ABSTRACT

The northwestern Greenland margin contains several underexplored sedimentary basins formed by Cretaceous rifting and Cenozoic postrift sedimentation. The basins are thought to contain significant hydrocarbon reserves, although no exploration wells have been drilled to date. This paper reports the discovery of a gas-charged submarine landslide mass transport deposit (MTD) covering 420 km2 (162 mi2) above the Melville Bay ridge (MBR) rift structure. The sedimentary succession that deformed into the MTD was likely deposited within a shallow-marine spit complex developed along the ridge axis extension during the Eocene. The MTD displays landslide characteristics with distinct blocks up to 1 km (3281 ft) wide and 80 m (262 ft) thick that geometrically fit together like a jigsaw puzzle. Clear direct hydrocarbon indicators and velocity estimations suggest the mass transport blocks are composed of highly porous, gas-charged sands intercalated with shale layers and overlain by postslide pelagic mudstones. The reconstruction of all 499 MTD blocks suggests emplacement by bidirectional sliding, triggered by rejuvenation and a southward tilt of the MBR. Sliding most likely occurred slowly along a low-angle decollement surface, with the blocks remaining intact despite not being confined within a typical slide mass. Instead, coherency was likely aided by lithological layering and diagenesis. Gravitational shedding of the steep block margins has created interblock sand accumulations, which may enhance connectivity.

This study provides an important analog for significant reservoir occurrence in large MTD blocks and provides constraints on the basin development and petroleum prospectivity of northeast Baffin Bay.

INTRODUCTION

Sediments deposited by gravitational and mass-wasting processes are commonplace in deep-water settings (Prior et al., 1984; Hampton et al., 1996; Butler and Turner, 2010). These processes can create seismic-scale deposits consisting of chaotic facies that can commonly host rotated and translated slide blocks within the matrix of the flow. These blocks commonly consist of meter- to kilometer-scale packages of undeformed strata that have remained coherent and intact throughout the sliding process (Huvenne et al., 2002; Weimer and Shipp, 2004; Jackson, 2011; Alves, 2015). In the rock record, these deposits are referred to as mass transport complexes or mass transport deposits (MTDs) (Weimer and Shipp, 2004).

On the northwestern Greenland shelf, a well-preserved MTD covering 420 km2 (162 mi2) above the Melville Bay ridge (MBR) rift structure has been interpreted using three-dimensional (3-D) seismic data. The main objectives of this paper are to document the occurrence, architecture, and lithology of enigmatic, jigsawlike blocks within this potentially gas-charged MTD, while also unraveling the complex depositional and deformational history that led to its emplacement. The paper concludes by assessing reservoir connectivity and the potential for exploration and development.

The discovery of this MTD reservoir was achieved because of renewed exploration interest in the Arctic caused in part by increasing oil prices from 2002 to 2008 and a prediction that the Arctic contains some 30% and 13% of the world’s undiscovered gas and oil, respectively (Gautier et al., 2009). A significant proportion of this interest was focused offshore West Greenland because of its favorable fiscal terms and unexplored, thick sedimentary rift sequences (Henriksen et al., 2009). This interest prompted hydrocarbon exploration license rounds from 2007 to 2008 and 2010, when five licenses were awarded in northeast Baffin Bay alone (Figure 1). This led to the acquisition of extensive two-dimensional (2-D) seismic data sets that cover much of the wider Baffin Bay area, offshore northwestern Greenland.

Pitu, one of the five awarded blocks within Melville Bay, contains a 3-D seismic survey covering an area of 1672 km2 (646 mi2) over part of the MBR and the western flank of the Melville Bay graben (MBG) (Figure 1). The nearest well calibration is more than 300 km (>186.5 mi) to the south and is used to provide a chronostratigraphic framework for the shallow stratigraphy where key horizons can be tied southward above large areas of volcanic deposits to Ocean Drilling Program (ODP) site 645 (Figure 1) (Knutz et al., 2015; Gregersen et al., 2016). Approximate constraints on the likely ages of older stratigraphy are inferred from their stratigraphic relationship to tied mega-unit boundaries, an understanding of the regional geology (Gregersen et al., 2013) and data from seabed sampling (Gregersen et al., 2016) (which was not available for use in this study).

GEOLOGICAL AND TECTONIC SETTING

The initial onset of rifting between Greenland and Canada began in the Late Jurassic, evidenced by volcanism and intruded dykes to the south of the Pitu (Umpleby, 1979; Larsen et al., 2009). This was triggered by northward propagation of North Atlantic spreading into the Arctic basins, leading to the creation of oceanic crust in central Baffin Bay during the Paleocene and Eocene (Oakey and Chalmers, 2012; Gregersen et al., 2013). Rifting was focused during the Cretaceous and created a series of northwest-southeast–trending sedimentary basins, separated by elongate structural ridgelike highs (Whittaker et al., 1997) (Figures 1, 2).

These basins and extensive ridges dominated the topography of the Melville Bay area throughout the Paleogene and into the Neogene. The largest of these basins is the 35–90-km (22–56-mi)-wide MBG that is bounded to the east by the Melville Bay Fault (which shows a maximum heave of >30 km [>18.6 mi]) and is separated from the Kap York Basin to the north and the Kivioq Basin to the west by the MBR (Whittaker et al., 1997) (Figure 1). The MBR developed as an elongated synrift tilted fault block that has subsequently experienced postrift reactivation (Gregersen et al., 2013) (Figure 1). This ridge likely existed as a small emergent island extending from the Greenland mainland to the north during much of the Paleogene and Neogene (Figure 2). This would have partially separated the deeper waters of the MBG from the rest of Baffin Bay to the west, creating an embayment (Gregersen et al., 2013, 2016).

The restricted basin was infilled by Cretaceous–Paleogene sedimentary successions that contain mainly marine mudstones with interfingering coarse sands sourced from both the Greenland craton to the east and the uplifted MBR to the west (Gregersen et al., 2013). These successions can reach thicknesses up to approximately 13 km (∼8 mi) and include likely source-rock deposition during the Late Cretaceous (Cenomanian–Turonian) (Whittaker et al., 1997; Bojesen-Koefoed et al., 1999; Planke et al., 2009; Gregersen et al., 2013) (Figure 2). Accommodation upon the MBR was preserved during periods of uplift quiescence, allowing sediments to accumulate and create a thick (<80 m [<262 ft]) package of prograding sands, which constitute the potential reservoir studied here (Oakey and Chalmers, 2012; Gregersen et al., 2013, 2016).

Major extension and sea-floor spreading ceased during the late Eocene–Oligocene (Oakey and Chalmers, 2012; Welford et al., 2018), with thermal subsidence driving the drowning of the emerged MBR and causing the transgression of clastic systems within Melville Bay as well as a widespread transition into a deep-marine environment (Figure 2) (Whittaker et al., 1997; Gregersen et al., 2013). The margin subsequently underwent several episodes of uplift and exhumation (up to 2 km [1.2 mi] over three time phases: 36–30 Ma, 11–10 Ma, and 7–2 Ma), evidenced by apatite fission-track modeling, vitrinite reflectance analysis, and seismic studies (Oakey, 2005; Japsen et al., 2006; Knutz et al., 2015) (Figure 2). This led to the creation of significant inversion structures as well as the reactivation of several structural ridges within eastern Baffin Bay, including the MBR (Gregersen et al., 2013). The remnant rift topography of the MBR, along with continued phases of uplift during the late Paleogene and Neogene has caused sediment packages to thin over the high and for the deposition to be concentrated within the deeper basin, leading to the wedgelike geometry of postrift packages (Figure 3) (Whittaker et al., 1997; Japsen et al., 2006; Gregersen et al., 2013, 2016). This effect is increased by sand input from the Greenland craton to the east, depositing within the deeper basin before reaching the MBR slope (Knutz et al., 2012, 2015; Gregersen et al., 2013, 2016).

The late Pliocene and Pleistocene cycles of glacial advance and retreat of the Greenland Ice Sheet have caused the adjacent northwestern Greenland continental shelf to be extensively reworked (Aksu and Piper, 1987). This is evidenced by several erosional surfaces and several significant glacial sedimentary wedges overlying much of the deeper rift sequence within Baffin Bay (Knutz et al., 2015, 2019; Newton et al., 2017) (Figure 3).

The differentiation between basin and ridge rift structures and the thick sedimentary succession within the MBG is clearly evident on seismic data across the Pitu license block (Figure 3). The 2-D and 3-D seismic data used within this study have been interpreted, resulting in nine seismic stratigraphic (mega-unit) horizons that define the sedimentary infill of the basin (Figures 2, 3). These regional interpretations follow the work completed by Gregersen et al. (2013, 2016, 2019). This work defines the main rift-related sediments within the MBG as mega-units G–D1, which are overlain by postrift infill as well as glaciogenic sediments (mega-units C–A). The reservoir that this study focuses on exists within the base of mega-unit D2 (Figures 2, 3). These sediments are underlain by early rift sediments that thin onto the high and are overlaid by polygonally faulted infill muds of mega-unit D1 (Figure 3).

DATA AND METHODS

The main data set used within this study consisted of a 3-D seismic reflection survey that was acquired by Cairn Energy, PLC, in 2011 that consists of 93 3-D acquisition lines using a bin size of 25 × 12.5 m (82 × 41 ft) and 1-km (0.62-mi) separation between sail lines (Figure 1). The shotpoint interval used was 25 m (82 ft) (flip-flop) with a source separation of 50 m (164 ft), leading to a common midpoint fold of 70 m (230 ft). The total survey area is 1672 km2 (646 mi2) with 12.6% data infill and is provided in two-way time (TWT) down to 6.5 s. Processing steps included signal noise attenuation and corrections and velocity analysis using Kirchhoff prestack time migration (PSTM). The frequency ranges between 5 and 75 Hz, with a dominant frequency within the target interval of 28 Hz producing a dominant wavelength of 71 m (233 ft) (using an average velocity of 2.0 km/s [6562 ft/s]) and a vertical resolution of 18 m (59 ft). Prestack depth migration was completed using a Kirchhoff algorithm down to 10,000 m (32,808 ft).

The survey was reprocessed in 2013, which included a more detailed poststack depth migration study using a Kirchhoff algorithm and attempted to remove several unwanted features such as a residual bubble oscillation, strong seabed multiples, and wave diffractions caused by glacial seabed scours. A subset high-resolution 3-D seismic survey in TWT was also produced that covers an area of 1135.5 km2 (438 mi2) down to 5 s, with a frequency range of 5–150 Hz and a dominant frequency across the target interval of 45 Hz producing a dominant wavelength of 44 m (144 ft) (using an average velocity of 2.0 km/s [6562 ft/s]) and an increased vertical resolution of 11 m (36 ft). The spatial resolution was also increased to 12.5 m (inline) × 6.25 m (crossline) (41 × 20.5 ft) (Figure 1).

The data used in this study also include four regional 2-D seismic reflection lines (Figure 1) that form part of the Baffin Bay 2-D regional seismic survey data set (BBRE11), provided by TGS, that was acquired between 2007 and 2009, covering 5226.5 km (3248 mi) across Melville Bay. This survey was acquired using a 2000 psi source with a 25-m (82-ft) interval and 8-m (26-ft) gun depth. Data were recorded by a single 6000-m (19,685-ft) streamer with 480 channels spaced at 12.5-m (41-ft) intervals, using a sample interval of 2 ms. The survey was reprocessed in 2011, which involved bubble-pulse attenuation, diffraction multiple attenuation, low-frequency enhancement, and Kirchhoff PSTM.

All seismic data were provided in Society of Exploration Geophysicists normal polarity, with positive peaks (red) representing a downward increase in acoustic impedance and negative troughs (blue) representing a downward decrease in acoustic impedance (Figure 3C).

Converting the TWT thickness of blocks interpreted within the high-resolution seismic survey to depth was completed using an estimated average interval velocity of 1.69 km/s (5545 ft/s), which was calculated from the velocity pushdown effect observed beneath the reservoir blocks in seismic data (see the Seismic Observations section). This method was used instead of directly measuring the thicknesses on the depth-converted seismic survey. This was because of the increased vertical resolution within the high-resolution survey allowing more accurate imaging and interpretation of the blocks, leading to a more accurate thickness estimate. Seismic observations and interpretations were made within Schlumberger’s Petrel software using industry-standard seismic interpretation techniques (Posamentier, 2004; Posamentier et al., 2007). Spectral decomposition was completed and interpreted using Geoteric, which allowed for noise cancellation, seismic frequency selection, and color blend cube creation (Castagna and Sun, 2006). Surface extractions were then taken from color blend cubes for interpretation (Wright et al., 2018).

The landslide reconstruction process was carried out in ArcMap, in which the blocks were iteratively returned to their likely source location by comparing the following.

  1. Geometrical fit: Because of block coherency, the shape and structure of the reservoir blocks in map view remains visible and allows for a geometrical reconstruction, much like jigsaw pieces, in which the pieces are slid back together. This process considered mass wasting and erosion at the block edges, giving a slightly blurry fit, and block translation and rotation.

  2. Block thickness: Blocks that were once connected laterally adjacent to each other would likely be of similar thickness. Thickness trends across multiple blocks were used to constrain the reconstruction.

  3. Internal reflections: Matching internal reflections from seismic profiles showed continuous depositional style and constituents across originally adjacent blocks.

  4. Dip and azimuth of decollement surface: Because the uplift of the MBR is the most likely trigger of slide movement, the decollement surface structure was used as a guide to the possible flow paths and the direction of sliding along which the blocks can be repositioned in their original location.

The process only considered reservoir blocks that were thicker than 30 ms (∼25 m [∼82 ft]) in thickness. This allowed for a clear definition between reservoir blocks and interblock areas and defined a total of 499 individual blocks for use in the reconstruction. The assumption was made that the large main reservoir block existing on the MBR platform remains in its original location of deposition, allowing for the remaining blocks to be reconstructed back to this center. The preslide location for each of the reservoir blocks was decided using the four guiding characteristics of either the blocks themselves or the underlying decollement surface outlined above. If the four considerations matched, then the blocks were moved into laterally adjacent positions. Each block was restored separately, according to the guiding characteristics, but the final fit of each block depended on the fit of previously reconstructed blocks.

The most likely direction of block sliding (flow line) was determined by comparing the pre- and postslide location and orientation of individual blocks. Additionally, this process considered the pathway for all surrounding blocks, as deformational trends likely occurred across multiple block sections, with the crossing of individual slide paths being unlikely. This allowed an iterative assessment of block flow lines working outward from the main reservoir block, creating trends that agreed across multiple blocks as well as connecting individual pre- and postslide block locations. Direct evidence of flow direction, such as erosional structures on the decollement surface, is not observed. This is possibly either because of a lack of beneath-block erosion occurring during sliding or existing features not being imaged within the seismic data. This may be because of limited vertical seismic resolution or beneath-block velocity pushdown significantly affecting the imaging and structure of the decollement surface.

SEISMIC OBSERVATIONS

A package of bright amplitudes and potential direct hydrocarbon indicators (DHIs) that exist on the crest and eastern flank of the MBR have been investigated using the Pitu high-resolution 3-D seismic survey. This package exists at the base of mega-unit D2, which consists of Paleogene sediments (Gregersen et al., 2013), with the top D1 horizon having been interpreted as middle Miocene via a long-distance tie to ODP site 645 (Knutz et al., 2012, 2015) (Figure 3). The package is likely Eocene in age because of the correlation of the base package horizon (top mega-unit E) into Eocene volcanics to the south of Melville Bay (Gregersen et al., 2013).

Mass Transport Deposit Characteristics

Seismic interpretation of the uppermost soft reflection revealed that this was associated with an extensive deposit that covers an area of 420 km2 (162 mi2) (Figure 4). The strong negative amplitudes are observed across much of the crest and eastern flank of the MBR, with the highest negative amplitudes existing on the platformlike section of the MBR in the north. The response is observed to extend southeast along the strike of the MBR but becomes less continuous to the south and east (Figure 5). Bright amplitudes are, however, observed to the south of 3-D seismic coverage on 2-D regional line B (Figure 1) on the boundary of the Pitu and Tooq license blocks. This may suggest the package extends beyond the southern limit of the 3-D survey.

The discontinuous soft response indicates that the package of reflections has broken up into several angular blocks that become smaller and further spaced apart to the south and east (Figure 4B) before becoming no longer observed further downslope (having likely disintegrated) (Figure 5). The angular blocks range in sizes up to 1 km (3281 ft) wide and 80 m (262 ft) thick (maximum TWT of 95 ms at 1.69 km/s [1.05 mi/s]), with block thickness increasing toward the northwest (Figure 5). The entire deposit sits on a single decollement surface (Figure 4) that is consistent with the elongated dome structure created by the uplifted MBR. The deposit is observed to still be intact (with a continuous soft reflection) across much of the platformlike section of this decollement above the MBR to the north (Figures 4A, 5). However, away from the central axis of the MBR where the decollement dip increases, the blocks show evidence of movement, with dominant sliding directions to the south in the dip direction along strike of the MBR and also to the east toward the deeper graben (Figure 5).

On the western flank of the MBR, some extensive elongate ridgelike blocks have dislodged from the headscarp but have not disintegrated into smaller isolated blocks such as observed on the eastern flank (Figure 5). The high-amplitude response is not observed further down the steeply dipping western slope or on regional 2-D seismic lines that extend beyond the 3-D seismic survey limits to the west.

Direct Hydrocarbon Indicators

The seismic expression of the blocks shows clear DHIs with bright soft and hard events at the top and base of the package, respectively, with internal architectures that range from multiple continuous layers of varying acoustic impedance to more homogenous blocks with dim discontinuous internal reflections (Figure 4). The deposit appears to have slid along a single decollement surface that displays as a positive amplitude response with reflection amplitudes increasing beneath the blocks. The approximately plane-parallel decollement surface also shows variable TWT between areas beneath and adjacent to the blocks. This is most likely caused by velocity pushdown because of anomalous fluids such as gas or oil within the package (Figure 4).

The velocity pushdown effect observed beneath the blocks has been used to estimate the primary wave velocity within the package in an attempt to understand its potential lithology and fluid content and to specifically test whether the DHIs observed could be caused by porous, gas-bearing sands. This estimation uses the difference in TWT depth of the decollement surface in areas beneath and adjacent to the blocks (in areas in which the DHI response is not observed) (Figure 6). In reality, the decollement surface is continuous in depth between the two areas, but slower velocities within the package are causing the apparent shift and are likely created by either a different lithology or pore fluid compared to the surrounding overburden (Figure 6B, C). The extent of the velocity reduction will provide evidence to what lithology and pore fluid the package may consist of.

A typical reservoir block was selected for this calculation and is shown in Figure 6. The TWT value from the top of the package to the decollement surface adjacent to the block (without the pushdown) (TWTnorm) is used to calculate the block height (H) (equation 1). This assumes an average velocity for the overburden sediments (Voverburden) of 2.0 km/s (6562 ft/s). This gives a block height of 70 m (230 ft). The average velocity for within the block was then calculated using this block height along with the TWT value for the block and the pushdown (TWTslow), measured from the top reflection to the decollement surface beneath the block (equation 2). This gives an estimated average velocity through the block (Vblock) of 1.69 km/s (5545 ft/s), with this value being used for block thickness conversions from the TWT to depth. Additionally, if the overburden velocity is assumed at 2.2 km/s (7218 ft/s) instead, the block velocity is then estimated at 1.85 km/s (6070 ft/s). 
formula
 
formula
This estimation, however, only considers the block to consist of 100% sand, at which point it is far more likely to contain several muddy layers, as evidenced by internal seismic reflections (Figures 4, 6). Considering the amount of internal layers within the typical block, it is estimated that mud could comprise up to one-third of the total block thickness (Figure 6). Therefore, the mud must be considered in the velocity estimation because these low porosity layers will retain the overburden velocity (2.0 km/s [6562 ft/s]) and not create the velocity pushdown observed. The slower velocities causing the pushdown effect will likely be confined to the higher-porosity sand layers within the block. 
formula
The estimation of Vsand (equation 3) only considers the two-thirds of the block height that is sand and removes the TWT of the mud layer (0.33 TWTnorm) from TWTslow. This gives an estimated velocity for the sand layers within the package of 1.56 km/s (5118 ft/s), which is significantly lower than that of typical sandstones with 30%–40% porosity at this depth (commonly 2–2.5 km/s [6562–8202 ft/s]) (Rider and Kennedy, 2011). This velocity reduction is, therefore, most likely caused by the pore fluid within the sands and suggests that the package consists of gas-charged highly porous sands.

A spectral decomposition color blend of 10 (red), 20 (green), and 50 Hz (blue) (equivalent to a tuning thicknesses of 42, 21, and 8.5 m [138, 69, and 28 ft] at 1.69 km/s [5545 ft/s]) was created using the high-resolution 3-D seismic survey. An extraction along the top reservoir horizon clearly depicts a dominant bright white frequency response over much of the reservoir area (Figure 5). This represents high saturations from all three blended frequencies and is a response typical for a relatively shallow (550 ms [550 m {1804 ft}] using an average velocity of 2.0 km/s [6562 ft/s]) below the seabed) gas sand reservoir (Wright et al., 2018). Other areas of the reservoir and surrounding decollement surface show dominance toward the low-frequency (red) response. The image also highlights the breakup of the deposit into a large number of separated blocks, with the thickest and most laterally extensive reservoir sections existing on the MBR platform in the north and the increased breakup and movement of smaller blocks mainly to the south and east (Figure 5A). The reservoir is shown to thicken in two areas within the deposit, with reservoir thickness up to 80 m (262 ft) (Figure 5B).

Spectral decomposition also highlights the same bright, multiple-frequency response seen for the reservoir blocks within certain interblock areas surrounding the large separated blocks south of the main reservoir section (Figure 5A). This signature was also noted in the seismic extraction on the top reservoir surface and in the seismic cross section where interblock areas show similar soft and hard kicks to that of the main reservoir blocks (Figure 6). The seismic sections show that the separated reservoir blocks narrow upward as well as the hummocky and erosive nature of the top reservoir reflections. The cross section shows that the high-amplitude response from the interblock area is absent in places. This can also be observed in Figure 5A in which dark areas between the interblock bright responses represent areas of absence. This absence of response is more prevalent deeper into the graben on the eastern flank and between the smaller blocks within the far southeastern section.

Deformation

The spectral decomposition image (Figure 5) also highlights a series of east-west elongate and/or oblong features on the top reservoir surface that vary in frequency response and terminate at a similar depth on the slope (∼−1600 ms) (Figure 7A) at their western edge. To the east of this termination, no bright-amplitude reservoir blocks are observed. Seismic amplitude extractions across these features display a dim, negative amplitude response (Figure 7A). The onset of these features updip commonly occurs at the location of ridge-parallel extensional faults, with the feature existing on the downthrown, slightly steeper part of the slope (Figure 7). Similarly, the features commonly terminate downslope at fault locations. Within each of the features exists numerous linear, low-amplitude zones that are perpendicular to their east-west orientation (Figure 7B). These zones represent the location of small extensional faults (Figure 7B, C). In the east, and downslope of the termination of these features, several deep, valleylike erosional depressions that trend basinward are observed on the decollement surface. High positive (hard kick) seismic amplitude responses are observed to be confined within these depressions that extend downslope and likely beyond the eastern edge of the seismic survey (Figure 7E).

All of the reservoir features observed sit on a single decollement surface (Figure 4). To ascertain controls on the slide block distribution, the present-day dip of the decollement has been estimated (Figure 8). Because subsequent deformation has augmented the paleotopography, the present-day angles are likely much greater than the original decollement dip at the time of slide emplacement. The dip of the decollement increases away from the MBR axis with a flatter, platformlike area on top of the ridge and along strike (Figure 8). The majority of the reservoir blocks exist within the green low dip areas (0°–2°), with blocks becoming increasingly broken up into areas of increasing dip (1°–4°) and completely absent in areas of high dip (≥4°) shown in Figure 8. The variations in reservoir signature across areas of increasing dip are commonly separated by linear areas of high dip (≥4°) that represent fault locations (Figures 7D, 8). Blocks are commonly observed adjacent to these features updip but are not observed in the downdip section (Figures 7D, 8).

The dip of the decollement also highlights a hinge point on top of the ridge where spreading occurred radially from this high point. This coincides with the onset of block separation and sliding to the south away from the main reservoir block in the north. The higher-average slope angles shown by transects D-A (1.6°), D-C (3.3°), and D-D (2.6°) (Figure 8A), highlight areas in which the slope angle dramatically increases away from the ridge hinge point, coinciding with shorter sliding vectors and a lack of observed reservoir blocks. Transect D-B, along strike of the MBR, shows the most gradual dip, with an average dip angle of 0.4°. In this direction, the majority of reservoir blocks are still observed intact, having slid further distances downslope (Figure 8).

Controls on Fault Development

Reservoir blocks are flanked at their edges by normal faults that extend subvertically through the overburden and into the base of mega-unit D1 (Figure 9A). Mega-unit D1 is characterized by numerous small horst and graben packages of discontinuous horizons that are offset and separated by thin, linear, subvertical low-amplitude zones (Figures 3, 9A). Coherency and variance attribute time slices from within mega-unit D1 (Figure 9B) show how these zones commonly connect to create networks, a typical characteristic of polygonal faults (Cartwright et al., 2003). These faults are mostly layer bound within the deep-water muds of mega-unit D1 but show occasional fault extensions into mega-unit C and can reach close to the seabed. Many of these polygonal faults are shown to nucleate at the vertical extent of the block, bounding normal faults with the orientation of extension commonly following the directional trend set out by the underlying faults and block-edge orientations (Figure 9A, C). Additionally, a small number of the block-edge normal faults seem to extend directly through mega-units D1 and C and are likely tectonic faults rather than polygonal. These faults show larger degrees of offset with a continuous orientation of extension that is still determined by the location of the block edge.

LANDSLIDE RECONSTRUCTION

The reconstruction of the 499 landslide blocks to their preslide configuration was facilitated by the high quality of imaging in the high-resolution 3-D survey used and the unique dispersal pattern and angular edges of the reservoir slide blocks. The reconstruction aids the understanding of the triggers and mechanisms of sliding as well as the uplift history of the MBR.

The comparison maps (Figure 10) show the reconstructed location of the blocks that remain within the study area, along with large sections of exposed decollement, which likely represent areas in which once-deposited reservoir has now been shed from the high. This implies the significant transport of sandy sediments into the deeper parts of the basin in which data quality, acoustic characteristics, and data availability do not allow mapping of the equivalent deposit. Thickness trends and internal reflections across multiple blocks, along with interconnecting block shapes, indicate that the reservoir was deposited along the MBR and adjacent to the large undeformed section of the reservoir in the north (see the Data and Methods section). The blocks show a general trend of having been deposited close to the central axis of the northwest-southeast–trending MBR. The reconstructed reservoir map in Figure 10B is color coded by distance traveled caused by sliding. This highlights an increased distance of sliding in the southern section of the reservoir, along the strike of the MBR in the least dipping direction of the decollement surface (Figures 8, 10).

The maximum distance of block sliding was shown to be 11,825 m (38,795 ft) with an average slide distance of 3500 m (11,483 ft) (Figure 11). The dominance of the 0–500-m (0–1640-ft) travel distance (78 blocks) is caused by small blocks that closely surround the large central reservoir block and are still within the flatter, platformlike area of the MBR. This causes the average travel distance to be reduced. Additional observations include two data spikes that are observed at 2000–2500-m (6562–8202-ft) and 6500–7000-m (21,325–22,965-ft) ranges. All of the blocks that traveled a distance over 10,000 m (>32,808 ft) are observed within the southernmost section of the reservoir, which may be because of a gentler slope gradient in this direction (axis of MBR) (causing the blocks not to disaggregate) (Figure 8) but could also, to some extent, be biased by the distribution of the available data set. It is possible that blocks exist outside of the data set, but is more likely that any blocks transported beyond the survey edge will have disintegrated because of an increased slope gradient (Figure 8) away from the MBR central axis and been redeposited as gravity flows in the deeper basin, as seen on the eastern flank (Figure 7).

Further analysis of the reconstruction over an area on the eastern flank depicts the flow directions for each of the reconstructed blocks (Figure 12). This process highlights two trends of motion. First, the areas of the reservoir directly above the MBR trend toward the southeast along strike of the dipping ridge. The blocks then move in a secondary trend as they reach the eastern edge of a narrowing MBR and slide eastward and down into the deeper MBG. It is unknown whether sliding in the two directions was separated by a period of no movement or a smooth continuation.

Within the southern section of the main reservoir block, two large areas do not show frequency or DHI responses and most likely do not contain reservoir (Figures 5, 10, 13). This is also suggested by an opposite amplitude response (hard event) across these sections compared to that of the reservoir blocks and by the absence of the velocity pushdown effect likely created by gas in the reservoir. The two sections are underlain by localized high areas that suggest increased elevation and perhaps nondeposition on the decollement surface during original reservoir deposition. The location of these high areas coincides with the crests of tilted fault blocks that exist beneath the MBR and consist of prerift stratigraphy (mega-unit H) (Figure 3) (Gregersen et al., 2013). The surrounding internal reflections within the reservoir are shown to thin and onlap onto the flanks of the localized highs (Figure 13).

Comparison of the two adjacent nonreservoir areas shows a differing relationship with the elongated reservoir block to the west (Figure 13). Within the southern section, the block looks to have slid away from the flank of the high, whereas the northern section of the elongated block is still directly adjacent to the high. This suggests that the whole block has not simply slid westward but has rotated clockwise by approximately 23°. Blocks are also shown to only exist above areas where the decollement is relatively flat, with no further blocks observed on the steeply dipping western flank of the MBR beyond the elongated reservoir blocks (Figure 13).

Internal Stratigraphy of Landslide Blocks

Completing the geometric landslide reconstruction process allows the presliding seismic characteristics of the reservoir to be assessed. This assessment removes the interblock areas along a seismic cross section (extracted along an MTD slide vector), juxtaposing the sections of the blocks, which were once laterally adjacent (Figure 14). This provides a view of the original depositional structure of the reservoir presliding, highlighting continuing internal stratification. The process can also help to highlight stratigraphic features that occur across multiple blocks, which may not be readily visible because of their present separation. The example highlights a central package within the reservoir response that are of lower amplitude to the under- and overlying sections. This package only exists within the two thicker reservoir areas shown in Figure 5B. Within this reconstructed package, several steeply dipping, oblique-sigmoidal reflections are observed that resemble clinoform features dipping toward the southeast (Figure 14).

DISCUSSION

The MTDs have a significant impact on the hydrocarbon industry by commonly serving as hydrocarbon seals (Alves et al., 2014; Sun et al., 2017) and by forming major reservoirs for several fields in the North Sea and Gulf of Mexico alone (Meckel, 2010). With less than 10% of MTDs worldwide being sandy, it is often difficult to differentiate between sand-prone and shale-prone MTDs in seismic data, and it is often only after drilling a target that a sand-prone MTD interpretation can be made (Meckel, 2010). Here, seismic observations have identified the presence of a sandy MTD consisting of gas-charged, highly porous blocks on the crest and eastern flank of the MBR (Figures 3, 4) that are of landslide origin having experienced postdepositional breakup and sliding. The package is clearly defined by high amplitudes and exists at the base of mega-unit D2 above a single decollement surface (the top reflection of mega-unit E [E1]) (Figure 3). Clear DHIs, frequency analysis via spectral decomposition, and estimations for velocity within the package all suggest a reservoir composed of highly porous sand that is likely gas charged, suggesting a working petroleum system within this area (Figures 4, 5).

Reservoir Deposition and Deformation

The basin and ridge topography, created by Cretaceous rifting, existed throughout the Paleogene and into the Neogene in the Melville Bay area (Whittaker et al., 1997; Gregersen et al., 2013). The MBR was likely a small, elongated emergent island extending from the northwestern Greenland mainland southward, creating a deep-water embayment above the MBG (Figures 2, 15). This is evidenced by onlap terminations of thick synrift deposits on the flank of the high as well as the increasing ridge height to the north (Figure 15). During periods of ridge uplift, no deposition occurred on the high and any sediment input would have bypassed into the deeper graben via gravity-driven processes (Gregersen et al., 2013) (Figure 16).

A period of net subsidence of the MBR allowed for the deposition of reservoir sands upon the ridge (Gregersen et al., 2016) (Figure 16). This likely occurred during the Eocene based on correlation of the base sand reflection (mega-unit E) on regional 2-D seismic data, with Eocene volcanics further south (Gregersen et al., 2013). The reservoir surrounds areas of nondeposition that exist above elevated areas on the ridge crest created by deep-seated tilted fault blocks (Figures 13, 15). This suggests sand deposition in a very shallow-marine environment, where restriction of deposition on these slightly more elevated areas is likely a result of being above the wave base.

Additional accommodation, possibly caused by localized faulting of the ridge, allowed the deposition of a localized thicker package within the reservoir that is observed during seismic reconstruction (Figure 14). This package is notably restricted to two areas on the ridge top platform (thicker areas of reservoir in Figure 5B) and is seen to contain possible southeastwardly prograding clinoform foresets. These observations, along with the southeast sediment transport direction along the MBR axis extension, suggest the development of a spitlike complex that is restricted to the shallow waters on the ridge top (Figure 15). Sediment transport may have been driven by near-surface ocean currents in the wider Baffin Bay, moving sediment southeastward along the paleo-coastline before eventual progradation along the submerged MBR southerly nose. The thickness and preservation of the sands upon the ridge suggest a high-sediment supply (Swift, 1968) and would have likely led to the bypass and transport of excess sand into deeper waters via gravity-driven processes (Figure 15) (Raynal et al., 2009).

Candidate deposits that may contain these sediments have been observed by Knutz et al. (2012) and Gregersen et al. (2013) as submarine fans at the base of mega-unit D2 with sand transport downslope being the likely cause of canyon development at this horizon on the eastern flank of the MBR (Figure 7E). However, deep-marine clastics in the graben were still dominantly sourced from the Greenland mainland to the east, creating large packages of onlapping sediments that are observed at the basin center (Gregersen et al., 2016). The focal point for sediment input may have been a relay ramp between fault sections of the MBG boundary fault (Figure 15).

Major extension ended in Baffin Bay during the late Eocene–Oligocene (Oakey and Chalmers, 2012), and Melville Bay experienced thermal subsidence and deepening waters leading to the preservation of the reservoir sands. Relative sea-level rise forced a southeast–northwest transgression of the spit complex system (Figures 15, 16), leading to increased reservoir thicknesses to the northwest before a transition of the environment to deep-marine mud deposition (Figures 3, 4, 5B).

Soon after reservoir deposition and before the overlying muds were in place, the reservoir sands underwent significant deformation, leading to the mass redistribution of sediment from the ridge top to its upper flanks, resulting in the modern-day reservoir structure, characterized by a large number of intact, separated MTD blocks along with a larger stable reservoir section to the north (Figures 4, 16). The breakup and sliding of reservoir blocks was likely triggered by a southward tilt of the MBR, evidenced by the reconstructed flow directions (Figure 12). This tilt was either caused by renewed heterogeneous uplift along strike of the MBR (with a relative increased degree of uplift to the north) or increased subsidence to the south (Figure 16). This is also supported by the increased quantity and travel distance (some >10 km [>6.2 mi]) of blocks southward (Figure 10). However, the southern slope represents the least dipping direction because it is along the southerly nose of the MBR (Figure 8). Therefore, the increased number of intact blocks may be because of preservation bias, with blocks down the steeper eastern and western ridge flanks having disintegrated.

The east-west–trending, low-amplitude features observed on the eastern flank of the MBR (Figures 5, 7) are likely to represent decollement surface deformation and extensional slumping, controlled by the location of faults (Figure 7). Low-amplitude zones within these features represent small extensional faults that facilitate deformation of the decollement surface (Figure 7B, C). The deformational features seem to mimic the shape of the sliding reservoir blocks seen along strike and were possibly caused by beneath-block deformation of decollement muds during sliding. It is possible that these features represent resting places for the blocks, thus creating an imprint or slide scar on the decollement surface before sliding further down the steepening slope and disaggregating (since the blocks themselves are not observed). This disaggregation caused much of the sliding reservoir sand to be redeposited by graben floor gravity flows (Knutz et al., 2012; Gregersen et al., 2013) or to be trapped in topographically controlled depocenters on the ridge slopes in features such as half grabens and canyons (Figures 7D, E; 16). The large volume of sediment shed from the high will have aided the development of the deep linear canyons that are observed trending into the MBG to the east (Figure 7E). Within these canyons, high positive seismic amplitudes (Figure 7E) likely represent redistributed reservoir sands.

The deformational features observed all suggest that reservoir deformation and preservation are controlled by the slope angle of the decollement (Figure 8). This angle is likely controlled by the uplift and resultant structure of the MBR along with the location of faults. Based on this, the system can be subdivided into four zones of deformation style that define the distribution and character of the reservoir sands (Figures 7D, 8).

  1. Stable platform crest: postdepositional deformation and sliding not observed, likely bald high areas with reservoir onlap.

  2. Mega-block sliding: shallow slope-induced breakup into blocks and sliding along a muddy decollement layer.

  3. Slide scars and disaggregation: sliding reservoir blocks caused deformation of the underlying decollement muds before the disaggregation of sand blocks because of slope steepening (possibly controlled by fault locations).

  4. Canyonization: erosional canyonization of the decollement surface caused by the continued downslope shedding of sediment; disaggregated sands deposit within canyon features.

These four deformational styles transition across areas of different dip angles seen across the modern-day decollement surface. However, it is the paleodip of the decollement surface during the period of deformation (Eocene) that would have had the controlling effect on the modern-day reservoir distribution. It is difficult to estimate paleodip in an area dominated by deep-water hemipelagic sedimentation, a clastic supply dominantly from the east (Gregersen et al., 2013), and significant sediment erosion caused by recent glaciations (Figures 2, 3). Still, paleodip was likely similar or less than that observed today because uplift of the MBR is expected to have continued into the Neogene, increasing the slope angle postsliding (Oakey, 2005; Japsen et al., 2006; Knutz et al., 2015). Additionally, the main sliding vector toward the southeast aligning with the direction of lowest average dip at 0.41° suggests that breakup and sliding of the reservoir commenced at a very low dip angle (<0.5°).

After the deformation of the reservoir sands and the full transition to a deep-marine setting during the late Eocene, a thick sequence of mud deposition occurred over both the basin and ridge. Mud deposition infilled between the separated reservoir blocks (evidenced by low-amplitude, flat-reflection geometries between blocks), suggesting deposition postreservoir deformation. These muds make up the lower section of the thick, polygonally faulted mega-unit D1 (Figures 3, 9).

The observed coincidence between faults extending subvertically from the block edge and the lower tips of polygonal faults (Figure 9) suggests that the reservoir blocks were a major factor in the development of the polygonal fault network above the MTD deposit. This occurred because of differences in compaction behavior between the sand blocks and infilled interblock muddy areas, which created a series of normal faults at the block edge (Figure 9). The compactional differences between mud and sandy block areas likely created subtle stress perturbations, which controlled the nucleation of polygonal faults into the overburden. This process potentially created a vertical fluid pathway constrained at the block edge from the reservoir to shallower stratigraphy, potentially representing a significant exploration risk, although polygonal fault planes are only thought to conduct fluids when actively forming, and polygonal faulted claystones are extremely effective seals in much of the North Sea Basin (Cartwright et al., 2007; Goulty, 2012).

Mechanisms of Sliding

The deposition of MTDs commonly results in a deformed mass of partly disaggregated sediment, which may lack coherent primary depositional structures, and is typically characterized by chaotic internal seismic reflections (Shipp et al., 2011). These gravitational deposits, however, are capable of transporting large clasts or blocks within the flow, which often maintain their primary structure and internal stratification (Alves, 2015; Jackson, 2011).

The phenomenon of relatively undeformed siliciclastic “mega-blocks” within a submarine slide deposit has been observed in different parts of the world (Table 1); examples include the northern Hikurangi Margin, New Zealand, where internally bedded slide blocks have been transported for greater than 40 km (>24.9 mi) (Collot et al., 2001); the Hopedale–Makkovik failure complex, southwest Labrador Sea, which contains angular blocks up to 6 km (3.7 mi) across with well-preserved internal stratification (Deptuck et al., 2007); and the internally undeformed slide blocks of the lower conglomerate sandstone that reach thicknesses of 30 m (98 ft) and widths up to 100 m (328 ft), found within basal canyon fill of the Upper Cretaceous Rosario Formation, Mexico (Morris and Busby-Spera, 1988).

The enigma of the MTD studied here is the apparent lack of transporting flow, with blocks sliding downslope as independent rafts of sediment, not confined or hosted within a more typical debris flow as seen in the majority of other block-containing MTDs (Table 1) (Deptuck et al., 2007; Jackson, 2011; Alves, 2015). This is evidenced by areas between blocks being infilled by hemipelagic sedimentation postsliding (Figure 4). Despite this, the blocks have still managed to maintain their gross depositional structure throughout the processes of breakup and sliding up to and greater than distances of 10 km (>6.2 mi). This is evidenced by the large, angular, sandy reservoir blocks along with the apparently unaffected internal stratification of the blocks postsliding at least on a seismic scale (Figures 4, 5). This suggests that slide momentum and block cohesion during sliding can occur independently and without containment in a typical cohesive debris flow. Although the more typical confining flow is not observed, the similarities in block size, distribution, and run-out length to other MTD analogs (Figure 17; Table 1) supports the conclusion that similar gravitational processes, including the downslope coherent sliding of reservoir facies, led to the modern-day structure and distribution of the MTD studied here.

The similarity of this MTD to other analogs is highlighted by its maximum block size (maximum block width vs. maximum block height) plotting within a data trend that strongly suggests that increased block width commonly coincides with increased block height within MTDs (Figure 17). The blocks from this MTD plot within the center of the distribution; therefore, it could be argued that blocks observed here represent a somewhat average example with regard to block size in MTDs.

Without the surrounding coherency and sliding lubrication provided by confinement within a larger debris flow, coherency of the blocks within this MTD was likely maintained and impacted by differing factors. First, the decollement surface itself would have provided a lubricated and smooth surface for the blocks to slide along (most likely a muddy horizon). This surface represents an unconformity above the underlying mega-units E and F (Figure 3), which are interpreted to be dominated by fine-grained claystones (Figure 18) (Gregersen et al., 2013). This weak, high–water-content lithology may have led to the development of a thin, subseismic veneer of mud slurry or a low-viscosity water layer (Prior et al., 1984) upon the decollement surface. In that scenario, a basal lubricating layer will reduce basal drag during sliding, increasing both block coherency and run-out distance while maintaining momentum. The underlying lubricating layer may also have caused blocks to hydroplane and decouple from the underlying surface during sliding; however, the probable slow speed of sliding makes hydroplaning less likely (Mohrig et al., 1998; Harbitz et al., 2003).

Slow, creeplike sliding would have reduced the attrition of the layered sediments, leading to a maintained primary depositional structure (Masson et al., 1996). The rate of sliding is most likely controlled by the decollement angle (Kehle, 1970) (Figure 8). This may be the reason why no reservoir blocks are observed beyond the platform edge in areas where the decollement slope dip angle increases significantly (>4°) (Figure 8). Increasing slope angle away from the ridge axis, or at fault locations, would promote faster sliding, disaggregation, and shedding of sediments into the deeper basin (Figures 7, 8, 16). Along the ridge axis, however, the slide-triggering tilt of the MBR caused either by differential uplift or subsidence along strike (northwest-southeast) (Gregersen et al., 2013), would have likely only created a decollement surface tilt of less than 0.5° (Figures 8, 18). This low angle is commonly thought to be enough to facilitate sliding of marine sediments (Harbitz et al., 2003; Kvalstad et al., 2005) but remains low enough to maintain a slow sliding speed. Furthermore, the large scale of the blocks may provide protection to internal strata from disaggregation at the block edges (Morris and Busby-Spera, 1988; Alves, 2015). This protection may have occurred as larger slide blocks broke away from the main platform section and slid as one before subsequently breaking up into smaller blocks, as seen in Collot et al. (2001) (Figure 11).

Block coherency may have also been promoted by the internal stratification of the reservoir, evidenced by bright seismic reflections within the reservoir package (Figures 4, 18). This heterogeneity suggests that the reservoir contains muddy layers that will have experienced a degree of compaction and dewatering because of the thickness of the reservoir (Figure 18). This compaction would have increased the shear strength of these mud layers, which in turn would increase the stability of the reservoir block. Additionally, these mud layers, along with mud entrained into the reservoir sands, would have caused the sediment to become more cohesive and may also have helped block stability during sliding (Figure 18) (Le Hir et al., 2011). Furthermore, the environment transition into a deep-marine setting during the time of sliding may have caused slight burial of the reservoir by a hemipelagic mud drape. The covering of sand beds with thin layers of muddy sediment has been proven to enhance the coherency of the beds. This is because of silt grains plugging the pore space of sand beds and reducing the inflow in the bed, leading to a reduction in erosion and increased bed stability (Bartzke et al., 2013). However, any burial would have been minimal because of the short time between deposition and sliding, evidenced by the lack of slide-related deformation of the overburden.

Finally, early-onset carbonate cementation may have occurred within the reservoir because of the potential deposition of shelly carbonate material within the reservoir sands (Figure 18). Grain cementation would likely reduce the porosity of the sands but increase the shear strength of the sediment package, causing it to become more stable and resist collapse during sliding (Dyke and Dobereiner, 1991). Any cementation would however be slight because the fluid effect is strong, implying low acoustic rigidity.

Implications for Reservoir Connectivity

Postdepositional breakup and sliding has caused much of the reservoir to exist as distributed MTD blocks. The potential disconnection between these blocks may have a major impact on hydrocarbon extraction efforts, causing much of the reservoir to be uneconomic. However, the distribution of DHIs across all observed MTD blocks and within the interblock areas (Figures 4, 5, 6) suggest that gas has reached all parts of the reservoir. Because gas charging is thought to have occurred after the deformation and burial of the reservoir (to allow the seal to be in place), this may suggest that the isolated reservoir blocks are connected to allow migration.

However, source rocks within the Melville Bay area are likely to exist within Upper Cretaceous (Cenomanian and Turonian) stratigraphy (mega-unit F) (Whittaker et al., 1997; Planke et al., 2009; Gregersen et al., 2013), the sediments that directly underlie the majority of the reservoir, updip from potential deeper-source kitchens in the MBG and South Kivioq Basin to the west and east, respectively (Figure 3). This connection between source rocks and the overlying reservoir would allow for updip migration into the MBR and subsequent upward migration and charging of all overlying reservoir sands. Therefore, a connection between distributed MTD blocks is likely not required to create the distribution of gas observed. It is more likely that any connectivity between MTD blocks is restricted to areas containing interblock sediments that have been mapped (Figures 5, 6). This sediment shows similar frequency and DHI responses on seismic data to the thicker reservoir blocks and likely represents gas-charged sands (Figures 5, 6). It was most likely deposited because of syn- and postslide block exposure at the seabed before seal coverage and gas charging. The edges of the reservoir sections would have resembled up to 80-m (262-ft)-tall cliffs with vast, deep areas between the blocks. This varied seabed topography, along with poorly consolidated sediment, would have promoted cliff edge erosion and gravitational collapse that was likely aided by current flow. This block-edge erosion is evidenced by the seismic geometry of the reservoir blocks (Figure 6) and is also depicted in schematic form in Figure 19, showing the erosional collapse of sediment from the cliff edge caused by exposure. However, because of the angular nature of reservoir blocks (Figure 10), erosion over much of the reservoir is likely to be minimal or below seismic resolution, with more significant erosion confined to blocks within areas defined by reservoir zones in Figure 20.

Within these zones, eroded block sediment was deposited adjacent to the block edge, upon the exposed decollement surface (Figures 6, 19), most likely during and after sliding, allowing for deposition to be relatively widespread around the block edges. This led to the creation of a sandy connection between separated reservoir blocks, which may provide widespread reservoir communication.

However, this sandy connection and potential reservoir communication may only exist within the identified reservoir zones (Figure 20) because charged interblock sediment is not observed in other areas (Figures 5, 6, 19, 20). This absence may be caused by sediment shedding occurring only in certain areas or caused by postdepositional erosion of the interblock sediment. Also, because of the slow rate of sliding as well as the transition of the system into a deeper-marine environment, fine-grained hemipelagic sediment may have become entrained into the interblock sands. This would reduce reservoir quality and potentially restrict both hydrocarbon charge and the fluid amplitude response. Overall, the sporadic absence of the reservoir-connecting sediment suggests that significant areas of the reservoir will remain disconnected.

Nevertheless, large areas of the reservoir do contain interblock sediment and are potentially in pressure communication. These areas have been divided into separate zones that are most suitable for exploration targeting (Figure 20). The six most connected zones cover an area of 160.3 km2 (62 mi2) with an average thickness of 33.5 ms (28 m [92 ft]). The remaining unknowns regarding interblock infill creating block connection increase exploration risk significantly. However, a large part of the selected reservoir zone area exists within zone 1, which is the main reservoir block in its original depositional location. This block covers an area of 100.2 km2 (39 mi2) with an average thickness of 47 ms (40 m [131 ft]) and may provide fewer production issues than the other selected surrounding zones.

CONCLUSION

Seismic investigations show an MTD prospect that displays acoustic and velocity characteristics consistent with thick gas-charged sands intercalated with mudstone layers. Reservoir structure shows landslide characteristics with much of the reservoir consisting of intact MTD blocks, which have slid downslope as independent rafts of sediment, not confined or hosted within a more typical debris flow. Sliding is interpreted to have occurred slowly and soon after deposition, with sediment coherency during sliding likely being aided by lithological and diagenetic characteristics as well as lubrication along a mud slurry or water layer upon the decollement surface. The reconstruction of 499 reservoir blocks provided evidence for basin development and postrift tectonic adjustments. The process identified a bidirectional sliding motion that suggests rejuvenation and a southward tilt of the MBR, which was likely the trigger of reservoir breakup and sliding. The process also provided evidence for the source of reservoir sands from the northwest, which were likely deposited within a shallow-marine transgressional spit complex at the southern end of an elongated emergent island created by the uplifted MBR during the Eocene.

The mechanisms of sliding along a low-angled decollement, along with the maintained sediment coherency during deformation, provide a high-quality analog of postdepositional breakup and sliding of reservoir facies. Furthermore, clear DHIs and velocity pushdown effects serve to calibrate MTD lithology and fluid content and are evidence of a working petroleum system. Overall, the reservoir has significant exploration potential focused around the large 100.2 km2 (39 mi2) main reservoir block (zone 1). However, any exploration considerations of the wider reservoir area must consider substantial development challenges linked to the separation and isolation of reservoir sections, as well as the additional uncertainty of interblock sediment connectivity.

ACKNOWLEDGMENTS

The authors would like to thank Cairn Energy, PLC, for access to seismic data from the Pitu area and for permission to publish images and results herein. The results and opinions expressed within this work are those of the authors and are not a representation of Cairn Energy, PLC. We would also like to thank TGS for the provision of the Baffin Bay two-dimensional regional seismic survey (BBRE11).

 David R. Cox is part of the Natural Environment Research Council (NERC) Centre for Doctoral Training in Oil & Gas (grant number: NE/M00578X/1). It is sponsored by The University of Manchester (50%) and the British Geological Survey via the British University Funding Initiative (50%) (studentship number: S356), both of which are gratefully acknowledged. Andrew M. W. Newton was sponsored by Cairn Energy, PLC, and NERC (NE/K500859/1).

Finally, we are grateful for software provisions to The University of Manchester that were used within this work from Schlumberger (Petrel), Esri (ArcMap), and Foster Findlay Associates, Ltd. (Geoteric).

David R. Cox joined The University of Manchester in 2016 as a Ph.D. student after working for 2 years in the oil industry. His Ph.D. research is focused on the impacts of glaciation on Arctic petroleum systems, encompassing topics such as seismic geomorphology, fluid flow, gas hydrates, reservoir characterization, basin modeling, and shallow hazard analysis.

Mads Huuse is professor of geophysics at The University of Manchester. He received his Ph.D. from Aarhus University in 1999 and joined Manchester in 2009 to lead the seismic interpretation group. His interests include basin fill, temperature, diagenesis, gas hydrates, reservoir and seal characterization, and fluid flow. His interests also include seismic geomorphology of glaciated basins and margins.

Andrew M. W. Newton received his Ph.D. in seismic geomorphology of glaciated margins from The University of Manchester in 2017. After a short postdoctoral, he joined Queen’s University Belfast as an independent research fellow and remains a visiting researcher at Manchester. His current research interests include using seismic geomorphology to understand subsurface evolution, paleoclimate, and fluid flow.

Paul Gannon is a geoscientist working for Cairn Energy, PLC, as part of the Norwegian North Sea exploration team, based in Stavanger Norway, and previously as part of the North Atlantic exploration team, focused on Cairn’s Greenlandic portfolio of assets. Paul holds a degree in geology from Trinity College Dublin and a master’s degree in petroleum geoscience from Aberdeen University.

John Clayburn graduated from the University of Oxford in 1981 with a D.Phil. in radiogenic isotope geochemistry and has published in numerous journals including The Royal Society and Nature. He has more than 35 years of oil industry experience, having looked at rocks in more than 100 countries. His most recent role was head of exploration for Cairn Oil & Gas, Ltd., and Cairn Energy, PLC.

Gold Open Access. This paper is published under the terms of the CC-BY license.