Discriminating cool‐water from warm‐water carbonates and their diagenetic environments using element geochemistry: The Oligocene Tikorangi Formation (Taranaki Basin) and the dolomite effect

Hood, Steven D.; Nelson, Campbell S.; Kamp, Peter J.J.

doi:10.1080/00288306.2004.9515093

Cited by 5 publications

(5 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…9) for the studied samples plot along with the Cenozoic New Zealand carbonates (but on the higher side of the Mn, Mg and Na) indicating their genesis in a temperate cooler waters but in actual condition the MVI (Lesser Antilles) is located in the zone of tropics which is a known latitudinal tectonic setting. Here we report a deviation from the general observation of Winefield et al(1996); Rao (1991), Hood et al(2004 and Azizi et al (2014) on the temperate limestones, although the geochemical parameters and ratios as mentioned above satisfy the discrimination. The authors also suggested that the regional generalisations can be made limited to the skeletal differences, diagenetic process involved etc., Based on the above and analysed data sets of the studied samples, the net effect of volcanogenesis, carbonate dilution and dissolution play an important role in discriminating the carbonates of tropical origins.…”

Section: Contamination and Diagenetic Alterationscontrasting

confidence: 72%

Geochemistry of Marine Carbonates from Hole 1394, off the Coast of Montserrat, IODP Expedition-340; Implications on Provenance, Paleoenvironment and Lesser Antilles Arc Migration

Subramanyam

Balaram

Manikyamba

et al. 2020

Society of Earth Scientists Series

View full text Add to dashboard Cite

HAL is a multi-disciplinary open access archive for the deposit and dissemination of scientific research documents, whether they are published or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. L'archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d'enseignement et de recherche français ou étrangers, des laboratoires publics ou privés.

show abstract

Section: Contamination and Diagenetic Alterationscontrasting

confidence: 72%

Geochemistry of Marine Carbonates from Hole 1394, off the Coast of Montserrat, IODP Expedition-340; Implications on Provenance, Paleoenvironment and Lesser Antilles Arc Migration

Subramanyam

Balaram

Manikyamba

et al. 2020

Society of Earth Scientists Series

View full text Add to dashboard Cite

show abstract

“…Sr concentration and mineralogy composition of carbonates have a direct relationship, as Sr values increase with aragonite increase and decrease with calcite increase (Rao & Adabi, 1992; Rao & Amini, 1995; Rao, 1996; Adabi, 2004). Sr values range from 8000 to 10 000 ppm in recent tropical bulk carbonate samples (Milliman, 1974), while in recent temperate bulk carbonates it reduces and ranges from 1500 to 4500 ppm (Rao, 1991; Rao & Adabi, 1992; Hood, Nelson & Kamp, 2004). The values of Sr in low-Mg calcite, high-Mg calcite and aragonite are 1000 ppm, 3000 ppm and up to 10 000 ppm, respectively (Kinsman, 1969; Carpenter & Lohmann, 1992; Rao, 1996; Rao et al 1998).…”

Section: Original Carbonate Mineralogymentioning

confidence: 99%

Guadalupian cool versus warm water deposits in central Iran: a record of the Capitanian Kamura event

Arefifard

2017

Geol. Mag.

View full text Add to dashboard Cite

An integration of geochemical and grain association studies were carried out on Middle Permian deposits in central Iran where both cool and warm water carbonates are found. The recrystallization of most bioclasts, lime-mud matrix and ooids along with high Sr contents suggests a probable original aragonite mineralogy for carbonates of the Middle Permian Jamal Formation at the Shotori section. Low bulk carbonate δ18O values imply pervasive diagenetic alteration in this section. Conversely, Middle Permian deposits at the correlative Bagh-e Vang section have a probable calcite precursor supported by low Sr contents and no evidence of recrystallization. This mineralogical variation in these coeval carbonates is considered to be due to the change in depth and temperature of the depositional palaeoenvironment. δ13C values started to rise over 2 ‰ PDB and reached a maximum of 4.3 ‰ PDB at the Wordian–Capitanian boundary at the Bagh-e Vang section. This δ13C rise is attributed to high primary productivity as previously reported in the Capitanian Abadeh Formation in central Iran. The positive δ13C excursion in these sections is correlated with the Capitanian ‘Kamura event’ identified from the mid-Panthalassian sections in Japan. No noticeable positive excursion occurs in the δ13C plot at the Shotori section making the interpretation of palaeo-productivity difficult. It is suggested that an active oceanic upwelling was the probable driver of the Middle Permian oceanic productivity in central Iran. Remarkable negative δ13C excursions around 3.7 and 4.2 ‰ PDB in Capitanian carbonates close to the Guadalupian–Lopingian boundary at the Bagh-e Vang and Abadeh sections, respectively are recorded, which are a proxy for low palaeo-productivity and a transition from a cool to warm climate, consistent with an early Lopingian sea level rise.

show abstract

“…, ). Sr concentration also has a direct relation with increasing water temperature (Hood, Nelson, & Kamp, ; Morse & Mackenzie, ; Winefield, Nelson, & Hodder, ). Although aragonite recrystallization results in Sr loss (Brand & Veizer, ), but limestones with aragonite origin have naturally higher concentration than those with calcite origin (Veizer & Demovic, ).…”

Section: Lithological Geochemical and Faunal Paleoclimate Proxies Imentioning

confidence: 99%

“…The Sr content in recent tropical bulk carbonates ranges from 8,000 to 10,000 ppm (Milliman, 1974;Rao, Amini, & Ferguson, 1998), while in recent temperate carbonate it ranges from 1,600 to 5,000 ppm (Rao & Amini, 1995;Rao & Jayawardane, 1994;Rao et al, 1998). Sr concentration also has a direct relation with increasing water temperature (Hood, Nelson, & Kamp, 2004;Morse & Mackenzie, 1990;Winefield, Nelson, & Hodder, 1996). Although aragonite recrystallization results in Sr loss (Brand & Veizer, 1980), but limestones with aragonite origin have naturally higher concentration than those with calcite origin (Veizer & Demovic, 1974).…”

Section: Bauxitementioning

confidence: 99%

Evidence of warm climate during late Sakmarian–early Artinskian in Posht‐e Badam Block, Central Iran and its paleogeographic implication

Arefifard

2017

Geological Journal

View full text Add to dashboard Cite

Examination of the geochemical data, faunal associations, and bauxite/laterite horizons in the Khan Formation, in Kalmard area, Posht‐e Badam Block, Central Iran are presented. The data provide insights on the paleogeographic position of Central Iran as part of the Cimmerian during the late Sakmarian–early Artinskian time. Bauxite/laterite as valuable warm and humid paleoclimate proxies are observed in all studied sections of the mixed siliciclastic‐carbonate Khan Formation and are meters to tens of meters thick. The warm and humid climate is also verified by the previous studies of Khan Formation sandstones yielding high chemical weathering and highly mature quartz grains. Plant fossils recovered from these sandstones are further evidence of the warm and wet climate. The results of the geochemical studies of the Khan Formation carbonates are in robust agreement with the inferred paleoclimate condition from bauxite/laterite horizons and sandstone studies of the Khan Formation. The bivariate plot of major and minor elements shows that aragonite as an indicator of warm water conditions was the major carbonate mineralogy of the Khan Formation limestones. Temperature calculation based on the heaviest oxygen isotope value of the least‐altered sample indicates that the temperature was around 36 and 29 °C for dolomites and limestones of the Khan Formation, respectively. The skeletal grains of the Khan Formation limestones are representative of a photozoan association with fusulinids, smaller foraminifers, calcareous algae, and common crinoids, brachiopods and bryozoans and also ooids and peloids as non‐skeletal grains. Therefore, the results of this study are not in agreement with previous fusulinid‐based paleogeographic interpretations, which suggested a high‐latitude paleoposition for the Posht‐e Badam Block and its separation from other Central Iran terrains during the late Sakmarian–early Artinskian. These data indicate that Posht‐e Badam Block was part of Central Iran during the late Sakmarian–early Artinskian, and its paleoposition was at a low paleolatitude.

show abstract

Discriminating cool‐water from warm‐water carbonates and their diagenetic environments using element geochemistry: The Oligocene Tikorangi Formation (Taranaki Basin) and the dolomite effect

Cited by 5 publications

References 29 publications

Geochemistry of Marine Carbonates from Hole 1394, off the Coast of Montserrat, IODP Expedition-340; Implications on Provenance, Paleoenvironment and Lesser Antilles Arc Migration

Geochemistry of Marine Carbonates from Hole 1394, off the Coast of Montserrat, IODP Expedition-340; Implications on Provenance, Paleoenvironment and Lesser Antilles Arc Migration

Guadalupian cool versus warm water deposits in central Iran: a record of the Capitanian Kamura event

Evidence of warm climate during late Sakmarian–early Artinskian in Posht‐e Badam Block, Central Iran and its paleogeographic implication

Contact Info

Product

Resources

About