Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-21T04:20:08.178Z Has data issue: false hasContentIssue false

Radiocarbon Dates from the Archaeological Site of Sakas, Bihar, India

Published online by Cambridge University Press:  29 April 2024

J Bates*
Affiliation:
Department of Archaeology and Art History, Seoul National University, Seoul 08826, South Korea
V K Singh
Affiliation:
Department of AIHC & Archaeology, Banaras Hindu University, Varanasi-221005, India
R N Singh
Affiliation:
Department of AIHC & Archaeology, Banaras Hindu University, Varanasi-221005, India McDonald Institute for Archaeology, University of Cambridge, Cambridge, UK
Manisha Singh
Affiliation:
Department of AIHC & Archaeology, Banaras Hindu University, Varanasi-221005, India DAV Post Graduate College, Banaras Hindu University, Varanasi-221005, India
Brij Mohan
Affiliation:
Department of AIHC & Archaeology, Viswa-Bharati, Shantiniketan-731204, India
Sudarshan Chakradhari
Affiliation:
Department of History, Babasaheb Bhimrao Ambedkar University, Lucknow-226025, India
Abhay P Singh
Affiliation:
Department of AIHC & Archaeology, Banaras Hindu University, Varanasi-221005, India
Matthew Conte
Affiliation:
Department of Archaeology and Art History, Seoul National University, Seoul 08826, South Korea
Yongje Oh
Affiliation:
Department of Archaeology and Art History, Seoul National University, Seoul 08826, South Korea
*
Corresponding author: J Bates; Email: jbates01@snu.ac.kr
Rights & Permissions [Opens in a new window]

Abstract

Dates from recently excavated Gangetic site of Sakas in Bihar, India, place it at ca.1800–1100 BC. The ceramic and lithic chronologies have been interpreted as Early Farming, Transitional and Chalcolithic/Developed Farming in date. However, depending on where in the Ganges Plains is studied, the time frame of Early, Developed and Advanced Farming periods varies widely, from 7th millennium to 2nd millennium BC and beyond, making the chronological framing of absolute dates within a regional scheme highly complex. In this paper we report the new radiocarbon results from Sakas and note how while these are critical for cementing the absolute dating of the site, until such time as a more stable periodization linked not only to relative and absolute dates but also human lifeways within the different zones of the Ganges plains is created, there remains difficulties in understanding how Sakas and other sites of similar date fit into the changing social, cultural and economic systems in this region.

Type
Research Article
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 (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of University of Arizona

Introduction

The origins of agriculture are of critical importance in archaeology across the world. In South Asia there were multiple processes of agricultural development, including introduced agricultural species and systems such as at Mehrgarh, native domestications such as millets in the Southern Indian Neolithic alongside complex systems of pastoralism before crop cultivation, and indigenous developments in the Ganges (Bates Reference Bates2023). Understanding these processes requires not only good archaeobotanical, zooarchaeological and archaeological data, but also a solid chronological foundation, both relative and absolute.

This has created challenges, as collecting absolute dates (primarily radiocarbon) from South Asian sites has often been difficult. This is either due to a lack of datable material collected or preserved, stratigraphic and contextual difficulties, and the “old wood” problem (see for example Petrie Reference Petrie2015 at Mehrgarh). Relative chronologies and the type site have therefore reigned supreme in chronology creation. This is no more so than in the Ganges during the Early, Advanced and Developed Farming Periods, where tying relative chronologies created through ceramic typing, type sites (such as Lahuradewa) to absolute chronologies and creating an overarching chronological scheme in the Ganges Plains has been an extremely complex endeavor (Begum Reference Begum2010). There have been several radiocarbon dating programs at sites (e.g.: Lahuradewa—Pokharia Reference Pokharia2011; Tewari et al. Reference Tewari, Srivastava, Saraswat, Singh and Singh2008, Reference Tewari, Srivastava, Singh, Saraswat, Singh, Chauhan, Pokharia, Saxena, Prasad and Sharma2006, Reference Tewari, Srivastava, Singh, Vinay, Trivedi and Singh2005, Reference Tewari, Srivastava, Singh, Saraswat and Singh2003; Jhusi—Pokharia Reference Pokharia2008; Pokharia et al. Reference Pokharia, Pal and Srivastava2009; Koldihwa—Sharma Reference Sharma1985; Senuwar— Saraswat Reference Saraswat and Singh2004), but the plains are wide with numerous environmental and cultural microniches, and as yet a comprehensive chronology across these pinned to absolute dates has yet to be established. This challenge is not unique to the Ganges nor South Asia, but a worldwide one, and in this paper we endeavor to highlight how the difficulties of relating an individual site to a regional framework has implications for interpreting not only the site itself but the wider processes around agricultural changes in the Ganges Plains.

Background

The sheer diversity of environmental niches in the Middle Ganges Plains (covering eastern Uttar Pradesh and Bihar) have made it an ideal locality for exploring issues around the origins of agriculture, and subsequent implications of agricultural developments (Figure 1). During the Mesolithic period it has been argued that most sites were focused on or near water. Scholars such as Pandey (Reference Pandey1990) and Pal (Reference Pal, Schug, Walimbe and Kennedy2016) have gone as far as to term them the Mesolithic Lake Cultures, citing sites like Lahuradewa in the north and Chopani Mando in the southeast. Utilizing a broad-spectrum hunting strategy (see Joglekar Reference Joglekar2006; Joglekar et al. Reference Joglekar, Misra, Pal and Gupta2003; Pal Reference Pal, Schug, Walimbe and Kennedy2016) the Mesolithic lifeways were well adapted to exploiting the rich floral and faunal landscapes of the region. Over time though changes towards a more cultivation-centric lifeway is seen, and certainly by the second millennium BC across the entire plains what can be described as an agricultural culture or set of cultures is apparent, attested at numerous sites including Lahuradewa (north), Chopani Mando, Jhusi, Hetapatti, (southeast), Senuwar (southwest) to name only a few examples (Sharma and Misra Reference Sharma and Misra1980; Saraswat Reference Saraswat and Singh2004; Singh Reference Singh2004; Tewari et al. Reference Tewari, Srivastava, Singh, Saraswat and Singh2003, Reference Tewari, Srivastava, Singh, Saraswat, Singh, Chauhan, Pokharia, Saxena, Prasad and Sharma2006, Reference Tewari, Srivastava, Saraswat, Singh and Singh2008; Pokharia et al. Reference Pokharia, Pal and Srivastava2009; Pokharia Reference Pokharia2011).

Figure 1 Location of site of Sakas and additional sites mentioned throughout this text.

The implications of these developments are important as the Middle Ganges Plains are an important region for political and cultural consolidation as well as site nucleation pre-urbanism in the 1st millennium BC. The problem though is understanding the chronology of the intervening period, the Neolithic.

The term Neolithic has often been deemed difficult to apply outside of European contexts. To avoid the Eurocentric baggage of the term, Tewari et al. (Reference Tewari, Srivastava, Saraswat, Singh and Singh2008) attempted to re-periodize Gangetic sites and proposed that farming was a critical development that could be used to explain changes. As such they suggested that Early Farming could be used as terms to describe the changes seen after the Mesolithic, followed by a shift towards a Chalcolithic or more regionally a Developed Farming period, before the early Iron Age or Advanced farming that led into the 1st millennium BC.

These terms were framed around the periodization of Lahuradewa, a type site in the northern part of the Ganges plains. Lahuradewa is a small settlement on a lake edge that was excavated by Tewari and colleagues and showed five periods of occupation, three of which are foundational to the chronology debated here. Period I was dated to 7000–2000 BC and termed Early Farming, followed by Period II the Developed Farming between 2000–1200 BC and then Period III starting in 1200 BC as the Advanced Farming (Tewari et al. Reference Tewari, Srivastava, Singh, Saraswat, Singh, Chauhan, Pokharia, Saxena, Prasad and Sharma2006). This regionalized chronology has been taken up in some instances, but not consistently (see Tokwa for example—Misra et al. Reference Misra, Pal and Gupta2000), but there are other problems besides terms to deal with.

While at Jhusi and Koldihwa there are Neolithic or Early Farming levels going back to the 7th millennium BC (perhaps earlier) similar to Lahuradewa, at Senuwar the date of Period IA, the Neolithic or Early Farming is 2200–1950 BC, with a Transitional phase in Period II between 1950–1300 BC before the Chalcolithic or as Tewari et al. (Reference Tewari, Srivastava, Singh, Saraswat, Singh, Chauhan, Pokharia, Saxena, Prasad and Sharma2006) term it Developed Farming at 1300–600 BC (Begum Reference Begum2010; Pokharia Reference Pokharia2008; Saraswat Reference Saraswat and Singh2004). Other sites like Chirand also show a much later Neolithic or Early Farming period, while some like Tokwa sit halfway between, at roughly the 6th–5th millennium.

Given the different trajectories undertaken by sites like Senuwar compared with Lahuradewa (amongst many others), it is important to go back and reassess not only the chronologies, relative and absolute, but also the lifeways occurring in the Ganges Plains, to explore how and why different farming transitions occurred and how these narratives relate to the developments after these initial formative periods (see Begum Reference Begum2010).

Dating in the Ganges Plains though has always been wildly controversial (Allchin and Allchin Reference Allchin and Allchin1982; Pandey Reference Pandey and Roy1988; Kajale Reference Kajale and Renfrew1991; Mandal Reference Mandal, Misra and Pal1997; Singh Reference Singh2001; Fuller Reference Fuller, Settar and Korisettar2002). The nature of the dates and materials used to build chronologies has been at the heart of this.

To begin with many of the dates available are older, using older radiocarbon dating methods or older calibration methods. While this can be corrected for to a degree, there is still a level of error to factor in. For example the dates at Koldihwa (Sharma et al. Reference Sharma, Misra, Mandal, Misra and Pal1980) are widely seen as unreliable due in part to such issues (see Possehl and Rissman Reference Possehl, Rissman and Ehrich1992; Bellwood Reference Bellwood and Harris1996; Fuller Reference Fuller, Settar and Korisettar2002) yet are frequently cited in an early Early Farming/Neolithic boundary setting. More problematically though, the material used in many of these older dating programs are wood or wood charcoal, often done in bulk due to the high carbon requirements of the older machines. The “old wood problem” (Schiffer Reference Schiffer1986; Kim et al. Reference Kim, Wright, Hwang, Kim and Oh2019) haunts much of the dataset and raises questions about the accuracy of dating seen across the region.

Beyond this are sample size issues—for example at Lahuradewa, the vital type site for much of the chronology building in the region, the lower levels of Period IA are dated by only 3 samples of bulk charcoal. This is supported by additional dates from the nearby lake (thus out of context in relation to the human habitation) and some confusingly described dates on rice husk (context not clear) (see Tewari et al. Reference Tewari, Srivastava, Singh, Saraswat, Singh, Chauhan, Pokharia, Saxena, Prasad and Sharma2006) that have been used to push human action at the site back further but also used to extend the Neolithic/Early Farming despite not being linked to the period excavated.

This is a vital set of problems from which to build a chronology of a region. The periodizations used in the Ganges are, like many archaeological regions worldwide, based on a ceramic (or artifactual) assemblage and then tied into the absolute dates. For example, the presence of cord impressed pottery and burnished black and burnished red wares have been linked as markers of the Early Farming or Neolithic period. When excavating a new site, the discovery of such wares along with distinctive forms are used to periodize the layers being dug, and comparisons made with type sites like Lahuradewa or Senuwar (for example) to assist in this. It is assumed that radiocarbon dating will eventually be done, but with funding restrictions this is not always the case, and assumptions that your site and the type site match in date because of ceramic assemblage similarities becomes a short hand way of assigning not only a period but also a date.

Given the problems outlined for the Ganges where we have no clear chronological horizons for our periods, these assumptions could be loading interpretative burdens on the archaeological data. What can be seen then is the complex challenge facing Gangetic archaeology, as we appear to have different dates for the Early Farming in the wider region. It is with this in mind that a new comprehensive program of dating was undertaken at the site of Sakas to explore what the absolute dates say in comparison with the ceramics, and what this implies for the overall Gangetic chronologies we currently have available.

Site Background

Sakas is an archaeological site in Sasaram (Rohtas) district of Bihar in the foothills of Vindhyan-Kaimurranges, India (24°54'27"N; 83°58'3"E) (see Figure 1) (Singh et al. Reference Singh, Joglekar, Singh, Pandey, Tripathi, Pandey, Chatterjee, Singh, Chakradhari, Alam, Singh, Mohan, Kumar, Singh, Singh, Singh, Mushrif-Tripathy and Singh2020a, Reference Singh, Singh, Pandey, Chakradhari, Mohan, Alam and Chatterjee2020b, Reference Singh, Singh, Pandey, Chakradhari, Mohan, Alam and Chatterjee2020c, Reference Singh, Tripathi, Singh, Pandey, Chakradhari, Mohan, Alam and Singh2020d). In 2019 was excavated by Banaras Hindu University (Director of excavation Dr Vikas Kumar Singh) (Singh et al. Reference Singh, Joglekar, Singh, Pandey, Tripathi, Pandey, Chatterjee, Singh, Chakradhari, Alam, Singh, Mohan, Kumar, Singh, Singh, Singh, Mushrif-Tripathy and Singh2020a, Reference Singh, Singh, Pandey, Chakradhari, Mohan, Alam and Chatterjee2020b, Reference Singh, Singh, Pandey, Chakradhari, Mohan, Alam and Chatterjee2020c, Reference Singh, Tripathi, Singh, Pandey, Chakradhari, Mohan, Alam and Singh2020d). It is being analyzed by a collaborative team from Banaras Hindu University (PI: Prof. Vikas Kumar Singh, Prof. RN Singh) and Seoul National University (PI: Prof. Jennifer Bates).

Initially the site was thought to be Early Farming to Northern Black Polished Ware (NBPW) in date, with Singh (Reference Singh1990) observing that “Sakas appears to be small hamlet of Neolithic and Chalcolithic phase which was possibly reoccupied during the NBPW phase. As such the remains of the first two phases are found from the main mound while the last is found slightly away where the present village is situated”. During the 2019 excavation the earliest form of ceramics and lithics found look to similar to those found at nearby Senuwar, and as such the earliest period was determined to be of the Early Farming period. Singh et al. (Reference Singh, Joglekar, Singh, Pandey, Tripathi, Pandey, Chatterjee, Singh, Chakradhari, Alam, Singh, Mohan, Kumar, Singh, Singh, Singh, Mushrif-Tripathy and Singh2020a, Reference Singh, Singh, Pandey, Chakradhari, Mohan, Alam and Chatterjee2020b, Reference Singh, Singh, Pandey, Chakradhari, Mohan, Alam and Chatterjee2020c, Reference Singh, Tripathi, Singh, Pandey, Chakradhari, Mohan, Alam and Singh2020d) suggested that the latest phase of the site was Chalcolithic based also on ceramics. In order to test how the relative chronology links to absolute dates samples were sent for radiocarbon dating.

Methods

Sakas was excavated using a box-grid system, with four trenches, XA16, XA15, AB15 and AA15 placed at the highest point in the site to gain the best stratigraphic sequences. The trenches reached up to 5 m in depth (Figures 24). The site was excavated contextually—each new feature was dug as a separate context and sampled. This has resulted in hundreds of samples, and a detailed stratigraphic profile. In order to interpret the site these were amalgamated into larger layers in the profile drawings (Figures 24). Detailed contextual description will be published in due course.

Figure 2 Section drawing of Sakas Trench AB15. Symbolism follows Wheeler (Reference Wheeler1954).

Figure 3 Section drawing of Sakas Trench XA15. Symbolism follows Wheeler (Reference Wheeler1954).

Figure 4 Section drawing of Sakas Trench XA16. Symbolism follows Wheeler (Reference Wheeler1954).

Trench AA15 was not dug to a full depth of the site partially due to COVID19 restrictions during the later part of the season and also because of the discovery of (ancient) human remains which halted excavation due to both time and permit restrictions but also ethical concerns regarding the handling, removal and future storage of the bones. Samples for radiocarbon were not sent for dating from this trench as a full sequence could not be assured as a result.

Sampling for botanical remains (seed and charcoal) was done using a bucket-flotation system, with samples being initially sorted at BHU and then sent to SNU for further analysis. The seeds were found in almost all contexts and appear to form the background life use at the site (e.g.: food waste, crop processing burning). Analysis to understand the taphonomic pathways is underway. A preference for radiocarbon dating short lived seeds was made, though in one case a wood charcoal sample was submitted. The species of this wood sample could not be determined prior to submission. Work is ongoing to determine the species of the remaining charcoal samples. Despite the potential for the old wood problem (Schiffer Reference Schiffer1986; Kim et al. Reference Kim, Wright, Hwang, Kim and Oh2019), the date for this sample (Beta-604685) aligns well with the other dates at the site.

Preservation of botanical material at Sakas is excellent, accounting for the 100% dating success on samples submitted to all labs. This was a surprise to the authors as usually during dating, even small-sample size AMS dating, samples submitted from South Asian sites are expected to have some failures. This is due to low carbon yield, caused typically by poor preservation (such as in Indus village sites see Petrie et al. Reference Petrie, Bates, Higham and Singh2016) but also by incomplete carbonization. This is the reason that multiple seeds per sample were submitted, to ensure a minimum sample weight of 3–5 g was met to increase the chances of success. However, it appears that given the preservation at Sakas this was unnecessary, and in future should more dates be required from Sakas and from other similarly well-preserved deep Gangetic sites single seed sampling is recommended.

23 samples in total were submitted—this was seen as sufficient to gain an understanding of the span of chronological change across the site. In future more dates are needed to see subtle changes in the many individual contexts and gain a deeper understanding of site usage over time. Three samples for radiocarbon from the other trenches to establish a baseline for the site were initially sent to Beta-Analytic for dating. As this was a limited number of dates it was realized that more were needed to establish the full sequence of the site occupation. A further 10 dates were submitted to IUAC (MoES/16/07/11(i)-RDEAS and MoES/P.O.(Seismic)8(09)-Geochron/2012). In addition to these dates focusing on rice and lentils were required for the Meso-Neo Rice Project (SNU Asia Centre project 0448A-20210070), a pilot study for the Indica Project (SNU Creative Pioneers Project 100-20220080), and a further 10 samples were sent to 14 Chrono Belfast with a specific focusing rice and lentils and stratigraphically contemporary materials.

Beta-Analytic provided the initial three dates submitted. Beta-Analytic provided ISO/IEC-17025:2017 accredited results. Analysis was carried out on their 4 in-house NEC accelerator Mass Spectrometers and 4 Thermo IRMSs. The results reported were calculated relative to NISTSRM-1990C and corrected for isotopic fractionation. The standard used was NIST SRM-4990C (oxalic acid).

IUAC dates were analysed on the 500kV Ion accelerator machine in-house. AMS δ13C values were used for isotopic fractionation correction, and the standard for normalization was OX II. Data quality was monitored with a secondary standard sample (IAEA-C7).

14 Chrono Belfast analysed samples on a tandem accelerator Ionplus Mini Carbon Dating System (MICADAS). Standard normalization used OX2 standards. Dates were corrected for fractionation using AMS δ13C values.

In all labs across all samples the AAA (acid-alkali-acid) pretreatment recommend in de Vries et al. (Reference de Vries, Barendsen and Waterbolk1958) and Fischer and Heinemeier (Reference Fischer and Heinemeier2003) for charred botanical materials was used.

The raw reports from the labs including all data, lab-provided details, and additional information (e.g.: lab-calibrated dates) can be found in the SI, which is stored in an open repository (https://osf.io/ea46z/?view_only=bb15ce21f8dc4cb294f51ed115fc4f4b).

In order to standardize the calibrated results, the uncalibrated BP dates were put through OxCal 4.4 version 155 (Bronk Ramsey Reference Bronk Ramsey2009). This is because the different labs provided calibrated results using different software and curves. To ensure better comparability the calibrated BC dates provided here use INTCAL20 (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Bronk Ramsey, Butzin, Cheng, Edwards, Friedrich, Grootes, Guilderson, Hajdas, Heaton, Hogg, Hughen, Kromer, Manning, Muscheler, Palmer, Pearson, van der Plicht, Reimer, Richards, Scott, Southon, Turney, Wacker, Adolphi, Büntgen, Capano, Fahrni, Fogtmann-Schulz, Friedrich, Köhler, Kudsk, Miyake, Olsen, Reinig, Sakamoto, Sookdeo and Talamo2020).

Results by Lab

Beta Analytic

Comments: The materials from Sakas submitted to Beta Analytic were collected by various trench supervisors in the field, sorted and identified by B. Mohan and submitted by V.K. Singh.

IUAC

Comments: The materials from Sakas submitted to IUAC were collected by various trench supervisors in the field, sorted and identified by B. Mohan and submitted by V.K. Singh.

14 Chrono Belfast

Comments: The materials from Sakas submitted to 14 Chrono Belfast were collected by various trench supervisors in the field, sorted by B. Mohan, and identified and submitted by J. Bates.

Plotted Dates

Dates have been plotted by trench using OxCal 4.4 version 155 (Bronk Ramsey Reference Bronk Ramsey2009) (Figure 5). Full raw data and the data logs can be found in the SI stored in the open repository, Open Science Framework: https://osf.io/ea46z/?view_only=bb15ce21f8dc4cb294f51ed115fc4f4b.

Figure 5 Dates plotted in OxCal using INTCAL 20. Each trench is plotted in a different color.

Discussions on the Implications of the Sakas Dates

The overall date range for the site is 3413±25 BP (1744–1675 cal BC) to 2924±24 (1130–1054 cal BC). This date range is consistent across the trenches. This is critical as the 1–2 ha occupation area has a deep stratigraphy (up to 5 m), implying that over a roughly 600 year period we see multiple layers of repeated and dense use.

The dates interestingly suggest two phases of use at the site, one between 1100–1400 BC and the other between 1500–1700 BC. The excavated materials (ceramics, lithics, artifacts) suggested three periods of use: Early Farming/Neolithic, Transitional, and Developed Farming/Chalcolithic. There is some overlap in the radiocarbon dates which may account for a transitional phase, which fall into Period II according to typo-chronological and stratigraphic work. These have less dates taken from them, partly due researcher bias (interest in the earlier period) and partly due to less dateable (charred seed) material available. The reduced (though not lacking) seeds could imply less intensive occupation, and more work is needed therefore on the Transitional/Period II layers to explore their cultural implications, particularly as they are not devoid of life-makers. Numerous floors, both packed dirt and plastered, are seen, as well as human burials (in trench XA15 below plaster layer 5). Ceramics and lithics as well as other artifacts (e.g.: bone point, beads, bangles) continue to be found. This 100 years between the radiocarbon phase I and II therefore needs further work to refine alongside the other markers of time and cultural activity.

There are no apparent disparities in dating caused by using different labs for the dating of the 23 samples. Indeed, the use of multiple labs providing the same chronological range supports the dates gained—they are consistent across labs and throughout the stratigraphy. The absolute dates provide a strong chronology for Sakas with no “odd” results that would need to be explained either by checking lab protocol differences or checking the stratigraphy against the new dates for aspects of possible contamination. Checking of the stratigraphy was of course done multiple times, and indeed when looking to the stratigraphy the consistency in chronology implied by the radiocarbon dates lines up with the site formation—there is little to no evidence of bioturbation, cutting or contamination.

The relative chronology for Sakas was created through comparison with Senuwar. At Senuwar period IA was determined to be an Early Farming type settlement based on the similarities of its ceramics and lithics to sites like Chirand and Taradih. At Senuwar there are four dates, all from period IB, the overlap between the Neolithic and Chalcolithic (ca. 1800 BC), while at Chirand the Early Farming period has dates that put the Early Farming period into the 1800–1200 BC bracket (see Vishnu-Mittre 1972). Taradih has no radiocarbon dates. This means that the new dates from Sakas, which are more comprehensive in number (23 versus the 3 from Tokwa for example—see Misra et al. Reference Misra, Pal and Gupta2000) and precise in analytical method (AMS), tally well with the chronological framework established at other sites in the area.

A new challenge therefore arises—how do we fit this sub-regional framework in with the larger pan-Gangetic chronological periodization? Returning to the earlier debate however, if one were to take the term “Early Farming Period” at face value without interrogating what it meant at this site and why it was chosen (comparison with Senuwar’s ceramics and the absolute and relative dating framework in the Vindhyan region it sits in), one might be fooled into thinking this site was contemporary with (at worst) or had similar agricultural process to (at best) sites in other parts of the Gangetic plains.

As established at other sites, we can see different chronological time spans for “Early Farming” being used at sites like Lahuradewa putting it the 7th millennium BC, Jhusi in the 5th millennium BC and the Vindhyan sites like Sakas and Senuwar placing it firmly in the 2nd millennium BC. Similar ceramics and lithics are seen at all, such as corded ware, black-and-red-ware, microliths, bone points, even feature types like distinctive shaped hearths (see discussions in Pal Reference Pal, Schug, Walimbe and Kennedy2016). It is the radiocarbon dating frameworks that appear to be out-of-sync yet creating new patterns to explore.

The question that arises then is what exactly was the Early Farming period? While some work has been done to explore what Early, Advanced and Developed Farming meant in terms of cultural phases rather than ceramic/radiocarbon chronologies, much of this is based on the data from a limited number of sites.

While at Lahuradewa and Tokwa for example there is good archaeobotanical evidence, this remains elusive at many other sites (see Pokharia Reference Pokharia2011; Pokharia et al. Reference Pokharia, Pal and Srivastava2009; Tewari et al. Reference Tewari, Srivastava, Saraswat, Singh and Singh2008, Reference Tewari, Srivastava, Singh, Saraswat, Singh, Chauhan, Pokharia, Saxena, Prasad and Sharma2006, Reference Tewari, Srivastava, Singh, Vinay, Trivedi and Singh2005, Reference Tewari, Srivastava, Singh, Saraswat and Singh2003). At Lahuradewa the archaeobotanical data for example suggests that Early Farming should be seen as a period of incipient agriculture perhaps even just the cultivation of semi-wild local crops. The Developed Farming shows the introduction of non-local crops, long distance contact and the establishment of more secure farming practices, and Advanced farming was fully agrarian and yield-focused systems. At Senuwar and Tokwa though we see a different pattern, with Early Farming levels having non-local crops already present, but still grown in a low-intensity system (see discussion in Kingwell-Banham Reference Kingwell-Banham2019; Pokharia Reference Pokharia2008).

To this end, if we were to compare Sakas with these different “Early Farming” socio-economic schemes, it would appear Early Farming, potentially even Developed Farming at Tokwa or Senuwar but Developed or Advanced Farming at Lahuradewa. This is because of the presence of established non-local crops (wheat, barley, lentils, peas) alongside domesticated local crops (rice, millets, tropical pulses) grown across a complex two season (rabi winter and kharif summer monsoon) system. The animal remains are still to be studied but could complicate things further.

Thinking in such ways might require us to rethink the periodisation of Gangetic sites away from pan-plains chronological schemes and more towards human behavioural markers. Further work is needed then to disentangle not only the sub-regional nuances in when Early, Developed, Advanced periods began but what these actually mean in terms of cultural systems at each site of the Ganges plains.

Data availability statement

All the raw data provided by Beta Analytic, 14 Chrono Belfast and IUAC as well as the OxCal logs can be found on the OSF: https://osf.io/ea46z/?view_only=bb15ce21f8dc4cb294f51ed115fc4f4b

Acknowledgments

The authors are grateful to their institutions (Banaras Hindu University and Seoul National University) for supporting this work. The authors are thankful to Beta Analytical for their support. They are also grateful to IUAC for extending AMS facility for radiocarbon dating funded by Ministry of Earth Science (MoES), Govt. of India with reference numbers MoES/16/07/11(i)-RDEAS and MoES/P.O.(Seismic)8(09)-Geochron/2012. The authors were supported in the dating of Sakas materials from 14 Chrono Belfast by the Research Grants for Asian Studies funded by Seoul National University Asia Center (SNUAC) in 2022. The project was entitled “Meso-Rice: testing the early rice domestication hypothesis in the Ganges Mesolithic and Neolithic” (SNU Asia Centre project 0448A-20210070) and ran from 2021 to 2022. The Indica Project, fully titled “Indica: rethinking our reliance on paddy rice through looking to past domestication and agricultural systems” (SNU Creative Pioneers Project 100–20220080) is supported by the Creative-Pioneering Researchers Program through Seoul National University and runs 2022-2028. The authors are exceptionally grateful to the Archaeological Survey of India, Government of India, for their support in the excavations and ongoing analyses. Without the ASI such work would not be possible. In addition, the authors would like to thank the reviewers of this paper who provide constructive and interesting feedback that improved the paper and provided new directions for future work.

References

Allchin, B, Allchin, FR. 1982. The rise of civilization in India and Pakistan. Cambridge world archaeology. Cambridge University Press, Cambridge; New York.Google Scholar
Bates, J. 2023. The origins and development of agriculture in South Asia. In: Oxford Research Encyclopedia of Anthropology. Oxford University Press. https://doi.org/10.1093/acrefore/9780190854584.013.553 Google Scholar
Begum, N. 2010. Neolithic settlement patterns of the Middle Ganga Plain. Int J Sci Res Sci Technol II:92104.Google Scholar
Bellwood, P. 1996. The origins and spread of agriculture in the Indo-Pacific region: gradualism and diffusion or revolutions and colonization? In: Harris, DR, editor. The origins and spread of agriculture and pastoralism in Eurasia. UCL Press, London. p. 465498.Google Scholar
Bronk Ramsey, C. 2009. Bayesian Analysis of Radiocarbon Dates. Radiocarbon 51:337360. https://doi.org/10.1017/S0033822200033865 CrossRefGoogle Scholar
de Vries, H, Barendsen, GW, Waterbolk, HT. 1958. Groningen Radiocarbon Dates II. Science 127:129137. https://doi.org/10.1126/science.127.3290.129 CrossRefGoogle ScholarPubMed
Fischer, A, Heinemeier, J. 2003. Freshwater reservoir effect in 14C dates of food residue on pottery. Radiocarbon 45:449466. https://doi.org/10.1017/S003382220003280X CrossRefGoogle Scholar
Fuller, DQ. 2002. Fifty years of archaeobotanical studies in India: laying a solid foundation. In: Settar, S, Korisettar, R, editors. Indian Archaeology in Retrospect III: Archaeology and Interactive Disciplines. Manohar, New Delhi. p. 247364.Google Scholar
Joglekar, PP. 2006. A fresh appraisal of the animal-based subsistence and domestic animals in the Ganga Valley. Pragdhara 18:309321.Google Scholar
Joglekar, PP, Misra, VD, Pal, JN, Gupta, MC. 2003. Mesolithic Mahadaha: the faunal remains. University of Allahabad, Allahbad.Google Scholar
Kajale, MD. 1991. Current status of Indian palaeoethnobotany: introduced and indigenous food plants with a discussion of the historical and evolutionary development of Indian agriculture and agricultural systems in general. In: Renfrew, JM, editor. New light on early farming—recent developments in palaeoethnobotany. Edinburgh University Press, Edinburgh. p. 155189.Google Scholar
Kim, J, Wright, DK, Hwang, J, Kim, J, Oh, Y. 2019. The old wood effect revisited: a comparison of radiocarbon dates of wood charcoal and short-lived taxa from Korea. Archaeol Anthropol Sci 11:34353448. https://doi.org/10.1007/s12520-018-0766-8 CrossRefGoogle Scholar
Kingwell-Banham, E. 2019. Dry, rainfed or irrigated? Reevaluating the role and development of rice agriculture in Iron Age-Early Historic South India using archaeobotanical approaches. Archaeol Anthropol Sci. https://doi.org/10.1007/s12520-019-00795-7 CrossRefGoogle Scholar
Mandal, D. 1997. Neolithic culture of the Vindhyas: excavations at Mahagara in the Belan Valley. In: Misra, VD, Pal, JN, editors. Indian Prehistory 1980. University of Allahabad, Allahbad. p. 163174.Google Scholar
Misra, VD, Pal, JN, Gupta, MC. 2000. Excavation at Tokwa: a Neolithic–Chalcolithic settlement. Pragdhara 11:5972.Google Scholar
Pal, JN. 2016. Mesolithic Foragers of the Ganges Plain and Adjoining Hilly. In: Schug, GR, Walimbe, SR, Kennedy, KAR, editors. A companion to South Asia in the past, Blackwell Companions to anthropology. John Wiley & Sons, Chichester, West Sussex, UK. p. 86101.CrossRefGoogle Scholar
Pandey, JN. 1990. Mesolithic in the Middle Ganga Valley. Bull Deccan Coll Res Inst 49:311316.Google Scholar
Pandey, JN. 1988. Northern Vindyan Neolithic settlement. In: Roy, UN, editor. Rural life and folk culture in ancient India. University of Allahabad, Allahbad. p. 128138.Google Scholar
Petrie, CA. 2015. Mehrgarh, Pakistan. In: Barker G, Goucher C, editors. The Cambridge World History. Cambridge University Press. p. 289–309. https://doi.org/10.1017/CBO9780511978807.012 CrossRefGoogle Scholar
Petrie, CA, Bates, J, Higham, T, Singh, RN. 2016. Feeding ancient cities in South Asia: dating the adoption of rice, millet and tropical pulses in the Indus civilisation. Antiquity 90:14891504. https://doi.org/10.15184/aqy.2016.210 CrossRefGoogle Scholar
Pokharia, A. 2008. Palaeoethnobotanical record of cultivated crops and associated weeds and wild taxa from Neolithic site, Tokwa, Uttar Pradesh, India. Curr Sci 94.Google Scholar
Pokharia, A, Pal, JN, Srivastava, A. 2009. Plant macro-remains from Neolithic Jhusi in Ganga Plain: evidence for grain-based agriculture. Curr Sci 97:564572.Google Scholar
Pokharia, AK. 2011. Palaeoethnobotany at Lahuradewa: a contribution to the 2nd millennium BC agriculture of the Ganga Plain, India. Curr Sci 101:15691578.Google Scholar
Possehl, GL, Rissman, P. 1992. The chronology of prehistoric India: from earliest times to the Iron Age. In: Ehrich, RW, editor. Chronologies in Old World archaeology. University of Chicago Press, Chicago. p. 465490.Google Scholar
Reimer, PJ, Austin, WEN, Bard, E, Bayliss, A, Blackwell, PG, Bronk Ramsey, C, Butzin, M, Cheng, H, Edwards, RL, Friedrich, M, Grootes, PM, Guilderson, TP, Hajdas, I, Heaton, TJ, Hogg, AG, Hughen, KA, Kromer, B, Manning, SW, Muscheler, R, Palmer, JG, Pearson, C, van der Plicht, J, Reimer, RW, Richards, DA, Scott, EM, Southon, JR, Turney, CSM, Wacker, L, Adolphi, F, Büntgen, U, Capano, M, Fahrni, SM, Fogtmann-Schulz, A, Friedrich, R, Köhler, P, Kudsk, S, Miyake, F, Olsen, J, Reinig, F, Sakamoto, M, Sookdeo, A, Talamo, S. 2020. The Intcal20 Northern Hemisphere radiocarbon age calibration curve (0–55 CAL kBP). Radiocarbon 1–33. https://doi.org/10.1017/RDC.2020.41 CrossRefGoogle Scholar
Saraswat, KS. 2004. Plant Economy of Early Farming Communities. In: Singh, BP, editor. Early farming communities of the Kaimur (excavations at Senuwar). Publication Scheme, Jaipur. p. 416535.Google Scholar
Schiffer, MB. 1986. Radiocarbon dating and the “old wood” problem: the case of the Hohokam chronology. J Archaeol Sci 13:1330. https://doi.org/10.1016/0305-4403(86)90024-5 CrossRefGoogle Scholar
Sharma, GB, Misra, BB. 1980. Excavations at Chopani-Mando (Belan Valley) 1977–1979 : epipalaeolithic to protoneolithic. University of Allahabad, Allahbad.Google Scholar
Sharma, GR. 1985. From hunting and food gathering to domestication of plants and animals in the Belan and Ganga Valleys. Recent Adv Indo-Pac Prehistory 369–371.CrossRefGoogle Scholar
Sharma, GR, Misra, VD, Mandal, D, Misra, BB, Pal, JN. 1980. Beginnings of Agriculture (Epi-Palaeolithic to Neolithic: excavations at Chopani-Mando, Mahadaha, and Mahagara). Abinash Prakashan, Allahabad.Google Scholar
Singh, BP. 2004. Early farming communities of the Kaimur: excavations at Senuwar, 1986–87, 89–90, 1st ed. Publication Scheme, Jaipur.Google Scholar
Singh, BP. 1990. Early farming communities of Kaimur Foothills. Puratattva 19:6–18.Google Scholar
Singh, P. 2001. The Neolithic cultures of northern and eastern India. In: Indian Archaeology in Retrospect I: Prehistory: Archaeology of South Asia. Manohar, New Delhi. p. 127150.Google Scholar
Singh, VK, Joglekar, PP, Singh, M, Pandey, AK, Tripathi, R, Pandey, CL, Chatterjee, G, Singh, DP, Chakradhari, S, Alam, A, Singh, SK, Mohan, B, Kumar, D, Singh, AP, Singh, U, Singh, A, Mushrif-Tripathy, V, Singh, RN. 2020a. Preliminary Report on Excavations at Sakas, District Sasaram (Rohtas), Bihar, 2018–19. Man Environ XLV:66–77.Google Scholar
Singh, VK, Singh, M, Pandey, AK, Chakradhari, S, Mohan, B, Alam, A, Chatterjee, G. 2020b. Preliminary report on excavations at Sakas, district Sasaram (Rohtas), Bihar, 2018–19 background and objectives. Indian J Archaeol 5:2494.Google Scholar
Singh, VK, Singh, M, Pandey, AK, Chakradhari, S, Mohan, B, Alam, A, Chatterjee, G. 2020c. Sakas: a burial site in Kaimur Range, Sasaram (Rohtas), Bihar. Indian J Archaeol 5:2429.Google Scholar
Singh, VK, Tripathi, R, Singh, M, Pandey, CL, Chakradhari, S, Mohan, B, Alam, A, Singh, RN. 2020d. Further excavations at Sakas, distract Sasaram (Rohtas), Bihar (2019–2020). Itihas Darpan XXV:221–226.Google Scholar
Tewari, R, Srivastava, KK, Singh, KK, Vinay, R, Trivedi, RK, Singh, GC. 2005. Recently excavated sites in the Ganga Plain and North Vindhyas: some observations regarding the pre-urban context. Pragdhara 15:3949.Google Scholar
Tewari, R, Srivastava, RK, Saraswat, KS, Singh, IB, Singh, KK. 2008. Early farming at Lahuradewa. Pragdhara 18:347373.Google Scholar
Tewari, R, Srivastava, RK, Singh, KK, Saraswat, KS, Singh, IB. 2003. Preliminary report of the excavation at Lahuradewa, District Sant KabirNagar, U.P. 2001–2002: wider archaeological implications. Pragdhara 13:3768.Google Scholar
Tewari, R, Srivastava, RK, Singh, KK, Saraswat, KS, Singh, IB, Chauhan, MS, Pokharia, AK, Saxena, A, Prasad, A, Sharma, M. 2006. Second preliminary report of the excavations at Lahuradewa district Sant Kabir Nagar, U.P. : 2002-2003-2004 & 2005-06. Pragdhara 16:35–68.Google Scholar
Varma, RK, Misra, VD, Pandey, JN, Pal, JN. 1985. A preliminary report on the excavations at Damdama (1982–1984). Man Environ 9:4565.Google Scholar
Vishnu-Mittre. 1972. Neolithic plants economy at Chirand, Bihar. J Palaeosciences 21:1822. https://doi.org/10.54991/jop.1972.1463 CrossRefGoogle Scholar
Wheeler, M. 1954. Archaeology from the earth. Munshiram Manoharlal Publ Pvt Ltd, New Delhi.Google Scholar
Figure 0

Figure 1 Location of site of Sakas and additional sites mentioned throughout this text.

Figure 1

Figure 2 Section drawing of Sakas Trench AB15. Symbolism follows Wheeler (1954).

Figure 2

Figure 3 Section drawing of Sakas Trench XA15. Symbolism follows Wheeler (1954).

Figure 3

Figure 4 Section drawing of Sakas Trench XA16. Symbolism follows Wheeler (1954).

Figure 4

Figure 5 Dates plotted in OxCal using INTCAL 20. Each trench is plotted in a different color.