Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-23T19:01:20.021Z Has data issue: false hasContentIssue false

Stable oxygen isotope chemostratigraphy and paleotemperature regime of mosasaurs at Bentiaba, Angola

Published online by Cambridge University Press:  18 February 2015

C. Strganac*
Affiliation:
Roy M. Huffington Department of Earth Sciences, Southern Methodist University, Dallas, Texas 75275, USA Perot Museum of Nature and Science, Dallas, Texas 75201, USA
L.L. Jacobs
Affiliation:
Roy M. Huffington Department of Earth Sciences, Southern Methodist University, Dallas, Texas 75275, USA
M.J. Polcyn
Affiliation:
Roy M. Huffington Department of Earth Sciences, Southern Methodist University, Dallas, Texas 75275, USA
K.M. Ferguson
Affiliation:
Roy M. Huffington Department of Earth Sciences, Southern Methodist University, Dallas, Texas 75275, USA
O. Mateus
Affiliation:
GeoBioTec, Faculdade de Ciências e Tecnologia, Universidade Nova de Lisboa, Caparica, Portugal Museu da Lourinhã, Rua João Luis de Moura, 2530-157, Lourinhã, Portugal
A. Olímpio Gonçalves
Affiliation:
Departamento de Geologia, Faculdade de Ciencas, Universidade Agostinho Neto, Avenida 4 de Fevereiro 7, Luanda, Angola
M.-L. Morais
Affiliation:
Departamento de Geologia, Faculdade de Ciencas, Universidade Agostinho Neto, Avenida 4 de Fevereiro 7, Luanda, Angola
T. da Silva Tavares
Affiliation:
Departamento de Geologia, Faculdade de Ciencas, Universidade Agostinho Neto, Avenida 4 de Fevereiro 7, Luanda, Angola Université de Bourgogne, Dijon, France
*
*Corresponding author. Email: [email protected]

Abstract

Stable oxygen isotope values of inoceramid marine bivalve shells recovered from Bentiaba, Angola, are utilised as a proxy for paleotemperatures during the Late Cretaceous development of the African margin of the South Atlantic Ocean. The δ18O values derived from inoceramids show a long-term increase from –3.2‰ in the Late Turonian to values between –0.8 and –1.8‰ in the Late Campanian. Assuming a constant oceanic δ18O value, an ∼2‰ increase may reflect cooling of the shallow marine environment at Bentiaba by approximately 10°. Bentiaba values are offset by about +1‰ from published records for bathyal Inoceramus at Walvis Ridge. This offset in δ18O values suggests a temperature difference of ∼5° between coastal and deeper water offshore Angola. Cooler temperatures implied by the δ18O curve at Bentiaba coincide with the stratigraphic distribution of diverse marine amniotes, including mosasaurs, at Bentiaba.

Type
Original Article
Copyright
© Netherlands Journal of Geosciences Foundation 2015 

Introduction

We present a temporally calibrated, shallow marine δ18O chemostratigraphic curve for Bentiaba, southern Angola (Fig. 1), relating stable oxygen isotopes of this portion of the southern hemisphere to values from the Walvis Ridge offshore Angola and elsewhere around the globe. The presented δ18O values are used to estimate the paleotemperature regime in which mosasaurs and other marine amniotes along this portion of southwest Africa lived throughout much of the Late Cretaceous.

Fig. 1. Location map of Bentiaba, Angola. Inset shows location of Angola within Africa, offshore basins labelled in capital letters. Note location of DSDP Hole 530A, which is discussed in the text. Modified from Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a).

Mosasaurs have a fossil record extending from the Cenomanian, approximately 98 Ma, to their extinction at the end of the Cretaceous at 66 Ma (Jacobs et al., Reference Jacobs, Ferguson, Polcyn and Rennison2005a,b; Polcyn et al., Reference Polcyn, Tchernov and Jacobs1999, Reference Polcyn, Jacobs, Araújo, Schulp and Mateus2014). Since 2005 our team, Projecto PaleoAngola, has conducted field expeditions in Cretaceous and younger rocks of coastal Angola, greatly improving the fossil record of vertebrates from the eastern South Atlantic (Jacobs et al., Reference Jacobs, Mateus, Polcyn, Schulp, Antunes, Morais and Tavares2006). The oldest mosasaurs known from the South Atlantic Ocean, Angolasaurus bocagei and Tylosaurus iembeensis, are found at Iembe, north of the capital Luanda, in Late Turonian nearshore deposits that also produced the sauropod dinosaur Angolatitan adamastor (Mateus et al., Reference Mateus, Jacobs, Schulp, Polcyn, Tavares, Neto, Morais and Antunes2011). Marine amniote remains known from Iembe also include halisaurine vertebrae and a marine turtle, Angolachely mbaxi (Mateus et al., Reference Mateus, Jacobs, Polcyn, Schulp, Vineyard, Antunes and Neto2009, Reference Mateus, Polcyn, Jacobs, Araújo, Schulp, Marinheiro, Oereira and Vineyard2012; Polcyn et al., Reference Polcyn, Lindgren, Bardet, Cornelissen, Verding and Schulp2012).

The greatest concentration of mosasaurs in Angola comes from Upper Campanian–Maastrichtian sediments at Bentiaba (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014b), but there are significant exposures below the fossil-bearing horizons, which range in age from Cenomanian to Santonian. The chronological context for Bentiaba is provided by the magnetostratigraphy and a δ13C chemostratigraphic framework anchored by an 84.5 Ma 40Ar/39Ar whole-rock radiometric date on an intercalated basalt of the Ombe Formation, which is consistent with ammonite biostratigraphy (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a). The Bentiaba δ18O curve presented here was constructed as a complement to the δ13C record presented by Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a).

The mosasaur fauna of the Campanian Baba Formation is fragmentary and includes both russellosaurians and mosasaurines, while that of the overlying Maastrichtian Mocuio Formation is predominately mosasaurine (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014b). Within the Mocuio Formation, the mid-Maastrichtian (approximately 71.5 Ma) Bench 19 fauna is particularly rich (Schulp et al., Reference Schulp, Polcyn, Mateus, Jacobs, Morais and Tavares2006, Reference Schulp, Polcyn, Mateus, Jacobs, Morais and Everhart2008, Reference Schulp, Polcyn, Mateus and Jacobs2013; Polcyn et al., Reference Polcyn, Jacobs, Schulp and Mateus2010, Reference Polcyn, Jacobs, Araújo, Schulp and Mateus2014; Mateus et al., Reference Mateus, Polcyn, Jacobs, Araújo, Schulp, Marinheiro, Oereira and Vineyard2012), and it is the subject of a paleoecological analysis (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014b). The paleogeographic context of Angolan vertebrates was initially examined in Jacobs et al. (Reference Jacobs, Mateus, Polcyn, Schulp, Scotese, Goswami, Ferguson, Robbins, Vineyard and Neto2009, Reference Jacobs, Strganac and Scotese2011) and Polcyn et al. (Reference Polcyn, Jacobs, Schulp and Mateus2010), and their paleoecology was examined initially in Robbins et al. (Reference Robbins, Ferguson, Polcyn, Jacobs and Everhart2008) and Polcyn et al. (Reference Polcyn, Jacobs, Schulp and Mateus2010, Reference Polcyn, Jacobs, Araújo, Schulp and Mateus2014).

Little paleotemperature research relevant to this study has been conducted in Africa. An analysis of paleosols in the Samba drill core from the Congo Basin (Cahen et al., Reference Cahen, Ferrand, Haarsma, Lepersonne and Verbeek1959), representing the interior of Gondwana prior to the opening of the South Atlantic, indicates Jurassic average annual soil temperatures between 25 and 40±3°C, with an average of 33°C, σ = 7.6°C (Myers et al., Reference Myers, Tabor and Jacobs2011), accompanied by low biological productivity (Myers et al., Reference Myers, Tabor, Jacobs and Mateus2012). Myers et al. (Reference Myers, Tabor and Jacobs2011) also presented a Lower Cretaceous soil temperature estimate of 23±3°C.

Temperature tolerances for mosasaurs of Cenomanian age, near the time of origin for the group, were considered by Jacobs et al. (Reference Jacobs, Polcyn, Taylor and Ferguson2005b). Kolodny & Luz (Reference Kolodny, Luz, Taylor, O’Neil and Kaplan1991) reported the δ18O value of the Cenomanian shark Cretolamna appendiculata from Angola, included by Pucéat et al. (Reference Pucéat, Lécuyer, Donnadieu, Naveau, Cappetta, Ramstein, Huber and Kriwet2007) in their study of Cretaceous latitudinal temperature gradients. The current study provides temperature estimates of shallow marine environments, below wave base, for much of Late Cretaceous time as the South Atlantic was growing and was inhabited by diverse assemblages of marine amniotes.

Cretaceous δ18O records have been used to elucidate changes in ocean circulation as well as temperature (Cramer et al., Reference Cramer, Toggweiler, Wright, Katz and Miller2009; Friedrich et al., Reference Friedrich, Herrle, Wilson, Cooper, Erbacher and Hemleben2009, Reference Friedrich, Norris and Erbacher2012). Most paleotemperature records utilise benthic foraminifera, whose δ18O values reflect offshore deep marine environments with little to no influence by meteoric input or fluctuations in salinity (Grossman, Reference Grossman, Gradstein, Ogg, Schmitz and Ogg2012). These methods can be extended to shallow shelf setting unaffected by high freshwater influx (Sessa et al., Reference Sessa, Ivany, Schlossnagle, Samson and Schellenberg2012), which we assume to be the case at Bentiaba (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014b). The δ18O curve from Bentiaba provides a shallow marine temperature curve that can be compared to the long-term benthic records to track broader temperature trends, to obtain indications of larger circulation patterns, and to provide a paleotemperature context for evolution in the marine realm.

The Late Cretaceous marks the transition from global high temperatures during the Late Cenomanian-Turonian climatic maximum and progressing through the cooler temperatures that characterise much of the Cenozoic. Cretaceous temperature trends coincide with significant paleoceanographic events, including Oceanic Anoxic Event 2 at the Cenomanian-Turonian Boundary, which is a widespread period of rapid burial of organic matter related to marine productivity and enhanced ocean stratification (Arthur et al., Reference Arthur, Dean and Pratt1988; Erbacher et al., Reference Erbacher, Huber, Norris and Markey2001, Forster et al., Reference Forster, Kuypers, Turgeon, Brumsack, Petrizzo and Sinninghe Damsté2008; Friedrich et al., Reference Friedrich, Norris and Erbacher2012; Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a). Connections between major ocean basins increased after the Turonian as a result of tectonic drift of continents, allowing cool waters derived from high latitudes to circulate equatorially, contributing to declining global temperature (Hay et al., Reference Hay, DeConto, Wold, Wilson, Voigt, Schultz, Wold, Dullo, Ronov, Balukhovsky, Söding, Barrera and Johnson1999; Miller et al., Reference Miller, Barrera, Olsson, Sugarman and Savin1999; Cramer et al., Reference Cramer, Toggweiler, Wright, Katz and Miller2009; Robinson & Vance, Reference Robinson and Vance2012). The δ18O stratigraphic curve presented here is a proxy for shallow marine temperature change at Bentiaba during the Late Cretaceous development of the South Atlantic.

The mosasaur-bearing portion of the Bentiaba section lies above the Ombe basalt in the Baba and Mocuio formations (Fig. 2). Carbonate cement creates benches in the Mocuio Formation, which are numbered in the section. Vertebrates occur throughout the Baba and Mocuio formations. The Campanian Baba Formation preserves a fragmentary but mixed russellosaurine-mosasaurine fauna extending into the lower part of the Mocuio Formation. In the Lower Maastrichtian part of the Mocuio Formation, the Bench 19 Fauna is dominated by mosasaurines. The highest levels of the Mocuio fauna, which we interpret as Upper Maastrichtian (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a), preserve the globidensine Carinodens and a large, derived Prognathodon (Mateus et al., Reference Mateus, Polcyn, Jacobs, Araújo, Schulp, Marinheiro, Oereira and Vineyard2012; Schulp et al., Reference Schulp, Polcyn, Mateus and Jacobs2013; Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014b).

Fig. 2. Section at Bentiaba with δ13C and inoceramid δ18O stratigraphic curves. Red bones and ‘19’ indicate marine amniote-bearing horizons and Bench 19. Note that the δ13C curve is composite of inoceramid and other bivalve data in Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a).

Methods and materials

Stratigraphic δ18O sampling

The inoceramid bivalves in this study represent a subset of data used in a δ13C chemostratigraphic curve at Bentiaba (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a). Marine bivalves throughout the section were sampled for stable isotope chemostratigraphy. Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a) tested inoceramid shells for diagenetic alteration by visual examination with binocular microscope and by scanning electron microscopy (SEM). Additional tests for alteration were performed by electron dispersive spectroscopy (EDS) and X-ray diffraction. Only samples of inoceramids with intact calcite prisms were used to estimate paleotemperatures in this study. Samples altered to dolomite were rejected, and stable oxygen isotope values from non-inoceramid bivalves were not used in this study, as these samples were not examined for diagenetic alteration in detail.

Twenty-four inoceramid shells were powdered with a carbide drill near the hinge where the shell is thickest to develop δ13C and δ18O chemostratigraphic curves. These powder samples were vacuum-sealed in vessels and reacted with 100% orthophosphoric acid. Calcite reactions were performed in a 25°C bath for at least 4 hours and dolomite was reacted at 50°C for at least 24 hours. The resulting carbon dioxide gas was cryogenically purified and analysed in a Finnigan MAT 252 mass spectrometer with a precision of 0.1‰.

The δ18O values were used to produce an oxygen isotope chemostratigraphic curve for Bentiaba that was then compared to δ18O compilations from the South Atlantic at Walvis Ridge and from the Pacific Ocean (Friedrich et al., Reference Friedrich, Norris and Erbacher2012). Paleotemperatures (T) were estimated using the calcite-temperature equation of Kim & O’Neil (Reference Kim and O’Neil1997):

$${\rm{1000ln}}\alpha _{{\rm{calcite - water}}} {\rm{ = 18}}{\rm{.03(10}}^{\rm{3}} T^{{\rm{ - 1}}} {\rm{)}}-{\rm{32}}{\rm{.42}}$$

where α calcite-water represents the calcite–water fractionation factor.

Results

The results of the stable oxygen isotopic analysis for 14 calcite shells and 10 additional samples that were altered to dolomite are shown in Table 1. The δ18O values of calcite samples range between –3.2‰ and –0.8‰, with an average value of –1.6‰. These values and those for shells altered to dolomite are plotted in Fig. 2 against stratigraphy and the δ13C chemostratigraphic and paleomagnetic data from Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a). The resulting pattern in stable oxygen isotopes of calcite shows a general trend of increasing δ18O values up section. A positive ∼2‰ excursion in the uppermost Salinas Formation to Lower Baba Formation results from values of –3.2‰, –2.1‰ and –1.2‰ derived from shells recovered at 57, 67 and 69.5 m, respectively. Between 71 and 81 m, δ18O values remain relatively constant, ranging between –1.4 and –1.9‰. The maximum values of –0.8‰ and –0.9‰ are from shells collected at 108 m and 110.5 m. A positive 0.5‰ shift is observed in inoceramids recovered at the base of the Mocuio Formation, at 116 m, and remain between –1.2‰ and –1.8‰ to 128 m.

Table 1. Stable isotope values of inoceramid shells for the Bentiaba δ18O stratigraphy. Paleotemperature calculated using calcite–temperature equation of Kim & O’Neil (Reference Kim and O’Neil1997).

Discussion and conclusions

The pattern of δ18O from inoceramids at Bentiaba is similar to those known from benthic foraminifera from the Pacific Ocean, albeit with a negative ∼1‰ offset (Fig. 3). This suggests that the oxygen isotope stratigraphy at Bentiaba tracks declining global temperatures beginning in the Late Turonian, concurrent with a deep ocean connection in the equatorial Atlantic. A δ18O value of –3.2‰ derived from inoceramids at Bentiaba coincides with depleted values during the Late Turonian from benthic foraminifera in the Pacific and Inoceramus at Walvis Ridge. Values decrease ∼2‰ by the Late Campanian, similar to the decrease observed at Walvis Ridge (Barron et al., Reference Barron, Saltzman and Price1984). In the Late Campanian, fluctuations of less than 1‰ in δ18O at Bentiaba may reflect smaller variability in temperature or effects of salinity superimposed on a warming interval observed globally. Similar fluctuations in δ18O values are also observed near the same time interval at the Walvis Ridge (Barron et al., Reference Barron, Saltzman and Price1984).

Fig. 3. Comparison of Bentiaba δ18O stratigraphy to Inoceramus (Barron et al., Reference Barron, Saltzman and Price1984) and benthic foraminifera (Li & Keller, Reference Li and Keller1998; Friedrich et al., Reference Friedrich, Norris and Erbacher2012) from Walvis Ridge and the Pacific Ocean compilation (Friedrich et al., Reference Friedrich, Norris and Erbacher2012; their supplemental). Figure is as follows left to right: Bentiaba section with stable oxygen- and magnetostratigraphy, Bentiaba δ18O curve calibrated with δ13C (horizontal shaded areas) and paleomagnetic (dashed lines) correlations from Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a), Walvis Ridge and Pacific δ18O curves.

Bentiaba δ18O values indicate a similar pattern to global values from the Turonian through the Late Campanian (Fig. 3) during a time when the shallow marine environment at Bentiaba became increasingly confined, possibly due to falling sea levels during the Campanian, indicated by dolomitisation of inoceramids at two stratigraphic levels in the Bentiaba section during the Late Campanian and Early Maastrichtian (Warren, Reference Warren2000; Friedrich et al., Reference Friedrich, Herrle, Wilson, Cooper, Erbacher and Hemleben2009; Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a). While these conditions may seem to support higher evaporation rates and high salinities, the relatively depleted values at Bentiaba, offset by negative ∼1‰ from deep ocean values, does not support this. Barron et al. (Reference Barron, Saltzman and Price1984) predicted that the enrichment in δ18O at Walvis Ridge in the Campanian was the result of dense saline waters originating from shallow seas from Africa, which our results also do not support. Depleted δ18O values may result from meteoric input, but Bentiaba was within the arid latitudes (∼24°S) and the sedimentary textures, mineralogy and sources suggest low meteoric input (Strganac et al., Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014b).

At Bentiaba, a Late Turonian paleotemperature estimate from calcite is ∼25°C. In the earliest Campanian the estimated paleotemperatures decrease to 15–18°C, similar to that estimated for the Australian Pacific (Friedrich et al., Reference Friedrich, Norris and Erbacher2012). By the Late Campanian–earliest Maastrichtian, Bentiaba paleotemperatures remain approximately the same, 16–19°C, whereas temperatures in the Pacific and Walvis Ridge have decreased to ∼10°C. Assuming a constant ocean δ18O value during the Cretaceous, the change in δ18O values from –3.2 to –1.2‰ observed at Bentiaba corresponds to a ∼10° temperature decrease from the Late Turonian to Early Maastrichtian, similar to temperature changes inferred from oxygen isotopes derived from deep sea benthic foraminifera in the Pacific Ocean and Southern Ocean (Clarke & Jenkyns, Reference Clarke and Jenkyns1999; Cramer et al., Reference Cramer, Toggweiler, Wright, Katz and Miller2009; Friedrich et al., Reference Friedrich, Herrle, Wilson, Cooper, Erbacher and Hemleben2009, Reference Friedrich, Norris and Erbacher2012).

Mosasaurs are known from Angola from the Late Turonian at Iembe to the Maastrichtian at Bentiaba (Fig. 1), during a trend of declining sea temperature implied by the Bentiaba stable oxygen isotope curve. During the Turonian, temperatures at Bentiaba ranged from ∼22.4 to 25.3°C (Table 1). The temperature calculated from δ18O values at the lowest amniote fossils at Bentiaba (Baba Formation, Chron C33n, approximately 75 Ma) is 16.7°C. The temperature estimate for Chron C32n2n (approximately 73 Ma), within the Baba Formation, which contains indeterminate russellosaurian and mosasaurine mosasaur fossils, is 19.0°C. The estimate for the mosasaurs and plesiosaurs in the Mocuio Formation, higher in Chron C32n2n at 72.8 Ma, is 13.9°C, reflecting a relatively rapid drop in temperature. The mosasaurine-dominated Bench 19 Fauna was recovered from sediments dated to Chron C32n1n, about 71.5 Ma, which directly overlies a sampled interval that indicate temperatures of ∼18.5°C.

Examination of the δ13C curve presented in Strganac et al. (Reference Strganac, Jacobs, Ferguson, Polcyn, Mateus, Schulp, Morais, Tavares and Gonçalves2014a) shows declining, but relatively stable, values during deposition of the Baba Formation, but within the lower part of the Mocuio Formation a sharp negative excursion of ∼3‰ in δ13C values occurs with a recovery of equal magnitude coincident with the onset of the bench-forming depositional regime. This negative excursion is correlated with global patterns interpreted as the Campanian–Maastrichtian Boundary Events (tie points 9a and 8 sensu Voigt et al., Reference Voigt, Gale, Jung and Jenkyns2012), but the precipitous recovery (tie point 7), coincident with the base of Bench 19, appears strongest in the South Atlantic Ocean observed in foraminifera from the Walvis Ridge and Bentiaba, and thus may reflect increased localised primary productivity for this time, which may account at least in part for the large number of marine amniotes in this part of the section.

Mosasaurs originated in relatively low latitudes during the high temperatures of the Cenomanian (Polcyn et al., Reference Polcyn, Tchernov and Jacobs1999; Jacobs et al., Reference Jacobs, Ferguson, Polcyn and Rennison2005a,Reference Jacobs, Polcyn, Taylor and Fergusonb; Bardet et al., Reference Bardet, Houssaye, Rage and Superbiola2008). Before the end of the Cretaceous they occupied waters from the Antarctic to the tropics and into the northern high temperate latitudes. Their dispersal across the globe is accompanied by an increase in size and morphological disparity (Polcyn et al., Reference Polcyn, Jacobs, Araújo, Schulp and Mateus2014), and by the acquisition and maintenance of high body temperature (Bernard et al., Reference Bernard, Lécuyer, Vincent, Amiot, Bardet, Buffetaut, Cuny, Fourel, Martineau, Mazin and Prieur2010), reasonably considered in this case as an adaptation to colder water temperatures, especially in high latitudes. In addition, skin pigmentation preserved in exceptional specimens indicates dark colouration, which has been suggested to be an aid in thermoregulation (Lindgren et al., Reference Lindgren, Sjövall, Carney, Uvdal, Gren, Dyke, Schultz, Shawkey, Barnes and Polcyn2014). In this study we have seen temperature decrease in waters throughout most of the Late Cretaceous Period in one region along the Angola coast continuously inhabited by mosasaurs.

Acknowledgements

This publication results from Projecto PaleoAngola, an international cooperative research effort among the contributing authors and their institutions, funded by the National Geographic Society, the Petroleum Research Fund of the American Chemical Society, Sonangol EP, Esso Angola, Fundação Vida of Angola, LS Films, Maersk, Damco, Safmarine, ISEM at SMU, the Royal Dutch Embassy in Luanda, TAP Airlines, Royal Dutch Airlines and the Saurus Institute. We thank Margarida Ventura and André Buta Neto for providing our team with help in the field. Tako and Henriette Koning provided valuable support and friendship in Angola.

References

Arthur, M.A., Dean, W.E. & Pratt, L.M., 1988. Geochemical and climatic effects of increased marine organic carbon burial at the Cenomanian/Turonian boundary. Nature 35: 714717.CrossRefGoogle Scholar
Bardet, N., Houssaye, A., Rage, J-C. & Superbiola, X.P., 2008. The Cenomanian–Turonian (Late Cretaceous) radiation of marine squamates (Reptilia): the role of the Mediterranean Tethys. Bulletin de la Société Géologique de France 179 6: 605622.CrossRefGoogle Scholar
Barron, E.J., Saltzman, E. & Price, D.A., 1984. Occurrence of Inoceramus in the South Atlantic and oxygen isotope paleotemperatures in Hole 530A. Initial Reports DSDP 75: 893904.Google Scholar
Bernard, A., Lécuyer, C., Vincent, P., Amiot, R., Bardet, N., Buffetaut, E., Cuny, G., Fourel, F., Martineau, F., Mazin, J.-M. & Prieur, A., 2010. Regulation of body temperature by some Mesozoic marine reptiles. Science 328: 13791382.CrossRefGoogle ScholarPubMed
Cahen, L., Ferrand, J.J., Haarsma, M.J.F., Lepersonne, J. & Verbeek, T., 1959. Description du Sondage de Samba. Annales du Musée royal du Congo Belge, Tervuren (Belgique). Série in-8°. Sciences Géologiques 29: 1210.Google Scholar
Clarke, L.J. & Jenkyns, H.C., 1999. New oxygen isotope evidence for long-term Cretaceous climatic change in the Southern Hemisphere. Geology 27: 699702.2.3.CO;2>CrossRefGoogle Scholar
Cramer, B.S., Toggweiler, J.R., Wright, J.D., Katz, M.E. & Miller, K.G., 2009. Ocean overturning since the Late Cretaceous: Inferences from a new foraminiferal isotope compilation. Paleoceanography 24: PA4216. doi:10.1029/2008PA001683.CrossRefGoogle Scholar
Erbacher, J., Huber, B.T., Norris, R.D. & Markey, M., 2001. Increased thermohaline stratification as a possible cause for an ocean anoxic even in the Cretaceous period. Nature 409: 325327.CrossRefGoogle Scholar
Forster, A., Kuypers, M.M.M., Turgeon, S.C., Brumsack, H-J., Petrizzo, M.R. & Sinninghe Damsté, J.S., 2008. The Cenomanian/Turonian oceanic anoxic event in the South Atlantic: New insights from a geochemical study of DSDP Site 530A. Palaeogeography, Palaeoclimatology, Palaeoecology 267: 256283.CrossRefGoogle Scholar
Friedrich, O., Herrle, J.O., Wilson, P.A., Cooper, M.J., Erbacher, J. & Hemleben, C., 2009. Early Maastrichtian carbon cycle perturbation and cooling event: Implications from the South Atlantic Ocean. Paleoceanography 24: PA2211. doi:10.1029/2008PA001654.CrossRefGoogle Scholar
Friedrich, O., Norris, R.D. & Erbacher, J., 2012. Evolution of middle to Late Cretaceous oceans-A 55 m.y. record of Earth’s temperature and carbon cycle. Geology 40(2): 107110.CrossRefGoogle Scholar
Grossman, E.L., 2012. Chapter 10: Oxygen Isotopes. In: Gradstein, F.M., Ogg, J.G., Schmitz, M. & Ogg, G. (eds): The Geologic Time Scale 2012. Elsevier (Amsterdam).Google Scholar
Hay, W.W., DeConto, R.M., Wold, C.N., Wilson, K.M., Voigt, S., Schultz, M., Wold, A.R., Dullo, W.-C., Ronov, A.B., Balukhovsky, A.N. & Söding, E., 1999. Alternative global Cretaceous paleogeography. In: Barrera, E. & Johnson, C.C. (eds): Evolution of the Cretaceous Ocean-Climate system. Geological Society of America Special Paper 332: 147.Google Scholar
Jacobs, L.L., Ferguson, K., Polcyn, M.J. & Rennison, C., 2005a. Cretaceous δ13C stratigraphy and the age of dolichosaurs and early mosasaurs. Netherlands Journal of Geosciences 84: 257268.CrossRefGoogle Scholar
Jacobs, L.L., Polcyn, M.J., Taylor, L.H. & Ferguson, K. 2005b. Sea-surface temperatures and palaeoenvironments of dolichosaurs and early mosasaurs. Netherlands Journal of Geosciences 84: 269281.CrossRefGoogle Scholar
Jacobs, L.L., Mateus, O., Polcyn, M.J., Schulp, A.S., Antunes, M.T., Morais, M.L. & Tavares, T. da S., 2006. The occurrence and geological setting of Cretaceous dinosaurs, mosasaurs, plesiosaurs, and turtles from Angola. Journal of the Paleontological Society of Korea 22(1): 91110.Google Scholar
Jacobs, L.L., Mateus, O., Polcyn, M.J., Schulp, A.S., Scotese, C.R., Goswami, A., Ferguson, K.M., Robbins, J.A., Vineyard, D.P. & Neto, A.B., 2009. Cretaceous paleogeography, paleoclimatology, and amniote biogeography of the low and mid-latitude South Atlantic Ocean. Bulletin of the Geological Society of France 180(4): 333341.CrossRefGoogle Scholar
Jacobs, L.L., Strganac, C. & Scotese, C.R., 2011. Plate motions, Gondwana dinosaurs, Noah’s Arks, Ghost Ships, and Beached Viking Funeral Ships. Anais da Academia Brasileira de Ciências 83(1): 322.CrossRefGoogle ScholarPubMed
Kim, S.T. & O’Neil, J.R., 1997. Equilibrium and nonequilibrium oxygen isotope effects in synthetic carbonates. Geochimica et Cosmochimica Acta 61(16): 34613475.CrossRefGoogle Scholar
Kolodny, Y. & Luz, B., 1991. Oxygen isotopes in phosphates of fossil fish – Devonian to Recent. In: Taylor, H.P. Jr., O’Neil, J.R. & Kaplan, I.R. (eds): Stable Isotope Geochemistry: A Tribute to Samuel Epstein. The Geochemical Society, Special Paper 3: 105119.Google Scholar
Li, L. & Keller, G., 1998. Maastrichtian climate, productivity and faunal turnovers in planktic foraminifera in South Atlantic DSDP sites 525 and 21. Marine Micropaleontology 33: 5586.CrossRefGoogle Scholar
Lindgren, J., Sjövall, P., Carney, R.M., Uvdal, P., Gren, J.A., Dyke, G., Schultz, B.P., Shawkey, M.D., Barnes, K.R. & Polcyn, M.J., 2014. Skin pigmentation provides evidence of convergent melanism in extinct marine reptiles. Nature 506: 484488.CrossRefGoogle ScholarPubMed
Mateus, O., Jacobs, L.L., Polcyn, M.J., Schulp, A.S., Vineyard, D.P., Antunes, M.T. & Neto, A.B., 2009. The oldest African eucryptodiran turtle from the Cretaceous of Angola. Acta Paleontologica Polonica 54: 581588.CrossRefGoogle Scholar
Mateus, O., Jacobs, L.L., Schulp, A.S., Polcyn, M.J., Tavares, T.S., Neto, A.B., Morais, M.L. & Antunes, M.T., 2011. Angolatitan adamastor, a new sauropod dinosaur and the first record from Angola. Anais da Academia Brasileira de Ciências 83(1): 221233.CrossRefGoogle ScholarPubMed
Mateus, O., Polcyn, M.J., Jacobs, L.L., Araújo, R., Schulp, A.S., Marinheiro, J., Oereira, B. & Vineyard, D., 2012. Cretaceous amniotes from Angola: Dinosaurs, pterosaurs, mosasaurs, plesiosaurs, and turtles. V Jornadas Internacionales sobre Paleontología de Dinosaurios y su Entorno 75105.Google Scholar
Miller, K.G., Barrera, E., Olsson, R.K., Sugarman, P.J. & Savin, S.M., 1999. Does ice drive early Maastrichtian eustacy? Geology 27(9): 783786.2.3.CO;2>CrossRefGoogle Scholar
Myers, T.S., Tabor, N.J. & Jacobs, L.L., 2011. Late Jurassic paleoclimate of central Africa. Palaeogeography, Palaeoclimatology, Palaeoecology 311: 111125.CrossRefGoogle Scholar
Myers, T.S., Tabor, N.J., Jacobs, L.L. & Mateus, O., 2012. Estimating soil pCO2 using paleosol carbonates: Implications for the relationship between primary productivity and faunal richness in ancient terrestrial ecosystems. Paleobiology 38(4): 585604.CrossRefGoogle Scholar
Polcyn, M.J., Tchernov, E. & Jacobs, L.L., 1999. The Cretaceous biogeography of the eastern Mediterranean with a description of a new basal mosasauroid from ‘Ein Yabrud, Israel. National Science Museum, Tokyo, Monograph 15: 259290.Google Scholar
Polcyn, M.J., Jacobs, L.L., Schulp, A.S. & Mateus, O., 2010. The North African mosasaur Globidens phosphaticus from the Maastrichtian of Angola. Historical Biology 22(13): 175185.CrossRefGoogle Scholar
Polcyn, M.J., Lindgren, J., Bardet, N., Cornelissen, D., Verding, L. & Schulp, A.S., 2012. Description of new specimens of Halisaurus arambourgi Bardet & Pereda Superbiola, 2005 and the relationships of Halisaurinae. Bulletin of the Geological Society of France 183(2): 123136.CrossRefGoogle Scholar
Polcyn, M.J., Jacobs, L.L., Araújo, R., Schulp, A.S. & Mateus, O., 2014. Physical drivers of mosasaur evolution, Palaeogeography, Palaeoclimatology, Palaeoecology 400: 1727. http://dx.doi.org/10.1016/j.palaeo.2013.05.018.CrossRefGoogle Scholar
Pucéat, E., Lécuyer, C, Donnadieu, Y., Naveau, P., Cappetta, H., Ramstein, G., Huber, B.T. & Kriwet, J., 2007. Fish tooth 18O revising Late Cretaceous meridional upper ocean water temperature gradients. Geology 35: 107110.CrossRefGoogle Scholar
Robbins, J., Ferguson, K., Polcyn, M. & Jacobs, L.L, 2008. Application of stable carbon isotope analysis to mosasaur ecology. In: Everhart, M.J. (ed.): Proceedings of the Second Mosasaur Meeting, Fort Hays Studies Special Issue 3, Fort Hays State University (Hays, KS): 123130.Google Scholar
Robinson, S.A. & Vance, D., 2012. Widespread and synchronous change in deep-ocean circulation in the North and South Atlantic during the Cretaceous. Paleoceanography 27. doi :10.1029/2011PA002240.CrossRefGoogle Scholar
Schulp, A.S., Polcyn, M.J., Mateus, O., Jacobs, L.L., Morais, M.L. & Tavares, T. da S., 2006. New mosasaur material from the Maastrichtian of Angola, with notes on the phylogeny, distribution and paleoecology of the genus Prognathodon . Maastricht, Publicaties van het Natuurhistorisch Genootschap in Limburg 45(1): 5767.Google Scholar
Schulp, A.S., Polcyn, M.J., Mateus, O., Jacobs, L.L. & Morais, M.L., 2008. A new species of Prognathodon (Squamata, Mosasauridae) from the Maastrichtian of Angola, and the affinities of the mosasaur genus Liodon . In: Everhart, M.J. (ed.): Proceedings of the Second Mosasaur Meeting, Fort Hays Studies Special Issue 3, Fort Hays State University (Hays, KS): 112.Google Scholar
Schulp, A.S., Polcyn, M.J., Mateus, O. & Jacobs, L.L., 2013. Two rare mosasaurs from the Maastrichtian of Angola and the Netherlands. Netherlands Journal of Geosciences 92(1): 310.CrossRefGoogle Scholar
Sessa, J.A., Ivany, L.C., Schlossnagle, T.H., Samson, S.D. & Schellenberg, S.A., 2012. The fidelity of oxygen and strontium isotope values from shallow shelf settings: Implications for temperature and age reconstructions. Palaeogeography, Palaeoclimatology, Palaeoecology 342-343: 2739.CrossRefGoogle Scholar
Strganac, C., Jacobs, L.L., Ferguson, K.M., Polcyn, M.J., Mateus, O., Schulp, A.S., Morais, M.L., Tavares, T. da S. & Gonçalves, A.O., 2014a. Carbon isotope stratigraphy, magnetostratigraphy, and 40Ar/39Ar age of the Cretaceous South Atlantic coast, Namibe Basin, Angola. Journal of African Earth Sciences 99: 452462.CrossRefGoogle Scholar
Strganac, C., Jacobs, L.L., Ferguson, K.M., Polcyn, M.J., Mateus, O., Schulp, A.S., Morais, M.L., Tavares, T. da S. & Gonçalves, A.O., 2014b. Geological setting and paleoecology of the Upper Cretaceous Bench 19 Marine Vertebrate Bonebed at Bentiaba, Angola. Netherlands Journal of Geosciences – Geologie en Mijnbouw. Available on CJO 2014 doi:10.1017/njg.2014.32.Google Scholar
Voigt, S., Gale, S.G., Jung, C. & Jenkyns, H.C., 2012. Global correlation of Upper Campanian–Maastrichtian successions using carbon-isotope stratigraphy: development of a new Maastrichtian timescale. Newsletters on Stratigraphy 45(1): 2553.CrossRefGoogle Scholar
Warren, J., 2000. Dolomite: occurrence, evolution and economically important associations. Earth Science Reviews (52): 181.CrossRefGoogle Scholar
Figure 0

Fig. 1. Location map of Bentiaba, Angola. Inset shows location of Angola within Africa, offshore basins labelled in capital letters. Note location of DSDP Hole 530A, which is discussed in the text. Modified from Strganac et al. (2014a).

Figure 1

Fig. 2. Section at Bentiaba with δ13C and inoceramid δ18O stratigraphic curves. Red bones and ‘19’ indicate marine amniote-bearing horizons and Bench 19. Note that the δ13C curve is composite of inoceramid and other bivalve data in Strganac et al. (2014a).

Figure 2

Table 1. Stable isotope values of inoceramid shells for the Bentiaba δ18O stratigraphy. Paleotemperature calculated using calcite–temperature equation of Kim & O’Neil (1997).

Figure 3

Fig. 3. Comparison of Bentiaba δ18O stratigraphy to Inoceramus (Barron et al., 1984) and benthic foraminifera (Li & Keller, 1998; Friedrich et al., 2012) from Walvis Ridge and the Pacific Ocean compilation (Friedrich et al., 2012; their supplemental). Figure is as follows left to right: Bentiaba section with stable oxygen- and magnetostratigraphy, Bentiaba δ18O curve calibrated with δ13C (horizontal shaded areas) and paleomagnetic (dashed lines) correlations from Strganac et al. (2014a), Walvis Ridge and Pacific δ18O curves.