Prehistoric lime production technology

Pyrogenic lime mortars and plasters are sophisticated construction materials that involve the conversion of a source of calcium carbonate (CaCO₃), such as shell or limestone, into quicklime (calcium oxide: CaO) by burning at high temperatures (>800°C). Quicklime is then mixed with water to produce slaked (hydrated) lime, or calcium hydroxide (Ca(OH)₂), which can be shaped as a thick, plastic paste or ‘putty’ and used as a building material (Friesem et al. Reference Friesem, Abadi, Shaham and Grosman2019). Upon exposure to atmospheric carbon dioxide, this calcium hydroxide paste reverts to calcium carbonate, producing a hard, durable surface. In this article, we differentiate these mortars and plasters, defining the former as a material that consists of a fine lime matrix (binder) with an added coarse fraction (temper) used to construct architectural surfaces, such as floors, and the latter, plaster, as a medium, such as clay or lime, which is applied as a fine coat or finish to lime-mortared surfaces (Stoops et al. Reference Stoops, Canti, Kapur, Nicosia and Stoops2017).

The earliest studies of lime mortars used microarchaeological techniques, such as polarised light microscopy, scanning electron microscopy and X-ray diffraction (Gourdin & Kingery Reference Gourdin and Kingery1975; Goren & Goldberg Reference Goren and Goldberg1991). Polarised light microscopy, utilising cross polarised light (XPL) and plane polarised light (PPL), remains the standard for identification (Karkanas Reference Karkanas2007). Emerging research, however, highlights the strength of FTIR in assessment of the pyrogenic formation history of lime products (Friesem et al. Reference Friesem, Abadi, Shaham and Grosman2019). FTIR can identify burnt clays, pyrogenic aragonite and the high atomic disorder of pyrogenically formed lime (Berna et al. Reference Berna2007; Regev et al. Reference Regev2010; Toffolo & Boaretto Reference Toffolo and Boaretto2014).

Prehistoric pyrogenic lime technology is now well-documented globally, including in South-west Asia by at least 12 000 cal BP (Kingery et al. Reference Kingery, Vandiver and Prickett1988; Friesem et al. Reference Friesem, Abadi, Shaham and Grosman2019), China by 3000 BP, India by c. 5500–4500 BP, and Central and South America by c. 2500 BP (Carran et al. Reference Carran, Hughes, Leslie and Kennedy2012). Although lime technology is an ethnohistorically documented practice in Southeast Asia (Ceron & Eusebio Reference Ceron and Eusebio2007), it has not been previously identified in prehistoric contexts in this region.

Archaeology of Loc Giang

Loc Giang (10°59′43″N, 106°17′25″E) is a mounded site situated on a slightly raised Quaternary alluvial terrace on the east bank of the Vam Co Dong River, in An Ninh Tay Commune, Duc Hoa District, Long An Province, southern Vietnam (Figure 1). The extant portion of a formerly more extensive mound covers approximately 500m² and rises some 3m above the surrounding alluvial floodplain.

Figure 1. The location of Loc Giang and contemporaneous sites of An Son and Rach Nui in southern Vietnam (maps modified by E .Grono and reproduced with the permission of CartoGIS Services, The Australian National University).

Following excavations by the Long An Provincial Museum and the Vietnam Historical Museum in 1988, 1993 and 2007, renewed excavations at Loc Giang were undertaken in 2014 by a collaborative team from the Australian National University (Canberra), the Southern Institute of Social Sciences (Ho Chi Minh City) and Long An Provincial Museum (Tan An) (Piper et al. Reference Piper2017). The 2014 season focused on a 5 × 4m trench, from which the samples analysed in the current research were recovered.

Most of the mound accumulation results from a sequence of more than 30 surfaces, representing four phases of construction (Figures 2 & 3). The surfaces comprise relatively hard, compacted, creamy white sediments with a loam texture, a high calcareous content and an alkaline pH between 8 and 9 (Piper et al. Reference Piper2017: 35). The surfaces extended laterally across several metres of the excavated trench. The excavators’ preliminary interpretation of these surfaces was that they represented lime mortar floors (Piper et al. Reference Piper2017). The site was interpreted as a settlement based on the surfaces and associated features, including middens, pits, postholes and possible hearths; however, microarchaeological characterisation of the surfaces is essential to confirm the identification of domestic floors and the materials and technology of construction.

Figure 2. Section drawing of the west wall of the 2014 excavation trench, illustrating a well-preserved sequence of Phase 2 and Phase 3 surfaces (grey fill). The location of some of the intact micromorphology blocks investigated in the study are shown as black rectangles (modified from Piper et al. Reference Piper2017: fig. 5a).

Figure 3. a) Section of the west wall of the 2014 excavation trench, showing an example of the floor sequence (photograph by Dang N.K. and P.J. Piper); b–d) examples of intact floor fragments (left and centre), showing compacted, creamy-white, finely textured matrices and coarse temper, including ceramic fragments, burnt clay and charred plant remains. Equivalent thin sections scanned in cross polarised (XPL) light (right) exhibit well-reacted calcitic groundmasses and distinctive coarse temper inclusions; b) and d) thin section scans (right) show two superimposed floor surfaces, reflecting replacement and repair of original surfaces (images produced by E. Grono).

The earliest phase of construction (Phase 1) consists of at least five surfaces that are poorly preserved due to levelling activities prior to subsequent construction (Phase 2). Phase 2 consists of 11 surfaces that extend across a wider area, indicating a spatial expansion of construction activities. Phase 3 is the best preserved, consisting of more than 25 sequential surfaces, with evidence of replacement and repair (Figure 2). Surface edges and corners delineate the dimensions of living areas, and several discrete patches of burning suggest the presence of hearths on the surfaces. Finally, Phase 4 surfaces are fragmentary, having been affected by post-neolithic human activity.

Twelve radiocarbon dates indicate occupation between 3980 and 3270 cal BP (Piper et al. Reference Piper2017). The Bayesian chronological model of the Loc Giang dates suggests a rapid accumulation of the Phase 2 and Phase 3 surfaces across a period of 50–360 years between 3510–3370 cal BP and 3320–3150 cal BP (at 95.4% probability) (Piper et al. Reference Piper2017).

Discussion: technology of lime production in Southeast Asia

Based on the results reported here, Loc Giang is currently the earliest known example of the use of lime mortar in Southeast Asia. The microarchaeological analyses confirm well-established lime production technology by at least Phase 2 (c. 3510–3370 cal BP) and continuing through Phase 3 (c. 3320–3150 cal BP) of the settlement. The floor matrices consist of well-reacted lime binders (Figures 3b–d, 4a–b) that reflect high-quality construction and technological skill in the preparation of these surfaces (Karkanas Reference Karkanas2007). The absence of evidence for phases of experimental lime production implies that the inhabitants of Loc Giang were experienced in lime construction from the earliest use of the technique. To date, no kilns have been identified, perhaps indicating that lime was produced using ephemeral combustion features (e.g. open hearths or pit kilns), as suggested for the Neolithic of the Eastern Mediterranean (Kingery et al. Reference Kingery, Vandiver and Prickett1988; Karkanas Reference Karkanas2007; Goren & Goring-Morris Reference Goren and Goring-Morris2008). Lime mortar floors provide a hard, water-repellent and hygienic surface that would have been advantageous in a wet, tropical environment. Common types of temper, such as burnt and unburnt clays and plant remains (Figure 4d–e), improve the hardness and tensile strength of lime mortars (Stoops et al. Reference Stoops, Canti, Kapur, Nicosia and Stoops2017). Occasional inclusions of ceramic, bone, shell and coprolite fragments (Figure S2i–l) in the Loc Giang floors suggest that the inhabitants combined the inclusion of high-quality temper materials with rubbish recycled from everyday activities (Karkanas & Van De Moortel Reference Karkanas and Van De Moortel2014). Therefore, two practices essential to sedentary communities—settlement construction and waste management—seem to have developed in tandem at Loc Giang.

Limestone is not naturally present in this region of Vietnam, and the coastal province of Kien Giang, 200km south-west of Loc Giang, is the only source of this material in southern Vietnam (Nguyen Reference Nguyen1986). While it is possible that limestone was imported, it is completely absent in the thin sections examined here. If limestone had been used to produce lime at Loc Giang, it is expected that some partly burnt limestone residues would be identifiable within poorly reacted parts of the lime mortar (e.g. Karkanas Reference Karkanas2007; Friesem et al. Reference Friesem, Abadi, Shaham and Grosman2019). An alternative source of calcium carbonate is shell, which is used to prepare lime in many ethnographically documented societies (Panda & Misra Reference Panda and Misra2007) and would have been a readily available resource at Loc Giang. While today the site is approximately 85km inland, the coastline would have been much closer during the mid-Holocene, when sea levels were 2.5–4.5m higher than present (Proske et al. Reference Proske2010). As sea levels retreated, the Mekong Delta rapidly prograded, resulting in the brackish and tidal mangrove estuarine environment present during the period when Loc Giang was occupied (Proske et al. Reference Proske2010), as indicated by the mollusc assemblages from the site (Piper et al. Reference Piper2017: 41). Few microscopic shell fragments were identified in the thin sections examined here and only a few hundred shell fragments were recovered from the entire site, although the excavators recorded a number of burnt shell deposits during excavation (Piper & Nguyen Reference Piper and Nguyen2016: 107). The lack of shell remains in lime mortars and plaster is also consistent with traditional ethnographic techniques of lime production, which utilise sieves to separate fine lime powder from burnt shell fragments and other coarse impurities, thus leading to a lime paste without recognisable fragments of shell within its matrix (Panda & Misra Reference Panda and Misra2007: 263–64 & 269; Thakuria Reference Thakuria2012: 96).

Although recorded in several ethnographic contexts around the world (e.g. Ceron & Eusebio Reference Ceron and Eusebio2007; Panda & Misra Reference Panda and Misra2007; Russell & Dahlin Reference Russell and Dahlin2007), the use of shell in lime production still represents a lacuna in geoarchaeological research, which has focused almost exclusively on the use of limestone. The possible use of shells to produce lime mortar has been suggested for coastal regions of ancient China and medieval India, a medieval chapel in Scotland, Bronze Age (c. 5000–3000 cal BP) sites in the Aegean and Eastern Mediterranean, and Early to Late Classic (c. 1800–1200 BP) Maya sites in Belize (MacKinnon & May Reference MacKinnon and May1990; Brysbaert Reference Brysbaert2007; Deshpande-Mukherjee Reference Deshpande-Mukherjee2011; Thacker Reference Thacker and Hughes2013; Macphail & Goldberg Reference Macphail and Goldberg2017: 233; Zhang et al. Reference Zhang2019). In-depth microarchaeological examinations of shell lime production, however, are still lacking.

Consistency and repetition in both floor materials and technology throughout the stratigraphic sequence of Phases 2 and 3 (3510–3150 cal BP) at Loc Giang indicate that floor construction was a communal practice that drew on social memory and tradition (see Boivin Reference Boivin2000). Pyrogenic lime production involves considerable expenditure of time, labour and resources to create durable structures. The investment in dwelling construction, together with evidence of managed pig and dog populations (Piper et al. Reference Piper2017) and regulated waste disposal activities (Grono Reference Grono2020), would have required at least some of the community to reside permanently at the settlement; therefore, Loc Giang represents one of the earliest sedentary communities in mainland Southeast Asia.

Hard, laterally extensive surfaces similar to those at Loc Giang have also been recorded in association with postholes at the contemporaneous neolithic sites of An Son (c. 4300–3400 cal BP) on the Vam Co Dong River, 300m east of Loc Giang (Piper & Oxenham Reference Piper, Oxenham, Boyle, Rabett and Hunt2014), and at Rach Nui (c. 3500–3300 cal BP) approximately 80km to the south-east, on the Dong Nai River (Oxenham et al. Reference Oxenham2015). Additional construction evidence from the neolithic period has been recovered from the site of Khok Phanom Di in Peninsula Thailand (4000–3500 cal BP), including wattle-and-daub wall fragments and a clay floor with wall foundations (C.F.W. Higham pers. comm.); however, these architectural remains are thought to have had a mortuary rather than domestic function.

Piper and Oxenham's (Reference Piper, Oxenham, Boyle, Rabett and Hunt2014) comparative analysis of settlement evidence from Loc Giang, An Son and Rach Nui in southern Vietnam suggests that the use of lime mortar was a regional building tradition, invoking Bellwood et al.'s (Reference Bellwood2011: 160) ‘Greater Mekong’ cultural network of neolithic communities in southern Vietnam. At Rach Nui, 13 phases of floor construction took place across a period of approximately 200 years, representing the renewal of platforms and above-ground structures roughly every decade or two (Oxenham et al. Reference Oxenham2015). Similarly, repeated episodes of demolition, levelling and rebuilding at Loc Giang potentially reflect settlement maintenance and reconfiguration over time, in terms both of household shifts (e.g. Boivin Reference Boivin2000) and the requirements of living in tropical environments that accelerate building decay. In this region today, dwellings are replaced every 10–15 years, or even more frequently, due to insect infestations, damp conditions and the rotting of organic construction materials (Bernot Reference Bernot, Izikowitz and Sorensen1982: 35; Castillo et al. Reference Castillo2017: 75).

The microarchaeological identification of lime mortar at Loc Giang therefore offers the first insights into settlement construction and social dynamics during the mainland Southeast Asian neolithic period (c. 5000–3000 cal BP). It contributes one of the first robust lines of evidence for the emergence of sedentism; moreover, it adds to an emerging picture of the mainland Southeast Asian neolithic as an innovative period that was characterised by variability and regional diversification. Processes of ‘neolithisation’ in this region appear to have involved mosaics of local communities, who developed their own cultural and social identities and traditions (see Grono Reference Grono2020; Piper et al. Reference Piper, Higham and Kim2022), such as the use of lime mortar in southern Vietnam.

Understanding the non-mortuary aspects of neolithic communities in mainland Southeast Asia is only just beginning. Most archaeological research on prehistoric mainland Southeast Asia (between 5000 and 3000 years ago) has involved the excavation of burial sites (Piper & Oxenham Reference Piper, Oxenham, Boyle, Rabett and Hunt2014; for a summary of well-researched burial sites from this period, see Higham Reference Higham2014). In contrast, settlement sites have been less well researched—an imbalance that is probably caused by a combination of factors, including the low archaeological visibility of dwellings (Grono Reference Grono2020), past excavation strategies that have focused on burials, and logistical challenges involved in opening sufficiently large excavation areas to reveal the floor plans of potential dwellings.

Going forward, there is potential for further investigation of possible neolithic settlement sites with extensive in situ deposits in southern Vietnam (Loc Giang has now been almost completely destroyed through quarrying). We argue, however, that the successful identification of lime construction at Loc Giang was achieved through careful field excavation strategies coupled with the innovative use in this region of microarchaeology, rather than large-scale excavation. Microarchaeological techniques enable fine-grained insights into dwellings and floor sequences, including both the technological processes and social practices involved in floor construction. We believe that the detection of dwellings and the study of domestic activities and the use of space is most effectively achieved by integrating microscopic and macroscopic techniques (Karkanas & Goldberg Reference Karkanas and Goldberg2018), and we encourage the wider application of microarchaeology for the investigation of other settlement sites across the region.