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Vegetation History and Archaeobotany

, Volume 24, Issue 3, pp 357–375 | Cite as

Multi-profile fine-resolution palynological and micro-charcoal analyses at Esklets, North York Moors, UK, with special reference to the Mesolithic-Neolithic transition

  • Bruce Albert
  • James Innes
Original Article

Abstract

Multi-proxy palaeoecological data from two peat profiles at Esklets on the North York Moors upland provide a record of vegetation changes for much of the Holocene. Possible vegetation disturbance in the late Mesolithic and activity in the Neolithic and Bronze Age are recognised. In both profiles fine resolution analyses have been applied to the period leading up to the mid-Holocene Elm Decline which in this upland has been dated to ca. 4,800 bp (uncalibrated 14C years). Disturbance impacts at the Esklets Elm Decline are low scale, but phases of woodland disturbance, which include cereal (Hordeum)-type pollen, occur in both profiles ca. 5,200 bp, some centuries before the Elm Decline on the North York Moors, but similar to dates for this key palynological horizon in nearby lowland areas. A protocol is presented for the separation of Hordeum (cultivated species) and Glyceria (wild grass) pollen. The Esklets sites record disturbances during the late Mesolithic-Neolithic transition. These pre-Elm Decline disturbance phases represent either early penetration of neolithic cultivator-pastoralists into this upland or the activities of final mesolithic foragers. No neolithic archaeological sites occur nearby, but a ‘Terminal Mesolithic’ flint site dominated by microlith ‘rod’ forms occurs close to the palaeoecological sites. Such rod sites are dated in northern England to the centuries leading up to 5,000 bp and so are contemporary with the disturbance phases that included Hordeum-type pollen at Esklets. The cultural context of these disturbance phases and the role of ‘rod’ microlith sites during the Mesolithic-Neolithic transition require further focused research to clarify all issues relating to this important period.

Keywords

Mesolithic-Neolithic transition Palynology Hordeum Woodland disturbance Rod microliths North York Moors 

Notes

Acknowledgments

We are grateful to Chris Orton of the Design and Imaging Unit, Geography Department, Durham University for preparation of the figures, to Charlotte O’Brien for wood identification, to Natasha Barlow for assistance with computer modelling, to the landowner for access to the site and to the Leverhulme Trust for funding the research under project F/00128/BD. Radiocarbon dating was carried out at Poznan Radiocarbon Laboratory, Poland, at SUERC Radiocarbon Dating Laboratory, Glasgow, UK and at Beta Analytic, Florida, USA. We are also grateful to anonymous referees and the editor whose comments led to improvements in the text.

Supplementary material

334_2014_488_MOESM1_ESM.doc (64 kb)
Supplementary material 1 (DOC 64 kb)

References

  1. Andersen ST (1979) Identification of wild grass and cereal pollen. Dan Geol Unders Årb 1978:69–92Google Scholar
  2. Andersen ST (1990) Pollen spectra from two early neolithic lugged jars in the long barrow at Bjørnsholm, Denmark. Dan J Archaeol 9:59–63Google Scholar
  3. Atherden M (1976) The impact of late prehistoric cultures on the vegetation of the North York Moors. Trans Inst Brit Geogr NS 1:284–300CrossRefGoogle Scholar
  4. Atherden M (1989) Three pollen diagrams from the eastern North York Moors. Naturalist 114:55–63Google Scholar
  5. Bartley DD, Chambers C, Hart-Jones B (1976) The vegetational history of parts of south and east Durham. New Phytol 77:437–468CrossRefGoogle Scholar
  6. Behre K-E (1981) The interpretation of anthropogenic indicators in pollen diagrams. Pollen Spores 23:225–245Google Scholar
  7. Behre K-E (2007) Evidence for mesolithic agriculture in and around central Europe? Veget Hist Archaeobot 16:203–219CrossRefGoogle Scholar
  8. Behre K-E, Kučan D (1986) Die Reflektion archäologisch bekannter Siedlungen in Pollendiagrammen verschiedener Entfernung—Beispiel aus der Siedlungskammer Flögeln, Nordwestdeutschland. In: Behre K-E (ed) Anthropogenic indicators in pollen diagrams. Balkema, Rotterdam, pp 95–114Google Scholar
  9. Berglund BE, Ralska-Jasiewiczowa M (1986) Pollen analysis and pollen diagrams. In: Berglund BE (ed) Handbook of Holocene palaeoecology and palaeohydrology. Wiley, New York, pp 455–484Google Scholar
  10. Beug H-J (2004) Leitfaden der Pollenbestimmung für Mitteleuropa und angrenzende Gebiete. Pfeil, MünchenGoogle Scholar
  11. Blackford JJ (2000) Charcoal fragments in surface samples following a fire and the implications for interpretation of subfossil charcoal data. Palaeogeogr Palaeoclimatol Palaeoecol 164:33–42CrossRefGoogle Scholar
  12. Blackford JJ, Chambers FM (1999) Harold’s Bog, East Bilsdale Moor. In: Bridgland DR, Horton BP, Innes JB (eds) The Quaternary of north-east England field guide. Quaternary Research Association, London, pp 91–98Google Scholar
  13. Blackford JJ, Innes JB, Hatton JJ, Caseldine CJ (2006) Mid-Holocene environmental change at Black Ridge Brook, Dartmoor, SW England: a new appraisal based on fungal spore analysis. Rev Palaeobot Palynol 141:189–201CrossRefGoogle Scholar
  14. Bogucki P (1988) Forest, farmers and stockherders, early agriculture and its consequences in north central Europe. Cambridge University Press, CambridgeGoogle Scholar
  15. Bronk Ramsey C (2008) Depositional models for chronological records. Quat Sci Rev 27:42–60CrossRefGoogle Scholar
  16. Bronk Ramsey C (2009) Bayesian analysis of radiocarbon dates. Radiocarbon 51:337–360Google Scholar
  17. Brown AG, Hatton J, O’Brien CE, Selby KA, Stuijts I, Caseldine CJ (2005) Vegetation, landscape and human activity in Midland Ireland: mire and lake records from the Lough Kinale-Derragh Lough area, Central Ireland. Veget Hist Archaeobot 14:81–98CrossRefGoogle Scholar
  18. Bush MB (1988) Early mesolithic disturbance: a force on the landscape. J Archaeol Sci 15:453–462CrossRefGoogle Scholar
  19. Chatterton R (2007) South Haw, northern England. An upland mesolithic site in context. In: Waddington C, Pedersen K (eds) mesolithic studies in the North Sea basin and beyond. Oxbow Books, Oxford, pp 69–80Google Scholar
  20. Chiverrell R (2001) A proxy record of late Holocene climate change from May Moss, northeast England. J Quat Sci 16:9–29CrossRefGoogle Scholar
  21. Clarke C (1994) Differential recovery of fungal and algal palynomorphs versus embryophyte pollen and spores by three processing techniques. In: Davis OK (ed) Aspects of archaeological palynology: methodology and applications, vol 29. AASP Contributions Series, Dallas, pp 53–62Google Scholar
  22. Crombé P, Perdaen Y, Sergant J, Van Roeyen J-P, Van Strydonck M (2002) The Mesolithic-Neolithic transition in the sandy lowlands of Belgium: new evidence. Antiquity 76:699–706CrossRefGoogle Scholar
  23. Deforce K, Bastiaens J, Van Neer W, Ervynck A, Lentacker A, Sergant J, Crombé P (2013) Wood charcoal and seeds as indicators for animal husbandry in a wetland site during the late mesolithic-early neolithic transition period (Swifterbant culture, ca. 4600-4000 bc.) in NW Belgium. Veget Hist Archaeobot 22:51–60CrossRefGoogle Scholar
  24. Edwards KJ (1981) The separation of Corylus and Myrica pollen in modern and fossil samples. Pollen Spores 23:205–218Google Scholar
  25. Edwards KJ (1993) Models of forest farming for north-west Europe. In: Chambers FM (ed) Climate change and human impact on the landscape. Chapman and Hall, London, pp 134–145Google Scholar
  26. Ghilardi B, O’Connell M (2013) Fine-resolution pollen-analytical study of Holocene woodland dynamics and land use in north Sligo, Ireland. Boreas 42:623–649CrossRefGoogle Scholar
  27. Göransson H (1982) The utilization of the forests in North-West Europe during early and middle neolithic. PACT 7:207–221Google Scholar
  28. Griffiths S (2014) Points in time: the Mesolithic-Neolithic transition and the chronology of late rod microliths in Britain. Oxford J Archaeol 33:221–243CrossRefGoogle Scholar
  29. Hall VA, Pilcher JR, Bowler M (1993) Pre-Elm Decline cereal size pollen: evaluating its recruitment to fossil deposits using modern pollen rain studies. Biol Environ (Proc R Ir Acad) 93B:1–4Google Scholar
  30. Hartz S, Lübke H, Terberger T (2007) From fish and seal to sheep and cattle: new research into the process of neolithisation in northern Germany. In: Whittle A, Cummings V (eds) Going over. The Mesolithic-Neolithic transition in North-West Europe. Proceedings of the British Academy, Oxford, 144, pp 287–309Google Scholar
  31. Hayes RH (1988) Some mesolithic sites on the North York Moors. In: Wilson PR (ed) North-East Yorkshire studies: archaeological papers. Yorkshire Archaeological Society, Leeds, pp 1–27Google Scholar
  32. Hejcmanová P, Stejskalová M, Hejcman M (2014) Forage quality of leaf-fodder from the main broad-leaved woody species and its possible consequences for the Holocene development of forest vegetation in Central Europe. Veget Hist Archaeobot 23:607–613CrossRefGoogle Scholar
  33. Innes JB (2008) Tree remains from a buried mid-Holocene palaeoforest in upland north-east Yorkshire. Quat Newsl 115:40–43Google Scholar
  34. Innes JB, Blackford JJ (2003) The ecology of late mesolithic woodland disturbances: model testing with fungal spore assemblage data. J Archaeol Sci 30:185–194CrossRefGoogle Scholar
  35. Innes J, Blackford J (2009) An evaluation of palaeoecological data as evidence of cultural transition in the final mesolithic millennium of northern and north-western Europe. In: Crombé P, Van Strydonck M, Sergant J, Boudin M, Bats M (eds) Chronology and evolution within the mesolithic of north-west Europe. Proceedings of an international meeting, Brussels, May 30th-June 1st 2007. Cambridge Scholars Publishing, Newcastle upon Tyne, pp 573–590Google Scholar
  36. Innes JB, Simmons IG (1988) Disturbance and diversity: floristic changes associated with pre-Elm Decline woodland recession in north-east Yorkshire. In: Jones M (ed) Archaeology and the flora of the British Isles. Oxford University Committee for Archaeology, OxfordGoogle Scholar
  37. Innes JB, Simmons IG (2000) Mid-Holocene charcoal stratigraphy, fire history and palaeoecology at North Gill, North York Moors, UK. Palaeogeogr Palaeoclimatol Palaeoecol 164:151–165CrossRefGoogle Scholar
  38. Innes JB, Blackford JJ, Simmons IG (2010) Woodland disturbance and possible land-use regimes during the late mesolithic in the English uplands: pollen, charcoal and non-pollen palynomorph evidence from Bluewath Beck, North York Moors, UK. Veget Hist Archaeobot 19:439–452CrossRefGoogle Scholar
  39. Innes JB, Blackford JJ, Simmons IG (2011) Mesolithic environments at Star Carr, the eastern vale of Pickering and environs: local and regional contexts. J Wetl Archaeol 11:85–108CrossRefGoogle Scholar
  40. Innes JB, Laurie T, Simmons IG (2012) The age of the late mesolithic on the North York Moors, England: radiocarbon dating of a small flint artefact stratified within peat from East Bilsdale Moor. J Wetl Archaeol 12:48–57CrossRefGoogle Scholar
  41. Innes JB, Blackford JJ, Rowley-Conwy PA (2013) Late mesolithic and early neolithic forest disturbance: a high resolution palaeoecological test of human impact hypotheses. Quat Sci Rev 77:80–100CrossRefGoogle Scholar
  42. Jacobi RM (1978) Northern England in the eighth millennium bc: an essay. In: Mellars P (ed) The early postglacial settlement of northern Europe. Duckworth, London, pp 295–332Google Scholar
  43. Joly C, Barillé L, Barreau M, Mancheron A, Visset L (2007) Grain and annulus diameter as criteria for distinguishing pollen grains or cereals from wild grasses. Rev Palaeobot Palynol 146:221–233CrossRefGoogle Scholar
  44. Kolářová M, Tyšer L, Soukup J (2014) Weed vegetation of arable land in the Czech Republic: environmental and management factors determining weed species composition. Biologia 69:443–448Google Scholar
  45. Krause-Kyora B, Makarewicz C, Evin A, Flink LG, Dobney K, Larson G, Hartz S, Schreiber S, Von Carnap-Bornheim C, Von Wurmb-Schwark N, Nebel A (2013) Use of domesticated pigs by mesolithic hunter-gatherers in northwest Europe, Nature Comm, 4 (2348) doi: 10.1038/ncomms3348Google Scholar
  46. Kuneš P, Pokorný P, Šída P (2008) Detection of the impact of early Holocene hunter-gatherers on vegetation in the Czech Republic, using multivariate analysis of pollen data. Veget Hist Archaeobot 17:269–287CrossRefGoogle Scholar
  47. Manby TC, King A, Vyner B (2003) The neolithic and Bronze Ages: a time of early agriculture. In: Manby TC, Moorhouse S, Ottaway P (eds) The archaeology of Yorkshire. An assessment at the beginning of the 21st century. Yorkshire Archaeological Society Occasional Paper 3, Leeds, pp 35–116Google Scholar
  48. Moore PD (1996) Hunting ground for farmers. Nature 382:675–676CrossRefGoogle Scholar
  49. Moore PD, Webb JA, Collinson ME (1991) Pollen analysis, 2nd edn. Blackwell, OxfordGoogle Scholar
  50. O’Connell M, Molloy K (2001) Farming and woodland dynamics in Ireland during the neolithic. Biol Environ (Proc R Ir Acad) 101B:99–128Google Scholar
  51. Out W, Verhoeven K (2014) Late mesolithic and early neolithic human impact at Dutch wetland sites: the case study of Hardinxveld-Giessendam De Bruin. Veget Hist Archaeobot 23:41–56CrossRefGoogle Scholar
  52. Parker AG, Goudie AS, Anderson DE, Robinson MA, Bonsall C (2002) A review of the mid-Holocene Elm Decline in the British Isles. Prog Phys Geog 26:1–45CrossRefGoogle Scholar
  53. Peglar SM, Birks HJB (1993) The mid-Holocene Ulmus fall at Diss Mere, south-east England—disease and human impact? Veget Hist Archaeobot 2:61–68Google Scholar
  54. Perrin T (2003) Mesolithic and neolithic cultures co-existing in the upper Rhône valley. Antiquity 77:732–739CrossRefGoogle Scholar
  55. Pokorný P, Šída P, Chvojka O, Žačková P, Kuneš P, Světlík I, Veselý J (2009) Palaeoenviromental research of the Schwarzenberg Lake, southern Bohemia, and exploratory excavations of this key mesolithic archaeological area. Památky Archeol 101:5–48Google Scholar
  56. Punt W, Marks A, Hoen PP (2002) The Northwest European pollen flora, 66: myricaceae. Rev Palaeobot Palynol 123:99–105CrossRefGoogle Scholar
  57. Reimer PJ, Bard E, Bayliss A, Beck JW, Blackwell PG, Bronk Ramsey C, Grootes PM, Guilderson TP, Haflidason H, Hajdas I, Hattz C, Heaton TJ, Hoffmann DL, Hogg AG, Hughen KA, Kaiser KF, Kromer B, Manning SW, Niu M, Reimer RW, Richards DA, Scott EM, Southon JR, Staff RA, Turney CSM, van der Plicht J (2013) IntCal13 and Marine13 radiocarbon age calibration curves 0–50,000 Years cal. bp. Radiocarbon 55:1,869–1,877Google Scholar
  58. Robinson D (1984) The estimation of the charcoal content of sediments. A comparison of methods on peat sections from the Isle of Arran. Circaea 2:121–128Google Scholar
  59. Rowley-Conwy P (1981) Slash and burn in the temperate European neolithic. In: Mercer R (ed) Farming practice in British prehistory. Edinburgh University Press, Edinburgh, pp 85–96Google Scholar
  60. Simmons IG (1969) Pollen diagrams from the North York Moors. New Phytol 69:807–827CrossRefGoogle Scholar
  61. Simmons IG (1975) Towards an ecology of mesolithic man in the uplands of Great Britain. J Archaeol Sci 2:1–15CrossRefGoogle Scholar
  62. Simmons IG (1996) The environmental impact of later mesolithic cultures. Edinburgh University Press, EdinburghGoogle Scholar
  63. Simmons IG, Cundill PR (1974) Late Quaternary vegetational history of the North York Moors I. Pollen analyses of blanket peats. J Biogeogr 1:159–169CrossRefGoogle Scholar
  64. Simmons IG, Innes JB (1981) Tree remains in a North York Moors peat profile. Nature 294:76–78CrossRefGoogle Scholar
  65. Simmons IG, Innes JB (1985) Late mesolithic land-use and its impacts in the English uplands. Biogeogr Monogr 2:7–17Google Scholar
  66. Simmons IG, Innes JB (1988a) Studies in the Late Quaternary vegetational history of the North York Moors. VIII. Correlation of Flandrian II litho- and pollen stratigraphy at North Gill, Glaisdale Moor. J Biogeogr 15:249–272CrossRefGoogle Scholar
  67. Simmons IG, Innes JB (1988b) Late Quaternary vegetational history of the North York Moors. X. Investigations on East Bilsdale Moor. J Biogeogr 15:299–324CrossRefGoogle Scholar
  68. Simmons IG, Innes JB (1996a) An episode of prehistoric canopy manipulation. J Archaeol Sci 23:337–341CrossRefGoogle Scholar
  69. Simmons IG, Innes JB (1996b) The ecology of an episode of prehistoric cereal cultivation on the North York Moors, England. J Archaeol Sci 23:613–618CrossRefGoogle Scholar
  70. Simmons IG, Atherden MA, Cloutman EW, Cundill PR, Innes JB, Jones RL (1993) Prehistoric environments. In: Spratt DA (ed) Prehistoric and Roman archaeology of north-east Yorkshire, vol 87, CBA Research Report, London, pp 15–50Google Scholar
  71. Sørensen L, Karg S (2014) The expansion of agrarian societies towards the north—new evidence for agriculture during the mesolithic/neolithic transition in Southern Scandinavia. J Archaeol Sci 51:98–114CrossRefGoogle Scholar
  72. Spikins PA (1999) Mesolithic northern England: environment, population and settlement, BAR British Series 283. Archaeopress, OxfordGoogle Scholar
  73. Spikins PA (2002) Prehistoric people of the Pennines. West Yorkshire Archaeological Service, LeedsGoogle Scholar
  74. Spratt DA (ed) (1993) Prehistoric and roman archaeology of north east Yorkshire. CBA Research Report 87, LondonGoogle Scholar
  75. Switsur VR, Jacobi RM (1975) Radiocarbon dates for the Pennine mesolithic. Nature 256:32–34CrossRefGoogle Scholar
  76. Tinner W, Nielsen EH, Lotter AF (2007) Mesolithic agriculture in Switzerland? A critical review of the evidence. Quat Sci Rev 26:1,416–1,431CrossRefGoogle Scholar
  77. Troels-Smith J (1955) Characterisation of unconsolidated sediments. Dan Geol Unders, Række IV 3:1–73Google Scholar
  78. Turner J, Innes JB, Simmons IG (1993) Spatial diversity in the mid-Flandrian vegetation history of North Gill, North Yorkshire. New Phytol 123:599–647CrossRefGoogle Scholar
  79. Tweddle JC, Edwards KJ, Fieller NRJ (2005) Multivariate statistical and other approaches for the separation of cereal from wild Poaceae pollen using a large Holocene dataset. Veget Hist Archaeobot 14:15–30CrossRefGoogle Scholar
  80. Van Geel B (1986) Application of fungal and algal remains and other microfossils in palynological analyses. In: Berglund BE (ed) Handbook of palaeoecology and palynology. Wiley, New York, pp 497–505Google Scholar
  81. Van Geel B (2001) Non-pollen palynomorphs. In: Smol JP, Birks HJB, Last WM (eds) Tracking environmental change using lake sediments, vol 3., terrestrial, algal and siliceous indicators. Kluwer, Dordrecht, pp 99–119CrossRefGoogle Scholar
  82. Van Geel B, Buurman J, Brinkkemper O, Schelvis J, Aptroot A, Van Reenen G, Hakbijl T (2003) Environmental reconstruction of a Roman period settlement site in Uitgeest (The Netherlands), with special reference to coprophilous fungi. J Archaeol Sci 30:873–883CrossRefGoogle Scholar
  83. Wacnik A (2009) From foraging to farming in the Great Mazurian Lake District: palynological studies on lake Miłkowskie sediments, northeast Poland. Veget Hist Archaeobot 18:187–203CrossRefGoogle Scholar
  84. Wheeler BD, Proctor MCF (2000) Ecological gradients, subdivisions and terminology of north-west European mires. J Ecol 88:187–203CrossRefGoogle Scholar
  85. Whittle A, Healy F, Bayliss A (2011) Gathering time: dating the early neolithic enclosures of southern Britain and Ireland. Oxbow Books, OxfordGoogle Scholar
  86. Zvelebil M (1994) Plant use in the mesolithic and its role in the transition to farming. Proc Prehist Soc 60:35–74CrossRefGoogle Scholar

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Authors and Affiliations

  1. 1.Department of Ecology, Faculty of Environmental SciencesCzech Life Sciences UniversityPraha-SuchdolCzech Republic
  2. 2.Geography Department, Science LabsDurham UniversityDurhamUK

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