6533b859fe1ef96bd12b79ec
RESEARCH PRODUCT
Bone diagenesis in arid environments; An intra-skeletal approach
Anne-france MaurerAnne-france MaurerThomas TütkenSylvie Amblard-pisonLoïc SégalenLoïc SégalenAlain PersonAlain Personsubject
010506 paleontologyMineralogy[SDU.STU]Sciences of the Universe [physics]/Earth SciencesOceanography01 natural sciencesApatitechemistry.chemical_compound0601 history and archaeologyOrganic matterEcology Evolution Behavior and Systematics0105 earth and related environmental sciencesEarth-Surface Processeschemistry.chemical_classification060102 archaeologyEnamel paintStable isotope ratioBioerosionTrace elementPaleontology06 humanities and the artsDiagenesischemistryvisual_artvisual_art.visual_art_mediumCarbonateGeologydescription
Bone trace element content and isotopic composition are closely related to human nutrition. The investigation of archaeological bone geochemistry can help us to better understand the relationship between past populations and their environment alongside cultural practices as inferred from dietary reconstruction. However, dietary in- formation may be altered post-mortem by diagenetic processes in soil. In this study, bone mineralogy (Ca/P, sec- ondary minerals, organic matter content and bone apatite crystallinity), histology, element content (Mg, Na, F, Sr, Ba, Mn, Fe, La, Ce and U) and stable isotope composition (δ13Candδ18O carbonate) were investigated at the intra- individual scale in order to understand the effects of diagenesis on skeletons buried in different saharo-sahelian environments. Between 10 to 18 bone samples were taken from 4 Neolithic skeletons excavated in the Mauritanian Dhar Oualata and Nema and in the Daounas, Mali. Additionally, the enamel of two third molar teeth was also analysed from each skeleton for comparison with bone. The results show that the four skeletons, buried in the same desert climate area, all exhibited different degrees of diageneticmodification,relatedto localtaphonomic conditions. Highly drainedand periodically flooded environments generated substantial bone bacterial damage, low to moderate apatite crystallinity and secondary minerals in bone pores. Bone trace element content and isotopic composition were more diagenetically affected than in bones from skeletons buried in a drier environment, which display little bioerosion, high apatite crystallinity and the absence or late precipitation of secondary minerals in their bone pores. Intra-skeletal variability of the geochemical composition, and the comparison of geochemical data from bones and teeth, enables the approximation of ante-mortem bone trace element and stable isotope compositions using the best preserved bones from each skeleton
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2014-12-01 |