Phytoliths as an indicator of early modern humans plant gathering strategies, fire fuel and site occupation intensity during the Middle Stone Age at Pinnacle Point 5-6 (south coast, South Africa)

Esteban, Irene; Marean, Curtis W.; Fisher, Erich C.; Karkanas, Panagiotis; Cabanes, Dan; Albert, Rosa M.

doi:10.1371/journal.pone.0198558

Cited by 34 publications

(38 citation statements)

References 104 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, the simultaneous presence of biogenic aragonite from shells, which is a common component of the archaeological record at many sites across the globe, requires a spectroscopic approach able to distinguish between the two. This becomes especially apparent in the case of combustion features where aragonite may be present as a byproduct of high-temperature burning of fuel and as shell fragments embedded in the sedimentary matrix [51,52]. The same applies to aragonitic shells embedded in lime mortars [53].…”

Section: Aragonite In Heat-altered Sedimentsmentioning

confidence: 98%

FTIR-Based Crystallinity Assessment of Aragonite–Calcite Mixtures in Archaeological Lime Binders Altered by Diagenesis

et al. 2019

View full text Add to dashboard Cite

Lime plaster and mortar are pyrotechnological materials that have been employed in constructions since prehistoric times. They may nucleate as calcite and/or aragonite under different environmental settings. In nature, aragonite and calcite form through biogenic and geogenic processes that lead to different degrees of atomic order. The latter is a result of defects in the crystal lattice, which affect the properties of crystals, including their interaction with infrared light. Using Fourier transform infrared spectrometry (FTIR) with the KBr pellet method, it is possible to exploit these differences and assess the degree of atomic order of aragonite and calcite crystals and thus their mechanisms of formation. Here we use FTIR to characterize the degree of short-range atomic order of a pyrogenic form of aragonite recently observed in experimental and archaeological lime binders. We show that pyrogenic aragonite has a unique signature that allows its identification in archaeological sediments and lime binders of unknown origin. Based on these results, we developed a new FTIR-based method to assess the integrity and degree of preservation of aragonite and calcite when they occur together in the same material. This method allowed a better assessment of the diagenetic history of an archaeological plaster and finds application in the characterization of present-day conservation materials, such as lime plaster and mortar, where different polymorphs may nucleate and undergo recrystallization processes that can alter the mechanical properties of binders.

show abstract

Section: Aragonite In Heat-altered Sedimentsmentioning

confidence: 98%

FTIR-Based Crystallinity Assessment of Aragonite–Calcite Mixtures in Archaeological Lime Binders Altered by Diagenesis

et al. 2019

View full text Add to dashboard Cite

show abstract

“…(2) the percentage of fragile morphologies (Esteban et al 2018, and references therein); (3) the diversity of the phytolith assemblage (number of morphotypes identified; Madella and Lancelotti 2012); and (4) the percentage of broken grass silica short cell phytoliths (GSSCPs) bilobate for each unit. This method measures the strength and direction of the association between two ranked variables (phytolith concentration and the taphonomic indicators).…”

Section: Taphonomical Analysismentioning

confidence: 99%

New Excavations at Umhlatuzana Rockshelter, KwaZulu-Natal, South Africa: a Stratigraphic and Taphonomic Evaluation

et al. 2020

Self Cite

View full text Add to dashboard Cite

Umhlatuzana rockshelter has an occupation sequence spanning the last 70,000 years. It is one of the few sites with deposits covering the Middle to Later Stone Age transition (~40,000–30,000 years BP) in southern Africa. Comprehending the site’s depositional history and occupation sequence is thus important for the broader understanding of the development of Homo sapiens’ behavior. The rockshelter was first excavated in the 1980s by Jonathan Kaplan. He suggested that the integrity of the late Middle Stone Age and Later Stone Age sediments was compromised by large-scale sediment movement. In 2018, we initiated a high-resolution geoarchaeological study of the site to clarify the site formation processes. Here, we present the results of the excavation and propose a revised stratigraphic division of the Pleistocene sequence based on field observations, sedimentological (particle size) analyses, and cluster analysis. The taphonomy of the site is assessed through phytolith and geochemical (pH, loss on ignition, stable carbon isotope) analyses. The results indicate a consistent sedimentological environment characterized by in situ weathering. The analysis of the piece-plotted finds demonstrates semihorizontal layering of archaeologically dense zones and more sterile ones. There was no indication of large-scale postdepositional sediment movement. We show that the low-density archaeological horizons in the upper part of the Pleistocene sequence are best explained by the changing patterns of sedimentation rate.

show abstract

“…Weiner, Goldberg, and Bar‐Yosef (2002) tracked with FTIR the three‐dimensional distribution of aragonite within prehistoric sediments at Hayonim Cave, Israel, to exclude bone dissolution in places where aragonite was preserved but bones were not found. A similar approach was used at other prehistoric sites such as Kebara Cave, also located in Israel (Weiner et al, 2007), Grotte XVI in France (Karkanas, Rigaud, Simek, Albert, & Weiner, 2002), Pinnacle Point 5‐6 in South Africa (Esteban et al, 2018), and at Iron Age Tell es‐Safi/Gath, Israel (Namdar et al, 2011). Aldeias, Goldberg, Dibble, and El‐Hajraoui (2014) characterized the degree of preservation of biogenic aragonite at Contrebandiers Cave (Morocco) using micromorphology thin sections.…”

Section: Archaeological Significancementioning

confidence: 99%

“…They showed that biogenic aragonite from G. insubrica , one of the most common bivalves found at archaeological sites in Israel (e.g., Sivan et al, 2006), has a grinding curve markedly different from the curve of pyrogenic aragonite (Figure 3). Therefore, it is possible to assess whether aragonite found within combustion features is of biogenic or pyrogenic origin (e.g., Albert et al, 2008, table 2; Esteban et al, 2018). This method should be calibrated based on the type of biogenic aragonite available at the site, since different organisms mineralize aragonite crystals with various degrees of atomic order (Suzuki et al, 2011).…”

Section: Archaeological Significancementioning

confidence: 99%

The significance of aragonite in the interpretation of the microscopic archaeological record

Toffolo

2020

Geoarchaeology

View full text Add to dashboard Cite

Aragonite is one of the metastable polymorphs of calcium carbonate and is commonly found at archaeological sites in the form of mollusk shells and speleothems. Other occurrences include corals, fish otoliths, seed endocarps, wood ash, and lime plaster. These materials contain microscopic embedded information of fundamental importance for the assessment of the state of preservation of the archaeological record, the reconstruction of paleoenvironments, the identification of pyrotechnological processes, and the establishment of absolute chronologies. However, this information can be used only if the aragonite found at archaeological sites preserves its pristine structure and chemistry. Aragonite is metastable at ambient conditions and tends to dissolve and recrystallize into secondary aragonite or calcite, a process that entails the loss of its original elemental and isotopic signature. Therefore, well‐grounded archaeological interpretations depend on the correct identification of aragonite and the careful characterization of its basic properties. This article reviews the dissolution processes of different types of aragonite, the methods used for their identification, and the archaeological information that can be extracted. Particular emphasis is given to the discussion of key issues regarding absolute dating and postdepositional processes of archaeological sediments, and to a detailed overview of the recently observed pyrogenic aragonite.

show abstract

Phytoliths as an indicator of early modern humans plant gathering strategies, fire fuel and site occupation intensity during the Middle Stone Age at Pinnacle Point 5-6 (south coast, South Africa)

Cited by 34 publications

References 104 publications

FTIR-Based Crystallinity Assessment of Aragonite–Calcite Mixtures in Archaeological Lime Binders Altered by Diagenesis

FTIR-Based Crystallinity Assessment of Aragonite–Calcite Mixtures in Archaeological Lime Binders Altered by Diagenesis

New Excavations at Umhlatuzana Rockshelter, KwaZulu-Natal, South Africa: a Stratigraphic and Taphonomic Evaluation

The significance of aragonite in the interpretation of the microscopic archaeological record

Contact Info

Product

Resources

About