INTRODUCTION
Interlobate eskers represent one of the largest glaciofluvial landforms and can have sediments up to 100 m thick. They form between two ice lobes with different ice dynamics (Punkari, Reference Punkari1980; Lundqvist, Reference Lundqvist, Goldwaith and Matsch1989; Kujansuu et al., Reference Kujansuu, Kurkinen, Niemelä, Ehlers and Kozarski1995; Brennand and Shaw, Reference Brennand and Shaw1996; Thomas and Montaque, Reference Thomas and Montaque1997; Gruszka et al., Reference Gruszka, Morawski and Zieliński2012; Santos, Reference Santos2012). Interlobate glaciofluvial complexes may have highly varying internal structures due to variable sedimentation patterns and rapid changes in depositional processes and environments (Paterson and Cheel, Reference Paterson and Cheel1997; Russell and Arnott, Reference Russell and Arnott2003; Mäkinen, Reference Mäkinen2004). Although morphologically varying, long and continuous glaciofluvial deposits, including fan deposits, are generally referred to as eskers (cf. Mäkinen, Reference Mäkinen2003a); here we use the term glaciofluvial complex. This includes several glaciofluvial elements including the esker with its commonly boulder-rich esker core, subaqueous outwash fans, morphologically undetectable kettle holes (MUKHs), and ice-marginal crevasse deposits as described by Mäkinen (Reference Mäkinen2003b) for the Säkylänharju-Virttaankangas glaciofluvial complex located within the same interlobate system as the one studied here. The significance of these large landforms to society is great as they host significant ground water resources and sand and gravel deposits (Ahokangas, Reference Ahokangas2019). In the Köyliö area, southwest Finland, the esker chain has been mapped (Lindroos et al., Reference Lindroos, Hyyppä, Stén and Tuittila1983) to follow the sandstone-Svecofennian basement rock contact in the deep Satakunta sandstone depression (Fig. 1). According to Lindroos and colleagues (Reference Lindroos, Hyyppä, Stén and Tuittila1983), the esker core lies on to the sandstone-Svecofennian basement contact, which results in an asymmetric core form in the southeastern side of Lake Köyliönjärvi. Locally over 90 m of glaciofluvial sediments fill this ca. 200–1000-m-wide and up to 20-km-long depression (Palmu et al., Reference Palmu, Mattson and Valli1994).
Large interlobate glaciofluvial complexes completely filling bedrock depressions are uncommon in both Finland and elsewhere. Eskers in southern Finland usually directly overlie the crystalline Paleoproterozoic Svecofennian bedrock (>1800 Ma), but in Köyliö they overlie Mesoproterozoic sandstone. This is unusual as Mesoproterozoic sedimentary rocks are rare in Finland. The known occurrences are poorly exposed and have been preserved in bedrock depressions mainly filled with Quaternary sediments or in areas with low glacial erosion. Similar settings elsewhere in Finland are buried by glaciofluvial and glacial sediments that can be up to 100 m thick like in the Suupohja area adjacent to the Lauhanvuori Sandstone Formation (Pitkäranta, Reference Pitkäranta2009) and 140 m thick like in the Neo-Proterozoic Jothnian Muhos Formation in the Oulu district (cf. Breilin et al., Reference Breilin, Paalijärvi, Valjus, Huotari and Miettunen2006; Breilin and Putkinen, Reference Breilin and Putkinen2012). Moreover, the dimensions of the Satakunta sandstone depression are within the range of known tunnel valley dimensions (Ó Cofaigh, Reference Cofaigh1996; Praeg, Reference Praeg2003; Gibling, Reference Gibling2006; Kristensen et al., Reference Kristensen, Plotrowski, Huuse and Clausen2007). However, the Köyliö glaciofluvial complex seems to completely fill the depression, whereas tunnel valleys often have eskers running at the bottom while the rest of the valley is usually infilled with other types of sediments (Ó Cofaigh, Reference Cofaigh1996; Brennand et al., Reference Brennand, Russell, Sharpe and Knight2006). The Köyliö area also lacks the overlying fine-grained deposits or overlying/interbedded till deposits that have been found in several Canadian (Ahmad et al., Reference Ahmad, Schmitt, Rokosh and Pawlowicz2009; Pugin et al., Reference Pugin, Pullan, Hunter and Oldenborger2009, Reference Pugin, Oldenborger, Cummings, Russell and Sharpe2014a), North American (Clayton et al., Reference Clayton, Attig and Mickelson1999; Hooke and Jennings, Reference Hooke and Jennings2006), and European tunnel valley systems (Huuse et al., Reference Huuse, Piotrowski and Lykke-Andersen2003; Jørgensen and Sandersen, Reference Jørgensen and Sandersen2006; Kristensen et al., Reference Kristensen, Plotrowski, Huuse and Clausen2007). The evolution of the sandstone basin ended about 1270–1250 Ma (Pajunen and Wennerström, Reference Pajunen and Wennerström2010), and its geological history until the deglaciation and deposition of the interlobate glaciofluvial complex is unknown.
Detailed study of the depositional characteristics of interlobate glaciofluvial complexes, infilling a major bedrock depression, relies on geophysical methods such as ground penetrating radar (GPR) and the increasingly more cost-effective (e.g., landstreamer) high-resolution seismic reflection method (HRSR). The ability to resolve structures at depth in saturated, >100-m-thick glacial sediments makes the HRSR method excellent compared to GPR, which has penetration depths limited to 20–40 meters depending on the antenna frequency and electrical conductivity of the materials. The HRSR method with landstreamer has been used during various hydrogeological studies of tunnel valley aquifers in Canada and the United States (Pugin et al., Reference Pugin, Larson, Bergler, McBride and Bexfield2004; Ahmad et al., Reference Ahmad, Schmitt, Rokosh and Pawlowicz2009; Pugin et al., Reference Pugin, Pullan, Hunter and Oldenborger2009; Pugin et al., Reference Pugin, Oldenborger, Cummings, Russell and Sharpe2014a), and in esker characterization in Canada (Sharpe et al., Reference Sharpe, Pullan and Warman1992; Barnett et al., Reference Barnett, Sharpe, Russell, Brennand, Gorrell, Kenny and Pugin1998; Pugin et al., Reference Pugin, Pullan and Sharpe1999; Cummings and Russell, Reference Cummings and Russell2007; Pullan et al., Reference Pullan, Pugin and Hunter2007; Tremblay et al., Reference Tremblay, Hunter, Lamontagne and Nastev2010; Cummings et al., Reference Cummings, Gorrell, Guildbault, Hunter, Logan, Ponomarenko, Pugin, Pullan, Russell and Sharpe2011), Finland (Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017; Brodic et al., Reference Brodic, Malehmir, Pugin and Maries2018), and the European Alps (Burschil et al., Reference Burschil, Buness, Tanner, Wielandt-Schuster and Gabriel2018).
The Köyliö interlobate glaciofluvial complex hosts a substantial ground water reservoir, which has a high importance for the surrounding communities’ water supply. The hydrogeological characteristics of the glaciofluvial sediments in the Köyliö area were earlier investigated during 2014 (Ahokangas and Mäkinen, Reference Ahokangas and Mäkinen2014) in collaboration with the environmental authorities and neighboring communities to understand the depositional conditions of the glaciofluvial complex. However, the depth penetration of GPR (ca. 20 m) and limited drill-hole depths (9–47 m) were inadequate for the investigation of the deeper parts of the glaciofluvial complex.
The primary objective of the survey is to investigate the poorly known dimensions and tectonic characteristics of the Satakunta sandstone depression and related glacial stratigraphy to better characterize the composition of the glaciofluvial complex and its interlobate origin. The secondary objective is to determine the position of the possible high-conductivity, gravelly esker core and its connection with the other sediments that infill the sandstone depression. In addition, we explore the nature of the bedrock depression as a possible tunnel valley environment. We conducted a seismic survey with a newly developed digital-based landstreamer system (Brodic et al., Reference Brodic, Malehmir, Juhlin, Dynesius, Bastani and Paul2015; Malehmir et al., Reference Malehmir, Andersson, Mehta, Brodic, Munier, Place, Maries, Smith, Kamm, Bastani, Mikko and Lund2016) during August 2014. This paper presents the first application of the landstreamer-based HRSR survey to characterize a sedimentary rock depression and infilling late-Quaternary interlobate glaciofluvial sediments in Finland.
THE STUDY AREA
Bedrock characteristics and the tectonic development of the Satakunta sandstone basin
The predominantly crystalline bedrock of southwestern Finland formed ca. 1900–1800 Ma during the Svecofennian orogeny. After the orogeny, marked tectonic movements and erosion related to isostatic balancing reactivated earlier fault structures, and new brittle structures formed (Pajunen and Wennerström, Reference Pajunen and Wennerström2010). In the Köyliö area, the Svecofennian plutonic rocks consist mostly of granites, tonalities, granodiorites, and the supracrustal rocks of mica gneisses and schists (Veräjämäki, Reference Veräjämäki1998). The most important tectonic movements after the Svecofennian orogeny are related to the rapakivi intrusion ca. 1650–1550 Ma, the formation of the Jothnian sedimentary basin at ca. 1400–1300 Ma, and the setting of the post-Jothnian olivine diabases 1270–1250 Ma (e.g., Pajunen and Wennerström, Reference Pajunen and Wennerström2010). The Svecofennian structures have influenced the setting of the rapakivi granites (Pajunen et al., Reference Pajunen, Airo, Elminen, Mänttäri, Niemelä, Vaarma, Wasenius and Wennerström2008) and the development of the young brittle structures and partly determined their characteristics (Pajunen et al., Reference Pajunen, Airo, Wennerström, Niemelä and Wasenius2001). Young tectonic events were concentrated mainly on the old weakness zones of bedrock (Elminen et al., Reference Elminen, Airo, Niemelä, Pajunen, Vaarma, Wasenius and Wennerström2008; Pajunen et al., Reference Pajunen, Airo, Elminen, Mänttäri, Niemelä, Vaarma, Wasenius and Wennerström2008).
The Satakunta sandstone basin is located in a large northwest–southeast oriented graben ca. 70 km north of the city of Turku. The steep northwest–southeast oriented vertical faults partly border the graben (Heikkinen et al., Reference Heikkinen, Korja and Aaro1998; Paulamäki and Paananen, Reference Paulamäki and Paananen2001). The sandstone has a sharp contact to the porphyritic rapakivi granite and basement rocks (granodiorite) in the east (Veräjämäki, Reference Veräjämäki1998) (Fig. 2). Pajunen and Wennerström (Reference Pajunen and Wennerström2010) interpreted the sandstone basin as an oblique transtensional structure with a polyphase kinematic history that caused complex fault structures and open folding in the sandstone layers. The sandstone is intruded by olivine diabases occurring as large mafic laccoliths (Elo and Pirttijärvi, Reference Elo and Pirttijärvi2010; Pajunen and Wennerström, Reference Pajunen and Wennerström2010) and narrower diabase dykes. The stratified sandstone is fine- to coarse-grained, its bedding thickness varies from a few centimeters up to a meter (Veräjämäki, Reference Veräjämäki1998), and it was deposited by poorly channeled braided streams in an alluvial environment (Kohonen et al., Reference Kohonen, Pihlaja, Kujala and Marmo1993; Pokki et al., Reference Pokki, Kohonen, Lahtinen, Rämö and Andersen2013). The maximum thickness of the sandstone based on gravimetric data is ca. 1800 m (Elo, Reference Elo1976). Based on the gravimetric studies (Elo et al., Reference Elo, Kuivamäki, Kurimo, Palmu and Siivonen1993), it is ca. 180–195 m thick between Lake Köyliönjärvi and Pyhäjärvi. Diabase dykes (40–60 m thick) occur within the sandstone west of Lake Pitkäjärvi (Kurimo et al., Reference Kurimo, Elo and Mattson1992). Quaternary deposits mostly cover the sandstone basin, and only some sandstone exposures exist outside the study area (cf. Pajunen and Wennerström, Reference Pajunen and Wennerström2010).
The deglaciation and timing of esker deposits
The deglaciation of southwest Finland related to the decay of the Baltic Sea Ice Stream from the III Salpausselkä to the Gulf of Bothnia (Kleman et al., Reference Kleman, Hättestrand, Borgström and Stroeven1997; Boulton et al., Reference Boulton, Dongelmans, Punkari and Broadgate2001) (cf. Fig. 1). This ice stream divided into two sublobes in southwest Finland after the ice margin had retreated from the III Salpausselkä. The glaciofluvial complex running between Neittamonnummi and Lake Köyliönjärvi (cf. Fig. 2) is a part of the Pori-Koski esker chain formed in an interlobate position between two sublobes (Saarnisto and Salonen, Reference Saarnisto, Salonen, Ehlers and Kozarski1995; Mäkinen, Reference Mäkinen2004). The smaller Loimaa lobe in the southeast extended between the Pori-Koski esker chain and the Tampere interlobate zone. The western sublobe was more active on the sandstone area and in deeper water than the eastern Loimaa sublobe located on the Svecofennian rocks and in shallower water. The north–south oriented De Geer moraines on the southwest side of the Pori-Koski esker chain indicate an abrupt change in the direction of the ice margin (cf. Tikkanen, Reference Tikkanen1981) (cf. Fig. 1). The deglaciation of southwest Finland occurred during early Holocene between 11,600 and 11,000 cal yr BP (Hughes et al., Reference Hughes, Gyllencreutz, Lohne, Mangerud and Svendsen2016; Stroeven, Reference Stroeven, Hattestrand, Kleman, Heyman, Fabel, Fredin, Goodfellow, Harbor, Jansen, Olsen, Caffee, Fink, Lundqvist, Rosqvist, Strömberg and Jansson2016). The formation of Köyliönjärvi-Säkylänharju-Virttaankangas glaciofluvial deposits are dated to ca. 11,160–11,060 cal yr BP (Mäkinen, Reference Mäkinen2004), based on Sauramo's (Reference Sauramo1929) recession lines following the major esker chain through the Loimaa lowlands. The study area was subaquatic during initial deglaciation, and the highest shoreline (Yoldia Sea) was at ca. 170 m asl in the area (Eronen and Haila, Reference Eronen, Haila and Alalammi1990). The proglacial water depth ranged from ca. 220 m in the depression to 120–130 m in the surrounding area.
The characteristics of the sandstone depression and infilling sediments
Gravimetric, magnetic and refraction seismic measurements (Kurimo et al., Reference Kurimo, Elo and Mattson1992; Palmu et al., Reference Palmu, Mattson and Valli1994) indicate a fracture zone up to 1 km wide between Lakes Köyliönjärvi and Pitkäjärvi (see Fig. 2). The sandstone-basement rock contact is within this fracture zone. The bedrock surface on the western flank of the sandstone depression varies from 70 to 20 m asl. The deepest parts of the sandstone depression are between elevations of −30 to −50 m asl. The deep drill hole (SK 2) (see Figs. 2, 4) completed east of Lake Pitkäjärvi intercepted 92-m-thick sediments above the sandstone within the fracture zone (Johansson and Taanila, Reference Johansson and Taanila1975). The sediment cover is at its thinnest over the diabase (2–20 m; Lindroos et al., Reference Lindroos, Hyyppä, Stén and Tuittila1983), but it is commonly over 50 m and up to 90–100 m thick in the sandstone area.
The sandstone depression aligns obliquely with the ice flow directions of the Baltic Sea ice lobe in the deglacial phase (cf. Tikkanen, Reference Tikkanen1981). The large size of the Säkylänharju-Virttaankangas interlobate glaciofluvial complex (1–3 km wide and almost 22 km long) southeast of the Köyliö sandstone area, parts of which rise 70 m above the surrounding plains, is explained by the availability of easily erodible sandstone (Kaitanen and Ström, Reference Kaitanen and Ström1978). Sediments preceding esker core formation were imaged in an HRSR survey from the bedrock fracture beneath the Säkylänharju-Virttaankangas glaciofluvial complex ca. 20 km southeast of the Köyliö area (cf. Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017), implying that they may also exist in the Köyliö area.
The studied glaciofluvial complex emerges from the northwestern end of Lake Köyliönjärvi. The glaciofluvial ridge is most distinct between Lake Köyliönjärvi and Neittamonnummi, where its altitude is ca. 5–8 m above the surrounding areas. The ridge form disappears and the topography becomes flat in the Neittamonnummi area where the whole esker descends into the deep sandstone depression. Based on the sedimentology of the glaciofluvial sediments to the southeast of Lake Köyliönjärvi (Mäkinen, Reference Mäkinen2003a), the esker core of the glaciofluvial complex formed time-transgressively in a subglacial tunnel and was buried by repeated subaqueous fan sediments. Also, there the esker core follows the sandstone depression before it rises over the Svecofennian basement contact.
METHODS AND MATERIALS
The Köyliö study area was investigated using a combination of earlier GPR (2012–2014) data (Mäkinen and Ahokangas, Reference Mäkinen and Ahokangas2012; Ahokangas and Mäkinen, Reference Ahokangas and Mäkinen2014) and new HRSR data (2014), supported by the available reference drill holes. Several drillings were conducted in the study area between 2012 and 2018 (cf. Figs 2–4), including our new drill hole REF-2017, which drilled down to the sandstone bedrock to support the interpretation of the southern HRSR line. Additional information about bedrock depth was obtained from a private resident's geothermal heat well near seismic profile 1 (drill hole GH1) as well as two deep drill holes (SK1 and SK2) made in the 1970s (Johansson and Taanila, Reference Johansson and Taanila1975). Destia Ltd and Suomen Pohjavesitekniikka Ltd made the drill holes with a heavy drill machine, including a 3-m bedrock confirmation when bedrock was reached. All drill holes were cored to obtain the lithology of the sediments, but no sampling was performed. Ground water pipes were installed in most of the drill holes (excluding REF-2017, SK1, SK2, and GH1) for the observations of the Centre for Economic Development, Transport and the Environment. Most of the drill holes made during the hydrogeological investigations do not reach bedrock and are restricted to 9–47 m in depth due to cost and pumping well depth limitations (see Fig. 4). The Pitkäjärvi deep drill holes (SK1 and SK2) reach the sandstone at a depth of 91–92 m, and REF-2017 reaches sandstone at 60 m within the depression. Drill holes SPT2, SPT4, and GH1 reach the Svecofennian basement bedrock on the eastern side of the depression.
The Geological Survey of Finland (GTK) conducted three GPR reconnaissance surveys with 100 MHz antennae in 2012–2014, yielding a total of 40 km of GPR lines. The dielectricity value used was 6, and measurement time was 400 ns. The data were processed with background removal calculated from data, high and low pass filtering, and slight signal enhancement. No further processing was applied to the data. The radar profiles were plotted as .tiff images with a length scale of 10 m/cm. The 2014 GPR lines were acquired for ground water investigations between Lake Köyliönjärvi and Lake Ilmiinjärvi (cf. Fig. 3). These lines provided information on the ground water level, the uppermost 2–15 m of sedimentary structures, and the depth of the diabase bedrock in the west (Mäkinen and Ahokangas, Reference Mäkinen and Ahokangas2012; Ahokangas and Mäkinen, Reference Ahokangas and Mäkinen2014). The presence of fine-grained beds and clay decreased the penetration depth of the GPR in the Neittamonnummi area (see Fig. 4, drill holes SPT4–SPT5).
The seismic survey consisted of two seismic profiles (profile 1 and 2, see Fig. 3), each over 2 km long acquired mainly along the available gravel roads in the forest. The ground water table is at a depth of 1–13 m along seismic profile 1 and 3–8 m along seismic profile 2, placing most of the esker below the water table. We acquired the data with a newly developed broadband seismic landstreamer (Brodic et. al, Reference Brodic, Malehmir, Juhlin, Dynesius, Bastani and Paul2015) designed for high-resolution near-surface applications. We used the landstreamer, consisting of four segments, each containing 20 microelectromechanical broadband sensors (Fig. 5a), resulting in a total spread 200 m long for fast and efficient data acquisition. Although three-component data were recorded, we have used only vertical component data for this study. The data acquisition of 5 km of HRSR and refraction data (2–4 m receiver and shot spacing) took 5 days. We generated seismic energy using a 500-kg drop-hammer mounted on a Bobcat vehicle. To achieve greater length coverage and properly record refracted arrivals from the bedrock, 50 wireless recorders connected to 10 Hz geophones (see Fig. 5b) were spaced along each profile (10–20 m apart) in two or three stages (roll-along), covering the entire length of each profile. The maximum offset obtained this way was about 1000 m. Since the survey relied on the available roads, the wireless recorders also had the advantage of providing some data near crossing roads or bridges.
We picked first breaks of each shot record and used a 3D turning-ray travel time tomographic inversion algorithm (Tryggvason et al., Reference Tryggvason, Rognvaldsson and Flovenz2002) to make a near-surface velocity model fitting to the observed travel times. Root mean square errors of the final model were 2 and 2.3 ms for profiles 1 and 2, respectively. Reflection data processing followed a conventional processing flow (Malehmir et al., Reference Malehmir, Saleem and Bastani2013b; Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017) focused on prestack signal enhancements and including common midpoint stacking. The most time-consuming part was obtaining a proper normal move-out velocity to account for the steep velocity gradient with the depth and the dipping nature of the bedrock. The seismic reflection sections were migrated and converted from time to depth using a velocity of 1400 m/s for profile 1 and 1300 m/s for profile 2. The uppermost 10–20 m have few reflections in the seismic profiles. As such, the existing GPR lines and the previous sedimentological interpretations based on them (Mäkinen and Ahokangas, Reference Mäkinen and Ahokangas2012; Ahokangas and Mäkinen, Reference Ahokangas and Mäkinen2014), as well as drill hole data, were used to supplement the HRSR profiles and interpretations for the uppermost 20 m near the land surface (Ahokangas and Mäkinen, Reference Ahokangas and Mäkinen2014) (cf. Fig. 3) where the seismic profiles had poor quality due to low fold in near offsets.
RESULTS AND INTERPRETATION
The interpretation of the seismic data in the Köyliö study area
The high quality of the HRSR data allows both the bedrock and esker sediment characteristics in the Köyliö area to be interpreted. The deepest interpretable reflections extend to the depth of −150 m asl. The refraction tomography profile with velocities (Fig. 6) and drill holes allows the separation of infilling esker sediments and the bedrock surface within the sandstone depression. The bedrock structural features had similarities in both seismic profiles, and therefore the results are presented only for profile 2 (cf. Fig. 7). The position of the sandstone contact was interpreted with refraction tomography and the seismic reflection profiles, as well as with the drill hole information and previous work by Palmu and colleagues (Reference Palmu, Mattson and Valli1994). The bedrock elevation was interpreted from a combination of the first travel time tomography and reflection seismic profiles. We used the velocity for sandstone (3000–4000 m/s) for the outlining bedrock elevation in the southwest end of the profiles (see Fig. 6).
The implications of the Köyliö drill hole data
The drill holes in Neittamonnummi and the surrounding areas aided in the bedrock surface interpretations of the seismic sections (cf. Fig. 4). Only drill holes GH1, P3, SPT1, SPT2, SPT4, REF-2017, SK1, and SK2 intercepted the bedrock at 16.45 to −42 m asl. The bedrock surface in the rapakivi granite area of Neittamonnummi is in the depth of 27–35 m asl (SPT1, SPT2, and SPT4). The bedrock elevation is on average at 15–35 m asl outside the sandstone depression (drill holes HP3, GH1) (cf. Fig. 2).
The other drill holes (19.7–47 m deep) reached mostly fine-grained to sandy sediments (clay-silt, fine sand, and sand), supporting the presence of the sandstone depression. Coarse sand and bouldery sand sediments occur in drill holes SPT6 and SPT7 between the seismic profiles and in P1 and P2 north of profile 2 as well as in the deep drill holes REF-2017, SK1, and SK2. The new 75-m-deep reference drill hole (REF-2017) made next to profile 1 on the southwest flank of the sandstone depression reveals coarse sand, gravel with cobbles, and boulders on top of sandstone. Drill hole SK1 revealed 80 m of sand and 8 m of gravel, and SK2 revealed alternating sand and boulder beds on top of the sandstone. We interpret these to signify the presence of the esker core within the sandstone depression.
Bedrock characteristics and the structure of the sandstone depression
Seismic profiles 1 and 2 provide a delineation of the sandstone depression and the bedrock surface with reasonable accuracy. No clear high-velocity (e.g., >5000 m/s) boundary was reached in the depression zone tomography sections because of a combination of thick esker sediments (up to 100 m) and sandstone at the bottom of the depression. Coarse-grained sandstone and the overlying thick sediments also affected the general quality of the tomography profiles. The low seismic velocities (3000–4000 m/s) originate from the sandstone and fractured bedrock near the contact of granodiorite and rapakivi granite along the northeast part of profile 1 (see Fig. 6a). These velocities agree with previous refraction seismic soundings northwest of Lake Pitkäjärvi, approximately 5 km north of the study area (cf. Fig. 2) (Geological Survey of Finland, 1973). It provided velocities of 3500–3800 m/s for the sandstone and 3350–4500 m/s for the diabase dykes (Lindroos et al., Reference Lindroos, Hyyppä, Stén and Tuittila1983).
Based on the seismic profiles, the sandstone depression is approximately 800–850 m wide and extends down to a depth of ca. 100 m (see Figs. 6a and 6b). This calculated depth correlates well with the 92-m-deep Pitkäjärvi drill hole SK1 (Johansson and Taanila, Reference Johansson and Taanila1975) and with depths provided by the earlier seismic and gravity profiles (Palmu et al., Reference Palmu, Mattson and Valli1994). However, the previous interpretation (Palmu et al., Reference Palmu, Mattson and Valli1994) of the width of the fracture zone is 400–600 m too wide in the east compared to the seismic data. The difference is more apparent along seismic profile 2 (see Fig. 6b). An abrupt drop in the bedrock surface (profile 1: 1700–1800 m, profile 2: 1050–1100 m) is observed in both the tomography models (see Fig. 6) and the reflection seismic profiles (Figs. 8 and 9). This steep drop is interpreted as the position of the sandstone contact. The contact appears to be about 500 m farther east in profile 1 (distance 1700–1800 m) (see Figs. 6a and 9) and about 350–400 m farther west in profile 2 (distance 1000–1100 m) (see Figs. 6b and 9).
A strong and continuous reflection is observed in both seismic profiles 1 and 2 (see red solid line, Figs 8b and 9b). It is the strongest in parts of profile 1 (distance 950–1250 m) and profile 2 (200–550 m, 1200–2100 m). The level of this reflection varies along profile 1 between 20 and −40 m asl (see Fig. 8b). Along profile 2, it deepens from 20 m asl down to −70 m asl. A steep contact at a 1050-m distance interrupts the reflection, and then it rises to 0–20 m asl (see Fig. 9b). There is a small 200-m-wide and 10-m-deep concave drop in the reflector (distance 1500 m) in profile 1, indicated also by the collapsed sediments above (see pink shaded area, Fig. 8b). We interpret the continuous reflection to be associated with bedrock surface, which is supported by the two reference drill holes (GH-1, REF-2017) along profile 1. Reference drill hole REF-2017 reached compact and solid sandstone without indications of fracturing or weathering (Murto, S., personal communication, 2017). The small drop (profile 1 at 1500 m) in the bedrock elevation is interpreted to coincide with a vertical fault. The accuracy of the bedrock elevation between the 2017 reference drill hole (REF-2017) and the interpreted bedrock reflections in profile 1 is 2–3 m. The bedrock surface interpretation has some uncertainties in the deepest part of the sandstone depression. This is due to a thick sediment cover overlying the fractured bedrock surface (cf. Figs. 8 and 9). Therefore, the accuracy of the interpretation may fall to 5–10 m in the deepest part of the depression. Some strong, nearly horizontal reflections are present within the bedrock at −25 to –50 m asl in profile 1 (see lilac dashed lines, Fig. 8b). We interpret these as horizontal diabase laccoliths.
Figure 7 shows a tectonostratigraphic interpretation of seismic profile 2. The reflections are cut by a systematic array of breaks forming a structure corresponding to that seen on the sandstone outcrops nearby in Kiparoja, Eura (Pajunen and Wennerström, Reference Pajunen and Wennerström2010). These breaks (see thin blue lines, Fig. 7) represent brittle faults, fracture zones, and intense jointing. We interpret the continuous and high to moderate amplitude 100–300-m-long convex reflections (see pink lines, Fig. 7) as an open fold structure. Pajunen and Wennerström (Reference Pajunen and Wennerström2010) described similar open folding on the outcrop from the eastern end of Leistilänjärvi, Nakkila. The origin of the fractured area (see brown shaded area, Fig. 7) interrupting the bedrock surface close to the Svecofennian-sandstone border (distance 1000 m, depth ca. −50 m asl) is not known. It could be a collapsed structure similar to that shown in the Vampula mine, where sediments (Pokki, J., personal communication 2018) exist as strongly brecciated fragments in a clayey fault rock (gouge).
Sedimentary fill of the sandstone depression
The sediments overlying the bedrock
A 10–15-m-thick layer occurs above the bedrock surface with seismic tomography velocities of 2000–3000 m/s (distances 0–700 m, 900–1100 m, and 1400–1850 m) in profile 1 (see Fig. 8a) and in profile 2 (distances 350–500 m and 830–930 m) (see Fig. 9a). The layer corresponds with nearly horizontal and slightly inclined strong reflections on top of the interpreted bedrock surface in seismic profiles (see turquoise lines, Figs. 8b and 9b). The stacked arched-shaped reflections interrupt these reflections. The drill hole REF-2017 (at 1050 m) along profile 1 intercepted a 3.8-m bed of bouldery (0.8 m in diameter) diamicton (at a depth of 56.2–60 m) overlying the bedrock on the southwest side of the arched reflections (see Figs. 4 and 8b). A 7.2-m-thick gravel bed overlies a 0.8-m-diameter boulder on top of the diamicton bed. Common seismic velocities for sand and gravel are 400–2300 m/s, 1500–2700 m/s for glacial moraine (Reynolds, Reference Reynolds2011), and ca. 2000 m/s for tills (Malehmir et al., Reference Malehmir, Andersson, Lebedev, Urosevic and Mikhaltsevitch2013a; Salas-Romero et al., Reference Salas-Romero, Malehmir, Snowball, Lougheed and Hellqvist2015). The velocity ranges reported in the literature are overlapping, and thus drill-hole observations are needed for confident interpretation of reflections in addition to tomographic model. In the Köyliö profile 1, the 10–15-m-thick layer seen in the seismic data could be interpreted to contain till and water-saturated gravel based on observations in drill hole REF-2017. The till bed on top of the solid bedrock produces a strong reflection package similar to that observed by previous workers in an esker sediment–filled bedrock fracture zone at the Virttaankangas area (Pugin et al., Reference Pugin, Mäkinen, Ahokangas, Artimo, Vanhala, Pasanen, Moisio, Virtasalo and Tuusjärvi2014b; Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). However, no distinct reflection originated from the bouldery till on the southwest flank in profile 1.
The interpretation of the layers immediately overlying the bedrock and flanking the arched features (see turquoise lines, Figs. 8b and 9b) in the sandstone depression is challenging. The margins of the arched feature are weak on both seismic profiles, and the arched reflections are quite similar in strength compared to the surroundings. The definition of the margins of the arched feature is difficult, leading to uncertainty in the interpretations.
The esker elements (esker core, subaqueous fan lobes, MUKH structures, and distal esker sediments)
The low-velocity sediments (1000–2000 m/s) with slightly undulating horizontal and concave moderate- to high-amplitude reflections (see Figs. 8b and 9b) fill most of the sandstone depression. Their velocities correspond well with the refraction seismic sounding velocities from Koomankangas 5 km north of the study area with velocities of 300–1000 m/s for unsaturated and 1380–1590 m/s for saturated sediments (Lindroos et al., Reference Lindroos, Hyyppä, Stén and Tuittila1983). The ground water table is at ca. 45 m asl (drill hole SPT8) in profile 1 and 47 m asl in profile 2 (drill holes SPT9 and SPT10) (cf. Figs. 8b and 9b). The low-velocity zone of <1000 m/s is mostly above the water table and corresponds with the unsaturated silty to fine sand and sand sediments near the surface. The low-velocity sediments (<2000 m/s) filling most of the sandstone depression are interpreted to represent the glaciofluvial complex.
Some indications of the position of the possible coarse-grained esker core are seen on the 2014 GPR lines 127, 128, 130, and 133 in the Neittamonnummi area, as well as on lines 145, 147, and 148 near seismic profile 1 in the form of arched architecture of the sediments. The top part of the esker ridge has an arched shape with few internal reflections on GPR profile 148 (Fig. 10a). In seismic data, a 30-m-high and 200-m-wide stacked arch-shaped feature with convex reflections (profile 1: −10 to −45 m asl, 1150–1400 m, profile 2: −40 to −70 m asl, 600–850 m) interrupts the interpreted till bed on top of the bedrock (see long orange dashed line, Figs. 8b and 9b). The package is located 500 m southwest of the steep bedrock elevation drop (the new interpretation of sandstone contact position) in profile 1. The stacked feature appears to consist of two arch-shaped parts (see short orange dashed lines, Figs. 8b and 9b). The stacked arched features are interpreted as the esker core based on the convex reflection packages, arched geometry, and dimensions typical to esker cores (100–200 m wide, 20–30 m in height) (Shreve, Reference Shreve1985; Pugin et al., Reference Pugin, Pullan, Hunter and Oldenborger2009; Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). Moreover, the core consists of two parts in the Vampula pit ca. 16 km southeast of the study area (Mäkinen, Reference Mäkinen2003b). The gravel-rich sediments found in the REF-2017 reference drill hole, together with the 2014 GPR profiles 145 and 148 (cf. Fig. 10a), suggest the position of the esker core on the southwest flank of the sandstone depression in profile 1. Seismic profile 2 is slightly diagonal to the esker core, which makes the core appear slightly larger in the profile. The ca. 40–50 m thickness of the esker core is explained by overlapping proximal fan sediments (Mäkinen, Reference Mäkinen2003a). The GPR-based esker core position corresponds well with the interpretation of the esker core position from the seismic data.
A continuous reflection (0 m asl at 950–1170 m) immediately above the till bed occurs only on the southwest of the esker core in profile 1. This reflection corresponds with a 7.2-m-thick gravel layer at 0.7 to −6.5 m asl in REF-2017 (see dark green dashed line, Fig. 8b). This gravel bed is interpreted as representing coarser subaqueous outwash fan sediments on the southwest flank of the sandstone depression. It is plausible that the diamicton bed found on the bottom of the depression of profile 1 was eroded by the meltwater activity related to subaqueous outwash fan sediment deposition. The presence of this gravel layer in profile 2 could not be confirmed due to a lack of reference drilling. On the northeast side of the esker core in profile 1, undulating nearly horizontal reflections (−5 to –45 m asl at 1400–1550 m) end abruptly on the esker core and drape a fault (−60 m asl, 1500 m) (see light green dashed lines, Fig. 8b). In profile 2, medium- to high-amplitude, slightly undulating horizontal reflections are on both sides of the esker core (distance 300–600 m, 0 to −20 m asl and distance 950–1050 m, −20 to −40 m asl) (see light green dashed lines, Fig. 9b). Trough-shaped features truncate the reflections on the northeast side of the esker core in profile 2. We interpret these undulating horizontal reflections as the distal sandy subaqueous esker sediments. The sediments drape the fault symmetrically on profile 1 and do not have any indications of faulting or deformation, ruling out an MUKH structure interpretation. A discontinuous horizontal reflection (20 m asl at 900–1185 m) found near the land surface in the southwest side of profile 1 corresponds with a cobble-rich layer encountered at 17.5–20.5 m asl in REF-2017 (see Fig. 8b). This reflection is interpreted as representing a stronger meltwater flow phase during the deposition of the fan sediments.
Several trough-shaped features 150–300 m in width and 20–30 m in depth are found on top and lateral to the esker core and near the land surface (see yellow dashed lines, Figs. 8b, 9b). These features are similar to overlapping, successive fan lobes described from the Virttaankangas glaciofluvial complex by Artimo and colleagues (Reference Artimo, Saraperä, Puurunen and Mäkinen2010) and Maries and colleagues (Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). We identified them based on the concave-shape of their bottom. Some may have finer-grained beds beneath them (see blue dashed line, Figure 9b). Their fill contains weak and discontinuous reflections on top of the esker core and near the land surface in profiles 1 and 2 (see Figs. 8b, 9b). We interpret trough-shaped features as subaqueous fan channel fills (Miall, Reference Miall1985), which are clear in GPR profiles. They show distinct margins, probably due to the presence of fine-grained (silty to fine sand) material beds at the bottom and on the sides. The interpreted wide and shallow trough-shaped feature (distance 900–1100 m) in profile 2 represents the bottom of the major Ränkimyssuo channel (200–250 m wide, 10–20 m deep) identified in GPR profiles 133 and 135 near profile 2 and in GPR profiles 144, 145, and 148 near profile 1 (see Figs. 3 and 10b). Drill hole SPT11 intercepts the western flank of the channel and consists of fine sand. We cannot confirm the continuation of the channel between seismic profiles 1 and 2 due to the lack of GPR lines across the Ränkimyssuo peat bog (cf. Fig. 3). However, the other GPR lines around the peat bog do not show indications of the channel turning to the southwest-south or northeast.
A major 300-m-wide and 70-m-deep trough-shaped feature in seismic profile 2 (−15 to 20 m asl at 210–580 m) is interpreted as an MUKH (see brown dashed line, Fig. 9b). Previously, this feature was interpreted as a major MUKH (cf. Mäkinen, Reference Mäkinen2003b; Artimo et al., Reference Artimo, Saraperä, Puurunen and Mäkinen2010) that formed due to the burial of an ice block beneath Lake Ilmiinjärvi flanking the esker core (cf. Fig. 3). However, based on the distinct trough-shaped reflections in seismic profile 2, this feature can also be interpreted as one of several channels present in the southwest end of profile 2. It is plausible that an MUKH structure was formed first due to burial of some ice in the sediments, followed by the collapse of the ice support in the southwest flank, leaving room for the channel formation.
DISCUSSION
Geological setting of the sandstone depression
The Satakunta sandstone basin has a gently sloping bedrock surface in the west and a steep and abrupt rise in the bedrock surface in the east (see Figs. 6, 8, 9). The bottom of the sandstone basin was too deep to be revealed by our seismic profiles, which reached depths of −150 m asl (cf. Elo et al., Reference Elo, Kuivamäki, Kurimo, Palmu and Siivonen1993). The revealed brittle structures (brittle faults, fracture zones, and intense jointing) as well as open bending in the sandstone and the Svecofennian basement support the idea of the formation of the sandstone basin by oblique transtension (Pajunen and Wennerström, Reference Pajunen and Wennerström2010). The eastern sandstone contact is steep and has no indication of a stepwise structure described for the sandstone basin margins (Kohonen and Rämö, Reference Kohonen, Rämö, Lehtinen, Nurmi and Rämö2005). A stepwise structure would indicate normal faulting on the basin margins, suggesting a northeast to southwest–oriented extension (rift model) not supported by the observations of Pajunen and Wennerström (Reference Pajunen and Wennerström2010). The dimensions of the Satakunta sandstone depression as well as the position and character of the sandstone contact also deviate from previous research (Palmu et al., Reference Palmu, Mattson and Valli1994). This also means that the esker core does not follow the sandstone contact as suggested by Lindroos and colleagues (Reference Lindroos, Hyyppä, Stén and Tuittila1983).
The low bedrock velocities (3000–4000 m/s) suggest the presence of sandstone and the weathering or fracturing of the Svecofennian bedrock and do not indicate crystalline basement. It is plausible that a substantial amount of the bedrock surface within the Satakunta sandstone depression is broken, supported by the fracturing of mica gneisses and rapakivi granites adjacent to lithological contacts based on a refraction seismic profile north of the study area (Kurimo et al., Reference Kurimo, Elo and Mattson1992). The low bedrock velocities (<4000 m/s) and the multiple bedrock reflections indicate a zone of fractured bedrock at the contact of the rapakivi granite to granodiorite and granite close to the notheast end of profile 1 (cf. Figs. 2 and 8). The horizontal reflection packages within the sandstone represent a laccolith structure related to the intrusion of the diabases into the sandstone. The diabase within the sandstone was also detected in electromagnetic soundings ca. 10 km southwest of our study area (Elo and Pirttijärvi, Reference Elo and Pirttijärvi2010).
The characteristics of the bedrock in the sandstone depression area reflect the development of the sandstone basin until the intrusion of the diabases into the sandstone (1250–1270 Ma) (Pajunen and Wennerström, Reference Pajunen and Wennerström2010). The basin evolution between 1250 Ma and the Holocene is poorly known. The basin's present form is due to erosion that occurred after the intrusion of the diabases and rapakivi granite. The exact roles glaciations and meltwater processes played in the shaping of the sandstone depression are unknown. The sandstone was eroded by the glacier and transported beneath and within the glacier ice. This material was transported toward the subglacial tunnel when its walls were melting (cf. Shreve, Reference Shreve1985) and deposited into the esker forming within the tunnel. This explains the high amount of sandstone clasts present in the Säkylänharju-Virttaankangas esker sediments (Mäkinen, Reference Mäkinen2003a). The rate of this erosion is unclear, as is whether it took place only during deglaciation or during earlier glacial stages/glaciations.
Stratigraphy and depositional stages of the glaciofluvial complex
The Satakunta sandstone depression includes 100-m-thick interlobate esker deposits overlying bedrock. These deposits are sand dominated, and gravels are present mostly in the southwest flank and at the bottom of the depression similar to the gravels on top of the sedimentary bedrock in the Muhos Formation area (Paalijärvi, Reference Paalijärvi2010). Only one drill hole (REF-2017) revealed a till bed above the bedrock. The reflections of the bouldery till and solid sandstone bedrock were blended at 950–1250 m on profile 1 (see Fig. 8b), preventing the interpretation of the till bed on the bottom of the bedrock depression. The boulder-rich till detected in reference drill hole REF-2017 may represent older glacial sediments that were later eroded by glaciofluvial processes (Fig. 11a). The boulder on top of the till bed overlain by sorted material (7.2-m gravel bed) could represent boulder lag. Similar coarse sediments below the esker core occur in the 200–300-m-wide Virttaankangas bedrock fracture zone (Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). However, due to the presence of the beds on top of the bedrock along the bottom of the Köyliö sandstone depression and the low velocities (2000–3000 m/s) close to those observed from broken bedrock or sandstone in the Suupohja area (Pitkäranta, Reference Pitkäranta2013), these reflections may originate from heavily weathered and/or fractured bedrock.
The arch-shaped feature with convex reflections was interpreted as the esker core (cf. Pugin et al., Reference Pugin, Pullan, Hunter and Oldenborger2009; Pugin et al., Reference Pugin, Oldenborger, Cummings, Russell and Sharpe2014a; Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). The esker core does not follow the sandstone contact north of Lake Köyliönjärvi as stated by Lindroos and colleagues (Reference Lindroos, Hyyppä, Stén and Tuittila1983) and Palmu and colleagues (Reference Palmu, Mattson and Valli1994). The hydrostatic regime is more stable along the flank compared to the deepest part of the depression where ice was likely thickest (cf. Shreve, Reference Shreve1972; Shreve, Reference Shreve1985; Syverson et al., Reference Syverson, Gaffield and Mickelson1994). Therefore, the esker core follows the shallower flank of the sandstone depression. Unlike the previous interpretation (Lindroos et al., Reference Lindroos, Hyyppä, Stén and Tuittila1983), there is no indication of the esker core leaning on the sandstone contact and having an asymmetrical form. Rather the esker core retains its arched shape. The uppermost parts of the coarse-grained esker core are at a depth of 50–60 m that is too deep for cost-effective ground water intake.
The esker core was deposited in a subglacial tunnel on the flank of the bedrock depression (see Fig. 11b). As the ice front retreated and the crevasse above the tunnel started to open (see Fig. 11c), the core was covered by a subaqueous outwash fan with abundant filled channels as the meltwater channel started to wander from side to side over the core (cf. Shreve, Reference Shreve1985). The filling of the depression floor with sediments played a role in the location of the channelized meltwater flow. The coarser outwash fan sediments became concentrated on the southwestern flank and the distal sandy outwash fan sediments on the eastern flank of the esker core. Mäkinen (Reference Mäkinen2003a) also describes this for the glaciofluvial deposits along the same interlobate system southeast of Lake Köyliönjärvi. The steep eastern flank of the depression influenced the position of the esker core as well as the direction of the flanking subaqueous fan channels (cf. Rust and Romanelli, Reference Rust, Romanelli, Jopling and McDonald1975). Based on the interpretations of GPR profiles near the land surface and the shape of the western margin of the sandstone depression, the channels indicate paleoflow mostly to the south-southeast deeper in the depression and to the southwest closer to the land surface (cf. Fig. 3). Finally, the orientation and presence of the De Geer moraines support an inference of the widening of the interlobate environment toward the west. However, the paleoflow directions could not be determined for the channels found in the deeper parts of the sandstone depression. The Ränkimyssuo channel shown in both the GPR and HRSR profiles presents a continuous channel feature in the top part of the esker deposits. Its length (3–4 km), dimensions (200–250 m wide, 10–20 m deep), well-developed sedimentary structures observed from the GPR profiles, and position on top of the esker deposits indicate prolonged and steady channelized meltwater flow with aggrading subaqueous fan sediments during the last stages of the deposition of the glaciofluvial complex (see Fig. 11d). The ice-walled re-entrant maintained a relatively axial flow rather than permitting flow expansion toward the flanks of the glaciofluvial complex. This depositional stage could perhaps be compared with the interlobate ice-marginal crevasse deposits on the esker-fan deposits within the Säkylänharju-Virttaankangas glaciofluvial complex that forms a marked ridge on the Svecofennian basement rocks.
Some buried ice blocks within the sediments lateral to the esker core are interpreted to have led to the formation of the MUKH structures (cf. Fig. 11c). The buried ice blocks melted gradually within the sediment, leading to the collapse of overlying glaciofluvial sediments and littorally reworked sediments during the land uplift into the hole created by the melted ice (see Fig. 11d). After the removal of ice support from the southwest and the collapse of sediments, meltwaters diverted along the current Lake Ilmiinjärvi and formed channels. The large and deep MUKH structures present in the upper part of the profiles do not flank the esker core as distinctly in the Köyliö study area as in Virttaankangas (Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). A more detailed interpretation of the MUKH structures is partly inhibited by the weaker reflections present in the upper part of the seismic sections. The fractured and calving margins of the interlobate glaciofluvial bay (cf. Mäkinen, Reference Mäkinen2003b) released abundant ice blocks and bergs into the bay. In addition, local observations have been made of sporadic bouldery till-like sediments near profile 2 and further north on top of the glaciofluvial deposits (Mäkinen and Ahokangas, Reference Mäkinen and Ahokangas2012). This material is ice-rafted debris carried by icebergs, which calved off the floating ice in the Köyliö deep-water area.
Depositional conditions within the sandstone depression
The erosional history of the sandstone basin is poorly constrained before the onset of deglaciation and esker deposition. The thin and few sediment beds preceding esker formation indicate weak glacial erosion either prior to or during the Weichselian glaciation. This is in line with the 100-m-thick pre-Weichselian glacial deposits of the Suupohja region (e.g., Pitkäranta, Reference Pitkäranta2013) 110 km north of Köyliö. The Suupohja region was in the Southern Ostrobothnian interlobate region north of the Baltic Sea ice lobe (Punkari, Reference Punkari1980) where late-stage streamlined ice-flow forms and ice-marginal deposits are lacking. The pre-Late Weichselian sediments were preserved from glacial erosion (Pitkäranta, Reference Pitkäranta2013). The Baltic Sea ice lobe divided into two separate and differently flowing ice lobes in southwest Finland (Punkari, Reference Punkari1980). The eastern sublobe (Loimaa lobe) terminated in shallower water with small supra-aquatic areas in the southeast. The western sublobe terminated in deeper water and flowed faster due to increased calving (Mäkinen, Reference Mäkinen2003b). This velocity difference between the sublobes enhanced the sediment and meltwater delivery into the interlobate area. In addition, the deep sandstone depression in the Köyliö area likely acted as a major storage for the glacial meltwaters as the focusing of (subglacial) meltwater is controlled by the location of bedrock valleys (Rattas, Reference Rattas, Johansson and Sarala2007).
The esker core deposition in the Köyliö area was likely preceded by the erosion of the existing deposits by the increased meltwater activity related to the interlobate glaciofluvial deposition as in the Virttaankangas fracture valley (Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017), where the continuation of deposits beneath the esker core could be more reliably confirmed.
A similar depositional setting occurs in the Muhos Formation (Breilin et al., Reference Breilin, Paalijärvi, Valjus, Huotari and Miettunen2006; Paalijärvi, Reference Paalijärvi2010), which is the only known setting where eskers deposited on sedimentary rocks occur in major bedrock depressions in Finland. Globally, several examples are found of eskers interconnected with incised (sedimentary) bedrock valleys (e.g., Brennand and Shaw, Reference Brennand and Shaw1994; Fisher et al., Reference Fisher, Jol and Boudreau2005; Jørgensen and Sandersen, Reference Jørgensen and Sandersen2006; Kehew and Kozlowski, Reference Kehew, Kozlowski, Johansson and Sarala2007). The Köyliö depositional setting has similarities with the tunnel channel type V described by Kehew and Kozlowski (Reference Kehew, Kozlowski, Johansson and Sarala2007) where an upward-fining gravelly esker sediment sequence is found at the bottom of the tunnel channel. Kehew and Kozlowski (Reference Kehew, Kozlowski, Johansson and Sarala2007) envision the type V tunnel channel to form by subglacial meltwater erosion followed by the long persistence of a subglacial meltwater channel during ice retreat and esker deposition.
The shape of the sandstone depression resembles tunnel valleys, which often have steep and asymmetric sides (Ó Cofaigh, Reference Cofaigh1996). The gently sloping western flank and steep eastern flank of the Köyliö sandstone depression are similar to the narrower Virttaankangas bedrock fracture zone (200–300 m), which also has asymmetric flanks (Maries et al., Reference Maries, Ahokangas, Mäkinen, Pasanen and Malehmir2017). The dimensions of the Köyliö sandstone depression (depth 0.1 km, width 0.9 km, and length 20 km) are also in agreement with the dimensions of known tunnel valleys (Schumm and Shepherd, Reference Schumm and Sheppard1973; Ó Cofaigh, Reference Cofaigh1996; Brennand et al., Reference Brennand, Russell, Sharpe and Knight2006; Gibling, Reference Gibling2006; Kristensen et al., Reference Kristensen, Plotrowski, Huuse and Clausen2007; Pugin et al., Reference Pugin, Oldenborger, Cummings, Russell and Sharpe2014a). Tunnel valleys typically show undulating or convex-up longitudinal profiles (Rattas, Reference Rattas, Johansson and Sarala2007), but this was not observed in the Köyliö study area or further north (Palmu et al., Reference Palmu, Mattson and Valli1994). The bedrock characteristics are interpreted as having influenced the asymmetric profile of the sandstone depression: sandstone in the west was more prone to glacial erosion (cf. Kaitanen and Ström, Reference Kaitanen and Ström1978), while the basement rocks in the east were more resistant.
The tunnel valleys in Denmark formed during a few hundred years by multiple glacial meltwater outbursts related to several ice-marginal positions (Sandersen et al., Reference Sandersen, Jørgensen, Larsen, Westergaard and Auken2009). The Köyliö study area has De Geer moraines and subaqueous fans as indications of ice-marginal positions, and the role of meltwater activity in influencing the morphology of the sandstone depression is plausible as the sandstone is easily erodible (cf. Kaitanen and Ström, Reference Kaitanen and Ström1978). Glacial erosion and the role of meltwater are possible mechanisms in tunnel valley formation (Brennand et al., Reference Brennand, Russell, Sharpe and Knight2006; Ó Cofaigh, Reference Cofaigh1996). The Köyliö sandstone depression ends shortly before the Kuivalahti-Säkylä tributary esker joining the extensive Säkylänharju-Virttaankangas interlobate glaciofluvial complex. The sandstone depression is also crosscut by another west-northwest to east-southeast–oriented major fracture zone south of Lake Köyliönjärvi (Palmu et al., Reference Palmu, Mattson and Valli1994). This fracture zone runs along the northern flank of the Säkylänharju-Virttaankangas glaciofluvial complex. The Köyliö sandstone depression and the adjacent crosscutting fracture zone acted as a major meltwater channel feeding substantial amounts of meltwater (cf. Lindroos, Reference Lindroos1975) and sediment into the Säkylänharju-Virttaankangas interlobate glaciofluvial complex. The 20–30- m beds of sorted sediments (gravels overlain by silty sands) beneath the esker core in the northwest part of Säkylänharju represent preexisting deposits partly incised by subglacial tunnel flow during the last phase of deglaciation (Mäkinen, Reference Mäkinen2003a). These beds may represent the eroded tunnel valley sediments deposited into the major fracture zone by the meltwater flows.
The tunnel valley origin of the sandstone depression cannot be confirmed with the existing evidence. The roles of the glacial erosion and meltwaters in shaping the sandstone depression morphology are acknowledged and should be investigated further, as implied by thick sorted sediments below the esker core in the southeast end of the sandstone basin (Mäkinen, Reference Mäkinen2003a).
CONCLUSIONS
The landstreamer-based high-resolution (2–4 m receiver and shot spacing) reflection and refraction seismic survey revealed the characteristics and stratigraphy of a bedrock depression infilled with interlobate glaciofluvial complex sediments in Köyliö, southwest Finland. The sandstone depression represents a geological setting with varying bedrock lithology and topography combined with the infilling interlobate glaciofluvial sediments of the Pori-Koski esker. For the first time, brittle structures (brittle faults, fracture zones, and intense joining) and open bending in the sandstone and the Svecofennian basement were revealed, supporting the formation of the sandstone basin by oblique transtension. In addition, we confirm the presence of a diabase laccolith within the sandstone, the steep nature of the sandstone contact, and a new interpreted position of the contact.
We defined the exact position of the esker core within the deep sandstone depression for the first time in detail. The position of the hydraulically conductive esker core was confirmed to be west of the sandstone contact, not to follow the contact, and to have an asymmetric form; this contrasts with the previous research. The sedimentary fill in the Köyliö area indicates development of repeated subaqueous fans above the esker core similar to those interpreted for the Säkylänharju-Virttaankangas interlobate glaciofluvial complex within the same glaciofluvial system but in a more bedrock-confined setting in deeper proglacial water. The study has defined the depth of the uppermost parts of the esker core (50–60 m), which permits improved assessment of the economic viability of ground water extraction from the esker core.
The glacial erosion of the sandstone is supported by the high amount of sandstone clasts in the Säkylänharju-Virttaankangas esker further southeast. The interlobate position, combined with a major bedrock depression, enhanced the collection of meltwaters into the depression and into the fracture system south of it. The depression acted as a major meltwater pathway contributing to the large size of the Köyliö and the Säkylänharju-Virttaankangas glaciofluvial complexes. The dimensions of the sandstone depression agree with known tunnel valleys, but we cannot confirm the tunnel valley origin of the depression. The roles of glacial erosion and meltwater in forming the morphology of the sandstone depression are acknowledged and should be investigated further. Our results confirm the suitability of the landstreamer-based HRSR survey for the research of thick glaciofluvial deposits and the underlying bedrock in the geological conditions of Finland.
ACKNOWLEDGMENTS
The authors acknowledge funding through the Trust 2.2 GeoInfra project (http://www.trust-geoinfra.se) and Formas project (252-2012-1907) under which the seismic landstreamer was developed. We thank reviewers Don Cummings and Robert Storrar for the constructive comments that improved the manuscript. Turku Region Water Ltd, Geological Survey of Finland (GTK), and University of Turku/Department of Geography and Geology sponsored the data acquisition and collaborated in this project. Elina Ahokangas was funded by the Finnish Cultural Foundation Satakunta Fund and the Doctoral Programme in Biology, Geography and Geology (University of Turku Graduate School). Graduate students from Uppsala University participated in the fieldwork, for which the authors are grateful. We thank A. Tryggvason (Uppsala University) for providing the PStomo_eq available for use for travel time tomography. GLOBE Claritas™ under license from the Institute of Geological and Nuclear Sciences Limited, Lower Hutt, New Zealand, was used to process the seismic data.