UCIAMS-91198

radiocarbon date Radiocarbon date from Uxbenka, c. 1704–1605 cal BP
Record created in XRONOS on 2022-12-02 00:50:45 UTC. Last updated on 2022-12-02 00:50:45 UTC. See changelog for details.
Contributors: XRONOS development team

Measurement

Age (uncal BP)
1755
Error (±)
15
Lab
NA
Method
NA
Sample material
ÃÂÂ
Sample taxon
NA

Calibration

Calibration curve
IntCal20 (Reimer et al. 2020)
Calibrated age (2σ, cal BP)
  • 1704–1687
  • 1674–1605

Context

Site
Uxbenka
Context
Sample position
NA
Sample coordinates
NA

Bibliographic reference Bibliographic references (25)

@misc{Prufer et al. 2017,
  
}
@article{p3k14c,
  title = {P3k14c, a Synthetic Global Database of Archaeological Radiocarbon Dates},
  author = {Bird, Darcy and Miranda, Lux and Vander Linden, Marc and Robinson, Erick and Bocinsky, R. Kyle and Nicholson, Chris and Capriles, José M. and Finley, Judson Byrd and Gayo, Eugenia M. and Gil, Adolfo and d’Alpoim Guedes, Jade and Hoggarth, Julie A. and Kay, Andrea and Loftus, Emma and Lombardo, Umberto and Mackie, Madeline and Palmisano, Alessio and Solheim, Steinar and Kelly, Robert L. and Freeman, Jacob},
  year = {2022},
  month = {jan},
  journal = {Scientific Data},
  volume = {9},
  number = {1},
  pages = {27},
  publisher = {Nature Publishing Group},
  issn = {2052-4463},
  doi = {10.1038/s41597-022-01118-7},
  abstract = {Archaeologists increasingly use large radiocarbon databases to model prehistoric human demography (also termed paleo-demography). Numerous independent projects, funded over the past decade, have assembled such databases from multiple regions of the world. These data provide unprecedented potential for comparative research on human population ecology and the evolution of social-ecological systems across the Earth. However, these databases have been developed using different sample selection criteria, which has resulted in interoperability issues for global-scale, comparative paleo-demographic research and integration with paleoclimate and paleoenvironmental data. We present a synthetic, global-scale archaeological radiocarbon database composed of 180,070 radiocarbon dates that have been cleaned according to a standardized sample selection criteria. This database increases the reusability of archaeological radiocarbon data and streamlines quality control assessments for various types of paleo-demographic research. As part of an assessment of data quality, we conduct two analyses of sampling bias in the global database at multiple scales. This database is ideal for paleo-demographic research focused on dates-as-data, bayesian modeling, or summed probability distribution methodologies.},
  copyright = {2022 The Author(s)},
  langid = {english},
  keywords = {Archaeology,Chemistry},
  month_numeric = {1}
}
@misc{Prufer et al. 2011,
  
}
@misc{Prufer et al. 2008: Table 1; Prufer et al. 2011,
  
}
@misc{Prufer et al. 2011; Culleton et al. 2012,
  
}
@misc{Culleton et al. 2012,
  
}
@misc{Prufer et al. 2008: Table 1; Culleton et al. 2012,
  
}
@misc{Aquino et al. 2013: Table 1,
  
}
@misc{Prufer et al. 2008: Table 1; Prufer et al. 2011; Culleton et al. 2012,
  
}
@misc{McKillop 2002: Table 5.3,
  
}
@misc{Prufer 2002:Table 8.2,
  
}
@misc{Aquino et al. 2013: 273,
  
}
@misc{Minnesota state database,
  
}
@misc{Mackay A. (2016). Three arcs: observations on the archaeology of the Elands Bay and northern Cederberg landscapes. Southern African Humanities 29 1-15.,
  
}
@misc{MesoRAD2020,
  
}
@misc{Kennett et al. 2014 Table 1,
  
}
@misc{Waters M.; Amoroso T. & Stafford T. 2015. Redating Fell's Cave Chile and the Chronological Placement of the Fishtail Projectile Point. American Antiquity 80(2): 376-386.,
  
}
@misc{Prufer et al. 2011: Table 1,
  
}
@misc{REED AND EMSLIE 2008,
  
}
@misc{Areshian 2012,
  
}
@misc{Zori & Urbina 2014,
  
}
@misc{KDC Archaeology 2010 (2007-097 permit),
  
}
@misc{Jenkins et al. 2013,
  
}
@misc{U of O,
  
}
@misc{Manning 2011:25,
  
}
{"bibtex_key":"Prufer et al. 2017","bibtex_type":"misc"}[{"bibtex_key":"p3k14c","bibtex_type":"article","title":"{P3k14c, a Synthetic Global Database of Archaeological Radiocarbon Dates}","author":"{Bird, Darcy and Miranda, Lux and Vander Linden, Marc and Robinson, Erick and Bocinsky, R. Kyle and Nicholson, Chris and Capriles, José M. and Finley, Judson Byrd and Gayo, Eugenia M. and Gil, Adolfo and d’Alpoim Guedes, Jade and Hoggarth, Julie A. and Kay, Andrea and Loftus, Emma and Lombardo, Umberto and Mackie, Madeline and Palmisano, Alessio and Solheim, Steinar and Kelly, Robert L. and Freeman, Jacob}","year":"{2022}","month":"{jan}","journal":"{Scientific Data}","volume":"{9}","number":"{1}","pages":"{27}","publisher":"{Nature Publishing Group}","issn":"{2052-4463}","doi":"{10.1038/s41597-022-01118-7}","abstract":"{Archaeologists increasingly use large radiocarbon databases to model prehistoric human demography (also termed paleo-demography). Numerous independent projects, funded over the past decade, have assembled such databases from multiple regions of the world. These data provide unprecedented potential for comparative research on human population ecology and the evolution of social-ecological systems across the Earth. However, these databases have been developed using different sample selection criteria, which has resulted in interoperability issues for global-scale, comparative paleo-demographic research and integration with paleoclimate and paleoenvironmental data. We present a synthetic, global-scale archaeological radiocarbon database composed of 180,070 radiocarbon dates that have been cleaned according to a standardized sample selection criteria. This database increases the reusability of archaeological radiocarbon data and streamlines quality control assessments for various types of paleo-demographic research. As part of an assessment of data quality, we conduct two analyses of sampling bias in the global database at multiple scales. This database is ideal for paleo-demographic research focused on dates-as-data, bayesian modeling, or summed probability distribution methodologies.}","copyright":"{2022 The Author(s)}","langid":"{english}","keywords":"{Archaeology,Chemistry}","month_numeric":"{1}"}]{"bibtex_key":"Prufer et al. 2011","bibtex_type":"misc"}{"bibtex_key":"Prufer et al. 2008: Table 1; Prufer et al. 2011","bibtex_type":"misc"}{"bibtex_key":"Prufer et al. 2011; Culleton et al. 2012","bibtex_type":"misc"}{"bibtex_key":"Culleton et al. 2012","bibtex_type":"misc"}{"bibtex_key":"Prufer et al. 2008: Table 1; Culleton et al. 2012","bibtex_type":"misc"}{"bibtex_key":"Aquino et al. 2013: Table 1","bibtex_type":"misc"}{"bibtex_key":"Prufer et al. 2008: Table 1; Prufer et al. 2011; Culleton et al. 2012","bibtex_type":"misc"}{"bibtex_key":"McKillop 2002: Table 5.3","bibtex_type":"misc"}{"bibtex_key":"Prufer 2002:Table 8.2","bibtex_type":"misc"}{"bibtex_key":"Aquino et al. 2013: 273","bibtex_type":"misc"}{"bibtex_key":"Minnesota state database","bibtex_type":"misc"}{"bibtex_key":"Mackay A. (2016). Three arcs: observations on the archaeology of the Elands Bay and northern Cederberg landscapes. Southern African Humanities 29 1-15.","bibtex_type":"misc"}{"bibtex_key":"MesoRAD2020","bibtex_type":"misc"}{"bibtex_key":"Kennett et al. 2014 Table 1","bibtex_type":"misc"}{"bibtex_key":"Waters M.; Amoroso T. & Stafford T. 2015. Redating Fell's Cave Chile and the Chronological Placement of the Fishtail Projectile Point. American Antiquity 80(2): 376-386.","bibtex_type":"misc"}{"bibtex_key":"Prufer et al. 2011: Table 1","bibtex_type":"misc"}{"bibtex_key":"REED AND EMSLIE 2008","bibtex_type":"misc"}{"bibtex_key":"Areshian 2012","bibtex_type":"misc"}{"bibtex_key":"Zori & Urbina 2014","bibtex_type":"misc"}{"bibtex_key":"KDC Archaeology 2010 (2007-097 permit)","bibtex_type":"misc"}{"bibtex_key":"Jenkins et al. 2013","bibtex_type":"misc"}{"bibtex_key":"U of O","bibtex_type":"misc"}{"bibtex_key":"Manning 2011:25","bibtex_type":"misc"}
---
:bibtex_key: Prufer et al. 2017
:bibtex_type: :misc
---
- :bibtex_key: p3k14c
  :bibtex_type: :article
  :title: "{P3k14c, a Synthetic Global Database of Archaeological Radiocarbon Dates}"
  :author: "{Bird, Darcy and Miranda, Lux and Vander Linden, Marc and Robinson, Erick
    and Bocinsky, R. Kyle and Nicholson, Chris and Capriles, José M. and Finley, Judson
    Byrd and Gayo, Eugenia M. and Gil, Adolfo and d’Alpoim Guedes, Jade and Hoggarth,
    Julie A. and Kay, Andrea and Loftus, Emma and Lombardo, Umberto and Mackie, Madeline
    and Palmisano, Alessio and Solheim, Steinar and Kelly, Robert L. and Freeman,
    Jacob}"
  :year: "{2022}"
  :month: "{jan}"
  :journal: "{Scientific Data}"
  :volume: "{9}"
  :number: "{1}"
  :pages: "{27}"
  :publisher: "{Nature Publishing Group}"
  :issn: "{2052-4463}"
  :doi: "{10.1038/s41597-022-01118-7}"
  :abstract: "{Archaeologists increasingly use large radiocarbon databases to model
    prehistoric human demography (also termed paleo-demography). Numerous independent
    projects, funded over the past decade, have assembled such databases from multiple
    regions of the world. These data provide unprecedented potential for comparative
    research on human population ecology and the evolution of social-ecological systems
    across the Earth. However, these databases have been developed using different
    sample selection criteria, which has resulted in interoperability issues for global-scale,
    comparative paleo-demographic research and integration with paleoclimate and paleoenvironmental
    data. We present a synthetic, global-scale archaeological radiocarbon database
    composed of 180,070 radiocarbon dates that have been cleaned according to a standardized
    sample selection criteria. This database increases the reusability of archaeological
    radiocarbon data and streamlines quality control assessments for various types
    of paleo-demographic research. As part of an assessment of data quality, we conduct
    two analyses of sampling bias in the global database at multiple scales. This
    database is ideal for paleo-demographic research focused on dates-as-data, bayesian
    modeling, or summed probability distribution methodologies.}"
  :copyright: "{2022 The Author(s)}"
  :langid: "{english}"
  :keywords: "{Archaeology,Chemistry}"
  :month_numeric: "{1}"
---
:bibtex_key: Prufer et al. 2011
:bibtex_type: :misc
---
:bibtex_key: 'Prufer et al. 2008: Table 1; Prufer et al. 2011'
:bibtex_type: :misc
---
:bibtex_key: Prufer et al. 2011; Culleton et al. 2012
:bibtex_type: :misc
---
:bibtex_key: Culleton et al. 2012
:bibtex_type: :misc
---
:bibtex_key: 'Prufer et al. 2008: Table 1; Culleton et al. 2012'
:bibtex_type: :misc
---
:bibtex_key: 'Aquino et al. 2013: Table 1'
:bibtex_type: :misc
---
:bibtex_key: 'Prufer et al. 2008: Table 1; Prufer et al. 2011; Culleton et al. 2012'
:bibtex_type: :misc
---
:bibtex_key: 'McKillop 2002: Table 5.3'
:bibtex_type: :misc
---
:bibtex_key: Prufer 2002:Table 8.2
:bibtex_type: :misc
---
:bibtex_key: 'Aquino et al. 2013: 273'
:bibtex_type: :misc
---
:bibtex_key: Minnesota state database
:bibtex_type: :misc
---
:bibtex_key: 'Mackay A. (2016). Three arcs: observations on the archaeology of the
  Elands Bay and northern Cederberg landscapes. Southern African Humanities 29 1-15.'
:bibtex_type: :misc
---
:bibtex_key: MesoRAD2020
:bibtex_type: :misc
---
:bibtex_key: Kennett et al. 2014 Table 1
:bibtex_type: :misc
---
:bibtex_key: 'Waters M.; Amoroso T. & Stafford T. 2015. Redating Fell''s Cave Chile
  and the Chronological Placement of the Fishtail Projectile Point. American Antiquity
  80(2): 376-386.'
:bibtex_type: :misc
---
:bibtex_key: 'Prufer et al. 2011: Table 1'
:bibtex_type: :misc
---
:bibtex_key: REED AND EMSLIE 2008
:bibtex_type: :misc
---
:bibtex_key: Areshian 2012
:bibtex_type: :misc
---
:bibtex_key: Zori & Urbina 2014
:bibtex_type: :misc
---
:bibtex_key: KDC Archaeology 2010 (2007-097 permit)
:bibtex_type: :misc
---
:bibtex_key: Jenkins et al. 2013
:bibtex_type: :misc
---
:bibtex_key: U of O
:bibtex_type: :misc
---
:bibtex_key: Manning 2011:25
:bibtex_type: :misc

Changelog