Hostname: page-component-745bb68f8f-l4dxg Total loading time: 0 Render date: 2025-01-10T18:23:18.873Z Has data issue: false hasContentIssue false
  • English
  • Français

Paiján obsidian points on the coastal desert of southern Peru and their source

Published online by Cambridge University Press:  27 November 2024

Jalh Dulanto Open the ORCID record for Jalh Dulanto [Opens in a new window] ,
Antonio Pérez-Balarezo Open the ORCID record for Antonio Pérez-Balarezo [Opens in a new window] ,
Jesús Briceño Open the ORCID record for Jesús Briceño [Opens in a new window] ,
Juan Yataco Open the ORCID record for Juan Yataco [Opens in a new window] ,
Edwin Silva Open the ORCID record for Edwin Silva [Opens in a new window] ,
Abel Icochea Open the ORCID record for Abel Icochea [Opens in a new window] ,
Dany Tarrillo Open the ORCID record for Dany Tarrillo [Opens in a new window]  and
Daniel Vergara Open the ORCID record for Daniel Vergara [Opens in a new window]
Jalh Dulanto*
Affiliation:
Departamento de Humanidades, Pontificia Universidad Católica del Perú (PUCP), Lima, Peru Grupo de Investigación en Poblamiento Inicial de las Américas, Pontificia Universidad Católica del Perú (GIPAM-PUCP), Lima, Peru Proyecto de Investigaciones Arqueológicas Paracas, Peru
Antonio Pérez-Balarezo
Affiliation:
Departamento de Humanidades, Pontificia Universidad Católica del Perú (PUCP), Lima, Peru Grupo de Investigación en Poblamiento Inicial de las Américas, Pontificia Universidad Católica del Perú (GIPAM-PUCP), Lima, Peru Histoire Naturelle de l'Homme Préhistorique, CNRS, Équipe PRÉTROP, Paris, France Institut Français d’Études Andines (IFEA), Lima, Peru
Jesús Briceño
Affiliation:
Department of Anthropology,University of North Carolina at Chapel Hill, USA Ministerio de Cultura, Trujillo, Peru
Juan Yataco
Affiliation:
Museo de Arqueología y Antropología, Universidad Nacional Mayor de San Marcos, Lima, Peru
Edwin Silva
Affiliation:
Escuela Profesional de Ingeniería Geológica, Universidad Nacional Mayor de San Marcos, Lima, Peru
Abel Icochea
Affiliation:
Proyecto de Investigaciones Arqueológicas Paracas, Peru
Dany Tarrillo
Affiliation:
Grupo de Investigación en Poblamiento Inicial de las Américas, Pontificia Universidad Católica del Perú (GIPAM-PUCP), Lima, Peru
Daniel Vergara
Affiliation:
Grupo de Investigación en Poblamiento Inicial de las Américas, Pontificia Universidad Católica del Perú (GIPAM-PUCP), Lima, Peru
*
*Author for correspondence ✉ jdulant@pucp.pe
Rights & Permissions [Opens in a new window]

Abstract

Limited research exists on preceramic sites in south-central coastal Peru. Systematic survey and excavations at Pampa Lechuza, Ica, now confirm a Late Pleistocene–Early Holocene Paiján (13 000–9000 cal BP) occupation and identify Quispisisa-sourced obsidian Paiján points, which are the only examples currently known to use this raw material.

Keywords

South Americacoastal PerúLate PleistoceneEarly HolocenePXRFhunter-gatherers
Type
Project Gallery
Information
Antiquity , First View , pp. 1 - 8
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Antiquity Publications Ltd

Introduction

The Ica Valley on the south-central coast of Peru represents the known southern limit of the Paiján lithic complex (Bonavia & Chauchat Reference Bonavia and Chauchat1990; Chauchat et al. Reference Chauchat, Wing, Lacombe, Demars, Uceda and Deza2006). Known for their distinctive stemmed bifacial points, Paiján lithics are found along 1000km of the Peruvian coast and date from 13 000 to 9000 cal BP. Research on the Paiján complex has largely been confined to the north coast (Pelegrin & Chauchat Reference Pelegrin and Chauchat1993; Chauchat et al. Reference Chauchat, Wing, Lacombe, Demars, Uceda and Deza2006; Maggard & Dillehay Reference Maggard, Dillehay and Dillehay2011), but a probable site (14B-IV-45 and 14B-IV-46) has been identified in the Quebrada de Pozo Santo, in an oasis within the desert area between the Pisco and Ica valleys (Bonavia & Chauchat Reference Bonavia and Chauchat1990; Engel Reference Engel1991). The site, now known as Pampa Lechuza, was rediscovered in 2010 (Dulanto Reference Dulanto, Vega-Centeno and Dulanto2020); located at 180m above sea level (masl), it is midway between the middle Ica valley and the coast south of the Paracas Peninsula (Figure 1). Given its strategic position as a resting place between these two distinct and complementary ecological zones, systematic surveys and excavations were conducted at the site (Dulanto Reference Dulanto, Vega-Centeno and Dulanto2020).

Figure 1. Location of the Pampa Lechuza site and its relationship with the Quispisisa obsidian source. The 250km least-cost-path between source and find sites is indicated by the dashed line (figure by J. Dulanto & A. Icochea, base map: Google Earth Pro satellite).

Methods

The systematic survey conducted between January and June 2018 covered 30 800m2 and revealed several partially superimposed concentrations of lithics, shells and occasional ceramics. The area was divided into 20 × 20m quadrants for survey and collection (Figure 2); 68 quadrants were classified as low density and nine as high density. Low-density quadrants were surveyed by 2m-wide transects, and materials were collected individually. A Trimble M3 total station was used to record artefact locations (<10mm error). High-density quadrants were surveyed by 0.5 × 0.5m squares, and materials were collected in bulk from each square.

Figure 2. Mapping 20 × 20m quadrants for systematic surveys and collection, with the spatial distribution of the obsidian points (P) highlighted (figure by J. Dulanto & A. Icochea).

Results and discussion

More than 170 000 lithics and 59 ceramic sherds were collected during the survey. The lithic assemblage is predominantly composed of debitage, accounting for more than 162 000 items. The assemblage also includes over 4000 tools and more than 4000 other types of artefact and non-local raw materials; 513 artefacts have been identified as points in various stages of manufacture.

Diagnostic Paiján lithics include stemmed bifacial points, bifacial foliate pieces, unifaces and other tools on flakes, blocks, pebbles and cobbles. Among the 513 bifacial points, seven were made of obsidian. Five are fragmentary (distal tips and small retouch or resharpening flakes) and were found towards the north of the site; two more complete points (6419 & 6420) were found towards the south (Figures 2 & 3). Generally, the fragments exhibit the same colouration as the points, although three are more transparent.

Figure 3. Lithic artefacts from the Paiján complex found at Pampa Lechuza: obsidian Paiján points (6420, 6419, previously illustrated in Dulanto Reference Dulanto, Vega-Centeno and Dulanto2020: 251); fragments of obsidian bifacial points (II160A, 3936, II115D, I214C, 22118); other specimens made from materials other than obsidian (IV19A, 27985, 7044, 10294, II243B) (figure by A. Pérez-Balarezo).

Portable x-ray fluorescence (PXRF) analysis was conducted using a Bruker Tracer 5i Handheld XRF Spectrometer by Laboratorio de Arqueología, Pontificia Universidad Católica del Perú. Results indicate that the obsidian used in all seven points is from the Quispisisa source (Figure 4), located on Cerro Jichqa Parco, Sacsamarca, Ayacucho (Burger & Glascock Reference Burger and Glascock2000). The source sits at 4000masl, 250km from Pampa Lechuza walking to the east (Figure 1). Previous evidence for the exploitation and transport of Quispisisa obsidian during the Late Pleistocene–Early Holocene has been limited to the highlands, although it is found up to 200 linear km from its source (Burger & Asaro Reference Burger and Asaro1978). Pampa Lechuza, at 180 linear km distance, is within this radius. This finding is also consistent with the use of obsidian from highland Alca (Cotahuasi, Arequipa) at the coastal site of Quebrada de Jaguay (150 linear km), during these same early periods (Sandweiss et al. Reference Sandweiss1998).

Figure 4. PXRF results for rubidium (Rb) and strontium (Sr), 90% confidence ellipses for all Peruvian obsidian sources also shown (after Rademaker et al. Reference Rademaker, Glascock, Reid, Zuñiga and Bromley2022, except for Puzolana which was collected and analysed by the authors) (figure by J. Dulanto & A. Pérez-Balarezo).

Artefacts 6419 and 6420 represent the first documented Paiján points made of obsidian in Peru. Both are complete, except for a minor stem fracture on 6419, are made from a dark-grey obsidian and show typical aeolian abrasion. Artefact 6420 shows a bi-convex blade and trifacial stem, measures 47.42 × 26.30 × 4.85mm and weighs 4.53g (Figure 5A & C). Artefact 6419 shows a rhomboidal blade section, measures 39.86 × 26.72 × 4.98mm and weighs 3.2g (Figure 5B & D).

Figure 5. Metric and technological analysis of obsidian Paiján points from Pampa Lechuza. (A, B) Standard photographs. (C, D) Position of measurements: TL, total length; BL, blade length; SL, stem length; SA, symmetry axis; MW, maximum width; BSW, blade/stem intersection width; SMW, stem maximum width; BMT, blade maximum thickness; BST, blade/stem intersection thickness; MT, maximum thickness. (E, F) Diacritical schemes with indication of removals patterns and partial knapping chronology (figure by A. Pérez-Balarezo).

Both artefacts have been shaped from flakes and follow a similar production process, which involved a flaking phase, at least four shaping phases (through soft-hammer percussion) and a final retouching phase (mainly through pressure technique) to achieve the desired outline (Figure 5E & F). These technological features match those previously described for Paiján points from northern Peru (Pelegrin & Chauchat Reference Pelegrin and Chauchat1993). Artefacts 6419 and 6420 also share morphological traits with Paiján points from Pampa de los Fósiles and Ascope, notably at Sites 13, 27 and 5 (Chauchat et al. Reference Chauchat, Wing, Lacombe, Demars, Uceda and Deza2006: 159, 306, 332, figs. 51, 133, 140).

The seven points are part of a larger sample of 682 specimens of Quispisisa obsidian found on the surface of Pampa Lechuza—almost all of which are debitage primarily representing the late stages of the chaîne opératoire. Obsidian artefacts seem to have arrived at Pampa Lechuza as finished or nearly finished products. This suggests that obsidian provisioning from Quispisisa involved not only significant mobility from and/or to the source, but probably also coast-highland intergroup social networks.

Conclusions

Before 2018, Paiján occupation of the south-central Peruvian coastal desert was unconfirmed. The 2018 survey and excavations, and subsequent technological analyses, confirm the Paiján affiliation of the Pampa Lechuza site, and provide evidence of Quispisisa obsidian use by early coastal hunter-gatherers—possibly as early as the Final Pleistocene–Early Holocene. Ongoing technological and sourcing research of these specimens will provide further insights into the mechanisms of exploitation, transport, exchange and use of obsidian on the south coast of Peru during this period.

Acknowledgements

We thank all members of the ‘Proyecto de Investigaciones Arqueológicas Paracas’ and the Sorbonne Université Emergence Project ‘La tropicalité, un mode d’émergence et d'innovations culturelles’.

Funding statement

This research was possible thanks to a research grant from the Dirección de Gestión de la Investigación, Vicerrectorado de Investigación, Pontificia Universidad Católica del Perú.

References

Bonavia, D. & Chauchat, C.. 1990. Presencia del Paijanense en el desierto de Ica. Bulletin de l'Institut Français d'Études Andines 19: 399412. https://doi.org/10.3406/bifea.1990.1013CrossRefGoogle Scholar
Burger, R. & Asaro, F.. 1978. Obsidian distribution and provenience in the central highlands and coast of Peru. Contributions of the University of California Archaeological Research Facility 36: 6183.Google Scholar
Burger, R.L. & Glascock, M.D.. 2000. Locating the Quispisisa obsidian source in the Department of Ayacucho, Peru. Latin American Antiquity 11: 258–68. https://doi.org/10.2307/972177CrossRefGoogle Scholar
Chauchat, C., Wing, E., Lacombe, J.-P., Demars, P.-Y., Uceda, S. & Deza, C.. 2006. Prehistoria de la costa norte del Perú. Lima: Institut Français d’Études Andines, Patronato Huacas del Valle Moche.CrossRefGoogle Scholar
Dulanto, J. 2020. Cazadores-recolectores de la costa surcentral del Perú: hallazgo de un sitio arqueológico con ocupaciones del Pleistoceno Final, el Holoceno Temprano y el Holoceno Medio en la Quebrada de Pozo Santo, in Vega-Centeno, R. & Dulanto, J. (ed.) Los desafíos del tiempo, el espacio y la memoria. Ensayos en homenaje a Peter Kaulicke: 233–60. Lima: Pontificia Universidad Católica del Perú.Google Scholar
Engel, F. 1991. Un desierto en tiempos prehispánicos: río Pisco, Paracas, río Ica. Lima: Centro de Investigación de Zonas Áridas.Google Scholar
Maggard, G. & Dillehay, T.. 2011. El Palto phase (13,800–9,800 BP), in Dillehay, T. (ed.) From foraging to farming in the Andes: new perspectives on food production and social organization: 7794. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Pelegrin, J. & Chauchat, C.. 1993. Tecnología y función de las puntas de Paiján: el aporte de la experimentación. Latin American Antiquity 4: 367–82. https://doi.org/10.2307/972073CrossRefGoogle Scholar
Rademaker, K., Glascock, M., Reid, D., Zuñiga, E. & Bromley, G.. 2022. Comprehensive mapping and compositional analysis of the Alca obsidian source, Peru. Quaternary International 619: 5671. https://doi.org/10.1016/j.quaint.2021.11.029CrossRefGoogle Scholar
Sandweiss, D. et al. 1998. Quebrada Jaguay: early South American maritime adaptations. Science 291: 1830–32. https://doi.org/10.1126/science.281.5384.1830CrossRefGoogle Scholar
Figure 0

Figure 1. Location of the Pampa Lechuza site and its relationship with the Quispisisa obsidian source. The 250km least-cost-path between source and find sites is indicated by the dashed line (figure by J. Dulanto & A. Icochea, base map: Google Earth Pro satellite).

Figure 1

Figure 2. Mapping 20 × 20m quadrants for systematic surveys and collection, with the spatial distribution of the obsidian points (P) highlighted (figure by J. Dulanto & A. Icochea).

Figure 2

Figure 3. Lithic artefacts from the Paiján complex found at Pampa Lechuza: obsidian Paiján points (6420, 6419, previously illustrated in Dulanto 2020: 251); fragments of obsidian bifacial points (II160A, 3936, II115D, I214C, 22118); other specimens made from materials other than obsidian (IV19A, 27985, 7044, 10294, II243B) (figure by A. Pérez-Balarezo).

Figure 3

Figure 4. PXRF results for rubidium (Rb) and strontium (Sr), 90% confidence ellipses for all Peruvian obsidian sources also shown (after Rademaker et al.2022, except for Puzolana which was collected and analysed by the authors) (figure by J. Dulanto & A. Pérez-Balarezo).

Figure 4

Figure 5. Metric and technological analysis of obsidian Paiján points from Pampa Lechuza. (A, B) Standard photographs. (C, D) Position of measurements: TL, total length; BL, blade length; SL, stem length; SA, symmetry axis; MW, maximum width; BSW, blade/stem intersection width; SMW, stem maximum width; BMT, blade maximum thickness; BST, blade/stem intersection thickness; MT, maximum thickness. (E, F) Diacritical schemes with indication of removals patterns and partial knapping chronology (figure by A. Pérez-Balarezo).