Geology and diagenesis of a zeolitic Foça tuff unit deposited in a Miocene phreatomagmatic lacustrine environment (western Anatolia)
Turkish Journal of Earth Sciences
http://journals.tubitak.gov.tr/earth/
Research Article
Turkish J Earth Sci
(2013) 22: 611-631
© TÜBİTAK
doi:10.3906/yer-1203-11
Geology and diagenesis of a zeolitic Foça tuff unit deposited in a Miocene
phreatomagmatic lacustrine environment (western Anatolia)
Mustafa ALBAYRAK, Abdullah Mete ÖZGÜNER*
Mineral Research and Exploration General Directorate, Ankara, Turkey
Received: 19.03.2012
Accepted: 31.10.2012
Published Online: 13.06.2013
Printed: 12.07.2013
Abstract: This study explains the relations between the depositional environment of a zeolitic tuff unit and its diagenesis. It gives new
ideas of the juvenile phreatomagmatic origin of the zeolitic unit with its bentonitic cap rock, and finds that the diagenetic alteration of
the volcanic ash deposition in a hot hydrologic system is penecontemporaneous and not epigenetic. A massive, fine-grained zeolitic
unit has a sharp contact with the underlying shallow subaqueous rhyolitic dome intrusions and their surrounding volcanoclastic ejecta.
Juvenile emanations from the basal subaqueous intrusions activated thorough zeolitic diagenesis within the overlying rhyolitic tuff
deposits extending as far as the periphery of the underlying intrusions. The bentonitic cap rock suggests that the diagenesis diminished
vertically with the weakened phreatomagmatic activity up to the overlying limestone. The lack of sedimentary evaporite minerals and
scarcity of boron-bearing authigenic K-feldspar indicate a nonsaline-alkaline depositional and diagenetic environment during the
zeolitic transformation. Geochemical data from the zeolitic tuff samples indicated that the main diagenetic factors were hydrolysis of the
glassy tuff in an open hydrologic system, under high heat flow rates and one of several scales of ion transfer. Zeolitisation developed with
a significant loss of alkaline elements and iron oxide, which were compensated for by an important gain in the alkaline earth elements
and absorption of strontium. The rhyolitic glass was altered by hydrolysis to form smectite and clinoptilolite, resulting in the release of
excess silica that was not removed from the system but was changed in crystal form to opal-CT.
Key words: Clinoptilolite, hydrolysis, opal-CT, peperites, pyroclastic flow, rhyolitic ash, subaqueous intrusion
1. Introduction
The study area is situated north of the city of İzmir and
the Güzelhisar River, between the gulfs of Aliağa and
Çandarlı on the Aegean coast of western Turkey (Figure
1). Neogene volcano-sedimentary basins in western
Anatolia contain evaporites and diagenetically related
important industrial minerals resources, such as borates,
gypsum (+celestite), industrial clays, and zeolites, within
subaqueously deposited calc-alkaline volcanoclastic
sediments (Kumbasar et al. 1985; Helvacı et al. 1988; Yalçın
1988; Gündoğdu et al. 1989; Helvacı et al. 1993; Gündoğdu
et al. 1996; Uz et al. 1996; Whateley et al. 1996). The zeolitic
tuff unit, with its bentonitic cap rock in the study area,
has similar subaqueously deposited calc-alkaline volcanic
characteristics. Some other publications directly related to
local zeolite occurrences in western Anatolia (e.g., Esenli
1986; Türkbileği 1988; Sirkecioğlu et al. 1990; Esenli &
Özpeker 1993; Özpınar et al. 1999; Köktürk et al. 2000;
Albayrak 2008) are mostly concerned with diagenetic,
mineralogical, geochemical, and technological properties
of zeolites, but their relations to the properties of the
depositional environments have mostly been neglected or
* Correspondence:
not examined in detail. Most of them have a hydrothermal
and epigenetic origin. The aim of this manuscript is to
describe the geological properties of the depositional
environment of the Foça zeolitic unit and their relations
to its diagenesis. The origin of the Foça zeolitic unit, with
its bentonitic cap rock, was a penecontemporaneous
diagenetic alteration of subaqueous volcanic ash fall
deposits in a hot juvenile phreatomagmatic environment,
and had a vertical zonation with the overlying bentonitic
cap rock.
The subaqueous-subaerial properties and calcalkaline–alkaline evolution of Neogene volcanism in the
Foça region, immediately south-west of the study area,
were examined by Akay & Erdoğan (2001, 2004). They
showed that mid-Miocene rhyolitic domes intruded
directly into a subaqueous environment and formed
hyaloclastic blankets in the region.
Clinoptilolite-heulandite and opal-CT are the most
abundant diagenetic minerals within rhyolite tuffs.
According to Resing & Sansone (1999), the zeolitisation
process started with clay rim formation around volcanic
glass shards in weak acidic fluids, originating from
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ALBAYRAK and ÖZGÜNER / Turkish J Earth Sci
N
BLACK SEA
İstanbul
AEGEAN SEA
Ankara
TURKEY
İzmir
Antalya
300 km
0
MEDITERRANEAN
Location map of the study area.
D
Altınova
İ K
KOZAK PLUTON
İ L
İ
Bergama
G
yunt.
R
A
Dikili
B
E
N
yunt.
B
E
R
G
A
M
A
G
R
A
B
E
N
N
Zeytindağ
Çandarlı
Ça
G nda
ul rlı
f
?
0
AEG
EAN
Aliağa Gulf
lst
?
lst
Şakran
Yuntdağ
Volcano
yunt.
yunt.
?
lst
lst
rhy.
Dumanlıdağ
Volcano
Lacustrine limestone
rhy
Foça rhyolites
yunt. Yuntdağ volcanics
?
?
lst
Meso. Mesozoic basement
?
rhy.
Foça
Quaternary deposits
yunt.
Aliağa
Miocene
SEA
Pınarcık lst
rhy.
10 km
?
Menemen
Central volcanic vents
Meso.
yunt.
?
Yamanlar
Volcano
?
?
Çiçekli
İZMİR
Inferred weakness
zones in basement
Probable direction
of extentional forces
Study area of zeolite
Centres of settlement
Figure 1. Distribution of the volcanic outcrops and main volcanic vents around the Aliağa-Pınarcık zeolite deposits. The regional
weakness zones in the basement were inferred on the basis of the alignment of volcanic vents and dyke trends (partly after Akay and
Erdoğan, 2004).
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ALBAYRAK and ÖZGÜNER / Turkish J Earth Sci
magmatic volatiles in the subaqueous environment,
followed by hydrolysation of soluble cations, leading to
a weakly basic environment for zeolitisation. Lander &
Hay (1993), Ghiara et al. (1999), and Snelling et al. (2008)
explained that clinoptilolite formed in situ from volcanic
glass in rhyolitic tuffs and that excess silica was not
removed from the system, but crystallised as opal CT. Hay
(1963), Boles & Coombs (1975), Rice et al. (1992), Leggo
et al. (2001), and Cocheme et al. (2003) further explained
that the clinoptilolite, cristobalite, and possibly amorphous
silica were pseudomorphic after rhyolitic glass shards, and
that in such an environment smectites developed from the
glass, forming a clay rim around the outline of the shards.
2. Materials and methods
2.1. Field methods
Stratigraphical sections were determined in different parts
of the volcano- sedimentary sequence. Detailed geological
mapping of the study area was undertaken, concentrating
on the origins of the volcano-sedimentary bodies, each time
correcting it when different origins and mutual relations
were discove (...truncated)