Carbonate drowning successions of the Bird’s Head, Indonesia

Gold, David P.; Burgess, Peter M.; BouDagher‐Fadel, Marcelle K.

doi:10.1007/s10347-017-0506-z

Cited by 23 publications

(11 citation statements)

References 88 publications

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“…We therefore interpret Interval 2 at Site U1463 to reflect increasing "northern ITF source waters" from the north Pacific as indicated by decreasing SST at Site 763 after 3.54 Ma. This interpretation is in line with the proposed closure and/or restriction of the equatorial Pacific ITF pathway due to the uplift of Halmahera and closure of the Halmahera strait (Godfrey, 1996;Gold et al, 2017;Hall, 2002;Hall et al, 1988;Kuhnt et al, 2004;Molnar & Cronin, 2015;Wijeratne et al, 2018; Figures 2, 3, and 5b). This led to a possibly narrower LC, similar to its modern configuration, with more turbulent flow and stronger LC eddy formation (Waite et al, 2007).…”

Section: 1029/2018pa003512supporting

confidence: 87%

“…Deep blue lines indicate active subduction zones during the Pliocene (Hall, , ). Uplift of Timor is implied by 3.5 Ma (Tate et al, ); closure of the Halmahera straight and uplift of Halmahera during this timeframe is implied by modeling data and field studies (Audley‐Charles, ; Cane & Molnar, ; Godfrey, ; Gold et al, ; Hall, ; Hall et al, ; Kuhnt et al, ; Molnar & Cronin, ). Vegetation cover was reduced in this map to reflect lower riverine influx indicating reduced precipitation.…”

Section: Discussionmentioning

confidence: 99%

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Timing and Pacing of Indonesian Throughflow Restriction and Its Connection to Late Pliocene Climate Shifts

Auer

Vleeschouwer

Smith

et al. 2019

Paleoceanog and Paleoclimatol

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The Pliocene was characterized by a gradual shift of global climate toward cooler and drier conditions. This shift fundamentally reorganized Earth's climate from the Miocene state toward conditions similar to the present. During the Pliocene, the progressive restriction of the Indonesian Throughflow (ITF) is suggested to have enhanced this shift toward stronger meridional thermal gradients. Reduced ITF, caused by the northward movement of Australia and uplift of Indonesia, impeded global thermohaline circulation, also contributing to late Pliocene Northern Hemisphere cooling via atmospheric and oceanographic teleconnections. Here we present an orbitally tuned high‐resolution sediment geochemistry, calcareous nannofossil, and X‐ray fluorescence record between 3.65 and 2.97 Ma from the northwest shelf of Australia within the Leeuwin Current. International Ocean Discovery Program Site U1463 provides a record of local surface water conditions and Australian climate in relation to changing ITF connectivity. Modern analogue‐based interpretations of nannofossil assemblages indicate that ITF configuration culminated ~3.54 Ma. A decrease in warm, oligotrophic taxa such as Umbilicosphaera sibogae, with a shift from Gephyrocapsa sp. to Reticulofenestra sp., and an increase of mesotrophic taxa (e.g., Umbilicosphaera jafari and Helicosphaera spp.) suggest that tropical Pacific ITF sources were replaced by cooler, fresher, northern Pacific waters. This initial tectonic reorganization enhanced the Indian Oceans sensitivity to orbitally forced cooling in the southern high latitudes culminating in the M2 glacial event (~3.3 Ma). After 3.3 Ma the restructured ITF established the boundary conditions for the inception of the Sahul‐Indian Ocean Bjerknes mechanism and increased the response to glacio‐eustatic variability.

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Section: 1029/2018pa003512supporting

confidence: 87%

Section: Discussionmentioning

confidence: 99%

Timing and Pacing of Indonesian Throughflow Restriction and Its Connection to Late Pliocene Climate Shifts

Auer

Vleeschouwer

Smith

et al. 2019

Paleoceanog and Paleoclimatol

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“…It is also recorded in offshore seismic data which shows the Miocene Klasafet Formation (and age equivalent units) have been folded (e.g., Bailly et al, , and arguably Pairault et al, , as well as Sapin et al, ; Figure ), the local sea‐level curve differs to global sea‐level curves. The local sea‐level curve shows a change from deeper water conditions (50–100 m) to shallower water conditions (0–10 m) between the Early to Late Pliocene (Gold, Burgess, et al, ; Gold, White, et al, ; Figure d), the removal of early Pliocene to Mesozoic sequences due to erosion—as recorded in various hydrocarbon exploration wells (cf. Figure 18 in Gold, White, et al, ) as well as in regional offshore seismic imagery (e.g., Bailly et al, ; Pairault et al, ). Our structural and geochronological data combined with these other data sources confirms the suggestion that the Lengguru Fold Belt must have developed due to a young (5–3 Ma) episode of crustal shortening (e.g., Decker et al, ; Dow et al, ; Moffat et al, ; Pieters et al, ; Visser & Hermes, ), rather than an earlier episode at ca.…”

Section: Discussionmentioning

confidence: 93%

“…At least two major accretion events are recognized along the length of New Guinea between ~45 Ma and the present day; (1) the obduction of the Papuan Ophiolites, accretion of volcanic arc fragments of Pacific affinity, and the development of a widespread unconformity across western New Guinea and the southern Molucca's during the Oligo‐Miocene (Ali & Hall, ; Gold, Burgess, et al, ; Gold, White, et al, ; Hall, ; Hall, Ali, & Anderson, ; Hall, Ali, Anderson, & Baker, ; Holm et al, , ), and (2) accretion of the additional arc material during the Pliocene‐Pleistocene (e.g., Davies, ; Dow et al, ; Holm et al, ; Monnier et al, ; Pigram & Symonds, ; Pubellier et al, ). These accretionary events are considered to have been driven by the northward advance of the Australian Plate since the Eocene and 40° clockwise rotation of the Philippine Sea Plate along the northern margin of the Australian Plate between the Early Neogene and present day (Ali & Hall, ; Hall, , ; Hall, Ali, & Anderson, ; Hall, Ali, Anderson, & Baker, ; Hill & Hall, ).…”

Section: Geologic Settingmentioning

confidence: 99%

Tectonic Mode Switches Recorded at the Northern Edge of the Australian Plate During the Pliocene and Pleistocene

et al. 2019

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We report new data from medium-high grade metamorphic rocks found at the northern margin of the Lengguru Fold Belt in West Papua. The study involved a systematic analysis of cross-cutting structures to establish the relative timing of deformation, together with isotopic dating to define when these tectono-thermal events occurred. These data show that the region underwent multiple episodes of deformation within the last six million years. Metamorphic mineral growth was associated with the development of ductile shear zones. This episode occurred during a phase of crustal stretching associated with the formation of a metamorphic core complex. Metamorphic zircon growth at 4.9 to 5.3 Ma was documented in two of the dated samples. These data are interpreted to postdate the peak pressure and temperature conditions of the phase of regional crustal stretching. The shear fabrics associated with the metamorphic core complex were later overprinted by at least two generations of folds. The change in mode from crustal extension to shortening reflects a tectonic mode switch. A subsequent mode switch is documented by numerous brittle extensional faults that cross-cut the earlier formed ductile fabrics. We interpret ca. 0.75-1.51 Ma (U-Th)/He age data to reflect cooling associated with the later stages of crustal shortening (marked by folds) or the later extensional unroofing of the peninsula. This work demonstrates that an orogen can record multiple tectonic mode switches within several million years. These outcomes should be considered in studies of ancient orogens where analytical uncertainties associated with isotopic dating may mask short-lived mode switches.Plain Language Summary How much time is required for a mountain belt to develop? Our knowledge of mountain building is somewhat limited because many of the best-studied mountain belts are quite old and our ability to date tectonic events is less precise the farther back we look through time. The work presented here investigates a mountainous peninsula that developed at the northern margin of the Australian Plate within the last six million years. This region records multiple episodes of deformation-we show that the relatively young rocks have been stretched, then pushed together and then stretched again (much like an accordion). These cycles must occur over a period of one to two million years, which is very fast compared to numerous studies of ancient mountain belts that consider the same processes occur over tens of millions of years.

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“…Tracing the stratigraphic distribution of the larger benthic foraminifera allows the understanding of the impact of climate, tectonic activity and volcanism on long-term (i.e. millions years) evolution of these shallow-water carbonate platforms (Courgeon et al, 2016(Courgeon et al, , 2017Gold et al, 2017aGold et al, , 2017b. Larger foraminifera and planktonic foraminifera overlap in occurrence in many localities allowing direct comparison of larger foraminifera "letter stages" biozones with oceanic planktonic scales (BouDagher-Fadel, 2002;BouDagher-Fadel, 2013, 2015Sharaf et al, 2013).…”

Section: Biostratigraphy and Phylogenetic Evolutionmentioning

confidence: 99%

Evolution and Geological Significance of Larger Benthic Foraminifera

2018

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Carbonate drowning successions of the Bird’s Head, Indonesia

Cited by 23 publications

References 88 publications

Timing and Pacing of Indonesian Throughflow Restriction and Its Connection to Late Pliocene Climate Shifts

Timing and Pacing of Indonesian Throughflow Restriction and Its Connection to Late Pliocene Climate Shifts

Tectonic Mode Switches Recorded at the Northern Edge of the Australian Plate During the Pliocene and Pleistocene

Evolution and Geological Significance of Larger Benthic Foraminifera

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