Printer Friendly

Rare earth elements (REEs) in vertebrate microremains from the upper Pridoli Ohesaare beds of Saaremaa Island, Estonia: geochemical clues to palaeoenvironment.


Rare earth element (REE) concentrations in biogenic apatites, including fossil bones, teeth and fish scales, have been used to infer palaeoseawater chemistry and redox conditions (e.g., Wright et al. 1987), to detect reworking of fossils (e.g., Trueman 1999; Suarez et al. 2010), and to accomplish or test palaeoenvironmental and palaeogeographic interpretations (e.g., Reynard et al. 1999; Trueman & Tuross 2002; Kemp & Trueman 2003; Lecuyer et al. 2004; Patrick et al. 2004; Ounis et al. 2008). This can be achieved since the major part of the REEs and other trace elements are incorporated in bioapatite post-mortem, directly from the bottom seawater and sediment pore water with little or no fractionation, usually within a few thousand years during early stages of diagenesis (Bernat 1975; Wright et al. 1984; Ederfield & Pagett 1986; Trueman & Tuross 2002; Kemp & Trueman 2003; Patrick et al. 2004; Tutken et al. 2008; Trueman et al. 2011). Bioapatites display REE patterns that are strictly similar to the seawater patterns, with an enrichment factor of about [10.sup.6] to [10.sup.7] , which is achieved through quantitative intake of REEs (with no associated fractionation) and is active as a rule for all biogenic phosphates at the seawater-sediment interface (Reynard et al. 1999). However, the preservation of this palaeoceanographic signal in marine vertebrate remains depends on the presence and extent of later, fractionated REE uptake during post-depositional recrystallization, or 'extensive diagenesis' (Reynard et al. 1999; Lecuyer et al. 2004). This late diagenetic effect is characterized by a strong middle REE (MREE) enrichment relative to light REEs (LREEs) and heavy REEs (HREEs). It leads to 'bell-shaped' patterns and is often explained as the effect of extensive re-crystallization (Lecuyer et al. 1998, 2004), which may no longer preserve early diagenetic REE signal reflecting depositional palaeoenvironment. Recently, Herwartz et al. (2011) have demonstrated that in most cases vertebrate bioapatite showed open system behaviour with respect to REE and Hf uptake, which would compromise the REEs as a tool for palaeoenvironmental reconstructions (Herwartz et al. 2013a), as well as for [sup.176]Lu-[sup.176]Hf radiometric dating (Herwartz et al. 2013b). However, these studies are based on vertebrate long bones, such as femura, humerus or ribs, which are composed of fine, nanometre-size plate-like crystallites and contain, with a large surface/volume ratio and significant amount, up to 20% organic phase and 5-10% water (Kohn et al. 1999; Enax et al. 2012). A large surface area to volume ratio of bone and dentine crystallites facilitates both the adsorption of REEs, and the substitution of original (primary) biomineral (e.g., Trueman 1999; Herwartz et al. 2013a). In our work, we use fossil bioapatite of dental tissues, such as enamel and enameloid, which is composed of compact and large crystallite (micrometre-sized) biomineral with as little as 1 wt% organic matter (Kohn et al. 1999; Sire et al. 2009; Enax et al. 2012) and in contrast to long bones, demonstrated high potential to preserve an early REE signal (Trueman & Palmer 1997; Kohn et al. 1999; Kemp & Trueman 2003; Trotter & Eggins 2006; Tutken et al. 2008; Trueman et al. 2011). Given the above, REE concentrations can serve as a record of depositional or early diagenetic conditions only as long as it is demonstrated that the later contribution of REEs such as from diagenetic pore fluids, is relatively minor (e.g., Reynard et al. 1999; Trueman 1999; Patrick et al. 2004) and the histology and crystallinity of fossil remains are taken into account (Zigaite et al. 2013; Fadel et al. 2015).

The aim of this work is to test the potential of REE compositions of vertebrate microremains from Ohesaare beds as a source of geochemical information and proxy to early depositional palaeoenvironment. Ohesaare is a famous fish locality, known already since the pioneering work by C. Pander in 1856, who described shields of the heterostracan Tolypelepis undulata, plates of the osteichthyan Lophosteus superbus and a number of jaw bones of acanthodians (Pander 1856). In addition to well-preserved macroscopic vertebrate remains, the dermoskeleton microremains of a number of squamate early vertebrate species are extremely abundant in Ohesaare and form bone beds in several levels of the section (Nestor 1990; Marss & Nestor 2014). Scales and spines of different morphological groups and variable histologies of the genus Nostolepis have been selected for this purpose in order to compare data from fossil apatite biomineral of different hard tissue structure and crystallinity, while avoiding any potential intertaxonomic bias.

Ohesaare beds represent the youngest Silurian sedimentary rocks in the entire Baltic area. Saaremaa was part of the Baltic palaeobasin in the Silurian, located in equatorial latitudes (Cocks & Torsvik 2005), and represents a wide range of tropical shelf environments with the accumulation of various calcareous deposits and occurrence of rich and diverse biotas (e.g., Nestor & Einasto 1997; Hints et al. 2008; Mannik 2014). Diverse and rich benthic fauna and intense bioturbations in the Ohesaare section indicate shallow nearshore environments. The presence of such trace fossils as Cruziana and Skolithos has led to interpretations that this part of the basin presumably had high hydrodynamic energy (Vinn & Wilson 2013; Vinn 2014). In this work we present results of the first REE analyses from fish microremains of this important early vertebrate site and the first quantitative interpretations of the REE data record as a proxy to palaeoredox conditions and palaeoenvironment.


The Ohesaare cliff section (Fig. 1) is one of the most famous and fossiliferous Palaeozoic localities in Estonia and is part of the Ohesaare Formation, Ohesaare Regional Stage. The presence of the conodont Ozarkodina remscheidensis allows us to correlate the Ohesaare Stage with the upper Pridoli and the following Oulodus elegans detortus conodont Biozone identifies it as the youngest Upper Silurian sequence in Estonia (Marss & Mannik 2013; Mannik 2014). It represents a carbonate platform succession of the high-energy open shoal and open shelf facies belts, characterized by intercalated thin-bedded limestones and marlstones formed during a considerable shallowing event (Hints et al. 2008; Vinn & Wilson 2013). These strata are rich in fossils, including macro- and microremains of agnathans and fishes, conodonts, diverse shelly fauna and associations of invertebrate microfossils, with intense bioturbation and Skolithos trace fossils (Nestor 1990; Vinn & Wilson 2013; Marss & Nestor 2014), altogether indicating shallowwater environment.



Nostolepis sp. body scales, spines, coronate plates and stellate tesserae were selected from samples collected in situ from the lower part of the Ohesaare cliff sequence. Nostolepis spines, corronated plates, stellated tesserae and body scales were chosen for geochemical analyses, in order to cover the largest variability of bioapatite tissue histologies and morphological variety of microremains. Acetic acid preparation of the samples was carried out at the Department of Earth Sciences of Lund University, Sweden. Extraction of the microremains and mechanical preparation of each scale for geochemical analyses was performed at the Department of Earth Sciences and the Department of Organismal Biology (Uppsala University, Sweden) and at the Imaging and Analysis Center (Natural History Museum of London, UK). The elemental compositions were obtained by Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) at the Imaging and Analysis Center of Science Facilities Department, Natural History Museum, London (UK). The LA-ICP-MS technique is widely used to determine in situ mineral elemental compositions and offers the necessary high spatial resolution enabling the analysis of REE and trace element compositions of micromeric scales in situ at a separate tissue level. Analyses were performed using a New Wave Research NWR193FX excimer laser ablation accessory coupled to an Agilent Technologies 7500s ICP-MS with an enhanced sensitivity S-option interface. Data were acquired for 120 s at each analysis site, taking individual points in different scale tissue regions (dentine or enameloid). Background signals were collected for the first ca 60 s and the laser was fired at the sample to collect sample signals for the remaining acquisition time. Data were collected using the time-resolved method and processed offline using LAMTRACE software (Simon Jackson, Macquarie University, Sydney). Elemental concentrations were calculated using the National Institute of Standards and Technology (NIST) standard reference material 612 for calibration and calcium was used for internal standardization. The limit of detection was taken as 1o of the mean background count and the data were filtered at twice this limit (2[sigma]). The calculated precision was better than 3% RSD (at 1o error) when using [sup.43]Ca as internal standard. The REE concentrations obtained were normalized to Post-Archean Australian Shale (PAAS) concentrations (LA-ICP-MS) of McLennan (1989). The obtained in situ REE compositions are explored below using basic geochemical calculations and quantifications in order to determine early burial palaeoenvironmental conditions. The analytical methods used in this study are similar to those used in Fadel et al. (2015).


The shale-normalized REE patterns are nearly identical across all the morphotypes and histologies of Nostolepis scales and spines analysed and have relatively flat (unfractionated) shapes with slight depletion in HREEs (Fig. 2A-D). Low concentrations of HREEs are attributed to coastal or marginal marine environments, as opposed to the characteristic HREE-enriched profiles of the open ocean seawater (see Patrick et al. 2004). There is no visible enrichment in MREE ('bell-shaped' patterns), which suggests good preservation of the 'early' REE signal, with major REE incorporation mainly via adsorption mechanism and during early stages of diagenesis (Trueman & Tuross 2002; Lecuyer et al. 2004). The shale-normalized compilation diagram of [(La/Yb).sub.SN] and [(La/Sm).sub.SN] REE ratios defined by Reynard et al. (1999) equally suggests the REE incorporation predominantly occurred via adsorption (Fig. 3) as opposed to 'late' or 'extensive' diagenesis, where REE uptake is prevailed by substitution mechanism and re-crystallization of bioapatite. The [(La/Yb).sub.SN] and [(La/Sm).sub.SN] ratio compilation results are also very similar across all the scales and spines analysed, both between the separate scale species and between different histologies within a single scale, tessera or spine. The average [(La/Sm).sub.SN] ratio of all the Nostolepis microremains is 0.73, with 0.81 average ratio for spines, 0.67 for coronate plates, 0.63 for body scales and 0.69 for stellate tesserae all largely exceeding 0.3 and corresponding to early (unfractionated) REE uptake as defined by Lecuyer et al. (2004). The observed slightly higher [(La/Sm).sub.SN] ratio in the Nostolepis spines also implies their better geochemical preservation, which can be explained by the spine histology of particularly compact dentine biomineral (Valiukevicius & Burrow 2005).

Based on the 'early' REE record preservation concluded above, we have calculated and plotted the shale-normalized anomalies of cerium [(Ce/[Ce.sup.*]).sub.SN] and praseodymium [(Pr/[Pr.sup.*]).sub.SN] in an attempt to reveal the prevailing redox conditions (after Bau & Dulski 1996). The presence of Ce anomaly in fossil bioapatite REE record of 'weak' or 'early' diagenesis can define the bottom seawater and/or sediment pore water anoxia of marine palaeobasins (see Kemp & Trueman 2003). In the case of rapid sedimentation rates, such as the majority of marginal marine environments, the REE uptake is at large affected by REEs derived from sediment pore waters. In modern shelf seas, sediments are commonly anoxic from within few centimetres of the sediment-water interface, and continued uptake of REEs within this anoxic region would tend to obscure any negative Ce anomaly (oxic conditions) inherited at the sediment water interface (Kemp & Trueman 2003). Therefore, negative Ce anomalies in marine fossil bioapatite REE record do suggest oxic conditions in the water column and upper pore waters, but the lack of negative Ce anomaly, or a positive Ce anomaly do not necessarily indicate seawater and/or bottom water anoxia.



In case of our data, there was no indication of Ce anomaly (Fig. 4). A few data points showed apparent positive Ce anomaly caused by a negative La anomaly (as defined by Bau & Dulski 1996), and one data point from the Nostolepis body scale showed a real positive Ce anomaly, likely reflecting pore water anoxia present in most of the depositional settings. These results indicate the absence of any pronounced palaeoseawater anoxia, suggesting oxic conditions, which in turn agrees with the existing sedimentological interpretations of Ohesaare bone beds representing high-energy shoal environment (Nestor 1990; Vinn & Wilson 2013; Vinn 2014).



Rare earth element compositions were nearly identical across all morphotypes and histologies of Nostolepis scales and spines analysed and showed flat (unfractionated) shale-normalized REE patterns with slight depletion in HREEs. No visible enrichment in MREEs indicated good geochemical preservation of bioapatite, with major REE uptake during the 'early' or 'weak' diagenesis likely via adsorption, with no pronounced fractionated REE incorporation during later stages of diagenesis. The shale-normalized [(La/Yb).sub.SN] and [(La/Sm).sub.SN] REE ratio compilation equally suggests that the REE uptake predominantly occurred via adsorption mechanism. There was no clearly defined Ce anomaly present in the analysed microremains, suggesting oxic seawater conditions, which does agree with sedimentological interpretations of Ohesaare beds referring to high-energy shoal palaeoenvironment.

doi: 10.3176/earth.2015.21

Acknowledgements. We would like to thank Git Klintvik Ahlberg (Lund University, Sweden) for acid preparation of the samples and Donglei Chen (Uppsala University, Sweden) for help with selection and identification of vertebrate microremains. We are grateful to Kevin Lepot (Universite Lille 1, France) and Lasclo Kocsis (University of Lausanne, Switzerland) for helpful discussions and advice and to the reviewers Rutt Hints and Kalle Kirsimae whose valuable comments improved the quality of the paper. This research has been funded by the Knut and Alice Wallenberg Foundation grant awarded to Per Erik Ahlberg (Uppsala University, Sweden). This work is also a contribution to the UNESCO and IUGS International Geosciences Programme project IGCP 591 'Early to Middle Palaeozoic Revolution'.


Bau, M. & Dulski, P. 1996. Distribution of yttrium and rare-earth elements in the Penge and Kuruman iron-formations, Transvaal Supergroup, South Africa. Precambrian Research, 79, 37-55.

Bernat, M. 1975. Les isotopes de l'uranium et du thorium et les terres rares dans l'environment marin. Cahiers OSTROM, Serie Geologique, 7, 65-83.

Cocks, L. R. M. & Torsvik, T. H. 2005. Baltica from the Late Precambrian to mid Palaeozoic: the gain and loss of a terrane's identity. Earth Science Reviews, 72, 39-66.

Ederfield, H. & Pagett, R. 1986. Rare earth elements in ichthyoliths: variations with redox conditions and depositional environment. Science of the Total Environment, 49, 175-197.

Enax, J., Prymak, O., Raabe, D. & Epple, M. 2012. Structure, composition, and mechanical properties of shark teeth. Journal of Structural Biology, 178, 290-299.

Fadel, A., Zigaite, Z., Blom, H., Perez-Huerta, A., Jeffries, T., Marss, T. & Ahlberg, P. E. 2015. Palaeoenvironmental signatures revealed from the rare earth element (REE) compositions of vertebrate microremains of the Vesiku Bone Bed (Homerian, Wenlock), Saaremaa Island, Estonia. Estonian Journal of Earth Sciences, 64, 36-41.

Herwartz, D., Tutken, T., Munker, C., Jochum, K. P., Stoll, B. & Sander, P. M. 2011. Rare earth element systematics of fossil bone revealed by LA-ICPMS analysis. Geochimica et Cosmochimica Acta, 75, 82-105.

Herwartz, D., Munker, C., Tutken, T., Hoffmann, J. E., Wittke, A. & Barbier, B. 2013a. Lu-Hf isotope systematics of fossil biogenic apatite and their effects on geochronology. Geochimica et Cosmochimica Acta, 101, 328-343.

Herwartz, D., Munker, C., Tutken, T., Hoffmann, J. E., Wittke, A., Barbier, B., Jochum, K. P. & Sander, P. M. 2013b. Rare earth element systematics of fossil bone revealed by LA-ICPMS analysis. Geochimica et Cosmochimica Acta, 103, 161-183.

Hints, O., Ainsaar, L., Mannik, P. & Meidla, T. (eds). 2008. The Seventh Baltic Stratigraphical Conference. Abstracts and Field Guide. Geological Society of Estonia, Tallinn, 46 pp.

Kemp, R. A. & Trueman, C. N. 2003. Rare earth elements in Solnhofen biogenic apatite: geochemical clues to the palaeoenvironment. Sedimentary Geology, 155, 109-127.

Kohn, M. J., Schoeninger, M. J. & Barker, W. W. 1999. Altered states: effects of diagenesis on fossil tooth chemistry. Geochimica et Cosmochimica Acta, 63, 2737-2747.

Lecuyer, C., Grandjean, P., Barrat, J.-A., Nolvak, J., Emig, C. C., Paris, F. & Robardet, M. 1998. S18O and REE contents of phosphatic brachiopods: a comparison between modern and lower Paleozoic populations. Geochimica et Cosmochimica Acta, 62, 2429-2436.

Lecuyer, C., Reynard, B. & Grandjean, P. 2004. Rare earth element evolution of Phanerozoic seawater recorded in biogenic apatites. Chemical Geology, 204, 64-102.

Mannik, P. 2014. The Silurian System of Estonia. In The 4th Annual Meeting of IGCP 591, The Early to Middle Palaeozoic Revolution, Field Guide (Bauert, H., Hints, O., Meidla, T. & Mannik, P., eds), pp. 123-128. Tartu.

Marss, T. & Mannik, P. 2013. Revision of Silurian vertebrate biozones and their correlation with the conodont succession. Estonian Journal of Earth Sciences, 62, 181-204.

Marss, T. & Nestor, V. 2014. Ohesaare cliff. In The 4th Annual Meeting of IGCP 591, The Early to Middle Palaeozoic Revolution, Field Guide (Bauert, H., Hints, O., Meidla, T. & Mannik, P., eds), pp. 200-201. Tartu.

McLennan, S. M. 1989. Rare earth elements in sedimentary rocks: influence of provenance and sedimentary processes. Reviews in Mineralogy and Geochemistry, 21, 169-200.

Nestor, H. 1990. Locality 7 : 4 Ohesaare cliff. In Field Meeting, Estonia 1990, An Excursion Guidebook (Kaljo, D. & Nestor, H., eds), pp. 175-178. Institute of Geology, Estonian Academy of Sciences, Tallinn.

Nestor, H. & Einasto, R. 1997. Ordovician and Silurian carbonate sedimentation basin. In Geology and Mineral Resources of Estonia (Raukas, A. & Teedumae, A., eds), pp. 192-204. Estonian Academy Publishers, Tallinn.

Ounis, A., Kocsis, L., Chaabani, F. & Pfeifer, H.-R. 2008. Rare earth elements and stable isotope geochemistry ([[delta].sup.13]C and [[delta].sup.18]O) of phosphorite deposits in the Gafsa Basin, Tunisia. Palaeogeography, Palaeoclimatology, Palaeoecology, 268, 1-18.

Pander, C. H. 1856. Monographie der fossilen Fische des silurischen Systems der russisch-baltischen Governments. Akademica Wissenschaft, St. Petersburg, 10, 1-91.

Patrick, D., Martin, J. E., Parris, D. C. & Grandstaff, D. E. 2004. Palaeoenvironmental interpretations of rare earth element signatures in mosasaurs (reptilian) from the upper Cretaceous Pierre Shale, central South Dakota, USA. Palaeogeography, Palaeoclimatology, Palaeoecology, 212, 277-294.

Reynard, B., Lecuyer, C. & Grandjean, P. 1999. Crystal-chemical controls on rare-earth element concentrations in fossil biogenic apatites and implications for paleoenvironmental reconstructions. Chemical Geology, 155, 233-241.

Sire, L.-Y., Donoghue, P. C. J. & Vickaryous, M. K. 2009. Origin and evolution of the integumentary skeleton in non-tetrapod vertebrates. Journal of Anatomy, 214, 409-440.

Suarez, C. A., Macpherson, G. L., Gonzalez, L. A. & Grandstaff, D. E. 2010. Heterogeneous rare earth element (REE) patterns and concentrations in a fossil bone: implications for the use of REE in vertebrate taphonomy and fossilization history. Geochimica et Cosmochimica Acta, 74, 2970-2988.

Trotter, J. A. & Eggins, S. M. 2006. Chemical systematic of conodont apatite determined by laser ablation. Chemical Geology, 233, 196-216.

Trueman, C. N. 1999. Rare earth element geochemistry and taphonomy of terrestrial vertebrate assemblages. PALAIOS, 14, 555-568.

Trueman, C. N. & Palmer, M. R. 1997. Diagenetic origin of REE in vertebrate apatite: a reconsideration of Samoilov and Benjamini, 1996. PALAIOS, 12, 495-497.

Trueman, C. N. & Tuross, N. 2002. Trace elements in recent and fossil bone apatite. In Phosphates: Geochemical, Geobiological, and Materials Importance (Kohn, M. L., Rakovan, J. & Hughes, J. M., eds), Reviews in Mineralogy and Geochemistry, 48, 489-522.

Trueman, C. N., Kocsis, L., Palmer, M. R. & Dewdney, C. 2011. Fractionation of rare earth elements within bone mineral: a natural cation exchange system. Palaeogeography, Palaeoclimatology, Palaeoecology, 310, 124-132.

Tutken, T., Vennemann, T. W. & Pfretzschner, H.-U. 2008. Early diagenesis of bone and tooth apatite in fluvial and marine settings: constraints from combined oxygen isotope, nitrogen and REE analysis. Palaeogeography, Palaeoclimatology, Palaeoecology, 266, 254-268.

Valiukevicius, J. & Burrow, C. 2005. Diversity of tissues in acanthodians with Nostolepis-type histological structure. Acta Palaeontologica Polonica, 50, 635-649.

Vinn, O. 2014. Cruziana traces from the Late Silurian (Pridoli) carbonate shelf of Saaremaa, Estonia. Estonian Journal of Earth Sciences, 63, 71-75.

Vinn, O. & Wilson, M. A. 2013. An event bed with abundant Skolithos burrows from the late Pridoli (Silurian) of Saaremaa (Estonia). Carnets de Geologie [Notebooks on Geology], Letter 02, 83-87.

Wright, J., Seymour, R. S. & Shaw, H. F. 1984. REE and Nd isotopes in conodont apatite: variations with geological age and depositional environment. In Conodont Biofacies and Provincialism (Clarck, D. L., ed.), Geological Society of America Special Paper, 196, 325-340.

Wright, J., Schrader, H. & Holster, W. T. 1987. Paleoredox variations in ancient oceans recorded by rare earth elements in fossil apatite. Geochimica et Cosmochimica Acta, 51, 631-644.

Zigaite, Z., Richter, M., Karatajutre-Talimaa, V. & Smith, M. M. 2013. Tissue diversity and evolutionary trends of the dermal skeleton of Silurian thelodonts. Historical Biology, 25, 143-154.

Received 16 July 2014, accepted 30 October 2014

Zivile Zigaite (a), Alexandre Fadel (a,b), Henning Blom (a), Alberto Perez- Huerta (c), Teresa Jeffries (d), Tiiu Marss (e) and Per Erik Ahlberg (a)

(a) Subdepartment of Evolution and Development, Department of Organismal Biology, Uppsala University, Norbyvagen 18A, 752 36 Uppsala, Sweden;

(b) Laboratoire Geosystemes, Universite Lille 1, CNRS UMR8217, Villeneuve d'Ascq 59655, France

(c) Department of Geological Sciences, University of Alabama, 2018 Bevill Building, Tuscaloosa, AL 35487, USA

(d) Earth Science Department, Imaging and Analysis Centre, The Natural History Museum, Cromwell Road, SW7 5BD London, UK

(e) Institute of Geology at Tallinn University of Technology, Ehitajate tee 5, 19086 Tallinn, Estonia
COPYRIGHT 2015 Estonian Academy Publishers
No portion of this article can be reproduced without the express written permission from the copyright holder.
Copyright 2015 Gale, Cengage Learning. All rights reserved.

Article Details
Printer friendly Cite/link Email Feedback
Author:Zigaite, Zivile; Fadel, Alexandre; Blom, Henning; Perez-Huerta, Alberto; Jeffries, Teresa; Marss, Ti
Publication:Estonian Journal of Earth Sciences
Article Type:Report
Geographic Code:4EXES
Date:Mar 1, 2015
Previous Article:Geochemical and palaeontological evidence for the definition of the Silurian/Devonian boundary in the Changwantang section, Guangxi province, China.
Next Article:An updated stratigraphic and environmental framework for the distribution of Silurian vertebrates on Gotland.

Terms of use | Copyright © 2017 Farlex, Inc. | Feedback | For webmasters