
188.3
314,853
7,954
17,303
1,712
1,353
0.580
11982.4
519.8
176.3
319,360
7,200
As, Co, Cr, Pb, Sb, Sn, Se = 0
402 403
28
ACCEPTED MANUSCRIPT 404
4. CONCLUSION
405
This study examined the foraminifer populations and the properties of the abnormal shell
406
structures observed in the foraminifers in the Quaternary sediments from the north-eastern
407
Aegean Sea between Dikili (İzmir), Güre (Balıkesir) and Küçükkuyu (Çanakkale). Core
408
samples obtained by drilling into the seabed at 3 locations, Küçükkuyu, Güre and Dikili, and
409
obtained from 13 other locations on land were examined to investigate this. Paleontological
410
investigation of the samples showed that the Dikili SK-1 drill core samples contained 15
411
foraminifer genera and 19 foraminifer species, whereas the Güre BH-2 and Küçükkuyu BH-3
412
drill core samples contained 6 genera and 8 species. A total of 10 foraminifer genera and 18
413
species were found in the core samples that represent the entire study area. In the same samples,
414
13 ostracod genera and 15 ostracod species were also found.
415 416
The abnormalities observed in the foraminifer shells and the yellow and/or black-coloured
417
shells of both the foraminifers and ostracods were the result of natural and anthropogenic
418
pollution. The vertical (chronological) and horizontal (spatial) distribution of the heavy metal
419
concentrations in both the core and drill core samples were examined to determine the causes
420
of the morphological abnormalities seen in the foraminifers.
421
The high diversity of the benthic foraminifers in the Güre samples, the overgrowth of the shell
422
sizes of the individuals and the orange-black coloured shells resulted from the basic water and
423
the intensity of the thermal resources. Scanning electron microscopy (SEM) was used to
424
perform elemental surface analysis of the dark yellow-orange foraminifers (Ammonia compacta
425
and Elphidium crispum), and the S, Fe and Mn concentrations of the shells were high. This is
426
similar to the high S and Fe content of thermal waters.
427
An ICP-OS device was used for the elemental analysis of the shells of foraminifers from the
428
Dikili region to determine the elements that had accumulated in the shells. As in the sediments
29
ACCEPTED MANUSCRIPT 429
from Dikili Fe, Zn, Mn, As, Cd, Co, Ni, Pb and Pt values were also quite high in these shells.
430
These values were at least 10 times higher than the ICP-OS values seen in the foraminifer
431
samples from Güre and Küçükkuyu. In the chemical analysis of the Güre drill core samples, the
432
concentrations were calculated based on the average values. Here, the Hg concentration was
433
1351.5 ppm, the Mn concentration was 462.06 ppm, the As concentration was 70.61 ppm and
434
the Cd concentration was 66.78 ppm; these values were quite high compared to those of the
435
Dikili region. The Cd, As and Pb concentrations in the Küçükkuyu drill core were high in the
436
upper levels and lower or zero towards the deeper layers. The higher concentrations of these
437
elements in the upper levels were due to the agricultural pesticides and fertilizers used in local
438
olive cultivation. The high concentrations of Hg observed at Güre and Küçükkuyu (Güre:
439
Hg = 1351.5 ppm and K. Kuyu: Hg = 1106.4 ppm) are a result of the hydrothermal mineral
440
deposits that are in contact with the carbonate rock formations in the Kaz Mountains.
441
The Pollution Index values of the sediments from the entire study area were calculated, and a
442
map showing the distribution of PI values for the region was produced. The locations at which
443
PI was higher than 1 (PI>1) correspond to the areas where olive cultivation and industrial
444
activities are currently intense; the locations at which the PI values were lower than 1 (PI<1)
445
are typically areas used as beaches and tourist attractions. In the locations with high pollution
446
levels, the number of foraminifer individuals was low and changes in coloration and
447
morphological deformities were observed to be common. In the locations where PI<1, the
448
number of fossil individuals was high, but no coloration changes or morphological deformities
449
were observed. This finding – which was identified for the first time in this study – is evidence
450
of the degree to which foraminifers and other organisms are affected by pollution in their
451
environment. Geochemical analyses of the hydrothermal and sea water samples were carried
452
out to determine the relationships among the heavy metal contents of the sea water,
453
hydrothermal water and sea sediments in the study area. The As concentration in Güre was
30
ACCEPTED MANUSCRIPT 454
14.578 ppm, whereas it was 3.018 ppm in Edremit. The high amount of As, which has a toxic
455
effect, is a subject that requires further investigation. The Ca (27.938 ppm), S (110.850 ppm),
456
and Al (35.326 ppm) concentrations in Edremit were 27.938 ppm, 110.850 ppm and
457
35.326 ppm, respectively, and these values are higher than those seen at Güre. The other
458
elements were approximately equal to each other. The pH in Edremit was 12.88, whereas it was
459
8.80 in Güre. The waters in both locations were alkaline and can be viewed as one of the reasons
460
for the large carbonate shells of the foraminifers. Furthermore, the high levels of sulphur noted
461
in both hydrothermal water samples were viewed as the main cause of the orange coloration
462
observed in the foraminifers.
463 464
Acknowledgements
465
The author thanks Yümün Mühendislik Ltd. Şti for their studies on drilling and core sampling
466
and Sevinç YÜMÜN for the preparation of the samples in the laboratory and for the separation
467
studies of other fossils. Also I would like to thank Güldemin Darbas for the identification of
468
Ostracods. The author also thanks Namık Kemal University Scientific Research Projects
469
Commission
470
NKUBAP.00.17.YL.13.07).
for
accepting
and
financing
the
scientific
studies
(Project
no:
471 472 473
References:
474 475
Avşar N (2002). Gökçeada, Bozcaada ve Çanakkale Üçgeni Kıta Sahanlığı (KD Ege Denizi)
476
Bentik Foraminifer Dağılımı ve Taksonomisi. Hacettepe University Journal of Earth
477
Sciences, 26, 53-75. (In Turkish)
31
ACCEPTED MANUSCRIPT 478
Bergin, F., Küçüksezgin, F., Uluturhan, E., Barut, İ. F., Meriç, E., Avşar, N. and Nazik. A.,
479
2006, The response of benthic foraminifera and ostracoda to heavy metal pollution in
480
Gulf of İzmir (Eastern Aegean Sea). Estuarine , Costal and Shelf Science, 66, 368-386.
481
Eryılmaz M, Yücesoy-Eryılmaz F (1998). Kıt’a Sahanlığı- Doğal Uzantı Kavramları ve Ege
482
Denizi’ndeki Kıt’a Sahanlığı Sorunu. Türkiye’nin Kıyı ve Deniz alanları II. Ulusal
483
Konferansı. The 98th Conference of the Coasts of Turkey Prosedings, 22/25, 737-748.
484
(In Turkish)
485 486
Meriç E (1983). Foraminiferler. Mineral Research and Exploration Institute Publications. Education Series No: 26. (In Turkish)
487
Meriç E, Avşar N, Bergin F, Barut İ F (2003). Dikili Körfezi'nde (KuzeyEge Denizi-Türkiye)
488
Bulunan Üç Anormal Bentik Foraminifer Örneği: Peneroplis planatus (Fichtel ve
489
Moll), Rosalina sp. ve Elphidium crispum (Linne) Hakkında. Mining Investigation and
490
Search Magazine. 127, 67-81. (In Turkish)
491
Meriç E, Avşar N, Mekik F, Yokeş B, Barut İ F, Dora Ö, Suner F, Yücesoy-Eryılmaz F,
492
Eryılmaz M, Dinçer F and Kam E (2009). Alibey ve Maden Adaları (Ayvalık-Balıkesir)
493
Çevresi Genç Çökellerinde Gözlenen Bnetik Foraminifer Kavkılarındaki Anormal
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oluşumlar ve Nedenleri. Geological Bulletin of Turkey, 52(1), 31-84. (In Turkish)
495
Meriç E, Avşar N, Nazik A, Koçak F, Eryılmaz F, Eryılmaz M, Barut İ, Yokeş M, Dinçer F,
496
Esenli F, Esenli V, Özdemir Z, Türker A, Aydın Ş (2012). Edremit Körfezi (Balıkesir)
497
Kıyı Alanlarında Oşinografik Özelliklerin Bentik Foraminifer, Ostrakod Ve Bryozoon
498
Toplulukları Üzerindeki Etkileri İle İlgili Yeni Veriler. Journal of Turkish Petroleum
499
Geology, 24 (2), 31-77. (In Turkish)
500
Meriç E, Avşar N, Nazik A, Tunoğlu C, Yokeş B, Barut İ F, Yücesoy- Eryılmaz F, Tuğrul B,
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Görmüş M, Öncel M S, Orak H, Kam E, Dinçer F (2008). Harmantaşı Mevkii (Saros 32
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Körfezi-Kuzey Ege Denizi) Deniz İçi Kaynakları Çevresindeki Foraminifer Ve
503
Ostrakod Topluluğuna Bu Alandaki Çevresel Koşulların Etkisi. Turkish Journal of Mine
504
Investigation and Research. 136, 63-84. (In Turkish)
505
Toker V, Yıldız A (2002). Kuzeydoğu Ege Denizi Gökçeada-Bozcaada-Çanakkale
506
Üçgenindeki Dip Sedimanlarında Güncel Planktonik Foraminifer Dağılımı. Hacettepe
507
University Journal of Geoscience, 25, 99-110. (In Turkish)
508
Uluturhan E, Küçüksezgin F, Cihangir B (1998). Ege Denizi Kıyılarında Kırma Mercanda (Pagellus erythrinus) Ağır Metal Birikimi 240-244.
509 510
Üstünada M., Erduğan H., Yılmaz S., Akgül R., Aysel V. 2011. Seasonal Concentrations of
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Some Heavy Metals (Cd, Pb, Zn and Cu) in Ulva Rigida J. Agardh (Chlorophyta) from
512
Dardanelles (Çanakkale, Turkey). Environmental Monitoring and Assessment, 177: 337-
513
342.
514
Yümün, Z.U., Meriç, E., Avşar, N., Nazik, A., Barut, I.F., Yokeş, B., Sagular, E.K., Yıldız, A.,
515
Eryılmaz, M., Kam, E., Başsarı, A., Sonuvar, B., Dinçer, F., Baykal, K., Kaya, S.,
516
(2016). Meiofauna, Microflora And Geochemical Properties Of The Late Quaternary
517
(Holocene) Core Sediments In The Gulf Of Izmir (Eastern Aegean Sea, Turkey). Journal
518
of African Earth Sciences - Elsevier. 124 (2016), 383-408.
519
Yumun, Z.U., (2017), The Effect of Heavy Metal Pollution on Foraminifera in the Western
520
Marmara Sea (Turkey), Journal of African Earth Sciences - Elsevier. 129 (2017) 346-
521
365
522 523 524
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ACCEPTED MANUSCRIPT 525 526 527
EXPLANATION OF PLATE-1 (Dikili)
528
Figure 1: Elphidium crispum, Sample: Dikili BH-3, 14.20-14.30 m
529
Figure 2: Elphidium macellum, Sample: Dikili BH-3, 15.20-15.30 m
530
Figure 3: Elphidium advenum, Sample: Dikili BH-3,28.00-28.50 m
531
Figure 4-5: Ammonia compacta, Sample: Dikili BH-3,19.80-19.90 m
532
Figure 6-7: Ammonia parkinsoniana, Sample: Dikili BH-3,19.20-19.30 m
533
Figure 8-9 : Melonis pompilioides, Sample: Dikili BH-3,17.50-17.60 m
534
Figure 10-11 : Anomalinoides rubiginosus ,Sample: Dikili BH-3,16.10-16.20 m
535
Figure 12-13: Nonionella turgida, Sample: Dikili BH-3,19.30-19.40 m
536
Figure 14-15 : Rosalina brody, Sample: Dikili BH-3,19.30-19.40 m
537
Figure 16-17 : Lobatula lobatula, Sample: Dikili BH-3,19.40-19.50 m
538
Figure 18-19: Pyrgo inornata, Sample: Dikili BH-3,28.00-28.50 m
539
Figure 20-21: Adelosina mediterranensis, Sample: Dikili BH-3,19.90-20.00 m
540
Figure 22-23: Adelosina duthiersi, Sample: : Dikili BH-3,16.20-16.30 m
541
Figure 24: Spiroloculina excavata, Sample:Dikili BH-3,28.00-28.50 m
542
Figure 25: Quinqueloculina seminula, Sample: Dikili BH-3,25.00-26.00 m
543
Figure 26: Reusella spinulosa, Sample: Dikili BH-3,18.10-18.20 m
544
Figure 27: Lagena strumosa, Sample: Dikili BH-3,21.00-22.00 m
545
Figure 28 :Fursenkoina acuta, Sample: Dikili BH-3,16.50-16.60 m
546
Figure 29: Brizalina spathulata: Dikili BH-3,18.60-18.70 m
547
Figure 30: Brizalina spathulata: Dikili BH-3,19.40-19.50 m
548 549 550 551 552
34
ACCEPTED MANUSCRIPT 553 554 555 556
EXPLANATION OF PLATE 2(Güre and Küçükkuyu)
557
Figure 1-2: Ammonia compacta, Sample: Güre :13.70.1
558
Figure 3-4: Ammonia compacta, Sample: Küçükkuyu :13.00.1
559
Figure 5-6: Elphidium crispum, Sample: Güre :13.70.4
560
Figure 7-8: Elphidium complanatum, Sample: Güre :14.70.1
561
Figure 9-10: Elphidium advenum, Sample: Küçükkuyu :10.40.1
562
Figure 11-12: Elphidium advenum, Sample: Güre :14.40.2
563
Figure 13-14: Adelosina mediterranensis, Sample: Güre :13.90.2
564
Figure 15-16: Adelosina mediterranensis, Sample: Küçükkuyu :17.10.2
565
Figure 17-18: Adelosina mediterranensis, Sample: Küçükkuyu :10.30.3
566
Figure 19-20: Quinqueloculina seminula, Sample: : Küçükkuyu :10.30.2
567
Figure 21-22: Miliolinella subratunda, Sample: Küçükkuyu :15.70.1
568
Figure 23-24: Massilina secans, Sample : Küçükkuyu :15.10.1
569
Figure 25-26: Massilina secans, Sample :Güre :15.90.1
570
Figure 27-28: Massilina secans, Sample :Güre :15.70.1
571 572 573 574 575 576 577
35
ACCEPTED MANUSCRIPT 578
PLATE-1 (Dikili)
579 580
36
ACCEPTED MANUSCRIPT 581
PLATE 2 (Güre and Küçükkuyu)
582 583
37
ACCEPTED MANUSCRIPT 584 585
EXPLANATION OF PLATE 3 (Core Samples)
586
Figure 1-2:Elphidium complanatum, Sample:Küçükkuyu-Güre: CORE 3.3(Güre Fener)
587
Figure 3: Elphidium macellum, Sample: Küçükkuyu-Güre:CORE 1.3(Burhaniye Ören)
588
Figure 4: Elphidium crispum, Sample: Küçükkuyu-Güre:CORE 1.5(Burhaniye Ören)
589
Figure 5: Elphidium advenum, Sample: Küçükkuyu-Güre:CORE 3.4(Güre Fener)
590
Figure 6: Elphidium advenum, Sample: Küçükkuyu-Güre:CORE2.15(Akçay Körfez)
591
Figure 7-8 :Ammonia tepida , Sample: Küçükkuyu-Güre:CORE10.5(Cunda Adası)
592
Figure 9-10 : Ammonia compacta, Sample: Küçükkuyu-Güre:CORE10.6(Cunda Adası)
593
Figure 11-12 : Rosalina brody, Sample: Küçükkuyu-Güre:CORE6.17(Çanakkale Babakale)
594
Figure 13-14:Lobatula Lobatula, Sample: Küçükkuyu-Güre:CORE7.3(Assos)
595
Figure 15-16: Peneroplis pertusus, Sample:Küçükkuyu-Güre:CORE 7.11(Assos)
596
Figure 17-18: Peneroplis planatus, Sample:Küçükkuyu-Güre:CORE 7.10(Assos)
597
Figure 19-20: Peneroplis planatus, Sample:Küçükkuyu-Güre:CORE6.1(Çanakkale Babakale)
598
Figure 21-22: Peneroplis sp., Sample:Küçükkuyu-Güre:CORE9-5
599
Figure 23-24: Spirolina arietinus, Sample:Küçükkuyu-Güre:CORE9-6
600
Figure 25-26: Vertabralina striata, Sample:Küçükkuyu-Güre:CORE10.2(Cunda Adası)
601
Figure 27-28: Nodobaculariella cristobalensis: Sample:Küçükkuyu-Güre: CORE6.EX.3 (Çanakkale Babakale)
602
Figure 29-30: Welmanellinella striata, :Sample:Küçükkuyu-Güre: CORE6.10 (Çanakkale Babakale)
603 604 605 606
38
ACCEPTED MANUSCRIPT 607 608
EXPLANATION OF PLATE 4 (Core Samples)
609
Figure 1-2: Adelosina mediterranensis, Sample: Küçükkuyu-Güre:CORE2.4(Akçay Körfez)
610
Figure 3-4: Adelosina mediterranensis, Sample: Küçükkuyu-Güre: CORE6.EX.6(Çanakkale Babakale)
611
Figure 5-6: Adelosina duthiersi, Sample: : Küçükkuyu-Güre: CORE6.EX.8(Çanakkale Babakale)
612
Figure 7-8: Adelosina cliarensis, Sample: Küçükkuyu-Güre:CORE4.2(Güre Merkez)
613
Figure 9-10: Pseudotriloculina leavigata, Sample: Küçükkuyu-Güre: CORE4.7(Güre Merkez)
614
Figure 11-12: Massilina secans, Sample: Küçükkuyu-Güre: CORE6.EX.11(Çanakkale Babakale)
615
Figure 13-14: Quinqueloculina bidentata, Sample: Küçükkuyu-Güre: CORE6.9(Çanakkale Babakale)
616
Figure 15-16: welmanellinella striata, Sample: Küçükkuyu-Güre: CORE6.18(Çanakkale Babakale)
617
Figure 17-18: Lachlanella variolata, Sample: Küçükkuyu-Güre: CORE6.4(Çanakkale Babakale)
618
Figure 19-20: Lachlanella undulata, Sample: Küçükkuyu-Güre: CORE6.EX.14(Çanakkale Babakale)
619
Figure 21-22: Massilina secans, Sample: Küçükkuyu-Güre: CORE2.1(Akçay Körfez)
620
Figure 23: Spiroloculina excavata, Sample: Küçükkuyu-Güre: CORE6.EX.19(Çanakkale Babakale)
621
Figure 24: Spiroloculina depressa, Sample: Küçükkuyu-Güre: CORE6.EX.20(Çanakkale Babakale)
622
Figure 25-26: Quinqueloculina bidentata, Sample: Küçükkuyu-Güre: CORE4.4(Güre Merkez)
623
Figure 27-28: Planorbulina mediterranensis, Sample:Küçükkuyu-Güre:CORE6.EX.16(Çanakkale Babakale)
624
Figure 29-30: Uvigerina senticosa, Sample:Küçükkuyu-Güre:CORE6.EX.22(Çanakkale Babakale)
625 626 627 628 629 630 631 632
39
ACCEPTED MANUSCRIPT 633
PLATE 3 (Core Samples)
634 635
40
ACCEPTED MANUSCRIPT 636
PLATE 4 (Core Samples)
637 638
41
Zeki Ünal Yümün, Melike Önce PII:
S1464-343X(17)30132-2
DOI:
10.1016/j.jafrearsci.2017.03.015
Reference:
AES 2851
To appear in:
Journal of African Earth Sciences
Received Date:
18 February 2017
Revised Date:
09 March 2017
Accepted Date:
17 March 2017
Please cite this article as: Zeki Ünal Yümün, Melike Önce, Monitoring heavy metal pollution in foraminifera from the gulf of edremit (northeaster aegean sea) between izmir, balikesir and çanakkale (turkey), Journal of African Earth Sciences (2017), doi: 10.1016/j.jafrearsci.2017.03.015
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ACCEPTED MANUSCRIPT
HIGHLIGHTS In this study, the populations and abnormal shell structures of Quaternary foraminifera in the sediments of the northeaster Aegean Sea were examined. Examination of the faunal and sedimentological properties of the samples showed that the Gulf of Edremit is completely influenced by the sea and has rich foraminifera and ostracod populations. Scanning electron microscopy was used to perform an elemental analysis of the surfaces of dark yellow-orange foraminifera. The S, Fe and Mn concentrations in the shells were found to be high like in hydrotermal waters.
ACCEPTED MANUSCRIPT 1
MONITORING HEAVY METAL POLLUTION IN FORAMINIFERA
2
FROM THE GULF OF EDREMIT (NORTHEASTER AEGEAN SEA)
3
BETWEEN İZMIR, BALIKESIR AND ÇANAKKALE (TURKEY)
4
Zeki Ünal YÜMÜN1 Melike ÖNCE2
5 6
1Namık
Kemal University, Çorlu Faculty of Engineering, Çorlu, Tekirdağ/TURKEY, [email protected]
7
2Namık
Kemal University, Çorlu Faculty of Engineering, Çorlu, Tekirdağ/TURKEY, [email protected]
8 9
ABSTRACT
10
In this study, the populations and abnormal shell structures of Quaternary foraminifers in the
11
sediments of the North-eastern Aegean Sea were examined. For this purpose, offshore drilling
12
was carried out at three locations, and core samples were collected from 13 locations at
13
Küçükkuyu (Çanakkale), Güre (Edremit-Balıkesir) and Dikili (İzmir). At these points, drilling
14
reached depths ranging from 3.00 to 22.00 m beneath the seafloor; recent sediments were
15
observed, but the bedrock was not reached. Examination of the faunal and sedimentological
16
properties of the samples showed that the Gulf of Edremit is completely influenced by the sea
17
and has rich foraminifers and ostracod populations.
18
The abnormalities observed in the foraminifer shells, as well as the yellow- and/or black-
19
coloured shells seen in both the foraminifer and ostracod populations, are due to natural and
20
anthropogenic ecological pollution. The vertical (chronological) and horizontal (spatial)
21
distributions of heavy metal concentrations in both the core and drill core samples were
22
investigated to determine the causes of the morphological abnormalities observed in the
23
foraminifers. In the present study, pollution index (PI) values were calculated to assess the
1
ACCEPTED MANUSCRIPT 24
degree of heavy metal pollution (Yümün 2017). The current land use status of the coastal areas
25
corresponding to the measured PI values was investigated to identify the sources of the
26
pollution. Especially in the Güre region, a large number of genera and species of benthic
27
foraminifers showed overgrowth in the shell sizes of individuals, and the coloration of the shells
28
is noteworthy.
29
These changes in the shells are a result of thermal sources and agricultural activities in the
30
region. Scanning electron microscopy (SEM) was used to perform an elemental analysis of the
31
surfaces of dark yellow-orange foraminifers (Ammonia compacta and Elphidium crispum). The
32
S, Fe and Mn concentrations in the shells were found to be high, based on the SEM analyses.
33
This is similar to the high S and Fe contents of thermal waters. Thus, the main causes of the
34
coloration of the shells have been accepted to be both thermal waters and fertilizers and
35
pesticides that are used in agricultural activities.
36 37
Keywords: Heavy metals, Pollution Index, Aegean Sea, Edremit, Balıkesir, Çanakkale
38 39
1. INTRODUCTION
40
Seas have been exposed to pollution caused by people for centuries. As technological
41
advancements have increased with time, the quantity and toxic properties of pollution have
42
changed. Before the Industrial Revolution, seas were only polluted with domestic and
43
agricultural wastes; following the Industrial Revolution, the discharge of dangerous chemical
44
wastes into the seas began. Of the wastes created by both industrial and agricultural activities,
45
heavy metals represent the most significant pollutants. Heavy metals dissolve in water; thus,
46
they are the most important pollutants in aquatic ecosystems.
2
ACCEPTED MANUSCRIPT 47
Their persistence in the environment, toxicity at high concentrations, tendency to accumulate
48
in tissues and biomagnification in the food chain pose a threat to people. Therefore, the
49
monitoring and control of heavy metals in aquatic ecosystems have been studied by many
50
researchers (Uluturhan and Küçüksezgin 1998). Because of its geographical location and
51
geological structure, the Gulf of Edremit is a landlocked gulf. In addition, the flow is limited in
52
the study area, so it is rather defenceless against heavy metal pollution. The effect of heavy
53
metals on foraminifers was investigated in the study area, which is an important tourist
54
attraction. Foraminifers are single-celled and usually very small organisms that date back to the
55
beginning of life on earth and that have evolved over time (Meriç, 1983). Recent studies have
56
used foraminifers as biological indicators of heavy metal pollution in seas, and this study
57
adopted the same method.
58
In a study conducted in the Dikili Gulf (in the northeastern Aegean Sea), Meriç et al. (2003)
59
identified three different abnormal benthic foraminifers species (Peneroplis planatus, Rosalina
60
sp. and Elphidium crispum). They reported that the individual benthic foraminifers they
61
observed, which had an abnormal appearance, may have been affected by the thermal sources
62
that have developed due to the presence of active earthquake faults in the region. Meriç et al.
63
(2008) investigated the effects of inner sea sources on the foraminifers and ostracod populations
64
in the Gulf of Saros. In their study, which was titled, “The Effect of Water Resources Containing
65
Thermal Minerals on the Benthic Foraminifers Population in the Coastal Areas of the Eastern
66
Aegean Sea”, Meriç et al. (2009), showed that the coloration and morphological deformities
67
observed in the foraminifers shells at certain locations occurred because the water contained
68
minerals from thermal springs. The present-day planktonic foraminifers species and their
69
spatial distribution were determined by Toker and Yıldız (2002). Avşar (2002) carried out a
70
taxonomic examination by examining the distribution of benthic foraminifers in the North-
71
eastern Aegean Sea. Üstünada et al. (2011) investigated seasonal changes in heavy metals in 3
ACCEPTED MANUSCRIPT 72
the benthic organisms of the species found in the Çanakkale Strait. Yümün et al. (2016) studied
73
the foraminifers, ostracod and mollusc populations in the İzmir Gulf (Karşıyaka, Bayraklı,
74
İnciraltı and Çeşmealtı), and the effects of heavy metals on these organisms. Yümün (2017)
75
investigated the effects of heavy metals on the foraminifers populations found in the Holocene
76
sediments in the western Marmara Sea. In this study, an average value called the “Pollution
77
Index (PI)” was used to summarize the results of geochemical analyses. The relationships
78
between the Pollution Index (PI) and foraminifers numbers, as well as the diversity of genera
79
and species, were assessed in this study.
80
The distribution of heavy metal concentrations in a wide area from Babakale (Çanakkale) to
81
Dikili (İzmir) was investigated, and zones with heavy metal pollution were identified. The
82
drilling data were used to determine the co-occurrence of heavy metals and foraminifers
83
populations over time, while data from the core samples were used to investigate the current
84
status. Approaches to studying the effects of heavy metals on foraminifers and the sources of
85
heavy metal pollution were developed, based on investigation of the samples. A similar study
86
was carried out by Bergin et al. (2006) in the İzmir Gulf. Meriç et al. (2012) studied the effects
87
of oceanographic properties on the benthic foraminifer, ostracod and bryozoan populations in
88
the coastal areas of the Gulf of Edremit (Balıkesir), but that study only focused on a small area
89
and was limited to grab samples, whereas this study used drill and core samples and considered
90
older periods in terms of geochronology.
91
2. MATERIALS AND METHODS
92
The present-day sediment samples were collected from three different locations in the
93
northeastern Aegean Sea, specifically Dikili (İzmir, SK-1), Güre (Balıkesir, SK-2) and
94
Küçükkuyu (Çanakkale, SK-3) (Fig. 1). A modular sea buoy and a drilling machine with a semi-
95
hydraulic rotary system built on the buoy were used for drilling. Furthermore, core samples
96
were collected from 13 different locations in the study area (Burhaniye-Ören, Akçay Körfez, 4
ACCEPTED MANUSCRIPT 97
Güre Fener, Güre Merkez, Dalyan, Babakale, Asos Kamplar, Altınoluk, Gömeç, Cunda Adası,
98
Sarımsaklı, and Altınova). The samples collected transported to the laboratory while protected
99
from the sun in opaque core boxes. A total of 241 samples, including 176 samples from the 3
100
drill cores and 65 samples from the other core samples, were examined (Table 1).
101
102 103
Figure 1: Sample (Bore Hole and Core Samples) location map
104 105
Moreover, sea water samples were collected from 10 locations, and hydrothermal water samples
106
were collected from 2 locations, to determine the relationships between the heavy metal
107
contents of the sea water, the hydrothermal water and the sea sediments (Table 1).
5
ACCEPTED MANUSCRIPT Table 1: The properties of the drilling and core samples
108 Sort No of Sample
Sea Water Samples
Dikili BH-1 Güre BH-2 K.Kuyu BH-3 Core-1 Core-2 Core-3 Core-4 Core-5 Core-6 Core-7 Core-8 Core-9 Core-10 Core-11 Core-12 Core-13
Hydrothermal Water Samples
Sample Locations
Dikili/İzmir Güre/Balıkesir K.Kuyu/Çanakkale Burhaniye- Ören Akçay-Balıkesir Güre/Fener-Balıkesir Güre/Merkez-Balıkesir Dalyan/Edremit Babakale-Çanakkale Asos/Çanakkale Altınoluk/Balıkesir Gömeç- Balıkesir Cunda Adası/Balıkesir Ayvalık Sarımsaklı Altınova/ B.Kesir Altınova/Balıkesir Dikili Altınova merker Cunda adası Sarımsaklı ayvalık Gömeç Burhaniye/Ören Dalyan edremit Akçay Güre merkezs Altınoluk ENTUR-Edremit/Balıkesir AFRODİT-Güre/Balıkesir
Geographic Coordinate East (Y) 490060.55 489776.20 466009.22 0493908 0493240 0487550 0489776 0495590 0489830 0448819 0478001 0483063 0472857 0471845 0480092 0485272 490145.45 478615.23 473445.98 471182.99 483322.06 493893.57 495272.12 493302.40 489535.40 477243.35 503670.19 490008.62
North (X) 4324738.74 4381514.27 4377155.44 4371663 4381247 4379549 4381655 4378221 4381641 4372621 4379661 4360373 4355018 4348423 4342318 4332873 4324372.27 4337596.56 4354828.82 4346301.37 4360944.68 4370561.51 4379490.82 4381485.51 4381686.38 4379525.96 4379973.70 4382032.28
Deniz Suyu Derinliği (m)
Numune Derinliği (m)
Numue Botu (m)
13,00 9,20 10,20 11,00 8,00 8,00 9,00 10,50 9,00 3,00 4,50 3,00 2,00 2,50 3,00 3,00 2,00 2,00 3,00 2,50 2,50 2,50 2,00 3,00 3,50 4,50 -
13,0-20,0 9,20-30,0 10,20-31,45 11,75 8,50 8,75 10,00 11,25 9,60 3,50 5,25 3,50 3,00 3,25 3,50 3,60 1,00 1,00 1,00 1,00 1,00 1,00 1,00 1,00 1,00 1,00 -
7,0 20,80 21,25 0,75 0,50 0,75 1,00 0,75 0,60 0,50 0,75 0,50 1,00 0,75 0,50 0,60 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt 1,50 lt
109 110
Wet sieve analysis was used to determine the grain-size distribution of the present-day sediment
111
samples. Prior to the sieve analysis, 10% H2O2 was added to 15 grams of each sediment sample.
112
The samples were then stored for 24 hours and washed with water in a 0.125 mm sieve.
113
Following the washing process, the samples were dried for 6 to 8 hours at 75 0C, and the
114
foraminifers and ostracods were identified with a binocular microscope. Microphotographs of
115
the foraminifers genera and species were taken with a scanning electron microscope (SEM)
116
belonging to the Scientific and Technological Research and Application Centre of Namık
117
Kemal University (NABİLTEM). An elemental surface analysis of the foraminifers that
118
showed changes in coloration (Ammonia compacta and Elphidium crispum) was also performed
119
with SEM. A geochemical analysis of the two water samples obtained from the geothermal
6
ACCEPTED MANUSCRIPT 120
water resources on the seashore were carried out to determine the source of the heavy metals
121
observed in the foraminifers shells.
122
For the heavy metal analysis, 15 grams of each sediment sample were simultaneously taken
123
from the same levels as were sampled for palaeontological analyses. Once the samples had been
124
dried at 50°C for 24 hours, they were then pulverized in a mortar. Heavy metal analysis of the
125
pulverized samples was carried out using a SPECTOBLUE model ICP-OS housed at
126
NABILTEM. For sample combustion, 0.5 grams of the pulverized samples was weighed and
127
transferred to combustion tubes. A 12-ml amount of HNO3 and 4 ml of HCl were added to these
128
samples, which were heated at 98°C for 1 hour and at 200°C for 1.5 hours. The tops of the
129
cooled tubes were opened in a fume hood, ultra-pure water was added to the tubes up to 50 ml,
130
and the contents were strained through filter paper.
131 132
The prepared samples were placed in the measurement unit of the ICP-OS device (Smart
133
Analyser Vision) to take readings. The concentrations in parts per million (ppm) of 24 heavy
134
metals (Cd, Fe, Cu, Pb, Zn, Co, Cr, Al, Mn, Ni, As and Hg) were then determined. Using the
135
method proposed by Yümün (2017), the Pollution Index (PI) is obtained by dividing the
136
proportion of the total heavy metal concentrations to their average values by the number of
137
measurements. This is the first study that has applied the Pollution Index method to a study
138
area. This method also separately correlates the PI values with the number of foraminifers
139
individuals and species. For quantitative age determinations, 150 grams of young sediment
140
were sampled from the lowest parts of drill cores BH-1, BH-2, and BH-3, which were collected
141
at Dikili (İzmir) (19.00 to 20.00 m), Güre (Edremit/Balıkesir) (29.00 to 30.00 m) and
142
Küçükkuyu (Çanakkale) (31.00 to 31.45 m), respectively.
143 144
7
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3. RESULTS
146
3.1. Regional Sedimentation
147
The present-day sediments in the Gulf of Edremit showed properties that are specific to the
148
gulf. Since the Gulf of Edremit is a closed basin, the connection between the gulf and the
149
Müsellim Strait and Dikili Channel is quite restricted. Therefore, there is almost no interaction
150
between the bottom sediments in these three regions. The Müsellim rocks to the east of
151
Bababurun and at the narrowest point between Midilli and the Anatolian landmass restricts the
152
connection between the Gulf of Edremit and the open sea. There is a jump from −100 metres
153
to −50 metres in the area where the Gulf of Edremit connects to the Dikili Channel. This
154
bathymetric difference obstructs the transfer of material from the bottom (50 m depth) of the
155
Gulf of Edremit to the Dikili Channel. The flow in this region is also limited (Eryılmaz and
156
Yücesoy-Eryılmaz 1998).
157 158
3.2. Sedimentological Properties of the Investigated Area
159
The investigated area exhibits a lithology that has a considerable thickness on land, and its grain
160
size changes from coarse to fine towards the sea. At the Dikili drilling site, the water depth is
161
13.00 m. Samples taken from the drill core, which penetrated 20 m, were silty clay and low in
162
sand. At the Güre drilling site, there was sea water between 0.00 and 9.20 m; between a depth
163
of 9.20 and 12.20 m, there was a high water content, as well as dark greenish-black shells at
164
low levels and clay that was low in sand (slime); between a depth of 12.20 and 16.00 m, there
165
was a high water content, medium to dark green shells at low levels and clay that was low in
166
sand; between a depth of 16.00 and 18.00 m, there was black-dark green clay that was low in
167
sand, and between a depth of 18.00 and 30.00 m, the sediment was observed to alternate
168
between green, gravelly and sandy clay, and green clay. At the Küçükkuyu drilling site, the
169
water depth was 10.20 m. This site was drilled to a depth of 31.45 m and yielded 21.25 m of 8
ACCEPTED MANUSCRIPT 170
core sample. The core had high water content and was made up of a dark bluish-black slime
171
between 10.20 and 17.0 m; had medium-high water content and a consistent slime that became
172
more condensed between depths of 17.0 and 20.50 m; and contained greyish-black silty clay
173
between the depths of 20.50 and 31.45 m. A radiometric age determination of the detrital
174
materials, which had largely terrestrial origins was carried out, and their sedimentation rates
175
were determined.
176 177
3.3 Radiometric Age and Sedimentation Rate Determination
178
The sediment samples taken from the bottom-most layers of the Dikili, Güre and Küçükkuyu
179
drill cores were sent to a laboratory (Beta Analytic Inc.) for radiocarbon age determination. In
180
the radiocarbon analysis, the sea sediments were analysed using standard AMS (14C) methods
181
(Table 2). The age of the Dikili sample from the bottom-most layer was determined to be
182
5750+/−30 Before Present (BP) with
183
penetrated 7 m deep below the sea bed. The 7 metres of sediment taken from the bottom of the
184
20-m core sample was tested. That 7 m of sedimentation occurred over 5750 years. The
185
sedimentation rate (Vs) was 1.217 mm/year (Table 2). With the
186
determined to be 2770 +/− 30 BP for the bottom-most layer of the core obtained from the Güre
187
drill site.
14C
dating. In the Dikili drill core (SK-1), the drill
14C
method, the age was
188 189
Table 2: The report from the radiocarbon dating analyses (Beta Analytic Inc.) Sample Data Beta - 423881 SAMPLE : EKP_1 (Dikili/İzmir) ANALYSIS : AMS-Standard delivery MATERIAL/PRETREATMENT : (organic sediment): acid washes 2 SIGMA CALIBRATION : Cal BC 4690 to 4520 (Cal BP 6640 to 6470) Beta – 423882 SAMPLE : EKP_2 (Küçükkuyu/Çanakkale) ANALYSIS : AMS-Standard delivery
9
Measured Radiocarbon Age 5750 +/- 30 BP
Conventional Radiocarbon Age(*) 5750 +/- 30 BP
Sedimentation speed (Vs) mm/year 1,217
3710 +/- 30 BP
3700 +/- 30 BP
5.743
ACCEPTED MANUSCRIPT MATERIAL/PRETREATMENT : (organic sediment): acid washes 2 SIGMA CALIBRATION : Cal BC 2195 to 2165 (Cal BP 4145 to 4115) and Cal BC 2150 to 2020 (Cal BP 4100 to 3970) and Cal BC 1990 to 1980 (Cal BP 3940 to 3930) Beta – 423883 SAMPLE : EKP_3 (Güre/Balikesir) ANALYSIS : AMS-Standard delivery MATERIAL/PRETREATMENT : (organic sediment): acid washes 2 SIGMA CALIBRATION : Cal BC 1000 to 835 (Cal BP 2950 to 2785)
2780 +/- 30 BP
2770 +/- 30 BP
7,509
190 191
Drilling at the 30.00-m-deep Güre site was carried out in a water depth of 9.20 m and yielded a
192
20.80 m core sample. The sedimentation rate (Vs) was found to be 7.509 mm/year by dividing
193
the core length by the sedimentation age. A total core length of 21.25 m was obtained from the
194
Küçükkuyu drill site. With the
195
sample taken from the bottom-most layer of the core. According to this, the sedimentation rate
196
in the Küçükkuyu region was determined to be Vs = 5.743 mm/year. The Dikili area is a plain,
197
and the effect of runoff is low; therefore, it had the lowest sedimentation rate
198
(Vs =1.217 mm/year). The relatively high sedimentation rates inferred from Güre
199
(Vs = 7.509 mm/year) and Küçükkuyu (Vs = 5.743 mm/year) were attributed to the relatively
200
steep slopes of the surrounding land.
14C
method, an age of 3700 +/− 30 BP was obtained for the
201 202
3.4 Foraminifer Population
203
3.4.1 The Foraminifer Population in Dikili:
204
In the Dikili SK-1 drill core samples, 15 genera and 19 species were identified. The foraminifers
205
were Adelosina duthiersi (Schlumberger), Adelosina mediterranensis (Le Calvez, J. and Y.),
206
Ammonia compacta (Hofker), Ammonia parkinsoniana (d'Orbigny), Anomalinoides
207
rubiginosus (Cushman), Brizalina spathulata (Williamson), Elphidium advenum (Cushman),
208
Elphidium crispum (Linne), Elphidium macellum (Fichtel and Moll), Fursenkoina acuta
209
(d'Orbigny), Lagena strumosa (Reuss), Lobatula (Walker and Jacob, 1798), Melonis
210
pompilioides (Fichtel & Moll), Nonionella turgida (Williamson), Pygro inornata (d'Orbigny), 10
ACCEPTED MANUSCRIPT 211
Quinqueloculina seminula (Linnaeus), Reusella spinulosa (Reuss), Rosalina bradyi (Cushman)
212
and Spiroloculina excavata (d'Orbigny).
213 214
3.4.2 The Foraminifer Population in Güre and Küççükkuyu:
215
Six genera and 8 species were found in the Güre SK-2 and Küçükkuyu SK-3 drill core. The
216
foraminifers were Adelosina mediterranensis (Le Calvez, J. and Y.), Ammonia compacta
217
(Hofker), Elphidium advenum (Cushman), Elphidium crispum (Linne), Elphidium
218
complanatum (d'Orbigny), Massilina secans (d'Orbigny), Miliolinella subrotunda (Montagu),
219
and Quinqueloculina seminula (Linnaeus).
11
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3.4.3 The Foraminifer Population in the Core Samples:
222
Ten genera and 18 species were seen in the core samples.
223
The foraminifers were Adelosina cliarensis, (Heron-Allen and Earland), Adelosina duthiersi
224
(Sclumberger), Adelosina mediterranensis (Le Calvez, J. and Y.), Amphistegina lobifera
225
(Larsen) and A. lessonii (d'Orbigny), Elphidium advenum (Cushman), Elphidium crispum
226
(Linne), Elphidium macellum (Fichtel and Moll), Lobatula (Walker and Jacob), Massilina
227
secans (d'Orbigny), Peneroplis pertusus (Forskål), Peneroplis planatus (Fichtel & Moll),
228
Planorbulina
229
Quinqueloculina
230
Spiroloculina excavata (d'Orbigny), and Vertabralina striata (d'Orbigny). Since the core
231
samples were obtained from a maximum of 1.0 m below the sea bed, they represent the sediment
232
of the present-day period. The numbers of foraminifers individuals, genera and species (Table
233
3) were compared against the heavy metal concentrations of the same samples (in terms of PI).
mediterranensis seminula
(d'Orbigny),
Quinqueloculina
bidentata
(d'Orbigny),
(Linnaeus),
Quinqueloculina
striata
(d'Orbigny),
234 235
Ostracod Populations: Significant numbers of ostracods were obtained from the 13 core
236
samples and 3 drill core samples collected from the area between Dikili and Babakale. The
237
ostracods, which were identified as belonging to 13 genera and 15 species, were
238
Acanthocythereis hystrix (Reuss), Aurila albicans (Ruggieri), Carinocythereis carinata
239
(Roemer), Carinocythereis whitei (Baird), Cytheridea acuminata (Bosquet), Cytherelloidea
240
vulgata (Müller), Cytherelloidea sp., Cytheretta sp., Falunia sp., Loxoconcha eliptica (Brady),
241
Loxoconcha rhomboidea (Fischer), Loxoconcha sp., Neomonoceratina sp., Pontocythere
242
elongata (Brady), Xestoleberis communis (Mueller), Xestoleberis glabrescens (Reuss),
243
Xestoleberis sp., Urocythereis favosa (Roemer), Urocythereis sororcula (Ulıczny), and
244
Urocythereis sp.
12
ACCEPTED MANUSCRIPT 245
As in the case with foraminifers, changes in colour were also observed in the ostracods. The
246
most common coloration change in the ostracods was to orange.
247 248
Table 3: The foraminifer genera and species in the core samples from the Gulf of Edremit
Core-11
Core-12
5 10
2 5
5
1
5 2 5
35
10 5
Core-8
15 11
1
Core-7
5
1
5
8 5 7
Core-10
3
Core-9
3
5
Core-6
Core-3
5 35
Core-5
10
Core-4
Adelosina cliarensis Adelosina duthiersi Adelosina mediterranensis Ammonia compacta Ammonia parkinsoniana Amphistegina lobifera A. lessonii Cribroelphidium poeyanum Cycloforina contorta Cycloforina villafranca Elphidium advenum Elphidium crispum Elphidium complanatum Elphidium macellum Lachlanella variolata Lobatula lobatula Massilina secans Melonis pompilioides Miliolinella subratunda Peneroplis pertusus Peneroplis planatus P. mediterranensis Porosononion granosum Pseudutriloculina oblonga Pseudotriloculina rotunda Quinqueloculina bidentata Quinqueloculina seminula Q. lamarckiana Quinqueloculina striata Sigmoilinita costata Spiroloculina angulosa Spiroloculina excavata Spiroplectinella sagittula Vertabralina striata Textularia bocki Triloculina marioni Triloculina marioni Number of foraminifer genus Number of foraminifer species Pollution Indes
Core-2
Foraminifers
Core-1
Core Sample No
7
35
25 3
1 7
55 7
1 3
4
12
11
7
7
35
36 17
7 4
4
15
2
1 13 5
1 8
2 4
3
7
5
15 11
7 1
35 11
3 1 4
25
5
11
3 7
4
3 5
4
17 7 3 1 3 19 11
7
11
10 7
11
20 15
40 12
15 10 3
7 7
3
10
12
10 4
7 12
2 3 9 3 5
5
5
2
15
11
13
7
9
2
7 5 5
2 3
1 1
7
4 5
12
3
12
8
17
10
6
13
10
8
4
5
13
4
14
9
23
10
7
14
12
12
6
1,18
1,33
1,03
1,06
1,11
0,86
0,65
0,95
1,62
0,67
0,74
1,20
249 250
13
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3.4.4 Morphological deformities in the Foraminifers and the geochemical analyses of their shells
253 254
The foraminifers were yellow-orange in the Güre region (Fig. 2), whereas the colour ranged
255
between orange and black in the Küçükkuyu region (Fig. 3). The foraminifers shells obtained
256
in the Dikili region were in the dark grey–black range (Fig. 4). The numbers of twin growths in
257
the shells of Massilina secans from the Güre and Küçükkuyu regions (Fig. 2/3 and 3/1) were
258
quite high. The hydrothermal waters controlling the ambient temperature, and the high Ca
259
concentration in the environment, were among the most important causes of these
260
morphological deformities.
261
262 263
Figure 2: The morphological deformities found in the Güre drill core samples:
264
1. Ammonia compacta (13.70 m) 2. Massilina secans (15.90 m) 3. Massilina secans (15.70 m)
265
14
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266 267
Figure 3: The morphological deformities in the foraminifers found in the Küçükkuyu drill core
268
samples: 1. Massilina secans (18.00 m) 2. Miliolinella subrotunda (15.80 m) 3. Adelosina
269
mediteranensis (15.10 m).
270 271 272
Geochemical analyses were carried out to determine the causes of the coloration changes
273
observed in shells from the Dikili region (Fig. 5). The microscopic elemental surface analysis
274
of 2 grams of foraminifers shells was carried out using the ICP-OS device to determine the
275
amounts of elements accumulated in the shells (Table 4). As in the Dikili sediments, the Fe, Zn,
276
Mn, As, Cd, Co, Ni, Pb and Pt values in the shells were quite high. These values are 10 times
277
higher than the ICP-OS values of the foraminifer samples obtained from Güre and Küçükkuyu.
278
279
15
ACCEPTED MANUSCRIPT 280
Figure 4: The coloration changes observed in the foraminifers found in the Dikili drill core
281
samples: 1: Elphidium crispum (14.20 to 14.30 m) 2: Elphidium macellum (15.20 to 15.30 m)
282
3: Elphidium advenum (28.00 to 28.50 m) 4: Ammonia parkinsoniana (19.20 to 19.30 m)
283 284
Table 4: The ICP-OS results of the heavy metals accumulated in the shells and foraminifer
285
tests collected at Dikili, Güre and Küçükkuyu Sample ID
Fe ppm
Dikili foraminifer tests Güre foraminifer tests Küçükkuyu foraminifer tests
143973.31 40.26
3799.11
3012.94
Sample ID
Dikili foraminifer tests Güre foraminifer tests Küçükkuyu foraminifer tests
Cu
Zn ppm
As ppm
B ppm
Cd ppm
Co ppm
Cr ppm
2524.83 255.15 0.40
176.31
22.84
3.49
2.00
5.38
6.73
2077.4
64.39
3.77
0.29
19.11
0
0.91
5.85
3.22
1454.85 28.99
3.59
1.77
15.48
0
0.35
2.21
Ni
Al ppm
Pb
Mn ppm
Ag ppm
Pt
Sb
Na
Mg
ppm
ppm
ppm
ppm
ppm
ppm
ppm
25.30
10.52
31.78
6.49
0.00
1023.35 827.65
14.76
4.10
0.28
0.00
0.33
5333.3
5.09
1.04
0.00
0.00
0.00
5571.25 337.42
K ppm
Ca ppm
P ppm
1291.33 442320.24 234.80
2093.08 1036.24 500787.20 1359.97
1080.27 507674.02 55.48
NOTE: Bi, Sn, Se, Hg and Mo = 0
286 287
Furthermore, the significantly elevated concentrations of some heavy metals (Fe, Zn, Mn, As,
288
Cd, Co, Ni, Pb and Pt) in foraminifers such as Elphidium were due to the perforated structure
289
of their shells. Foraminifer shells become mineral deposits at microscopic scales.
290
16
ACCEPTED MANUSCRIPT
291 292
Figure 5: The ICP-OS results of the foraminifer tests collected at Dikili, Güre and Küçükkuyu
293 294
The elemental surface analyses of the Küçükkuyu (Fig. 6/1) and Güre foraminifer shells (Fig.
295
6/2) were carried out using SEM. In the analyses, the S values of the Güre samples were much
296
higher than those of the Küçükkuyu samples. This is because, at Güre, the geothermal waters
297
mix with the sea in large amounts, whereas there are no geothermal resources in Küçükkuyu.
298
Therefore, water samples were taken from the seashore at Edremit and Güre to carry out
299
geochemical analyses.
300
17
ACCEPTED MANUSCRIPT
301
Figure 6: The elemental surface analysis graphs (sample: Güre BH-2, 15.10 m)
302 303
3.5 The Chemical Properties of the Sediment Samples
304 305
The core samples obtained from the Güre, Dikili and Küçükkuyu drill cores were vertically
306
sectioned at 10-cm intervals, and their heavy metal concentrations were determined (Table 5, 6
307
and 7).
308
In the chemical analyses of the drill core from the Dikili region, Fe and Al levels were higher
309
than those of the other drill cores. There is no significant change in the heavy metal
310
concentrations at different depths obtained from the same core. The fact that Hg was zero at all
311
levels is noteworthy.
312
In chemical analyses of the Güre drill core, the elemental concentrations showed sudden
313
increases at three different depths (Table 5). There was no similarity between the elemental
314
concentrations at other depths. Therefore, the evaluations were based on average values. The
315
average values were 1351.5 ppm for Hg, 462.06 ppm for Mn, 70.61 ppm for As, 66.78 ppm for
316
Cd, and these values were substantially higher than those from the Dikili region.
317
18
ACCEPTED MANUSCRIPT Table 5: The heavy metal distribution in the Güre SK-2 drill core samples
318
Derinlik (m) 13.20-13.30 13.30-13.40 13.40-13.50 13.50-13.60 13.60-13.70 13.70-13.80 13.80-13.90 13.90-14.00 14.00-14.10 14.10-14.20 14.20-14.30 14.30-14.40 14.40-14.50 14.50-14.60 14.60-14.70 14.70-14.80 14.80-14.90 14.9-15.00 15.00-15.10 15.10-15.20 15.20-15.30 15.30-15.40 15.40-15.50 15.50-15.60 15.60-15.70 15.70-15.80 15.80-15.90 15.90-16.00 Average Value
Co
Fe
Pb
As
Cr
Cu
Zn
Al
Mn
Ni
Hg
Cd
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppm
ppb
14.837 43.124 26.287 9.945 25.034 23.841 25.090 24.179 18.312 24.340 25.272 25.327 26.943 26.475 35.497 24.743 26.126 25.093 24.904 24.752 29.497 26.842 24.766 24.710 24.360 28.370 39.441 32.462
20871.80 43483.20 35806.50 13835.40 32805.30 32872.00 36375.70 32995.10 21643.90 30289.30 35394.50 35186.30 34200.90 36253.50 39254.60 35374.90 32955.90 33656.80 32410.40 34470.00 35612.90 35448.00 34096.10 33443.10 32794.10 36298.30 45622.00 42481.50
1.85 3.65 5.47 0.02 0.00 0.00 1.36 0.00 0.09 0.20 2.11 7.21 0.35 0.00 0.00 0.22 0.05 0.00 0.90 2.09 9.85 0.26 1.02 3.07 1.51 0.11 0.00 0.00
44.2894 83.6967 74.3962 29.4966 76.7601 70.3402 86.8838 66.5548 47.1204 81.25 84.032 68.9589 93.7122 87.1272 74.2573 83.1218 68.6532 71.0684 66.127 77.874 48.5521 55.9327 73.8981 75.3997 55.2406 82.9546 79.1742 70.1492
27.5 1755.6 58.4 16.9 60.6 57.5 65.7 53.9 504.9 53 54.1 46 79.9 58.4 1101.9 54.8 60.5 62.6 59.8 46.1 61.9 54.6 49.7 49.6 60.9 66.8 1094.5 71.7
3.1 40.6 18.3 5.7 13 10.9 17.2 15.2 0.4 6.4 18.4 14.7 12.6 10.4 21.2 13.8 10.9 10 10 12.3 21.2 17.5 9 12.9 10.7 18.6 35.3 25
29.60 56.80 51.80 10.10 67.20 50.90 51.70 51.10 20.20 40.00 52.60 58.90 52.70 51.00 52.40 52.50 51.70 50.80 62.80 50.20 55.70 53.80 46.60 46.70 45.40 55.10 66.70 65.30
9866.50 11909.90 11882.20 7379.90 12711.40 13095.20 11708.80 13474.10 9020.40 11536.70 12370.60 11001.90 13753.60 14890.00 14939.10 13054.60 14153.80 14005.80 11770.90 12026.70 11884.60 14514.50 12506.30 11313.50 12512.40 14071.50 16281.00 16949.00
247.1 638.7 444.1 173.8 419.7 383.5 434.8 421.5 281.5 399.9 470.1 525.1 481.7 418.3 529.8 407.5 433.9 435.4 462.8 460.2 573.2 512.2 469.8 461.6 523.5 527.9 590 810.2
39.5 954.8 84.9 16.9 68.2 66.9 71.8 64.7 273.3 61.3 70.2 70 86.2 70 601 67.5 80.6 75.2 77.3 70.5 95.8 85.7 69.1 69.3 73.4 90.5 643 102.9
822.7 1756.2 1398.1 540.7 1277.0 1315.3 1433.2 1349.3 841.3 1256.3 1436.5 1379.0 1375.3 1466.5 1600.7 1379.7 1328.9 1347.8 1278.9 1383.1 1392.7 1439.7 1370.9 1308.6 1302.9 1432.7 1864.0 1765.3
0.0 295.5 0.0 357.3 0.0 0.0 0.0 0.0 282.0 0.0 0.0 0.0 0.0 0.0 450 0.0 34.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 450.1
26.09
33783.29
1.478
70.61
206.71
14.83
50.01 12663.75
462.06 150.02
1351.5 66.78
319 320
The heavy metal concentrations obtained from the Küçükkuyu drill site are given in Table 7.
321
Here, Cd, As and Pb were high in the upper levels and lower or zero towards the bottom levels.
322
The high levels of these elements in the upper levels were attributed to the agricultural
323
pesticides and fertilizers that have recently been used in olive cultivation.
324 325 326
Table 6: The heavy metal concentrations in samples from the Dikili Drill Core-1 (BH-1) (Hg
327
was determined to be zero at each level) Numune Derinliği
Cd
Cu
Pb
Zn
Co
Cr
As
Mn
Ni
Fe
Al
(m)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
(ppm)
13.00-13.20
0.461
26.23
6.88
52.8
11.86
39.28
19
22.90
331.10
39.59
29722.60
14715.40
ACCEPTED MANUSCRIPT 13.20-13.40
0.831
26.44
7.20
49
10.40
32.78
20.63
363.30
35.32
28742.20
14135.00
13.40-13.60
0.910
26.97
7.37
63.2
10.22
35.85
21.54
281.50
36.01
30858.50
14420.10
13.60-13.80
1.392
28.92
7.12
58.6
11.49
45.28
20.86
238.40
40.52
32080.30
16369.90
13.80-14.00
1.234
29.10
9.15
67
11.94
44.83
18.02
236.10
40.63
32690.20
16124.80
14.00-14.20
0.786
23.21
10.47
52.2
9.84
32.57
21.58
215.00
32.43
27619.30
12596.20
14.20-14.40
0.738
26.71
0.00
58.2
13.86
79.44
22.68
207.70
50.61
34903.20
18310.00
14.40-14.60
1.265
25.81
6.32
46.3
11.67
42.55
24.69
206.30
39.14
28756.20
14815.10
14.60-14.80
1.338
25.23
7.97
50.6
11.31
40.98
20.74
217.70
37.69
29617.80
14619.60
14.80-15.00
1.050
23.41
7.46
62.3
10.90
40.97
17.98
233.50
36.13
30913.80
14361.20
15.00-15.20
1.382
26.33
9.76
47.3
12.26
39.56
35.50
403.70
41.44
30469.70
14760.60
15.20-15.40
1.240
27.12
6.73
54.6
11.74
40.36
36.72
481.80
42.15
32316.40
15791.30
15.40-15.60
1.519
26.08
9.41
51.7
12.28
42.55
31.84
408.00
43.58
32044.70
15352.90
15.60-15.80
1.455
27.65
8.16
64.8
11.89
47.44
28.08
274.40
45.64
36012.10
17496.20
15.80-16.00
0.926
31.62
7.28
66.1
13.51
106.68
24.96
336.50
62.81
37292.10
19291.90
16.00-16.20
0.000
21.08
7.21
51.1
10.73
39.84
21.18
255.60
34.17
31696.00
16735.90
16.20-16.40
0.388
21.60
7.10
46.4
10.58
59.65
19.49
249.30
44.53
30233.50
14885.30
16.40-16.60
1.315
21.76
5.78
58.5
13.35
56.33
28.65
281.50
47.36
34787.30
17268.80
16.60-16.80
1.456
23.86
4.75
58
11.36
46.39
26.68
279.10
42.58
34702.30
17743.80
16.80-17.00
1.424
23.57
7.14
56.3
11.48
47.03
32.05
308.00
43.22
35230.70
17816.80
17.00-17.20
1.192
22.62
7.15
54.3
11.16
44.51
27.03
272.60
38.97
34219.60
17676.10
17.20-17.40
1.241
22.75
7.13
56.8
11.03
44.03
25.12
301.30
38.27
34316.50
17652.10
17.40-17.60
0.961
42.37
7.82
51.4
16.03
394.11
30.82
326.70
232.44
32255.60
14584.00
17.60-17.80
0.659
19.03
6.65
50.1
9.14
37.19
15.58
221.20
32.92
28014.9
15030.80
17.80-18.00
0.937
27.76
6.06
48.5
14.43
542.18
18.80
280.60
289.58
31229.80
14902.00
18.00-18.20
0.809
20.88
6.45
54.2
11.24
44.46
25.37
269.90
37.22
32299.30
16763.60
18.20-18.40
1.373
22.22
7.99
67.4
11.37
45.07
22.32
277.50
37.85
34736.10
17275.80
18.40-18.60
0.267
21.98
6.61
51.4
10.81
43.24
24.40
272.80
37.85
33249.10
16077.00
18.60-18.80
0.499
23.16
0.00
65
15.38
70.43
27.95
257.10
48.26
36261.10
19070.20
18.80-19.00
2.024
31.80
10.04
195.9
12.51
73.57
30.56
319.90
55.31
40800.90
17458.80
19.00-19.20
0.906
20.29
2.47
53.3
10.45
74.66
19.28
225.70
51.81
29387.20
17094.70
19.20-19.40
1.3754 22.55
8.12
59.5
11.68
49.92
25.00
284.20
39.34
34272.20
17689.20
19.40-19.60
2.158
25.33
4.05
61.5
12.03
51.36
21.58
280.00
45.74
35461.60
18560.50
19.60-19.80
0.750
21.87
8.54
50.5
10.61
55.04
25.94
277.60
42.90
31737.40
14447.10
19.80-20.00 Average Value
1.362
21.38
2.05
56.7
13.35
57.53
26.64
274.10
44.01
33845.90
17676.70
1.075
25.10 6.697 59.76 11.826
73.933
24.661
284.277
54.515
32,650.75 16,273.4
328 329
As in the Güre samples, the Hg, Mn, Fe and Al concentrations in the Küçükkuyu samples were
330
high, and the average values of the other elements were similar.
331
Table 7: The heavy metal concentrations in the Küçükkuyu SK-3 drill core samples Depth of Sample 10.40-.10.60 12.50-12.70 12.70-12.90 13.00-13.20
Co
Fe
Pb
ppm ppm ppm 26.964 35954.20 7.44 22.287 29739.70 1.81 24.625 28472.70 3.19 25.071 32095.70 0.13
As ppm 80.5975 73.0552 96.5279 65.963
Cr
Cu
ppm 63.8 49.5 70.4 83
ppm 17.9 13.3 9.2 15.1
20
Zn
Al
Mn
Ni
ppm ppm ppm ppm 58.00 13197.30 497.9 98.7 78.10 11089.40 424.6 67.1 50.70 10044.70 421 71.8 53.70 13548.40 546 82.6
Hg
Cd
ppm ppb 1478.7 0.0 1149.4 101.0 0.0 23.3 1287.0 2575.2
ACCEPTED MANUSCRIPT 13.20-13.40 27.101 35240.90 4.70 13.40-13.60 24.736 33185.80 3.20 13.60-13.80 31.533 38575.90 1.33 13.80-14.00 29.484 32888.60 6.51 14.00-14.20 27.710 37164.80 0.00 14.20-14.40 29.146 37605.80 0.00 14.40-14.60 30.111 41727.40 0.45 14.60-14.80 30.225 35039.60 0.12 14.80.15.00 27.603 37302.90 0.00 15.00-15.20 27.806 37869.50 0.45 15.20-15.40 24.375 34583.30 1.25 15.40-15.60 25.842 36060.50 4.73 15.60-15.80 30.199 42221.50 0.00 15.80-16.00 29.830 40869.10 0.69 16.00-16.20 27.437 30093.90 2.46 16.20-16.40 23.184 31262.60 2.00 16.70-16.90 27.002 38198.80 0.00 16.90-17.10 26.267 37218.00 0.56 17.10-17.30 27.612 31471.40 6.17 17.30-17.50 25.670 30079.00 1.75 17.50-17.70 26.330 29225.70 4.68 17.70-17.90 24.645 33194.40 0.73 17.90-18.00 26.197 34970.70 0.00 18.00-18.20 27.423 37745.00 7.59 18.20-18.40 25.916 36399.80 2.22 18.40-18.60 27.126 31380.30 0.29 18.60-18.80 22.575 33532.60 0.10 18.80-19.00 25.398 34894.70 0.43 19.00-19.20 26.717 29562.00 8.64 19.20-19.40 24.885 32929.90 10.44 22.00-22.20 28.551 41556.00 0.46 22.20-22.40 29.031 37799.70 0.00 25.00-25.20 27.853 38261.30 1.61 25.20-25.40 29.869 39029.10 5.38 28.00-28.20 28.403 39315.30 0.03 28.20-28.40 27.669 32272.90 2.21 31.00-31.20 29.131 41711.30 9.52 31.20-31.40 30.226 40107.10 0.31 16.90-17.10 26.267 37218.00 0.56 17.10-17.30 27.612 31471.40 6.17 17.30-17.50 25.670 30079.00 1.75 17.50-17.70 26.330 29225.70 4.68 17.70-17.90 24.645 33194.40 0.73 17.90-18.00 26.197 34970.70 0.00 18.00-18.20 27.423 37745.00 7.59 18.20-18.40 25.916 36399.80 2.22 18.40-18.60 27.126 31380.30 0.29 18.60-18.80 22.575 33532.60 0.10 18.80-19.00 25.398 34894.70 0.43 19.00-19.20 26.717 29562.00 8.64 19.20-19.40 24.885 32929.90 10.44 22.00-22.20 28.551 41556.00 0.46 22.20-22.40 29.031 37799.70 0.00 25.00-25.20 27.853 38261.30 1.61 25.20-25.40 29.869 39029.10 5.38 28.00-28.20 28.403 39315.30 0.03 28.20-28.40 27.669 32272.90 2.21 31.00-31.20 29.131 41711.30 9.52 31.20-31.40 30.226 40107.10 0.31 35420.1 2.646 Average Value 27.1
92.6923 77.4262 56.8874 64.6729 58.2882 69.9353 115.562 75.8304 77.578 109.057 80.8339 65.6382 101.345 69.4819 84.2383 77.7235 45.5496 32.6499 81.6658 122.758 87.5902 81.2872 68.7409 71.5879 85.5852 76.5604 73.2443 83.2475 117.596 73.5847 91.5897 93.9082 71.8228 74.8619 65.8281 67.5886 71.6013 89.5641 32.6499 81.6658 122.758 87.5902 81.2872 68.7409 71.5879 85.5852 76.5604 73.2443 83.2475 117.596 73.5847 91.5897 93.9082 71.8228 74.8619 65.8281 67.5886 71.6013 89.5641
79.4
60.9 72.4 65.2 69.1 62.1 53.5 56.4 66.4 55.9 59.3 56.4 44.3 66.9 63.3 78.3 62.8 64.6 64.9 65.8 69 81.8 59.5 58.4 59.3 64.9 72 61 74.1 69.2 65.5 72.2 86.3 73 95.5 91.8 87.2 73.1 89.4 64.9 65.8 69 81.8 59.5 58.4 59.3 64.9 72 61 74.1 69.2 65.5 72.2 86.3 73 95.5 91.8 87.2 73.1 89.4
69.7
17.2 17.4 25.8 19.5 25 31.7 28.5 22.3 22.8 23.1 21.7 28.3 28.5 29.7 15.6 12.5 24.6 25.3 18.5 14.8 11.5 13.2 22 29 21.6 14.7 9.2 13.7 14.8 16.3 22.7 22.1 23.9 22.4 20.2 14.3 26 20 25.3 18.5 14.8 11.5 13.2 22 29 21.6 14.7 9.2 13.7 14.8 16.3 22.7 22.1 23.9 22.4 20.2 14.3 26 20
19.7
58.60 46.70 62.70 49.40 62.20 60.40 60.70 53.00 52.50 51.60 54.60 57.90 61.60 62.80 39.10 57.70 58.70 57.90 56.60 42.20 40.50 46.80 60.20 61.90 53.40 43.90 43.20 59.00 47.80 50.00 93.20 79.20 69.20 72.80 63.60 48.80 70.70 77.30 57.90 56.60 42.20 40.50 46.80 60.20 61.90 53.40 43.90 43.20 59.00 47.80 50.00 93.20 79.20 69.20 72.80 63.60 48.80 70.70 77.30
58.21
12449.60 11553.60 14427.40 11234.50 14574.80 15129.00 14041.70 11298.30 13734.50 14037.70 14175.00 12322.20 16176.90 15273.40 10403.60 10926.00 15746.70 14158.10 10901.20 11209.60 10170.30 13445.90 14269.10 13415.40 14583.30 12224.60 14588.40 14104.60 10408.40 11322.50 16649.10 16534.50 14885.00 14576.10 15548.40 12147.40 13157.30 14937.30 14158.10 10901.20 11209.60 10170.30 13445.90 14269.10 13415.40 14583.30 12224.60 14588.40 14104.60 10408.40 11322.50 16649.10 16534.50 14885.00 14576.10 15548.40 12147.40 13157.30 14937.30
13362.8
502.8 448.3 732.7 596.7 614.3 800.1 819 781.4 784.1 732.4 404.2 613.1 745.6 680.6 532.8 565.5 518 548.6 429.8 420.5 427.1 502.7 548.5 553.1 430.7 430.4 445.4 512.3 501.2 496.4 659.9 655.7 586.8 666.7 561 498.5 586.2 513.2 548.6 429.8 420.5 427.1 502.7 548.5 553.1 430.7 430.4 445.4 512.3 501.2 496.4 659.9 655.7 586.8 666.7 561 498.5 586.2 513.2
551
87.2 87.8 105.7 90.9 86.5 78 75.6 79.1 75.7 81.7 76.8 76.5 89.9 95.6 80.4 69.7 90.2 95.7 87.3 77.4 81.2 73.4 71.4 81.5 87.6 85.2 70.5 88.5 88.1 89.2 110.7 113.6 103.8 127.8 123.1 105.6 116.2 112.5 95.7 87.3 77.4 81.2 73.4 71.4 81.5 87.6 85.2 70.5 88.5 88.1 89.2 110.7 113.6 103.8 127.8 123.1 105.6 116.2 112.5
90.9
1438.1 789.5 1291.4 40.5 1569.4 0.0 0.0 25.7 1496.8 0.0 1551.9 0.0 1719.3 621.0 0.0 22.8 1500.2 0.0 1532.7 0.0 1406.2 0.0 1425.3 0.0 1699.1 0.0 1694.0 0.0 0.0 19.6 1238.7 43.8 1557.9 0.0 1439.6 0.0 0.0 21.0 0.0 27.8 0.0 25.4 1285.7 0.0 1429.1 0.0 1508.4 0.0 1482.1 0.0 0.0 29.0 1174.3 0.0 1407.7 0.0 0.0 22.3 1272.0 0.0 1658.3 0.0 1558.9 0.0 1515.3 0.0 1572.3 0.0 1593.6 0.0 0.0 24.1 1634.7 0.0 1604.8 0.0 1439.6 0.0 0.0 21.0 0.0 27.8 0.0 25.4 1285.7 0.0 1429.1 0.0 1508.4 0.0 1482.1 0.0 0.0 29.0 1174.3 0.0 1407.7 0.0 0.0 22.3 1272.0 0.0 1658.3 0.0 1558.9 0.0 1515.3 0.0 1572.3 0.0 1593.6 0.0 0.0 24.1 1634.7 0.0 1604.8 0.0
1106.4 66.2
332
In particular, the high levels of Hg seen at Güre and Küçükkuyu (Güre Hg = 1351.5 ppm and
333
K. Kuyu Hg = 1106.4 ppm) result from hydrothermal mineral deposits that are in contact with
334
carbonate rock formations in the Kaz Mountains. Table 8 shows the heavy metal concentrations
21
ACCEPTED MANUSCRIPT 335
of the core samples. In addition, the average heavy metal concentrations and Pollution Index
336
values of the core and drill core samples were calculated (Fig. 7).
337
338 339
Figure 7: The average values of the heavy metal concentrations in the drilling and core
340
samples
341
The average values of all core samples were calculated by using the average values obtained
342
for each core sample (Table 8 and Fig. 8). The ratio of each elemental concentration in the core
343
samples to the average value (the Pollution Index) was calculated. Here, a PI value of 1 (PI= 1)
344
was taken as the pollution threshold; PI values lower than 1 (PI<1) were taken to indicate non-
345
polluted environments, whereas PI values higher than 1 (PI>1) were taken to indicate polluted
346
environments (Table 9).
347
22
ACCEPTED MANUSCRIPT
348 349
Figure 8: A plot showing the Pollution Index (PI) values (red: PI>1; green: PI<1; blue: PI=1)
23
Table 8: The average values of the core and drill core samples and the calculated index values
350
ore No
Fe
Zn
Al
Mn
As
B
Cd
Co
Cr
Cu
Ni
Pb
Pt
Sb
Na
Mg
K
Ca
P
Pullotion Indeks (PI)
Core-1
29405.6
6055.5
13072.7
244.2
12
18
0.8
9.3
24
32
24
16.6
0.15
0.647
5644.2
3285.9
9206.2
8748.8
661.1
1.179
Core-2
37166.5
3413.8
15104.3
327.5
10.48
24.9
1.28
14.7
81.6
31.8
81
18.1
0.27
0.219
5474.9
6662.1
8150.4
16522.5
542.7
1.325
Core-3
36313
2783.7
15231.2
318.5
2.21
17.8
0.95
11.6
38.9
29.7
28.1
3.44
0.23
0.331
5375.4
4721.7
7875.1
17761.8
625.9
1.025
Core-4
30264.6
4806.1
12911.4
234
10.51
23.1
0.84
10.5
49.6
28.1
45.6
12.8
0.09
0.148
4860.6
4960.9
6545
14105.8
473.1
1.059
Core-5
35548.3
2440
16504.4
285.8
13.44
24.9
0.89
12.5
40.7
44.2
30.9
20.5
0.03
0
9963.5
4367.5
11648.1
7223.9
568.3
1.113
Core-6
26687.2
81.2
6506.4
385.7
5
10.8
1.3
7.7
11.5
10.5
7.6
11.5
0.84
0
3504.9
1595.9
3596.6
25335.1
786.2
0.855
Core-7
15571.3
21.5
6503.3
381.3
12.2
19.4
0.49
4.94
28.4
6.4
22.3
10.7
0.15
0
4210.6
3088.4
4286.8
24151.7
231.3
0.649
Core-8
27051.9
97.9
12459.3
280.4
5.5
15
0.8
9.5
51.3
39.5
41.9
22.5
0.16
0.3
3908.1
3582
4437.8
23921.8
485.8
0.945
Core-9
43598.7
82
12757.4
406.9
27.5
44.9
1.9
15.9
61.2
9
63
14.5
0.79
1.3
7899.5
4968
9085.6
21554.7
379.5
1.616
Core-10
13402.3
95
8085.6
118.9
5.6
51
0.28
2.5
10.6
13.7
7.4
14.3
0
0.279
8221.6
1577.8
5536.9
36467.5
118.7
0.672
Core-11
24791.2
169
11078.4
135.3
15.4
31.5
0.63
5.8
12.8
18.9
9.2
4.9
0.04
0.332
9825.7
1968.8
5804.2
23854
134.9
0.744
Core-12
25637.4
63.9
11265.4
300
4.9
19.9
0.62
12.4
294.6
19.8
178.4
6.9
0
0.132
6052.7
3338.3
8640.4
9204.5
729.3
1.198
Core-13
23948.6
47.8
9400.2
211.5
7.2
22.6
0.69
8.5
22.7
7.7
13.4
5
0.09
0
4660.8
2761.9
5072.5
7797.6
693.9
0.616
CORE SAMPLE AVERAGE
28414.4
1550.57
11606.15
279.2
10.15
24.9
0.88
9.68
55.99
22.41
42.52
12.4
0.22
0.284
6123.27
3606.1
6914.28
18203.8
494.6 7
1
DİKİLİ BH-1 AVERAGE
32,650.8
59.757
16,273.4 11
284.28
24.66
-
1.075
11.83
73.9
25.11
54.52
6.697
-
-
-
-
-
-
-
GÜRE BH-2 AVERAGE
33783.29
50.01
12663.75
462.06
70.61
-
66.78
26.09
206.7
14.83
150.0 2
1.478
-
-
-
-
-
-
-
KÜÇÜKKUYU BH-3 AVERAGE
35420.1
58.21
13362.8
551
79.4
-
66.2
27.1
69.7
19.7
90.9
2.646
-
-
-
-
-
-
-
24
ACCEPTED MANUSCRIPT 352 353
In Table 9, the locations at which PI was higher than 1 (PI>1) are the areas where olive
354
cultivation and industrial activities are currently intense; the locations at which PI was lower
355
than 1 (PI<1) usually correspond to areas used as beaches and tourist attractions. In the locations
356
with high pollution levels, the number of foraminifer individuals was low, and changes in
357
coloration and morphological deformities were commonly observed. In the locations where
358
PI<1, the number of fossil individuals was high, but no colour changes or morphological
359
deformities were observed. This finding – which was first reached in this study – was viewed
360
as evidence of how much foraminifers and other organisms are affected by the pollution in their
361
environment. Instead of attributing the low numbers of foraminifers individuals to changes in
362
coloration and to the morphological deformities to one element or a few elements, the
363
evaluations were based on the PI value proposed by Yümün (2017) to describe the pollution in
364
the environment.
365
A numeric PI map was developed to visually highlight the pollution of the Gulf of Edremit (Fig.
366
9). In the Pollution Index map, areas with PI>1 are red and areas with PI<1 are green. The
367
pollution distribution values seen in the map correspond to the current land use of the region
368
shown in Table 9.
369
25
ACCEPTED MANUSCRIPT
370 371
Figure 9: A map of the Pollution Index (PI) of the investigated area
372
Table 9: The Pollution Index values (PI) for each core sample STATION NO
STATION NAME
STATION-1
Burhaniye- Ören
STATION-2
Akçay-Balıkesir
STATION-3
Güre/Fener-Balıkesir
STATION-4
Güre/Merkez-Balıkesir
STATION-5
Dalyan/Edremit-Balıkesir
STATION-6
Babakale-Çanakkale
STATION-7
Asos/Kamplar-Çanakkale
STATION-8
Altınoluk/Balıkesir
STATION-9
Gömeç- Balıkesir
STATION-10
Cunda Adası/Balıkesir
STATION-11
Ayvalık Sarımsaklı
STATION-12
Altınova/ B.Kesir
STATION-13
Altınova/Balıkesir
Kirlilik İndeksleri (PI) 1.179 1.325 1.025 1.059 1.113 0.855 0.649 0.945 1.616 0.672 0.744 1.198 0.616
26
PI değerlendirmesi
Açıklama Bölgenin Güncel Durumu
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI>1: Kirli Ortam
Zeytin Tarımı ve Jeotermal
PI>1: Kirli Ortam
Zeytin Tarımı ve Jeotermal
PI>1: Kirli Ortam
Zeytin Tarımı ve Jeotermal
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI<1: Temiz Ortam
Turizm Alanı
PI<1: Temiz Ortam
Turizm Alanı
PI<1: Temiz Ortam
Turizm Alanı
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI<1: Temiz Ortam
Turizm Alanı
PI<1: Temiz Ortam
Turizm Alanı
PI>1: Kirli Ortam
Zeytin Tarımı ve Sanayisi
PI<1: Temiz Ortam
Turizm Alanı ve Plaj
ACCEPTED MANUSCRIPT 373 374
3.6 The Geochemical Properties of the Sea Water and Hydrothermal Waters
375
Geochemical analyses of hydrothermal water from two locations and sea water from ten
376
locations were carried out to determine the relationships among the heavy metal contents (Table
377
10 and Table 11). In Table 10, the geothermal analyses of the Entur and Afrodit hydrothermal
378
waters were examined together. Although the concentration of the element As in Güre was
379
14.57 ppm, it was 3.018 ppm in Entur. The high level of As, which has a toxic effect, is
380
noteworthy. The levels of Ca, S and Al in Entur were 27.938 ppm, 110.850 ppm and
381
35.326 ppm, respectively, and these values are much higher than those seen at Güre. The levels
382
of the other elements were approximately equal to each other. The water in both locations was
383
alkaline, which is expected to lead to large carbonate shells in the foraminifers. In the
384
geochemical analyses of the sea water samples from the Gulf of Edremit, the levels of As, Co,
385
Cr, Pb, Sb, Sn and Se were equal to zero. Although the levels of the elements that are released
386
into the sea by the geothermal facilities operating at the sea shore, such as As, Pb, Sb, Sn and
387
Se, were zero in the sea water, they were high in the foraminifer shells and sediments given in
388
Table 10. The sources of these elements were the coastal, hydrothermally generated mineral
389
operations and agricultural activities. The source of the sulphur (S) noted in the sediment and
390
foraminifer shells in the Güre region was geothermal water (Table 10).
391 392 393 394 395 396
27
ACCEPTED MANUSCRIPT 397
Table 10: The data from geochemical analysis of the hydrothermal waters of Entur
398
(Edremit/Balıkesir) and Afrodit (Güre/Balıkesir)
399 Element
GÜRE/AF RODİT
Na (ppm) Mg (ppm) K (ppm) Ca (ppm) S (ppm) As (ppb) Al (ppb) B (ppm) Bi (ppb) Cd (ppb)
225.110 0.990 3.317 7.667 93.347 14.578 0 2.255 8.109 1.521
EDREMİT/ENTUR
Element
GÜRE/AFRODİT
EDREMİT/ENTUR
235.013 Co (ppb) 2.122 0.923 Cr (ppb) 1.515 3.087 Cu (ppb) 1.714 27.938 Fe (ppb) 0.991 110.850 Mn (ppb) 1.972 3.018 Mo (ppb) 7.970 35.326 Pt (ppb) 1.637 1.200 Sb (ppb) 3.597 8.378 pH 8.80 1.612 EC 8.58 Not: Ag, Ni, P, Pb, Se, Sn, Ti, W, Zn, and Hg= 0
1.530 1.444 1.317 0 2.143 7.706 1.659 2.839 12,88 15,41
400 401
Table 11: The heavy metal concentrations of the sea water samples (ppm) SAMPLE LOCATİON Burhaniye Ören Liman 1 Akçay Dikili Güre Merkezs Dalyan Edremit Sarımsaklı Ayvalık Gömeç Altınoluk Cunda Adası Altınova Merker SAMPLE LOCATİON Burhaniye Ören Liman 1 Akçay Dikili Güre Merkezs Dalyan Edremit Sarımsaklı Ayvalık Gömeç Altınoluk Cunda Adası Altınova Merker
Fe
Zn
Al
Mn
Ag
B
Bi
Cd
Cu
10,436
0
576,357
5,251
32,264
3,368
40,965
1,516
4,849
15,075
2,856
794,424
7,884
28,640
3,145
0
1,436
3,097
4,737 35,743
3,866 0
733,022 447,644
3,594 4,302
37,008 32,867
3,109 3,189
0 0
4,046 0
2,542 2,314
14,788 14,490 135,699
0 0 0
716,435 601,590 563,554
2,819 4,034 7,377
33,641 29,070 33,773
3,089 3,294 3,156
0 0 0
0 0 0
1,997 2,295 11,016
14,152 14,366 6,216
0 0 0
856,393 812,480 1081.21
5,083 3,269 4,224
32,113 33,192 18,177
3,217 3,264 3,143
0 0 0
1,105 1,182 1,193
1,035 2,547 1,441
Mo 16,921
Ni 0
Pt 1,662
Hg 0.297
Na 12603.1
Mg 534.7
K 140.4
Ca 331,832
P 4,752
16,773
2,670
1,507
2,370
13144.1
532.2
216.7
307,658
9,195
15,727
2,489
4,234
0.800
13852.7
548.4
257.1
306,285
4,192
17,377
2,690
1,106
1,426
13327.7
582.2
279
304,256
9,012
16,805
1,124
0
0.736
13265.4
562.2
252.3
301,910
4,430
18,475
2,437
0
1,397
12196.0
520.3
187
298,783
9,213
17,244
3,242
0
0
12473.9
541.7
202.1
312,721 12,672
16,877
2,323
1,221
0
12575.2
542.5
188.4
303,924
4,028
16,866
2,268
1,097
2,720
12250.3
570.2
188.3
314,853
7,954
17,303
1,712
1,353
0.580
11982.4
519.8
176.3
319,360
7,200
As, Co, Cr, Pb, Sb, Sn, Se = 0
402 403
28
ACCEPTED MANUSCRIPT 404
4. CONCLUSION
405
This study examined the foraminifer populations and the properties of the abnormal shell
406
structures observed in the foraminifers in the Quaternary sediments from the north-eastern
407
Aegean Sea between Dikili (İzmir), Güre (Balıkesir) and Küçükkuyu (Çanakkale). Core
408
samples obtained by drilling into the seabed at 3 locations, Küçükkuyu, Güre and Dikili, and
409
obtained from 13 other locations on land were examined to investigate this. Paleontological
410
investigation of the samples showed that the Dikili SK-1 drill core samples contained 15
411
foraminifer genera and 19 foraminifer species, whereas the Güre BH-2 and Küçükkuyu BH-3
412
drill core samples contained 6 genera and 8 species. A total of 10 foraminifer genera and 18
413
species were found in the core samples that represent the entire study area. In the same samples,
414
13 ostracod genera and 15 ostracod species were also found.
415 416
The abnormalities observed in the foraminifer shells and the yellow and/or black-coloured
417
shells of both the foraminifers and ostracods were the result of natural and anthropogenic
418
pollution. The vertical (chronological) and horizontal (spatial) distribution of the heavy metal
419
concentrations in both the core and drill core samples were examined to determine the causes
420
of the morphological abnormalities seen in the foraminifers.
421
The high diversity of the benthic foraminifers in the Güre samples, the overgrowth of the shell
422
sizes of the individuals and the orange-black coloured shells resulted from the basic water and
423
the intensity of the thermal resources. Scanning electron microscopy (SEM) was used to
424
perform elemental surface analysis of the dark yellow-orange foraminifers (Ammonia compacta
425
and Elphidium crispum), and the S, Fe and Mn concentrations of the shells were high. This is
426
similar to the high S and Fe content of thermal waters.
427
An ICP-OS device was used for the elemental analysis of the shells of foraminifers from the
428
Dikili region to determine the elements that had accumulated in the shells. As in the sediments
29
ACCEPTED MANUSCRIPT 429
from Dikili Fe, Zn, Mn, As, Cd, Co, Ni, Pb and Pt values were also quite high in these shells.
430
These values were at least 10 times higher than the ICP-OS values seen in the foraminifer
431
samples from Güre and Küçükkuyu. In the chemical analysis of the Güre drill core samples, the
432
concentrations were calculated based on the average values. Here, the Hg concentration was
433
1351.5 ppm, the Mn concentration was 462.06 ppm, the As concentration was 70.61 ppm and
434
the Cd concentration was 66.78 ppm; these values were quite high compared to those of the
435
Dikili region. The Cd, As and Pb concentrations in the Küçükkuyu drill core were high in the
436
upper levels and lower or zero towards the deeper layers. The higher concentrations of these
437
elements in the upper levels were due to the agricultural pesticides and fertilizers used in local
438
olive cultivation. The high concentrations of Hg observed at Güre and Küçükkuyu (Güre:
439
Hg = 1351.5 ppm and K. Kuyu: Hg = 1106.4 ppm) are a result of the hydrothermal mineral
440
deposits that are in contact with the carbonate rock formations in the Kaz Mountains.
441
The Pollution Index values of the sediments from the entire study area were calculated, and a
442
map showing the distribution of PI values for the region was produced. The locations at which
443
PI was higher than 1 (PI>1) correspond to the areas where olive cultivation and industrial
444
activities are currently intense; the locations at which the PI values were lower than 1 (PI<1)
445
are typically areas used as beaches and tourist attractions. In the locations with high pollution
446
levels, the number of foraminifer individuals was low and changes in coloration and
447
morphological deformities were observed to be common. In the locations where PI<1, the
448
number of fossil individuals was high, but no coloration changes or morphological deformities
449
were observed. This finding – which was identified for the first time in this study – is evidence
450
of the degree to which foraminifers and other organisms are affected by pollution in their
451
environment. Geochemical analyses of the hydrothermal and sea water samples were carried
452
out to determine the relationships among the heavy metal contents of the sea water,
453
hydrothermal water and sea sediments in the study area. The As concentration in Güre was
30
ACCEPTED MANUSCRIPT 454
14.578 ppm, whereas it was 3.018 ppm in Edremit. The high amount of As, which has a toxic
455
effect, is a subject that requires further investigation. The Ca (27.938 ppm), S (110.850 ppm),
456
and Al (35.326 ppm) concentrations in Edremit were 27.938 ppm, 110.850 ppm and
457
35.326 ppm, respectively, and these values are higher than those seen at Güre. The other
458
elements were approximately equal to each other. The pH in Edremit was 12.88, whereas it was
459
8.80 in Güre. The waters in both locations were alkaline and can be viewed as one of the reasons
460
for the large carbonate shells of the foraminifers. Furthermore, the high levels of sulphur noted
461
in both hydrothermal water samples were viewed as the main cause of the orange coloration
462
observed in the foraminifers.
463 464
Acknowledgements
465
The author thanks Yümün Mühendislik Ltd. Şti for their studies on drilling and core sampling
466
and Sevinç YÜMÜN for the preparation of the samples in the laboratory and for the separation
467
studies of other fossils. Also I would like to thank Güldemin Darbas for the identification of
468
Ostracods. The author also thanks Namık Kemal University Scientific Research Projects
469
Commission
470
NKUBAP.00.17.YL.13.07).
for
accepting
and
financing
the
scientific
studies
(Project
no:
471 472 473
References:
474 475
Avşar N (2002). Gökçeada, Bozcaada ve Çanakkale Üçgeni Kıta Sahanlığı (KD Ege Denizi)
476
Bentik Foraminifer Dağılımı ve Taksonomisi. Hacettepe University Journal of Earth
477
Sciences, 26, 53-75. (In Turkish)
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ACCEPTED MANUSCRIPT 478
Bergin, F., Küçüksezgin, F., Uluturhan, E., Barut, İ. F., Meriç, E., Avşar, N. and Nazik. A.,
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2006, The response of benthic foraminifera and ostracoda to heavy metal pollution in
480
Gulf of İzmir (Eastern Aegean Sea). Estuarine , Costal and Shelf Science, 66, 368-386.
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Eryılmaz M, Yücesoy-Eryılmaz F (1998). Kıt’a Sahanlığı- Doğal Uzantı Kavramları ve Ege
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Denizi’ndeki Kıt’a Sahanlığı Sorunu. Türkiye’nin Kıyı ve Deniz alanları II. Ulusal
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Konferansı. The 98th Conference of the Coasts of Turkey Prosedings, 22/25, 737-748.
484
(In Turkish)
485 486
Meriç E (1983). Foraminiferler. Mineral Research and Exploration Institute Publications. Education Series No: 26. (In Turkish)
487
Meriç E, Avşar N, Bergin F, Barut İ F (2003). Dikili Körfezi'nde (KuzeyEge Denizi-Türkiye)
488
Bulunan Üç Anormal Bentik Foraminifer Örneği: Peneroplis planatus (Fichtel ve
489
Moll), Rosalina sp. ve Elphidium crispum (Linne) Hakkında. Mining Investigation and
490
Search Magazine. 127, 67-81. (In Turkish)
491
Meriç E, Avşar N, Mekik F, Yokeş B, Barut İ F, Dora Ö, Suner F, Yücesoy-Eryılmaz F,
492
Eryılmaz M, Dinçer F and Kam E (2009). Alibey ve Maden Adaları (Ayvalık-Balıkesir)
493
Çevresi Genç Çökellerinde Gözlenen Bnetik Foraminifer Kavkılarındaki Anormal
494
oluşumlar ve Nedenleri. Geological Bulletin of Turkey, 52(1), 31-84. (In Turkish)
495
Meriç E, Avşar N, Nazik A, Koçak F, Eryılmaz F, Eryılmaz M, Barut İ, Yokeş M, Dinçer F,
496
Esenli F, Esenli V, Özdemir Z, Türker A, Aydın Ş (2012). Edremit Körfezi (Balıkesir)
497
Kıyı Alanlarında Oşinografik Özelliklerin Bentik Foraminifer, Ostrakod Ve Bryozoon
498
Toplulukları Üzerindeki Etkileri İle İlgili Yeni Veriler. Journal of Turkish Petroleum
499
Geology, 24 (2), 31-77. (In Turkish)
500
Meriç E, Avşar N, Nazik A, Tunoğlu C, Yokeş B, Barut İ F, Yücesoy- Eryılmaz F, Tuğrul B,
501
Görmüş M, Öncel M S, Orak H, Kam E, Dinçer F (2008). Harmantaşı Mevkii (Saros 32
ACCEPTED MANUSCRIPT 502
Körfezi-Kuzey Ege Denizi) Deniz İçi Kaynakları Çevresindeki Foraminifer Ve
503
Ostrakod Topluluğuna Bu Alandaki Çevresel Koşulların Etkisi. Turkish Journal of Mine
504
Investigation and Research. 136, 63-84. (In Turkish)
505
Toker V, Yıldız A (2002). Kuzeydoğu Ege Denizi Gökçeada-Bozcaada-Çanakkale
506
Üçgenindeki Dip Sedimanlarında Güncel Planktonik Foraminifer Dağılımı. Hacettepe
507
University Journal of Geoscience, 25, 99-110. (In Turkish)
508
Uluturhan E, Küçüksezgin F, Cihangir B (1998). Ege Denizi Kıyılarında Kırma Mercanda (Pagellus erythrinus) Ağır Metal Birikimi 240-244.
509 510
Üstünada M., Erduğan H., Yılmaz S., Akgül R., Aysel V. 2011. Seasonal Concentrations of
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Some Heavy Metals (Cd, Pb, Zn and Cu) in Ulva Rigida J. Agardh (Chlorophyta) from
512
Dardanelles (Çanakkale, Turkey). Environmental Monitoring and Assessment, 177: 337-
513
342.
514
Yümün, Z.U., Meriç, E., Avşar, N., Nazik, A., Barut, I.F., Yokeş, B., Sagular, E.K., Yıldız, A.,
515
Eryılmaz, M., Kam, E., Başsarı, A., Sonuvar, B., Dinçer, F., Baykal, K., Kaya, S.,
516
(2016). Meiofauna, Microflora And Geochemical Properties Of The Late Quaternary
517
(Holocene) Core Sediments In The Gulf Of Izmir (Eastern Aegean Sea, Turkey). Journal
518
of African Earth Sciences - Elsevier. 124 (2016), 383-408.
519
Yumun, Z.U., (2017), The Effect of Heavy Metal Pollution on Foraminifera in the Western
520
Marmara Sea (Turkey), Journal of African Earth Sciences - Elsevier. 129 (2017) 346-
521
365
522 523 524
33
ACCEPTED MANUSCRIPT 525 526 527
EXPLANATION OF PLATE-1 (Dikili)
528
Figure 1: Elphidium crispum, Sample: Dikili BH-3, 14.20-14.30 m
529
Figure 2: Elphidium macellum, Sample: Dikili BH-3, 15.20-15.30 m
530
Figure 3: Elphidium advenum, Sample: Dikili BH-3,28.00-28.50 m
531
Figure 4-5: Ammonia compacta, Sample: Dikili BH-3,19.80-19.90 m
532
Figure 6-7: Ammonia parkinsoniana, Sample: Dikili BH-3,19.20-19.30 m
533
Figure 8-9 : Melonis pompilioides, Sample: Dikili BH-3,17.50-17.60 m
534
Figure 10-11 : Anomalinoides rubiginosus ,Sample: Dikili BH-3,16.10-16.20 m
535
Figure 12-13: Nonionella turgida, Sample: Dikili BH-3,19.30-19.40 m
536
Figure 14-15 : Rosalina brody, Sample: Dikili BH-3,19.30-19.40 m
537
Figure 16-17 : Lobatula lobatula, Sample: Dikili BH-3,19.40-19.50 m
538
Figure 18-19: Pyrgo inornata, Sample: Dikili BH-3,28.00-28.50 m
539
Figure 20-21: Adelosina mediterranensis, Sample: Dikili BH-3,19.90-20.00 m
540
Figure 22-23: Adelosina duthiersi, Sample: : Dikili BH-3,16.20-16.30 m
541
Figure 24: Spiroloculina excavata, Sample:Dikili BH-3,28.00-28.50 m
542
Figure 25: Quinqueloculina seminula, Sample: Dikili BH-3,25.00-26.00 m
543
Figure 26: Reusella spinulosa, Sample: Dikili BH-3,18.10-18.20 m
544
Figure 27: Lagena strumosa, Sample: Dikili BH-3,21.00-22.00 m
545
Figure 28 :Fursenkoina acuta, Sample: Dikili BH-3,16.50-16.60 m
546
Figure 29: Brizalina spathulata: Dikili BH-3,18.60-18.70 m
547
Figure 30: Brizalina spathulata: Dikili BH-3,19.40-19.50 m
548 549 550 551 552
34
ACCEPTED MANUSCRIPT 553 554 555 556
EXPLANATION OF PLATE 2(Güre and Küçükkuyu)
557
Figure 1-2: Ammonia compacta, Sample: Güre :13.70.1
558
Figure 3-4: Ammonia compacta, Sample: Küçükkuyu :13.00.1
559
Figure 5-6: Elphidium crispum, Sample: Güre :13.70.4
560
Figure 7-8: Elphidium complanatum, Sample: Güre :14.70.1
561
Figure 9-10: Elphidium advenum, Sample: Küçükkuyu :10.40.1
562
Figure 11-12: Elphidium advenum, Sample: Güre :14.40.2
563
Figure 13-14: Adelosina mediterranensis, Sample: Güre :13.90.2
564
Figure 15-16: Adelosina mediterranensis, Sample: Küçükkuyu :17.10.2
565
Figure 17-18: Adelosina mediterranensis, Sample: Küçükkuyu :10.30.3
566
Figure 19-20: Quinqueloculina seminula, Sample: : Küçükkuyu :10.30.2
567
Figure 21-22: Miliolinella subratunda, Sample: Küçükkuyu :15.70.1
568
Figure 23-24: Massilina secans, Sample : Küçükkuyu :15.10.1
569
Figure 25-26: Massilina secans, Sample :Güre :15.90.1
570
Figure 27-28: Massilina secans, Sample :Güre :15.70.1
571 572 573 574 575 576 577
35
ACCEPTED MANUSCRIPT 578
PLATE-1 (Dikili)
579 580
36
ACCEPTED MANUSCRIPT 581
PLATE 2 (Güre and Küçükkuyu)
582 583
37
ACCEPTED MANUSCRIPT 584 585
EXPLANATION OF PLATE 3 (Core Samples)
586
Figure 1-2:Elphidium complanatum, Sample:Küçükkuyu-Güre: CORE 3.3(Güre Fener)
587
Figure 3: Elphidium macellum, Sample: Küçükkuyu-Güre:CORE 1.3(Burhaniye Ören)
588
Figure 4: Elphidium crispum, Sample: Küçükkuyu-Güre:CORE 1.5(Burhaniye Ören)
589
Figure 5: Elphidium advenum, Sample: Küçükkuyu-Güre:CORE 3.4(Güre Fener)
590
Figure 6: Elphidium advenum, Sample: Küçükkuyu-Güre:CORE2.15(Akçay Körfez)
591
Figure 7-8 :Ammonia tepida , Sample: Küçükkuyu-Güre:CORE10.5(Cunda Adası)
592
Figure 9-10 : Ammonia compacta, Sample: Küçükkuyu-Güre:CORE10.6(Cunda Adası)
593
Figure 11-12 : Rosalina brody, Sample: Küçükkuyu-Güre:CORE6.17(Çanakkale Babakale)
594
Figure 13-14:Lobatula Lobatula, Sample: Küçükkuyu-Güre:CORE7.3(Assos)
595
Figure 15-16: Peneroplis pertusus, Sample:Küçükkuyu-Güre:CORE 7.11(Assos)
596
Figure 17-18: Peneroplis planatus, Sample:Küçükkuyu-Güre:CORE 7.10(Assos)
597
Figure 19-20: Peneroplis planatus, Sample:Küçükkuyu-Güre:CORE6.1(Çanakkale Babakale)
598
Figure 21-22: Peneroplis sp., Sample:Küçükkuyu-Güre:CORE9-5
599
Figure 23-24: Spirolina arietinus, Sample:Küçükkuyu-Güre:CORE9-6
600
Figure 25-26: Vertabralina striata, Sample:Küçükkuyu-Güre:CORE10.2(Cunda Adası)
601
Figure 27-28: Nodobaculariella cristobalensis: Sample:Küçükkuyu-Güre: CORE6.EX.3 (Çanakkale Babakale)
602
Figure 29-30: Welmanellinella striata, :Sample:Küçükkuyu-Güre: CORE6.10 (Çanakkale Babakale)
603 604 605 606
38
ACCEPTED MANUSCRIPT 607 608
EXPLANATION OF PLATE 4 (Core Samples)
609
Figure 1-2: Adelosina mediterranensis, Sample: Küçükkuyu-Güre:CORE2.4(Akçay Körfez)
610
Figure 3-4: Adelosina mediterranensis, Sample: Küçükkuyu-Güre: CORE6.EX.6(Çanakkale Babakale)
611
Figure 5-6: Adelosina duthiersi, Sample: : Küçükkuyu-Güre: CORE6.EX.8(Çanakkale Babakale)
612
Figure 7-8: Adelosina cliarensis, Sample: Küçükkuyu-Güre:CORE4.2(Güre Merkez)
613
Figure 9-10: Pseudotriloculina leavigata, Sample: Küçükkuyu-Güre: CORE4.7(Güre Merkez)
614
Figure 11-12: Massilina secans, Sample: Küçükkuyu-Güre: CORE6.EX.11(Çanakkale Babakale)
615
Figure 13-14: Quinqueloculina bidentata, Sample: Küçükkuyu-Güre: CORE6.9(Çanakkale Babakale)
616
Figure 15-16: welmanellinella striata, Sample: Küçükkuyu-Güre: CORE6.18(Çanakkale Babakale)
617
Figure 17-18: Lachlanella variolata, Sample: Küçükkuyu-Güre: CORE6.4(Çanakkale Babakale)
618
Figure 19-20: Lachlanella undulata, Sample: Küçükkuyu-Güre: CORE6.EX.14(Çanakkale Babakale)
619
Figure 21-22: Massilina secans, Sample: Küçükkuyu-Güre: CORE2.1(Akçay Körfez)
620
Figure 23: Spiroloculina excavata, Sample: Küçükkuyu-Güre: CORE6.EX.19(Çanakkale Babakale)
621
Figure 24: Spiroloculina depressa, Sample: Küçükkuyu-Güre: CORE6.EX.20(Çanakkale Babakale)
622
Figure 25-26: Quinqueloculina bidentata, Sample: Küçükkuyu-Güre: CORE4.4(Güre Merkez)
623
Figure 27-28: Planorbulina mediterranensis, Sample:Küçükkuyu-Güre:CORE6.EX.16(Çanakkale Babakale)
624
Figure 29-30: Uvigerina senticosa, Sample:Küçükkuyu-Güre:CORE6.EX.22(Çanakkale Babakale)
625 626 627 628 629 630 631 632
39
ACCEPTED MANUSCRIPT 633
PLATE 3 (Core Samples)
634 635
40
ACCEPTED MANUSCRIPT 636
PLATE 4 (Core Samples)
637 638
41