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Paleoethnobotany

February 16, 2024

Paleoethnobotany (also spelled palaeoethnobotany), or archaeobotany, is the study of past human-plant interactions through the recovery and analysis of ancient plant remains. Both terms are synonymous, though paleoethnobotany (from the Greek words palaios [παλαιός] meaning ancient, ethnos [έθνος] meaning race or ethnicity, and votano [βότανο] meaning plants) is generally used in North America and acknowledges the contribution that ethnographic studies have made towards our current understanding of ancient plant exploitation practices, while the term archaeobotany (from the Greek words archaios [αρχαίος] meaning ancient and votano) is preferred in Europe and emphasizes the discipline's role within archaeology.[1][2]

Flotation machine in use at Hallan Çemi, southeast Turkey, c. 1990. Note the two sieves catching charred seeds and charcoal, and the bags of archaeological sediment waiting for flotation.

As a field of study, paleoethnobotany is a subfield of environmental archaeology. It involves the investigation of both ancient environments and human activities related to those environments, as well as an understanding of how the two co-evolved. Plant remains recovered from ancient sediments within the landscape or at archaeological sites serve as the primary evidence for various research avenues within paleoethnobotany, such as the origins of plant domestication, the development of agriculture, paleoenvironmental reconstructions, subsistence strategies, paleodiets, economic structures, and more.[3]

Paleoethnobotanical studies are divided into two categories: those concerning the Old World (Eurasia and Africa) and those that pertain to the New World (the Americas). While this division has an inherent geographical distinction to it, it also reflects the differences in the flora of the two separate areas. For example, maize only occurs in the New World, while olives only occur in the Old World. Within this broad division, paleoethnobotanists tend to further focus their studies on specific regions, such as the Near East or the Mediterranean, since regional differences in the types of recovered plant remains also exist.

Macrobotanical vs. microbotanical remains edit

 
Charred barley grains viewed through a low-powered microscope.

Plant remains recovered from ancient sediments or archaeological sites are generally referred to as either ‘macrobotanicals’ or ‘microbotanicals.’

Macrobotanical remains are vegetative parts of plants, such as seeds, leaves, stems and chaff, as well as wood and charcoal that can either be observed with the naked eye or the with the use of a low-powered microscope.

Microbotanical remains consist of microscopic parts or components of plants, such as pollen grains, phytoliths and starch granules, that require the use of a high-powered microscope in order to see them.

The study of seeds, wood/charcoal, pollen, phytoliths and starches all require separate training, as slightly different techniques are employed for their processing and analysis. Paleoethnobotanists generally specialize in the study of a single type of macrobotanical or microbotanical remain, though they are familiar with the study of other types and can sometimes even specialize in more than one.

 
Pollen grains viewed through a high-powered microscope.

History edit

The state of Paleoethnobotany as a discipline today stems from a long history of development that spans more than two hundred years. Its current form is the product of steady progression by all aspects of the field, including methodology, analysis and research.

Initial work edit

The study of ancient plant remains began in the 19th century as a result of chance encounters with desiccated and waterlogged material at archaeological sites. In Europe, the first analyses of plant macrofossils were conducted by the botanist C. Kunth (1826)[4] on desiccated remains from Egyptian tombs and O. Heer (1866)[5] on waterlogged specimens from lakeside villages in Switzerland, after which point archaeological plant remains became of interest and continued to be periodically studied from different European countries until the mid-20th century. In North America, the first analysis of plant remains occurred slightly later and did not generate the same interest in this type of archaeological evidence until the 1930s when Gilmore (1931)[6] and Jones (1936)[7] analysed desiccated material from rock shelters in the American Southwest. All these early studies, in both Europe and North America, largely focused on the simple identification of the plant remains in order to produce a list of the recovered taxa.[1][2]

Establishment of the field edit

During the 1950s and 1960s, Paleoethnobotany gained significant recognition as a field of archaeological research with two significant events: the publication of the Star Carr excavations in the UK and the recovery of plant material from archaeological sites in the Near East. Both convinced the archaeological community of the importance of studying plant remains by demonstrating their potential contribution to the discipline; the former produced a detailed paleoenvironmental reconstruction that was integral to the archaeological interpretation of the site and the latter yielded the first evidence for plant domestication, which allowed for a fuller understanding of the archaeological record. Thereafter, the recovery and analysis of plant remains received greater attention as a part of archaeological investigations.[1] In 1968, the International Work Group for Palaeoethnobotany (IWGP) was founded.[8]

Expansion and growth edit

With the rise of Processual archaeology, the field of Paleoethnobotany began to grow significantly. The implementation in the 1970s of a new recovery method, called flotation, allowed archaeologists to begin systematically searching for plant macrofossils at every type of archaeological site. As a result, there was a sudden influx of material for archaeobotanical study, as carbonized and mineralized plant remains were becoming readily recovered from archaeological contexts. Increased emphasis on scientific analyses also renewed interest in the study of plant microbotanicals, such as phytoliths (1970s) and starches (1980s), while later advances in computational technology during the 1990s facilitated the application of software programs as tools for quantitative analysis. The 1980s and 1990s also saw the publication of several seminal volumes about Paleoethnobotany[9][10][3][11][12] that demonstrated the sound theoretical framework in which the discipline operates. And finally, the popularization of Post-Processual archaeology in the 1990s, helped broaden the range of research topics addressed by paleoethnobotanists, for example 'food-related gender roles'.[1][2]

Current state of the field edit

 
This image is part of reference collection work for archaeological dental calculus - i.e. looking at plants, animals and fungi from the inside to better understand them when finding them in archaeological samples. This image shows a piece of cranberry. This image was altered with AI to improve the quality and the colours

Paleoethnobotany is a discipline that is ever evolving, even up to the present day. Since the 1990s, the field has continued to gain a better understanding of the processes responsible for creating plant assemblages in the archaeological record and to refine its analytical and methodological approaches accordingly. For example, current studies have become much more interdisciplinary, utilizing various lines of investigation in order to gain a fuller picture of the past plant economies. Research avenues also continue to explore new topics pertaining to ancient human-plant interactions, such as the potential use of plant remains in relation to their mnemonic or sensory properties.[1][2] Interest in plant remains surged in the 2000s alongside the improvement of stable isotope analysis and its application to archaeology, including the potential to illuminate the intensity of agricultural labour, resilience, and long-term social and economic changes.[13]

Archaeobotany had not been used extensively in Australia until recently. In 2018 a study of the Karnatukul site in the Little Sandy Desert of Western Australia showed evidence of continuous human habitation for around 50,000 years, by analysing wattle and other plant items.[14][15][16][17]

Modes of preservation edit

As organic matter, plant remains generally decay over time due to microbial activity. In order to be recovered in the archaeological record, therefore, plant material must be subject to specific environmental conditions or cultural contexts that prevent their natural degradation. Plant macrofossils recovered as paleoenvironmental, or archaeological specimens result from four main modes of preservation:

 
Charred Plant Remains. Clockwise from top left: bitter vetch (Vicia ervilia); barley (Hordeum sp.); glume wheat (Triticum sp.) glumebases and spikelet; olive stones (Olea europaea); grape pedicels (Vitis vinifera sp.); and grape pips (Vitis vinifera sp.).
  1. Carbonized (Charred): Plant remains can survive in the archaeological record when they have been converted into charcoal through exposure to fire under low-oxygen conditions.[18] Charred organic material is more resistant to deterioration, since it is only susceptible to chemical breakdown, which takes a long time (Weiner 2010).[19] Due to the essential use of fire for many anthropogenic activities, carbonized remains constitute the most common type of plant macrofossil recovered from archaeological sites.[18] This mode of preservation, however, tends to be biased towards plant remains that come into direct contact with fire for cooking or fuel purposes, as well as those that are more robust, such as cereal grains and nut shells.[20][21]
     
    Waterlogged Plant Remains. From left to right: bog pond weed (Potamogeton poligonifolius); birch (Betula sp.); and common scurvygrass (Cochlearia officinalis).
  2. Waterlogged: Preservation of plant material can also occur when it is deposited in permanently wet, anoxic conditions, because the absence of oxygen prohibits microbial activity. This mode of preservation can occur in deep archaeological features, such as wells, and in lakebed or riverbed sediments adjacent to settlements. A wide range of plant remains are usually preserved as waterlogged material, including seeds, fruit stones, nutshells, leaves, straw and other vegetative matter.[20][18]
  3. Desiccated: Another mode by which plant material can be preserved is desiccation, which only occurs in very arid environments, such as deserts, where the absence of water limits decomposition of organic matter. Desiccated plant remains are a rarer recovery, but an incredibly important source of archaeological information, since all types of plant remains can survive, even very delicate vegetative attributes, such as onion skins and crocus stigmas (saffron), as well as woven textiles, bunches of flowers and entire fruits.[21][22]
     
    Mineralized Plant Remains. Left to right: grape endosperms (Vitis vinifera sp.); and fig seeds (Ficus cf. carica).
  4. Mineralized: Plant material can also preserve in the archaeological record when its soft organic tissues are completely replaced by inorganic minerals. There are two types of mineralization processes. The first, 'biomineralization,' occurs when certain plant remains, such as the fruits of Celtis sp. (hackberry) or nutlets of the Boraginaceae family, naturally produce increased amounts of calcium carbonate or silica throughout their growth, resulting in calcified or silicified specimens.[23][24][25] The second, 'replacement mineralization,' occurs when plant remains absorb precipitating minerals present in the sediment or organic matter in which they are buried. This mode of preservation by mineralization only occurs under specific depositional conditions, usually involving a high presence of phosphate. Mineralized plant remains, therefore, are most commonly recovered from middens and latrine pits – contexts which often yield plant remains that have passed through the digestive track, such as spices, grape pips and fig seeds. The mineralization of plant material can also occur when remains are deposited alongside metal artefacts, especially those made of bronze or iron. In this circumstance, the soft organic tissues are replaced by the leaching of corrosion products that form over time on the metal objects.[26][22][27][28]

In addition to the above-mentioned modes of preservation, plant remains can also be occasionally preserved in a frozen state or as impressions. The former occurs quite rarely, but a famous example comes from Ötzi, the 5,500 year old mummy found frozen in the French Alps, whose stomach contents revealed the plant and meat components of his last meal.[29][30] The latter occurs more regularly, though plant impressions do not actually preserve the macrobotanical remains themselves, but rather their negative imprints in pliable materials like clay, mudbrick or plaster. Impressions often result from the deliberate employment of plant material for decorative or technological purposes (such as the use of leaves to create patterning on ceramics or the use of chaff as temper in the construction of mudbricks), however, they can also derive from accidental inclusions. Identification of plant impressions is achieved by creating a silicone cast of the imprints and studying them under the microscope.[22][31]

Recovery methods edit

In order to study ancient plant macrobotanical material, Paleoethnobotanists employ a variety of recovery strategies that involve different sampling and processing techniques depending on the kind of research questions they are addressing, the type of plant macrofossils they are expecting to recover and the location from which they are taking samples.[2]

Sampling edit

In general, there are four different types of sampling methods that can be used for the recovery of plant macrofossils from an archaeological site:[1][32]

  • Full Coverage sampling: involves taking at least one sample from all contexts and features
  • Judgement sampling: entails the sampling of only areas and features most likely to yield ancient plant remains, such as a hearth
  • Random sampling: consists of taking random samples either arbitrarily or via a grid system
  • Systematic sampling: involves taking samples at set intervals during excavation
 
Sediment samples waiting to be processed by water flotation.

Each sampling method has its own pros and cons and for this reason, paleoethnobotanists sometimes implement more than one sampling method at a single site. In general, Systematic or Full Coverage sampling is always recommended whenever possible. The practicalities of excavation, however, and/or the type of archaeological site under investigation sometimes limit their use and Judgment sampling tends to occur more often than not.[1][32]

Aside from sampling methods, there are also different types of samples that can be collected, for which the standard, recommended sample size is ~20L for dry sites and 1-5L for waterlogged sites.[1][32]

  • Point/Spot samples: consist of sediment collected only from a particular location
  • Pinch samples: consist of small amounts of sediment that are collected from across the whole context and combined in one bag
  • Column samples: consist of sediment collected from the different stratigraphic layers of a column of sediment that was deliberately left unexcavated

These different types of samples again serve different research aims. For example, Point/Spot samples can reveal the spatial differentiation of food-related activities, Pinch samples are representative of all activities associated with a specific context, and Column samples can show change or variation or time.[1][32]

The sampling methods and types of samples used for the recovery of microbotanical remains (namely, pollen, phytoliths, and starches) follows virtually the same practices as outline above, with only some minor differences. First, the required sample size is much smaller: ~50g (a couple of tablespoons) of sediment for each type of microfossil analysis. Secondly, artefacts, such as stone tools and ceramics, can also be sampled for microbotanicals. And third, control samples from unexcavated areas in and around the site should always be collected for analytical purposes.[32][1]

Processing edit

There are several different techniques for the processing of sediment samples. The technique a paleoethnobotanist chooses depends entirely upon the type of plant macrobotanical remains they expect to recover.

  • Dry Screening involves pouring sediment samples through a nest of sieves, usually ranging from 5–0.5 mm. This processing technique is often employed as a means of recovering desiccated plant remains, since the use of water can weaken or damage this type of macrofossil and even accelerate its decomposition.[1][31][33]
  • Wet Screening is most often used for waterlogged contexts. It follows the same basic principle as dry screening, expect water is gently sprayed onto the sediment once it has been pour into the nest of sieves in order to help it break up and pass down through the various mesh sizes.[1][33][34]
 
Left to right: Flots drying after water flotation processing; a dried flot ready to be analysed under the microscope.
  • The Wash-Over technique was developed in the UK as an effective way of processing waterlogged samples. The sediment is poured into a bucket with water and gently agitated by hand. When the sediment has effectively broken up and the organic matter is suspended, all the contents from the bucket, expect for the heavy inorganic matter at the bottom, is carefully poured out onto a 300μ mesh. The bucket is then emptied and the organic matter carefully rinsed from the mesh back into the bucket. More water is added before the contents are again poured out through a nest of sieves.[33]
 
Left to right: Heavy residues drying after water flotation processing; a dried heavy residue being sorted with the naked eye.
  • Flotation is the most common processing technique employed for the recovery of carbonized plant remains. It uses water as a mechanism for separating charred and organic material from the sediment matrix, by capitalizing on their buoyancy properties.  When a sediment sample is slowly added to agitated water, the stones, sand, shells and other heavy material within the sediment sink to the bottom (heavy fraction or heavy residue), while the charred and organic material, which is less dense, float to the surface (light fraction or flot). This floating material can either be scooped off or spilled over into a fine-mesh sieve (usually ~300 μm). Both the heavy and light fractions are then left to dry before being examined for archaeological remains. Plant macrofossils are mostly contained within the light fraction, though some denser specimens, such as pulses or mineralized grape endosperms, are also sometimes found in the heavy fraction. Thus, each fraction must be sorted to extract all plant material. A microscope is used in order to aid the sorting of the light fractions, while heavy fractions are sorted with the naked eye. Flotation can be undertaken manually with buckets or by machine-assistance, which circulates the water through a series of tanks by means of a pump. Small-scale, manual flotation can also be used in the laboratory on waterlogged samples.[1][2][33]

Microbotanical remains (namely, pollen, phytoliths and starches) require completely different processing procedures in order to extract specimens from the sediment matrix. These procedures can be quite expensive, as they involve various chemical solutions, and are always carried out in the laboratory.[1]

Analysis edit

Analysis is the key step in paleoethnobotanical studies that makes the interpretation of ancient plant remains possible. The quality of identifications and the use of different quantification methods are essential factors that influence the depth and breadth of interpretative results.

Identification edit

 
Archaeobotanist and student analysing plant remains under the microscope.

Plant macrofossils are analysed under a low-powered stereomicroscope. The morphological features of different specimens, such as size, shape and surface decoration, are compared with images of modern plant material in identification literature, such as seed atlases, as well as real examples of modern plant material from reference collections, in order to make identifications. Based on the type of macrofossils and their level of preservation, identifications are made to various taxonomic levels, mostly family, genus and species. These taxonomic levels reflect varying degrees of identification specificity: families comprise big groups of similar type plants; genera make up smaller groups of more closely related plants within each family, and species consist of the different individual plants within each genus. Poor preservation, however, may require the creation of broader identification categories, such as ‘nutshell’ or ‘cereal grain’, while extremely good preservation and/or the application of analytical technology, such as Scanning Electron Microscopy (SEM) or Morphometric Analysis, may allow even more precise identification down to subspecies or variety level[1][31][35]

Desiccated and waterlogged macrofossils often have a very similar appearance with modern plant material, since their modes of preservation do not directly affect the remains. As a result, fragile seed features, such as anthers or wings, and occasionally even colour, can be preserved, allowing for very precise identifications of this material. The high temperatures involved in the carbonization of plant remains, however, can sometimes cause the damage to or loss of plant macrofossil features. The analysis of charred plant material, therefore, often includes several family- or genus-level identifications, as well as some specimen categories. Mineralized plant macrofossils can range in preservation from detailed copies to rough casts depending on depositional conditions and the kind of replacing mineral. This type of macrofossil can easily be mistaken for stones by the untrained eye.[18][20][21][26]

Microbotanical remains follow the same identification principles, but require a high-powered (greater magnification) microscope with transmitted or polarized lighting. Starch and phytolith identifications are also subject to limitations, in terms of taxonomical specificity, based on the state of current reference material for comparison and considerable overlap in specimen morphologies.[1][35][36]

Quantification edit

 
Charred plant remains being grouped by taxa type and quantified under the microscope.

After identification, paleoethnobotanists provide absolute counts for all plant macrofossils recovered in each individual sample. These counts constitute the raw analytical data and serve as the basis for any further quantitative methods that may be applied.[37] Initially, paleoethnobotanical studies mostly involved a qualitative assessment of the plant remains at an archaeological site (presence and absence), but the application of simple statistical methods (non-multivariate) followed shortly thereafter.[1][37] The use of more complex statistics (multivariate), however, is a more recent development. In general, simple statistics allow for observations concerning specimen values across space and over time,[37][1] while more complex statistics facilitate the recognition of patterning within an assemblage, as well as the presentation of large datasets.[1][38] The application of different statistical techniques depends on the quantity of material available. Complex statistics require the recovery of a large number of specimens (usually around 150 from each sample involved in this type of quantitative analysis), whereas simple statistics can be applied regardless of the amount of recovered specimens – though obviously, the more specimens, the more effective the results.

The quantification of microbotanical remains differs slightly from that of macrobotanical remains, mostly due to the high numbers of microbotanical specimens that are usually present in samples. As a result, relative/percentage occurrence sums are usually employed in the quantification of microbotanical remains instead of absolute taxa counts.[1][36]

Research results edit

The work done in Paleoethnobotany is constantly furthering over understanding of ancient plant exploitation practices. The results are disseminated in digital archives,[39] archaeological excavation reports and at academic conferences, as well as in books and journals related to archaeology, anthropology, plant history, paleoecology, and social sciences. In addition to the use of plants as food, such as paleodiet, subsistence strategies and agriculture, Paleoethnobotany has illuminated many other ancient uses for plants (some examples provided below, though there are many more):

See also edit

References edit

  1. ^ a b c d e f g h i j k l m n o p q r s t Pearsall, D.M. (2015). Paleoethnobotany: a handbook of procedures (Third ed.). Walnut Creek, California: Left Coast Press. ISBN 978-1-61132-298-9. OCLC 888401422.
  2. ^ a b c d e f Marston, J.M.; d'Alpoim Guedes, J.; Warinner, C. (2014). "Paleoethnobotanical Method and Theory in the Twenty-First Century". In Marston, J.M.; d'Alpoim Guedes, J.; Warinner, C. (eds.). Method and theory in paleoethnobotany. Boulder: University Press of Colorado. pp. 1–15. ISBN 978-1-60732-316-7. OCLC 903563629.
  3. ^ a b Christine Ann Hastorf; Virginia S. Popper, eds. (1988). Current paleoethnobotany: analytical methods and cultural interpretations of archaeological plant remains. Chicago: University of Chicago Press. ISBN 0-226-31892-3. OCLC 18134655.
  4. ^ Kunth, C. (1826). "Examen Botanique". In Passalacqua, J. (ed.). Catalogue Raisonne et Historique de Antiquites Decouvertes en Egypte. Paris: Musees Nationaux. pp. 227–28.
  5. ^ Heer, O. (1866). "Treatise on the Plants of the Lake Dwellings". In Keller, F. (ed.). The Lake Dwellings of Switzerland and Other Parts of Europe. Translated by Lee, J.E. London: Longman, Green & Co.
  6. ^ Gilmore, M.R. "Vegetal Remains of the Ozark Bluff-Dweller Culture". Papers of the Michigan Academy of Science, Arts, and Letters. 14: 83–102.
  7. ^ Jones, V.H. (1936). "The Vegetal Remains of Newt Kash Hollow Shelter". In Webb, W.S.; Funkhouser, W.D. (eds.). Rock Shelters in Menifee County, Kentucky. University of Kentucky Reports in Archaeology and Anthropology 3(4). Lexington: Dept. of Anthropology & Archaeology. pp. 147–167.
  8. ^ Heiss, Andreas G.; Bittmann, Felix; Kroll, Helmut; Pokorná, Adéla; Stika, Hans-Peter. "Website of the International Work Group for Palaeoethnobotany (IWGP)". Retrieved 2022-07-23.
  9. ^ Pearsall, D.M. (1989). Paleoethnobotany: A Handbook of Procedures (First ed.). San Diego: Academic Press.
  10. ^ Renfrew, J.M. (1973). Palaeoethnobotany: the prehistoric food plants of the Near East and Europe. New York: Columbia University Press. ISBN 0-231-03745-7. OCLC 520800.
  11. ^ Van Zeist, W.; Casparie, W.A.; International Work Group for Palaeoethnobotany (1984). Plants and ancient man: studies in palaeoethnobotany: proceedings of the Sixth Symposium of the International Work Group for Palaeoethnobotany, Groningen, 30 May-3 June 1983. Rotterdam: A.A. Balkema. ISBN 90-6191-528-7. OCLC 11059732.
  12. ^ Van Zeist, W.; Wasylikowa, K.; Behre, K.-E. (1991). Progress in old world palaeoethnobotany: a retrospective view on the occasion of 20 years of the International Work Group for Palaeoethnobotany. Rotterdam: A.A. Balkema. ISBN 90-6191-881-2. OCLC 22942783.
  13. ^ Lodwick, Lisa; Stroud, Elizabeth (2019). "Paleoethnobotany and Stable Isotopes". In López Varela, Sandra L. (ed.). The Encyclopedia of Archaeological Sciences. Malden, MA: Wiley-Blackwell. pp. 1–4. doi:10.1002/9781119188230.saseas0436. ISBN 9780470674611. S2CID 239512474.
  14. ^ Pownall, Angela (1 August 2014). "Custodians open up Carnarvon Range". The West Australian. Retrieved 19 July 2022.
  15. ^ McDonald, Jo; Veth, Peter (2008). "Rock- art: Pigment dates provide new perspectives on the role of art in the Australian arid zone". Australian Aboriginal Studies (2008/1): 4–21 – via ResearchGate.
  16. ^ Goerling, Samantha (20 March 2022). "Ancient campfire in Western Desert at least 50,000 years old, archaeologists say". ABC News. Australian Broadcasting Corporation. Retrieved 20 July 2022.
  17. ^ McDonald, Josephine; Reynen, Wendy; Petchey, Fiona; Ditchfield, Kane; Byrne, Chae; Vannieuwenhuyse, Dorcas; Leopold, Matthias; Veth, Peter (September 2018). "Karnatukul (Serpent's Glen): A new chronology for the oldest site in Australia's Western Desert". PLOS ONE. 13 (9): e0202511. doi:10.1371/journal.pone.0202511. PMC 6145509. PMID 30231025 – via ResearchGate. The re-excavation of Karnatukul (Serpent's Glen) has provided evidence for the human occupation of the Australian Western Desert to before 47,830 cal. BP (modelled median age). This new sequence is 20,000 years older than the previous known age for occupation at this site
  18. ^ a b c d Zohary, D.; Hopf, M.; Weiss, E. (2012). Domestication of plants in the Old World: the origin and spread of domesticated plants in Southwest Asia, Europe, and the Mediterranean Basin (4th ed.). Oxford: Oxford University Press. ISBN 978-0-19-954906-1. OCLC 761379401.
  19. ^ Weiner, Stephen (2010). Microarchaeology : beyond the visible archaeological record. New York: Cambridge University Press. ISBN 978-0-511-67760-1. OCLC 642205856.
  20. ^ a b c Jacomet, S. (2013). "Archaeobotany: Analyses of Plant Remains from Waterlogged Archaeological Sites". In Menotti, F.; O'Sullivan, A. (eds.). The Oxford Handbook of Wetland Archaeology. Oxford: Oxford University Press. pp. 497–514.
  21. ^ a b c Van der Veen, M. (2007). "Formation processes of desiccated and carbonized plant remains – the identification of routine practice". Journal of Archaeological Science. 34 (6): 968–990. doi:10.1016/j.jas.2006.09.007. ISSN 0305-4403.
  22. ^ a b c Gallagher, D.E. (2014). "Formation Process of the Macrobotanical Record". In Marston, J.; d'Alpoim Guedes, J.; Warriner, C. (eds.). Method and Theory in Paleoethnobotany. Boulder: University of Colorado Press. pp. 19–34.
  23. ^ Cowan, M.R.; Gabel, M.L.; Jahren, A.H.; Tieszen, L.L. (1997). "Growth and Biomineralization of Celtis occidentalis (Ulmaceae) Pericarps". The American Midland Naturalist. 137 (2): 266–273. doi:10.2307/2426845. ISSN 0003-0031. JSTOR 2426845.
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  25. ^ Messager, E.; Badou, A.; Fröhlich, F.; Deniaux, B.; Lordkipanidze, D.; Voinchet, P. (2010). "Fruit and seed biomineralization and its effect on preservation". Archaeological and Anthropological Sciences. 2 (1): 25–34. doi:10.1007/s12520-010-0024-1. ISSN 1866-9557. S2CID 128691588.
  26. ^ a b Carruthers, Wendy; Smith, D.N. (2020). Mineralised plant and invertebrate remains: a guide to the identification of calcium phosphate replaced remains. Swindon: Historical England. ISBN 978-1-80034-120-3. OCLC 1138677613.
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Bibliography edit

  • Twiss, K.C. 2019. The Archaeology of Food. Cambridge: Cambridge University Press. ISBN 9781108670159
  • Kristen J.G. 1997. People, Plants, and Landscapes: Studies in Paleoethnobotany. Alabama: University of Alabama Press. ISBN 0-8173-0827-X.
  • Miksicek, C.H.1987. "Formation Processes of the Archaeobotanical Record." In M.B.Schiffer (ed.). Advances in Archaeological Method and Theory 10. New York: Academic Press, 211–247. ISBN 0-12-003110-8.

External links edit

International Associations

  • Association of Environmental Archaeology (AEA)
  • International Work Group for Palaeoethnobotany (IWGP)

Journals

  • Vegetation History and Archaeobotany, exclusively publishing archaeobotanical/palaeoethnobotanical research, official publishing organ of the IWGP
  • Archaeological and Anthropological Sciences
  • Environmental Archaeology
  • Interdisciplinaria Archaeologica (IANSA)

Various knowledge resources

  • ArchBotLit, Kiel University
  • Digital Plant Atlas, Groningen University
  • Integrated Archaeobotanical Research Project (IAR), originally hosted at the University of Sheffield
  • Terry B. Ball, "Phytolith Literature Review"
  • Steve Archer, ""
  • Alwynne B. Beaudoin, "The Dung File"

February 16, 2024
paleoethnobotany, also, spelled, palaeoethnobotany, archaeobotany, study, past, human, plant, interactions, through, recovery, analysis, ancient, plant, remains, both, terms, synonymous, though, paleoethnobotany, from, greek, words, palaios, παλαιός, meaning, . Paleoethnobotany also spelled palaeoethnobotany or archaeobotany is the study of past human plant interactions through the recovery and analysis of ancient plant remains Both terms are synonymous though paleoethnobotany from the Greek words palaios palaios meaning ancient ethnos e8nos meaning race or ethnicity and votano botano meaning plants is generally used in North America and acknowledges the contribution that ethnographic studies have made towards our current understanding of ancient plant exploitation practices while the term archaeobotany from the Greek words archaios arxaios meaning ancient and votano is preferred in Europe and emphasizes the discipline s role within archaeology 1 2 Flotation machine in use at Hallan Cemi southeast Turkey c 1990 Note the two sieves catching charred seeds and charcoal and the bags of archaeological sediment waiting for flotation As a field of study paleoethnobotany is a subfield of environmental archaeology It involves the investigation of both ancient environments and human activities related to those environments as well as an understanding of how the two co evolved Plant remains recovered from ancient sediments within the landscape or at archaeological sites serve as the primary evidence for various research avenues within paleoethnobotany such as the origins of plant domestication the development of agriculture paleoenvironmental reconstructions subsistence strategies paleodiets economic structures and more 3 Paleoethnobotanical studies are divided into two categories those concerning the Old World Eurasia and Africa and those that pertain to the New World the Americas While this division has an inherent geographical distinction to it it also reflects the differences in the flora of the two separate areas For example maize only occurs in the New World while olives only occur in the Old World Within this broad division paleoethnobotanists tend to further focus their studies on specific regions such as the Near East or the Mediterranean since regional differences in the types of recovered plant remains also exist Contents 1 Macrobotanical vs microbotanical remains 2 History 2 1 Initial work 2 2 Establishment of the field 2 3 Expansion and growth 2 4 Current state of the field 3 Modes of preservation 4 Recovery methods 4 1 Sampling 4 2 Processing 5 Analysis 5 1 Identification 5 2 Quantification 6 Research results 7 See also 8 References 9 Bibliography 10 External linksMacrobotanical vs microbotanical remains edit nbsp Charred barley grains viewed through a low powered microscope Plant remains recovered from ancient sediments or archaeological sites are generally referred to as either macrobotanicals or microbotanicals Macrobotanical remains are vegetative parts of plants such as seeds leaves stems and chaff as well as wood and charcoal that can either be observed with the naked eye or the with the use of a low powered microscope Microbotanical remains consist of microscopic parts or components of plants such as pollen grains phytoliths and starch granules that require the use of a high powered microscope in order to see them The study of seeds wood charcoal pollen phytoliths and starches all require separate training as slightly different techniques are employed for their processing and analysis Paleoethnobotanists generally specialize in the study of a single type of macrobotanical or microbotanical remain though they are familiar with the study of other types and can sometimes even specialize in more than one nbsp Pollen grains viewed through a high powered microscope History editThe state of Paleoethnobotany as a discipline today stems from a long history of development that spans more than two hundred years Its current form is the product of steady progression by all aspects of the field including methodology analysis and research Initial work edit The study of ancient plant remains began in the 19th century as a result of chance encounters with desiccated and waterlogged material at archaeological sites In Europe the first analyses of plant macrofossils were conducted by the botanist C Kunth 1826 4 on desiccated remains from Egyptian tombs and O Heer 1866 5 on waterlogged specimens from lakeside villages in Switzerland after which point archaeological plant remains became of interest and continued to be periodically studied from different European countries until the mid 20th century In North America the first analysis of plant remains occurred slightly later and did not generate the same interest in this type of archaeological evidence until the 1930s when Gilmore 1931 6 and Jones 1936 7 analysed desiccated material from rock shelters in the American Southwest All these early studies in both Europe and North America largely focused on the simple identification of the plant remains in order to produce a list of the recovered taxa 1 2 Establishment of the field edit During the 1950s and 1960s Paleoethnobotany gained significant recognition as a field of archaeological research with two significant events the publication of the Star Carr excavations in the UK and the recovery of plant material from archaeological sites in the Near East Both convinced the archaeological community of the importance of studying plant remains by demonstrating their potential contribution to the discipline the former produced a detailed paleoenvironmental reconstruction that was integral to the archaeological interpretation of the site and the latter yielded the first evidence for plant domestication which allowed for a fuller understanding of the archaeological record Thereafter the recovery and analysis of plant remains received greater attention as a part of archaeological investigations 1 In 1968 the International Work Group for Palaeoethnobotany IWGP was founded 8 Expansion and growth edit With the rise of Processual archaeology the field of Paleoethnobotany began to grow significantly The implementation in the 1970s of a new recovery method called flotation allowed archaeologists to begin systematically searching for plant macrofossils at every type of archaeological site As a result there was a sudden influx of material for archaeobotanical study as carbonized and mineralized plant remains were becoming readily recovered from archaeological contexts Increased emphasis on scientific analyses also renewed interest in the study of plant microbotanicals such as phytoliths 1970s and starches 1980s while later advances in computational technology during the 1990s facilitated the application of software programs as tools for quantitative analysis The 1980s and 1990s also saw the publication of several seminal volumes about Paleoethnobotany 9 10 3 11 12 that demonstrated the sound theoretical framework in which the discipline operates And finally the popularization of Post Processual archaeology in the 1990s helped broaden the range of research topics addressed by paleoethnobotanists for example food related gender roles 1 2 Current state of the field edit nbsp This image is part of reference collection work for archaeological dental calculus i e looking at plants animals and fungi from the inside to better understand them when finding them in archaeological samples This image shows a piece of cranberry This image was altered with AI to improve the quality and the coloursPaleoethnobotany is a discipline that is ever evolving even up to the present day Since the 1990s the field has continued to gain a better understanding of the processes responsible for creating plant assemblages in the archaeological record and to refine its analytical and methodological approaches accordingly For example current studies have become much more interdisciplinary utilizing various lines of investigation in order to gain a fuller picture of the past plant economies Research avenues also continue to explore new topics pertaining to ancient human plant interactions such as the potential use of plant remains in relation to their mnemonic or sensory properties 1 2 Interest in plant remains surged in the 2000s alongside the improvement of stable isotope analysis and its application to archaeology including the potential to illuminate the intensity of agricultural labour resilience and long term social and economic changes 13 Archaeobotany had not been used extensively in Australia until recently In 2018 a study of the Karnatukul site in the Little Sandy Desert of Western Australia showed evidence of continuous human habitation for around 50 000 years by analysing wattle and other plant items 14 15 16 17 Modes of preservation editAs organic matter plant remains generally decay over time due to microbial activity In order to be recovered in the archaeological record therefore plant material must be subject to specific environmental conditions or cultural contexts that prevent their natural degradation Plant macrofossils recovered as paleoenvironmental or archaeological specimens result from four main modes of preservation nbsp Charred Plant Remains Clockwise from top left bitter vetch Vicia ervilia barley Hordeum sp glume wheat Triticum sp glumebases and spikelet olive stones Olea europaea grape pedicels Vitis vinifera sp and grape pips Vitis vinifera sp Carbonized Charred Plant remains can survive in the archaeological record when they have been converted into charcoal through exposure to fire under low oxygen conditions 18 Charred organic material is more resistant to deterioration since it is only susceptible to chemical breakdown which takes a long time Weiner 2010 19 Due to the essential use of fire for many anthropogenic activities carbonized remains constitute the most common type of plant macrofossil recovered from archaeological sites 18 This mode of preservation however tends to be biased towards plant remains that come into direct contact with fire for cooking or fuel purposes as well as those that are more robust such as cereal grains and nut shells 20 21 nbsp Waterlogged Plant Remains From left to right bog pond weed Potamogeton poligonifolius birch Betula sp and common scurvygrass Cochlearia officinalis Waterlogged Preservation of plant material can also occur when it is deposited in permanently wet anoxic conditions because the absence of oxygen prohibits microbial activity This mode of preservation can occur in deep archaeological features such as wells and in lakebed or riverbed sediments adjacent to settlements A wide range of plant remains are usually preserved as waterlogged material including seeds fruit stones nutshells leaves straw and other vegetative matter 20 18 Desiccated Another mode by which plant material can be preserved is desiccation which only occurs in very arid environments such as deserts where the absence of water limits decomposition of organic matter Desiccated plant remains are a rarer recovery but an incredibly important source of archaeological information since all types of plant remains can survive even very delicate vegetative attributes such as onion skins and crocus stigmas saffron as well as woven textiles bunches of flowers and entire fruits 21 22 nbsp Mineralized Plant Remains Left to right grape endosperms Vitis vinifera sp and fig seeds Ficus cf carica Mineralized Plant material can also preserve in the archaeological record when its soft organic tissues are completely replaced by inorganic minerals There are two types of mineralization processes The first biomineralization occurs when certain plant remains such as the fruits of Celtis sp hackberry or nutlets of the Boraginaceae family naturally produce increased amounts of calcium carbonate or silica throughout their growth resulting in calcified or silicified specimens 23 24 25 The second replacement mineralization occurs when plant remains absorb precipitating minerals present in the sediment or organic matter in which they are buried This mode of preservation by mineralization only occurs under specific depositional conditions usually involving a high presence of phosphate Mineralized plant remains therefore are most commonly recovered from middens and latrine pits contexts which often yield plant remains that have passed through the digestive track such as spices grape pips and fig seeds The mineralization of plant material can also occur when remains are deposited alongside metal artefacts especially those made of bronze or iron In this circumstance the soft organic tissues are replaced by the leaching of corrosion products that form over time on the metal objects 26 22 27 28 In addition to the above mentioned modes of preservation plant remains can also be occasionally preserved in a frozen state or as impressions The former occurs quite rarely but a famous example comes from Otzi the 5 500 year old mummy found frozen in the French Alps whose stomach contents revealed the plant and meat components of his last meal 29 30 The latter occurs more regularly though plant impressions do not actually preserve the macrobotanical remains themselves but rather their negative imprints in pliable materials like clay mudbrick or plaster Impressions often result from the deliberate employment of plant material for decorative or technological purposes such as the use of leaves to create patterning on ceramics or the use of chaff as temper in the construction of mudbricks however they can also derive from accidental inclusions Identification of plant impressions is achieved by creating a silicone cast of the imprints and studying them under the microscope 22 31 Recovery methods editIn order to study ancient plant macrobotanical material Paleoethnobotanists employ a variety of recovery strategies that involve different sampling and processing techniques depending on the kind of research questions they are addressing the type of plant macrofossils they are expecting to recover and the location from which they are taking samples 2 Sampling edit In general there are four different types of sampling methods that can be used for the recovery of plant macrofossils from an archaeological site 1 32 Full Coverage sampling involves taking at least one sample from all contexts and features Judgement sampling entails the sampling of only areas and features most likely to yield ancient plant remains such as a hearth Random sampling consists of taking random samples either arbitrarily or via a grid system Systematic sampling involves taking samples at set intervals during excavation nbsp Sediment samples waiting to be processed by water flotation Each sampling method has its own pros and cons and for this reason paleoethnobotanists sometimes implement more than one sampling method at a single site In general Systematic or Full Coverage sampling is always recommended whenever possible The practicalities of excavation however and or the type of archaeological site under investigation sometimes limit their use and Judgment sampling tends to occur more often than not 1 32 Aside from sampling methods there are also different types of samples that can be collected for which the standard recommended sample size is 20L for dry sites and 1 5L for waterlogged sites 1 32 Point Spot samples consist of sediment collected only from a particular location Pinch samples consist of small amounts of sediment that are collected from across the whole context and combined in one bag Column samples consist of sediment collected from the different stratigraphic layers of a column of sediment that was deliberately left unexcavatedThese different types of samples again serve different research aims For example Point Spot samples can reveal the spatial differentiation of food related activities Pinch samples are representative of all activities associated with a specific context and Column samples can show change or variation or time 1 32 The sampling methods and types of samples used for the recovery of microbotanical remains namely pollen phytoliths and starches follows virtually the same practices as outline above with only some minor differences First the required sample size is much smaller 50g a couple of tablespoons of sediment for each type of microfossil analysis Secondly artefacts such as stone tools and ceramics can also be sampled for microbotanicals And third control samples from unexcavated areas in and around the site should always be collected for analytical purposes 32 1 Processing edit There are several different techniques for the processing of sediment samples The technique a paleoethnobotanist chooses depends entirely upon the type of plant macrobotanical remains they expect to recover Dry Screening involves pouring sediment samples through a nest of sieves usually ranging from 5 0 5 mm This processing technique is often employed as a means of recovering desiccated plant remains since the use of water can weaken or damage this type of macrofossil and even accelerate its decomposition 1 31 33 Wet Screening is most often used for waterlogged contexts It follows the same basic principle as dry screening expect water is gently sprayed onto the sediment once it has been pour into the nest of sieves in order to help it break up and pass down through the various mesh sizes 1 33 34 nbsp Left to right Flots drying after water flotation processing a dried flot ready to be analysed under the microscope The Wash Over technique was developed in the UK as an effective way of processing waterlogged samples The sediment is poured into a bucket with water and gently agitated by hand When the sediment has effectively broken up and the organic matter is suspended all the contents from the bucket expect for the heavy inorganic matter at the bottom is carefully poured out onto a 300m mesh The bucket is then emptied and the organic matter carefully rinsed from the mesh back into the bucket More water is added before the contents are again poured out through a nest of sieves 33 nbsp Left to right Heavy residues drying after water flotation processing a dried heavy residue being sorted with the naked eye Flotation is the most common processing technique employed for the recovery of carbonized plant remains It uses water as a mechanism for separating charred and organic material from the sediment matrix by capitalizing on their buoyancy properties When a sediment sample is slowly added to agitated water the stones sand shells and other heavy material within the sediment sink to the bottom heavy fraction or heavy residue while the charred and organic material which is less dense float to the surface light fraction or flot This floating material can either be scooped off or spilled over into a fine mesh sieve usually 300 mm Both the heavy and light fractions are then left to dry before being examined for archaeological remains Plant macrofossils are mostly contained within the light fraction though some denser specimens such as pulses or mineralized grape endosperms are also sometimes found in the heavy fraction Thus each fraction must be sorted to extract all plant material A microscope is used in order to aid the sorting of the light fractions while heavy fractions are sorted with the naked eye Flotation can be undertaken manually with buckets or by machine assistance which circulates the water through a series of tanks by means of a pump Small scale manual flotation can also be used in the laboratory on waterlogged samples 1 2 33 Microbotanical remains namely pollen phytoliths and starches require completely different processing procedures in order to extract specimens from the sediment matrix These procedures can be quite expensive as they involve various chemical solutions and are always carried out in the laboratory 1 Analysis editAnalysis is the key step in paleoethnobotanical studies that makes the interpretation of ancient plant remains possible The quality of identifications and the use of different quantification methods are essential factors that influence the depth and breadth of interpretative results Identification edit nbsp Archaeobotanist and student analysing plant remains under the microscope Plant macrofossils are analysed under a low powered stereomicroscope The morphological features of different specimens such as size shape and surface decoration are compared with images of modern plant material in identification literature such as seed atlases as well as real examples of modern plant material from reference collections in order to make identifications Based on the type of macrofossils and their level of preservation identifications are made to various taxonomic levels mostly family genus and species These taxonomic levels reflect varying degrees of identification specificity families comprise big groups of similar type plants genera make up smaller groups of more closely related plants within each family and species consist of the different individual plants within each genus Poor preservation however may require the creation of broader identification categories such as nutshell or cereal grain while extremely good preservation and or the application of analytical technology such as Scanning Electron Microscopy SEM or Morphometric Analysis may allow even more precise identification down to subspecies or variety level 1 31 35 Desiccated and waterlogged macrofossils often have a very similar appearance with modern plant material since their modes of preservation do not directly affect the remains As a result fragile seed features such as anthers or wings and occasionally even colour can be preserved allowing for very precise identifications of this material The high temperatures involved in the carbonization of plant remains however can sometimes cause the damage to or loss of plant macrofossil features The analysis of charred plant material therefore often includes several family or genus level identifications as well as some specimen categories Mineralized plant macrofossils can range in preservation from detailed copies to rough casts depending on depositional conditions and the kind of replacing mineral This type of macrofossil can easily be mistaken for stones by the untrained eye 18 20 21 26 Microbotanical remains follow the same identification principles but require a high powered greater magnification microscope with transmitted or polarized lighting Starch and phytolith identifications are also subject to limitations in terms of taxonomical specificity based on the state of current reference material for comparison and considerable overlap in specimen morphologies 1 35 36 Quantification edit nbsp Charred plant remains being grouped by taxa type and quantified under the microscope After identification paleoethnobotanists provide absolute counts for all plant macrofossils recovered in each individual sample These counts constitute the raw analytical data and serve as the basis for any further quantitative methods that may be applied 37 Initially paleoethnobotanical studies mostly involved a qualitative assessment of the plant remains at an archaeological site presence and absence but the application of simple statistical methods non multivariate followed shortly thereafter 1 37 The use of more complex statistics multivariate however is a more recent development In general simple statistics allow for observations concerning specimen values across space and over time 37 1 while more complex statistics facilitate the recognition of patterning within an assemblage as well as the presentation of large datasets 1 38 The application of different statistical techniques depends on the quantity of material available Complex statistics require the recovery of a large number of specimens usually around 150 from each sample involved in this type of quantitative analysis whereas simple statistics can be applied regardless of the amount of recovered specimens though obviously the more specimens the more effective the results The quantification of microbotanical remains differs slightly from that of macrobotanical remains mostly due to the high numbers of microbotanical specimens that are usually present in samples As a result relative percentage occurrence sums are usually employed in the quantification of microbotanical remains instead of absolute taxa counts 1 36 Research results editThe work done in Paleoethnobotany is constantly furthering over understanding of ancient plant exploitation practices The results are disseminated in digital archives 39 archaeological excavation reports and at academic conferences as well as in books and journals related to archaeology anthropology plant history paleoecology and social sciences In addition to the use of plants as food such as paleodiet subsistence strategies and agriculture Paleoethnobotany has illuminated many other ancient uses for plants some examples provided below though there are many more Production of bread pastry in the widest sense 40 41 42 43 44 45 Production of beverages 46 47 48 49 50 Extraction of oils and dyes 51 52 53 54 Agricultural regimes irrigation manuring and sowing 55 56 57 Economic practices production storage and trade 58 59 Building materials 60 Fuel 61 62 Symbolic use in ritual activities 63 See also editAnthracology Palynology Dendrochronology Ethnobotany Paleobotany List of paleoethnobotanists TaphonomyReferences edit a b c d e f g h i j k l m n o p q r s t Pearsall D M 2015 Paleoethnobotany a handbook of procedures Third ed Walnut Creek California Left Coast Press ISBN 978 1 61132 298 9 OCLC 888401422 a b c d e f Marston J M d Alpoim Guedes J Warinner C 2014 Paleoethnobotanical Method and Theory in the Twenty First Century In Marston J M d Alpoim Guedes J Warinner C eds Method and theory in paleoethnobotany Boulder University Press of Colorado pp 1 15 ISBN 978 1 60732 316 7 OCLC 903563629 a b Christine Ann Hastorf Virginia S Popper eds 1988 Current paleoethnobotany analytical methods and cultural interpretations of archaeological plant remains Chicago University of Chicago Press ISBN 0 226 31892 3 OCLC 18134655 Kunth C 1826 Examen Botanique In Passalacqua J ed Catalogue Raisonne et Historique de Antiquites Decouvertes en Egypte Paris Musees Nationaux pp 227 28 Heer O 1866 Treatise on the Plants of the Lake Dwellings In Keller F ed The Lake Dwellings of Switzerland and Other Parts of Europe Translated by Lee J E London Longman Green amp Co Gilmore M R Vegetal Remains of the Ozark Bluff Dweller Culture Papers of the Michigan Academy of Science Arts and Letters 14 83 102 Jones V H 1936 The Vegetal Remains of Newt Kash Hollow Shelter In Webb W S Funkhouser W D eds Rock Shelters in Menifee County Kentucky University of Kentucky Reports in Archaeology and Anthropology 3 4 Lexington Dept of Anthropology amp Archaeology pp 147 167 Heiss Andreas G Bittmann Felix Kroll Helmut Pokorna Adela Stika Hans Peter Website of the International Work Group for Palaeoethnobotany IWGP Retrieved 2022 07 23 Pearsall D M 1989 Paleoethnobotany A Handbook of Procedures First ed San Diego Academic Press Renfrew J M 1973 Palaeoethnobotany the prehistoric food plants of the Near East and Europe New York Columbia University Press ISBN 0 231 03745 7 OCLC 520800 Van Zeist W Casparie W A International Work Group for Palaeoethnobotany 1984 Plants and ancient man studies in palaeoethnobotany proceedings of the Sixth Symposium of the International Work Group for Palaeoethnobotany Groningen 30 May 3 June 1983 Rotterdam A A Balkema ISBN 90 6191 528 7 OCLC 11059732 Van Zeist W Wasylikowa K Behre K E 1991 Progress in old world palaeoethnobotany a retrospective view on the occasion of 20 years of the International Work Group for Palaeoethnobotany Rotterdam A A Balkema ISBN 90 6191 881 2 OCLC 22942783 Lodwick Lisa Stroud Elizabeth 2019 Paleoethnobotany and Stable Isotopes In Lopez Varela Sandra L ed The Encyclopedia of Archaeological Sciences Malden MA Wiley Blackwell pp 1 4 doi 10 1002 9781119188230 saseas0436 ISBN 9780470674611 S2CID 239512474 Pownall Angela 1 August 2014 Custodians open up Carnarvon Range The West Australian Retrieved 19 July 2022 McDonald Jo Veth Peter 2008 Rock art Pigment dates provide new perspectives on the role of art in the Australian arid zone Australian Aboriginal Studies 2008 1 4 21 via ResearchGate Goerling Samantha 20 March 2022 Ancient campfire in Western Desert at least 50 000 years old archaeologists say ABC News Australian Broadcasting Corporation Retrieved 20 July 2022 McDonald Josephine Reynen Wendy Petchey Fiona Ditchfield Kane Byrne Chae Vannieuwenhuyse Dorcas Leopold Matthias Veth Peter September 2018 Karnatukul Serpent s Glen A new chronology for the oldest site in Australia s Western Desert PLOS ONE 13 9 e0202511 doi 10 1371 journal pone 0202511 PMC 6145509 PMID 30231025 via ResearchGate The re excavation of Karnatukul Serpent s Glen has provided evidence for the human occupation of the Australian Western Desert to before 47 830 cal BP modelled median age This new sequence is 20 000 years older than the previous known age for occupation at this site a b c d Zohary D Hopf M Weiss E 2012 Domestication of plants in the Old World the origin and spread of domesticated plants in Southwest Asia Europe and the Mediterranean Basin 4th ed Oxford Oxford University Press ISBN 978 0 19 954906 1 OCLC 761379401 Weiner Stephen 2010 Microarchaeology beyond the visible archaeological record New York Cambridge University Press ISBN 978 0 511 67760 1 OCLC 642205856 a b c Jacomet S 2013 Archaeobotany Analyses of Plant Remains from Waterlogged Archaeological Sites In Menotti F O Sullivan A eds The Oxford Handbook of Wetland Archaeology Oxford Oxford University Press pp 497 514 a b c Van der Veen M 2007 Formation processes of desiccated and carbonized plant remains the identification of routine practice Journal of Archaeological Science 34 6 968 990 doi 10 1016 j jas 2006 09 007 ISSN 0305 4403 a b c Gallagher D E 2014 Formation Process of the Macrobotanical Record In Marston J d Alpoim Guedes J Warriner C eds Method and Theory in 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Green F J 1979 Phosphatic mineralization of seeds from archaeological sites Journal of Archaeological Science 6 3 279 284 doi 10 1016 0305 4403 79 90005 0 ISSN 0305 4403 McCobb L M E D E G Briggs Carruthers W J Evershed R P 2003 Phosphatisation of seeds and roots in a Late Bronze Age deposit at Potterne Wiltshire UK Journal of Archaeological Science 30 10 1269 1281 doi 10 1016 S0305 4403 03 00016 5 ISSN 0305 4403 Otzi the Iceman s Stomach Contents Analyzed Archaeology Magazine www archaeology org Retrieved 2021 04 24 This Was Otzi the Iceman s Last Meal Science 2018 07 12 Archived from the original on April 23 2021 Retrieved 2021 04 24 a b c Cappers R T J Neef R 2012 Handbook of Plant Palaeoecology Groningen Barkuis Publishing p 192 ISBN 978 94 91431 07 4 OCLC 828688276 a b c d e d Alpoim Guedes J Spengler R 2014 Sampling Strategies in Paleoethnobotanical Analysis In Marston J M Guedes J A Warriner C eds Method and Theory in Paleoethnobotany Boulder University Press of Colorado pp 77 94 ISBN 978 1 60732 316 7 OCLC 903563629 a b c d White C E Shelton C P 2014 Recovering Macrobotanical Remains Current Methods and Techniques In Marston J M d Alpoim Guedes J Warriner C eds Method and theory in paleoethnobotany Boulder University Press of Colorado pp 95 114 ISBN 978 1 60732 316 7 OCLC 903563629 Tolar T Jacomet S Veluscek A Cufar K 2009 Recovery techniques for waterlogged archaeological sediments a comparison of different treatment methods for samples from Neolithic lake shore settlements Vegetation History and Archaeobotany 19 1 53 67 doi 10 1007 s00334 009 0221 y ISSN 1617 6278 S2CID 54768558 a b Fritz G Nesbitt M 2014 Laboratory Analysis and Identification of Plant Remains In Marston J M d Alpoim Guedes J Warriner C eds Method and Theory in Paleoethnobotany Boulder University Press of Colorado pp 115 145 ISBN 978 1 60732 316 7 OCLC 903563629 a b Piperno D R 2006 Phytoliths a comprehensive guide for archaeologists and paleoecologists Lanham MD AltaMira Press ISBN 0 7591 0384 4 OCLC 60705579 a b c Marston J M 2014 Ratios and Simple Statistics in Paleoethnobotanical Analysis Data Exploration and Hypothesis Testing In Marston J M d Alpoim Guedes J Warriner C eds Method and theory in paleoethnobotany Boulder University Press of Colorado pp 163 179 ISBN 978 1 60732 316 7 OCLC 903563629 Smith A 2014 The Use of Multivariate Statistics within Archaeobotany In Marston J M d Alpoim Guedes J Warriner C eds Method and Theory in Paleoethnobotany Boulder University Press of Colorado pp 181 204 ISBN 978 1 60732 316 7 OCLC 903563629 McKerracher M Hamerow H Bogaard A Bronk Ramsey C Charles M Forster E Hodgson J Holmes M Neil S Roushannafas T Thomas R 2023 Feeding Anglo Saxon England a bioarchaeological dataset for the study of early medieval agriculture Data paper Internet Archaeology 61 doi 10 11141 ia 61 5 Hansson Ann Marie 1994 Grain paste porridge and bread Ancient cereal based food Laborativ Arkeologi 7 5 20 Fechner Kai Mesnil Marianne 2002 Pain fours et foyers des temps passes Bread Ovens and Hearths of the Past Civilisations Bruxelles Universite Libre de Bruxelles 49 1 2 400 doi 10 4000 civilisations 964 Gonzalez Carretero Lara Wollstonecroft Michele Fuller Dorian Q 2017 A methodological approach to the study of archaeological cereal meals a case study at Catalhoyuk East Turkey Vegetation History and Archaeobotany 26 4 415 432 doi 10 1007 s00334 017 0602 6 PMC 5486841 PMID 28706348 Heiss Andreas G Antolin Ferran Bleicher Niels Harb Christian Jacomet Stefanie Kuhn Marlu Marinova Elena Stika Hans Peter Valamoti Soultana Maria 2017 State of the t art Analytical approaches in the investigation of components and production traits of archaeological bread like objects applied to two finds from the Neolithic lakeshore settlement Parkhaus Opera Zurich Switzerland PLOS ONE 12 8 e0182401 doi 10 1371 journal pone 0182401 PMC 5542691 PMID 28771539 Heiss Andreas G Antolin Ferran Berihuete Azorin Marian Biederer Benedikt Erlach Rudolf Gail Niki Griebl Monika Linke Robert Lochner Michaela Marinova Elena Oberndorfer Daniel Stika Hans Peter Valamoti Soultana Maria 2019 The Hoard of the Rings Odd annular bread like objects as a case study for cereal product diversity at the Late Bronze Age hillfort site of Stillfried Lower Austria PLOS ONE 14 6 e0216907 doi 10 1371 journal pone 0216907 PMC 6550392 PMID 31166950 Bates Jennifer Willcox Black Kelly Morrison Kathleen D 2022 Millet bread and pulse dough from early Iron Age South India Charred food lumps as culinary indicators Journal of Archaeological Science 137 105531 doi 10 1016 j jas 2021 105531 S2CID 245031081 Valamoti S M 2018 Brewing beer in wine country First archaeobotanical indications for beer making in Early and Middle Bronze Age Greece Vegetation History and Archaeobotany 27 4 611 625 doi 10 1007 s00334 017 0661 8 ISSN 1617 6278 S2CID 135345407 Wang J Liu L Ball T Yu L Li Y Xing F 2016 Revealing a 5 000 y old beer recipe in China Proceedings of the National Academy of Sciences 113 23 6444 6448 doi 10 1073 pnas 1601465113 ISSN 0027 8424 PMC 4988576 PMID 27217567 Heiss A G Berihuete Azorin M Antolin F Kubiak Martens L Marinova E Arendt E K Biliaderis C G Kretschmer H Lazaridou A Stika H P Zarnkow M Baba M Bleicher N Cialowicz K M Chlodnicki M Matuschik I Schlichtherle H Valamoti S M 2020 05 07 Mashes to Mashes Crust to Crust Presenting a novel microstructural marker for malting in the archaeological record PLOS ONE 15 5 e0231696 Bibcode 2020PLoSO 1531696H doi 10 1371 journal pone 0231696 ISSN 1932 6203 PMC 7205394 PMID 32379784 Margaritis E Jones M 2006 Beyond cereals crop processing and Vitis vinifera L Ethnography experiment and charred grape remains from Hellenistic Greece Journal of Archaeological Science 33 6 784 805 doi 10 1016 j jas 2005 10 021 ISSN 0305 4403 Valamoti S M Darcque P Chrysanthaki C K Malamidou D Tsirtsoni Z 2015 Diler A Kaan Senol A Aydinoglu U eds Olive Oil and Wine Production in Eastern Mediterranean During Antiquity International Symposium proceedings 17 19 November 2011 Urla Turkey Antikcag da Dogu Akdeniz de Zeytinyagi ve Sarap Uretimi Uluslararasi Sempozyum bildirileri 17 19 Kasim 2011 Urla Izmir Izmir Ege Universitesi Edebiyat Fakultesi Yayinlari pp 127 139 ISBN 978 605 338 120 4 OCLC 975246689 Andreou S Heron C Jones G Kiriatzi V Psaraki K Roumpou M Valamoti S M 2013 Smelly Barbarians or Perfumed Natives In Voutsaki F Valamoti S M eds Diet economy and society in the ancient Greek world towards a better integration of archaeology and science proceedings of the International Conference held at the Netherlands Institute at Athens on 22 24 March 2010 Leuven Peeters pp 173 185 ISBN 978 90 429 2724 7 OCLC 862107818 Chauhan M P Singh S Singh A K 2009 12 01 Post Harvest Uses of Linseed Journal of Human Ecology 28 3 217 219 doi 10 1080 09709274 2009 11906243 ISSN 0970 9274 S2CID 111310895 Hall A R 1996 A survey of palaeobotanical evidence for dyeing and mordanting from British archaeological excavations Quaternary Science Reviews 15 5 6 635 640 Bibcode 1996QSRv 15 635H doi 10 1016 0277 3791 96 83683 3 ISSN 0277 3791 Kofel D 2019 To Dye or Not to Dye Bioarchaeological Studies of Hala Sultan Tekke Site Cyprus Swiatowit 56 1 89 98 ISSN 0082 044X S2CID 187373177 Bogaard A Jones G Charles M 2005 The impact of crop processing on the reconstruction of crop sowing time and cultivation intensity from archaeobotanical weed evidence Vegetation History and Archaeobotany 14 4 505 509 doi 10 1007 s00334 005 0061 3 ISSN 1617 6278 S2CID 132300293 Jones G Bogaard A Halstead P Charles M Smith H 1999 Identifying the Intensity of Crop Husbandry Practices on the Basis of Weed Floras The Annual of the British School at Athens 94 167 189 doi 10 1017 S0068245400000563 ISSN 0068 2454 JSTOR 30103457 S2CID 128393537 Nitsch E K Jones G Sarpaki A Hald M M Bogaard A 2019 Farming Practice and Land Management at Knossos Crete New Insights from d13C and d15N Analysis of Neolithic and Bronze Age Crop Remains In Garcia D Orgeolet R Pomadere M Zurbach J eds Country in the city agricultural functions of protohistoric urban settlements Aegean and Western Mediterranean Oxford Archaeopress pp 152 168 ISBN 978 1 78969 133 7 OCLC 1123912620 Papanthimou A Valamoti S M Papadopoulou E Tsagkaraki E Voulgari E 2013 Food Storage in the Context of an Early Bronze Age Household Economy New Evidence from Archontiko Gianniston In Voutsaki S Valamoti S M eds Diet economy and society in the ancient Greek world towards a better integration of archaeology and science proceedings of the International Conference held at the Netherlands Institute at Athens on 22 24 March 2010 Leuven Peeters pp 103 111 ISBN 978 90 429 2724 7 OCLC 862107818 Margaritis E 2015 Agricultural Production and Domestic Activities In Rural Hellenistic Greece In Harris E M Lewis D M Woolmer M eds The Ancient Greek Economy Markets Households and City States Cambridge Cambridge University Press pp 187 203 ISBN 978 1 139 56553 0 OCLC 941031010 Willcox G Tengberg M 1995 Preliminary report on the archaeobotanical investigations at Tell Abraq with special attention to chaff impressions in mud brick Arabian Archaeology and Epigraphy 6 2 129 138 doi 10 1111 aae 1995 6 2 129 ISSN 1600 0471 Braadbaart F Marinova E Sarpaki A 2016 Charred olive stones experimental and archaeological evidence for recognizing olive processing residues used as fuel Vegetation History and Archaeobotany 25 5 415 430 doi 10 1007 s00334 016 0562 2 ISSN 1617 6278 S2CID 131380871 Fall P L Falconer S E Klinge J 2015 Bronze age fuel use and its implications for agrarian landscapes in the eastern Mediterranean Journal of Archaeological Science Reports 4 182 191 doi 10 1016 j jasrep 2015 09 004 ISSN 2352 409X Margaritis E 2014 Acts of Destruction and Acts of Preservation Plants in the Ritual Landscape of Prehistoric Greece In Touchais G Laffineur R Rougemont F eds Physis l environnement naturel et la relation homme milieu dans le monde egeen protohistorique actes de la 14e Rencontre egeenne internationale Paris Institut National d Histoire de l Art INHA 11 14 decembre 2012 Aegeum 37 Leuven Peeters pp 279 285 ISBN 978 90 429 3195 4 OCLC 903002501 Bibliography editTwiss K C 2019 The Archaeology of Food Cambridge Cambridge University Press ISBN 9781108670159 Kristen J G 1997 People Plants and Landscapes Studies in Paleoethnobotany Alabama University of Alabama Press ISBN 0 8173 0827 X Miksicek C H 1987 Formation Processes of the Archaeobotanical Record In M B Schiffer ed Advances in Archaeological Method and Theory 10 New York Academic Press 211 247 ISBN 0 12 003110 8 External links editInternational Associations Association of Environmental Archaeology AEA International Work Group for Palaeoethnobotany IWGP Journals Vegetation History and Archaeobotany exclusively publishing archaeobotanical palaeoethnobotanical research official publishing organ of the IWGP Archaeological and Anthropological Sciences Environmental Archaeology Interdisciplinaria Archaeologica IANSA Various knowledge resources ArchBotLit Kiel University Digital Plant Atlas Groningen University Integrated Archaeobotanical Research Project IAR originally hosted at the University of Sheffield Terry B Ball Phytolith Literature Review Steve Archer About Phytoliths Alwynne B Beaudoin The Dung File Retrieved from https en wikipedia org w index php title Paleoethnobotany amp oldid 1193591290, wikipedia, wiki, book, books, library,

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