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American sweet potato and Asia-Pacific crop experimentation during early colonisation of temperate-climate Aotearoa/New Zealand

Published online by Cambridge University Press:  26 September 2024

Ian G. Barber Open the ORCID record for Ian G. Barber [Opens in a new window]  and
Rebecca Waikuini Benham
Ian G. Barber*
Affiliation:
Department of Archaeology, University of Otago Ōtākou Whakaihu Waka, Dunedin, Aotearoa/New Zealand
Rebecca Waikuini Benham
Affiliation:
Heritage New Zealand Pouhere Taonga, Dunedin, Aotearoa/New Zealand
*
*Author for correspondence ✉ [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The American sweet potato (Ipomoea batatas) is a globally important comestible crop that features prominently in Polynesian lore; however, the timing and mode of its Oceanic transplantation remain obscure. New research from the Māori cultivation site M24/11 in Aotearoa/New Zealand, presented here, offers a re-evaluation of evidence for the early use and distribution of the sweet potato in southern Polynesia. Consideration of plant microparticles from fourteenth-century archaeological contexts at the site indicates local cultivation of sweet potato, taro and yam. Of these, only sweet potato persisted through a post-1650 climatic downturn it seems, underscoring the enduring southern-Polynesian appeal of this hardy crop.

Keywords

OceaniaTe Waipounamu/South Islandancestral Māori colonisationradiocarbon datingsweet potato/kūmarayam/uwhitaro
Type
Research Article
Information
Antiquity , Volume 98 , Issue 401 , October 2024 , pp. 1376 - 1394
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 historical distribution of the American sweet potato (Ipomoea batatas) crop across Oceania, an area where Asia-Pacific vegetables were otherwise dominant, is noteworthy (Yen Reference Yen1974; Hather & Kirch Reference Hather and Kirch1991: 887; Ballard et al. Reference Ballard, Brown, Bourke and Harwood2005). Hardy, quick-growing I. batatas, now a globally significant comestible, was first transferred into the Pacific in separate events to open up dry, marginal environments for productive agriculture (Ballard et al. Reference Ballard, Brown, Bourke and Harwood2005; Iese et al. Reference Iese2018). One early modern sweet potato journey into western Oceania revolutionised pre-nineteenth-century economics in cooler montane New Guinea (Yen Reference Yen1974: 104–26; Ballard et al. Reference Ballard, Brown, Bourke and Harwood2005; Kirch Reference Kirch2017: 114–15). In Eastern Polynesia, I. batatas arrived directly from the Americas to be dispersed widely sometime after initial human settlement, c. AD 900, from a central island ‘ellipse’ (Figure 1A). Asia-Pacific crops remained prominent in this ellipse historically. However, transplanted I. batatas became the dominant food crop in southern Polynesia—as kumara on dry, sub-tropical Rapa Nui, and as kūmara for Māori in temperate-climate Aotearoa/New Zealand (Yen Reference Yen1974; Ballard et al. Reference Ballard, Brown, Bourke and Harwood2005; Green Reference Green, Ballard, Brown, Bourke and Harwood2005; Kirch Reference Kirch2017: 198–203, 208–10, 236, 238, 241–42, 265; Kirch et al. Reference Kirch, Hather, Horrocks and Kirch2017: 172–73).

Figure 1. Location maps for places and regions of this study: A) Polynesia, including Eastern Polynesian homeland ‘ellipse’ region identified in grey fill (after Yen Reference Yen1974; Green Reference Green, Ballard, Brown, Bourke and Harwood2005); B) central Aotearoa (base data CC BY 4.0) (figure by Les O'Neill).

Māori grew annual single-season kūmara up to the crop's cool-climate limits on the leeward coast of Te Waipounamu/South Island (Figure 1B). From warmer localities across Aotearoa, semi-subterranean storage pits (rua kūmara) supplied dormant tuberous roots into winter months (Barber & Higham Reference Barber and Higham2021). Māori also cultivated the Asia-Pacific geophytes Dioscorea yam/uwhi (probably D. alata) and semiaquatic taro (Colocasia esculenta), but less widely. Taro and uwhi required longer growing seasons and deeper, wetter and more fertile soils than kūmara (Yen Reference Yen1974; Leach Reference Leach1984: 17–32, 58–72; Barber Reference Barber2012a; Kirch Reference Kirch2017: 200; Heider et al. Reference Heider2021).

Debate persists around Polynesian sweet potato origins. Some scientists cite theoretical mechanics of ocean drift, seed resistance to salinity and modelled pre-human American-Polynesian genetic separation to argue that I. batatas became naturally transpacific (Muñoz-Rodríguez et al. Reference Muñoz-Rodríguez2018; Pereira et al. Reference Pereira, Ferreira Nunes, Ruiz Pessenda and Oliveira2020; Temmen et al. Reference Temmen, Montenegro, Juras, Field and DeGrand2022). Many anthropologists propose instead that South American or returning Polynesian voyagers introduced I. batatas, probably alongside the American gourd/hue (Lagenaria siceraria). They cite comparable Indigenous South American and Pacific names for sweet potato, which pivot around Proto-East Polynesian *kūmara (Figure 2; see also reviews in Scaglion Reference Scaglion, Ballard, Brown, Bourke and Harwood2005; Kirch Reference Kirch2017: 210; Anderson & Petchey Reference Anderson and Petchey2020: 351, 370; Temmen et al. Reference Temmen, Montenegro, Juras, Field and DeGrand2022). The absence of recorded native (beyond feral) I. batatas populations anywhere in the Indo-Pacific area, despite a well-documented natural Oceanic distribution of other Ipomoea spp. (Yen Reference Yen1974: 223–30, 261–63; Green Reference Green, Ballard, Brown, Bourke and Harwood2005: 48; Ladefoged 2005: 363; Muñoz-Rodríguez et al. Reference Muñoz-Rodríguez2018; Reference Muñoz-Rodríguez, Wood, Scotland, Rull and Stevenson2022: 68–70), is also notable. This fits with a genetic model of pre-Columbian human I. batatas transfer into Polynesia (Roullier et al. Reference Roullier, Benoit, McKey and Lebot2013).

Figure 2. Location map of modelled and unmodelled chronometric ages for plausible reported pre-Columbian Polynesian I. batatas remains including related data and crop names. Report sources by location are: Anaho, Allen & Ussher (Reference Allen and Ussher2013); Anakena, Berenguer et al. (Reference Berenguer, Clavero, Saldarriaga-Córdoba, Rivera-Hutinel, Seelenfreund, Martinsson-Wallin, Castañeda and Seelenfreund2024); Kohala, Ladefoged et al. (Reference Ladefoged, Graves and Coil2005); Pūrākaunui, Barber & Higham (Reference Barber and Higham2021, modelled); Tangatatau, Niespolo et al. (Reference Niespolo, Sharp and Kirch2019, modelled); Te Niu, Horrocks & Wozniak (Reference Horrocks and Wozniak2008); Whangamatā, Gumbley & Laumea (Reference Gumbley and Laumea2019, modelled) (figure by Les O'Neill & Chris Jennings).

The timing of pre-Columbian I. batatas movements into and across Oceania is also debated. A once widely accepted c. AD 1000–1100 radiocarbon chronology on unidentified charcoal from Tangatatau rockshelter on Mangaia bracketed finds of I. batatas parenchyma at the site (Hather & Kirch Reference Hather and Kirch1991; Green Reference Green, Ballard, Brown, Bourke and Harwood2005: 50). But more recent modelling of shorter-life radiocarbon plant ages for this context supports uranium-series dating of coral to AD 1361–1466 (Kirch et al. Reference Kirch, Hather, Horrocks and Kirch2017: 172; Niespolo et al. Reference Niespolo, Sharp and Kirch2019: 22–23, 31; Anderson & Petchey Reference Anderson and Petchey2020: 352–53). From northern Polynesia, the earliest plausible radiocarbon report is AD 1290–1430 (95% probability) on a poorly preserved carbonised root at Kohala, Hawai‘i, identified “in favour” of I. batatas (Ladefoged et al. Reference Ladefoged, Graves and Coil2005: 367–68). From south-eastern Polynesia, macrobotanical I. batatas remains on Rapa Nui are no older then the thirteenth century AD, at most (Green Reference Green, Ballard, Brown, Bourke and Harwood2005: 51; Anderson & Petchey Reference Anderson and Petchey2020: 353–54; Muñoz-Rodríguez et al. Reference Muñoz-Rodríguez, Wood, Scotland, Rull and Stevenson2022: 70–73, 78). And, in south-west Polynesia, the earliest reported radiocarbon age (AD 980–1280) on a carbonised I. batatas root from Pouerua, northern Aotearoa, represents an outlier from a post-1500 context (Anderson & Petchey Reference Anderson and Petchey2020: 360).

Purported pre-Columbian palynomorphs cf. I. batatas have also been dated across Polynesia. These are primarily starch granules and occasionally pollens (see online supplementary material (OSM) Methods and Materials (OSM Methods hereafter). However, it is not always clear whether these palynomorphs have been, or even can be, differentiated from native Pacific Ipomoea spp., some of which are edible (Anderson & Petchey Reference Anderson and Petchey2020: 353, 354, 360; Muñoz-Rodríguez et al. Reference Muñoz-Rodríguez, Wood, Scotland, Rull and Stevenson2022: 69, 71–72, 74–76). Moreover, the disturbance or mobility of palynomorphs within sediments is indicated in core samples from Aotearoa and a Rapa Nui crater lake (Horrocks et al. Reference Horrocks2012: 190, 192, figs. 2–4, tab. 1; Anderson & Petchey Reference Anderson and Petchey2020: 360–62).

A few pre-Columbian I. batatas starch reports appear to have more reliable contexts. Mollusc tools dated generally to AD 1200–1400 from Anaho, Marquesas Islands, preserve starch granules attributed to I. batatas, discriminating I. pes-caprae (Allen & Ussher Reference Allen and Ussher2013: 2804, 2805, 2808, 2811, tabs. 2, 4–6). Intriguingly, South American human DNA may also arrive in the Marquesas group c. AD 1200 (Ioannidis et al. Reference Ioannidis2020). Coastal cultivation soils incorporating starch granules cf. Ipomoea from Te Niu, Rapa Nui, plausibly date to AD 1214–1436 (95% probability), although this radiocarbon estimate is on unidentified wood from “major forest burning” (Horrocks & Wozniak Reference Horrocks and Wozniak2008: 130, tab. 1). Along this same coast at Anakena, starch granules on obsidian tools from a basal archaeological deposit are attributed to I. batatas with a modelled probability >90%. There are various radiocarbon determinations for this deposit, among which calibrated short-life palm endocarp dates are reported as AD 1326–1448 (Berenguer et al. Reference Berenguer, Clavero, Saldarriaga-Córdoba, Rivera-Hutinel, Seelenfreund, Martinsson-Wallin, Castañeda and Seelenfreund2024). In Aotearoa, a short-life Bayesian radiocarbon model dates a boundary transition for archaeological deposits with ‘sweet potato’ and taro starch to AD 1316–1399 (95% probability) at coastal Whangamatā, north-eastern Te-Ika-a-Māui/North Island (Gumbley & Laumea Reference Gumbley and Laumea2019: 103, 131–32, 206). Whangamatā also lies around the indistinct southern natural limit of Ipomoea in Oceania (Figure 2; OSM Methods). Well south of that limit, Polynesia's southernmost archaeological starch granules cf. Ipomoea are reported from midden-capped rua kūmara deposits in a coastal dune at Pūrākaunui, south-eastern Te Waipoumanu. These assumed I. batatas deposits are dated to AD 1430–1460 in a short-life Bayesian radiocarbon model, also at 95% probability (Barber & Higham Reference Barber and Higham2021).

Seemingly, sweet potato invisibility in the earliest, unequivocally pre-1300 deposits of these island sequences supports persistent suggestions of delayed Polynesian I. batatas dispersal (Green Reference Green, Ballard, Brown, Bourke and Harwood2005; Ladefoged et al. Reference Ladefoged, Graves and Coil2005; Anderson & Petchey Reference Anderson and Petchey2020). In Aotearoa, the foundational food economy (c. AD 1300–1450) included native vegetables, shellfish and finfish, marine mammals and birds, especially the flightless moa megaherbivores (Aves: Dinornithiformes, extinct by c. 1450–1500). Polynesian foods introduced to the islands were domestic dogs (kurī, Canis familiaris), commensal rats (kiore, Rattus exulans) and crops (Anderson et al. Reference Anderson, Binney and Harris2014: 76–86). Among the latter, sweet potato has been seen as influential (Leach Reference Leach1984: 54–63; Barber Reference Barber, Furey and Holdaway2004, Reference Barber2012a), but a recent study has called for a “critical review of nearly all” reported pre-1400 Aotearoa I. batatas dates (Anderson & Petchey Reference Anderson and Petchey2020: 371). Pre-1400 cultivation becomes Asia-Pacific crop production primarily, with I. batatas deemed unimportant, if present (Anderson & Petchey Reference Anderson and Petchey2020: 356–64, 371–72; see also Prebble et al. Reference Prebble2019, Reference Prebble2020).

These problems inform our study at Te Tau Ihu/northern Te Waipounamu, a colonisation-era distribution hub for meta-argillite adzes (toki). In this region, with no native Ipomoea, pre-contact kūmara evidence is diverse and potentially early (Barber Reference Barber1996, Reference Barber2010, Reference Barber2012a, Reference Barber2013, Reference Barber2017). Our focus is a multi-century Māori cultivation complex (Barber Reference Barber2013). Short-life radiocarbon ages are modelled and diagnostic palynomorphs targeted in light microscopy (see OSM Methods for details). We ask, when were I. batatas and other Polynesian crops transplanted to Te Tau Ihu and how might this transplantation inform our understanding of southern Polynesian colonisation?

Te Tau Ihu study region and site

Eastern Polynesian toki and moa and seal bones characterise Aotearoa's earliest papakāinga (home base) at Wairau Bar, eastern Te Tau Ihu (radiocarbon dated AD 1320–1360), as well as scattered sites further west (Barber Reference Barber1996; Anderson et al. Reference Anderson, Binney and Harris2014: 77–79; Jacomb et al. Reference Jacomb, Holdaway, Allentoft, Bunce, Oskam, Walter and Brooks2014). Post-1500 earthworks () across the region signal later Māori occupation. Māra (cultivations) are dated to the sixteenth–seventeenth centuries from floodplain soils modified by gravel additions around Appleby, southern Te Tai-o-Aorere/Tasman Bay. In neighbouring Mohua/Golden Bay, potentially earlier coastal māra are identified in eastern dunes and at the coastal Triangle Flat in the north-west (Barber Reference Barber1996, Reference Barber2010, Reference Barber2012a & Reference Barberb, Reference Barber2013, Reference Barber2017).

Triangle Flat site M24/11 spreads across low sandy-shelly ridges behind Mohua's soft shore, approximately 1km north-east of a defended headland (). Site components include stratified māra soils and features, midden deposits, hāngi (earth ovens), burials and stone artefacts, consistent with a sustained papakāinga (Figures 3 & S1; Barber Reference Barber2013, Reference Barber2024). The stratigraphy at M24/11 is capped by black sand layer 1 (L1 etc. hereafter) that incorporates post-contact farm materials (Figures 46A, S1–S3; Barber Reference Barber2013). In many places L1 overlies redeposited bivalve shells (mostly Austrovenus stutchburyi) from beach sediments. This shelly deposit which incorporates occasional Māori materiality (only) is differentially mounded and caps black sand māra soil. Together, the capping shell and māra soil become L2. Substrate depressions (labelled SD) from L2 soil extend roughly 200mm into natural, C-horizon shelly sand (L5). Small intrusions (<100mm) may be kūmara root moulds (e.g. Figure S3). L1 or L2 overlie discontinuous midden deposits of marine molluscs (primarily Paphies sp. and Myitilidae), finfish, cetaceans, smaller birds, kurī and kiore, designated L3. A lower, intermittent, anthropic black sand A-horizon base is designated L4. This fills a natural subsurface channel which is expanded in one area. As in L2 soil, substrate depressions are cut below beach shell caps from L4 soil into L5 substrate (Figures 4 & 5B; Barber Reference Barber2013, Reference Barber2024).

Figure 3. Triangle Flat site M24/11 from: A) western hill looking east over woolshed (cf. Figure S1); B) inland shelly ridge edge looking south over N21 E5 (by arrow) (photographs by Ian Barber; figure by Les O'Neill).

Figure 4. M24/11 excavation plan for units N19 E3–N21 E5 (from Figure S1), with lower section A'–B' (below, see also Figure S2) and inset photograph for N21 E3–E5 north (photo by Ian Barber; figure by Les O'Neill).

Figure 5. M24/11 sections presenting shelly mounded surfaces above planting pits filled with post-harvest beach shell (indicated within broken lines): A) lower L2 context between oblique baulk edges below discrete but disturbed beach mollusc cap (ii) and extensive mollusc deposit (i), N41 E15 (location Figure S1; also in Barber Reference Barber2013: figs. 4, 6B–B'); B) L4 context at border of N21 E3–E4 (SD3, see Figure 2). Scale 100mm in each section (photographs by Ian Barber; figure by Les O'Neill).

Figure 6. Deep, proposed taro planting pit with surface depression in L4 context, N70 E31: A) stratigraphic section and inset photograph for texture; B–D) photomicrographs from surface depression fill including B) large (35μm) faceted starch granule with central fissures cf. I. batatas, scale, 10μm; C) bundles of needle-like structures 80μm long in brightfield (left) and polarised (right) light, cf. ‘short thick’ C. esculenta raphide bundles (see Figure S9A caption), scale 10μm; D) a granular aggregate (individually <7μm, e.g. by arrow) with dark tissue in brightfield (left) and polarisation (right) around projecting CaOx druses cf. C. esculenta, scale 20μm (photographs by Ian Barber & Rebecca Benham; figure by Les O'Neill).

The rounded to asymmetric substrate depressions at M24/11 resemble ‘planting pits’ on Rapa Nui that vary in size and crop use, and are so designated hereafter (Figures 46A cf. Stevenson et al. Reference Stevenson, Jackson, Mieth, Bork and Ladefoged2006: 934, figs. 9–12; Horrocks & Wozniak Reference Horrocks and Wozniak2008; Barber Reference Barber2010, Reference Barber2012a, Reference Barber2013). Durable lithic and beach mollusc sediments above archaeological Rapa Nui and M24/11 planting pits, respectively, preserved garden moisture and soils in place. This has facilitated cultivation reuse to the present on Rapa Nui (Barber Reference Barber2010, Reference Barber2013).

Previous palynomorph reports from M24/11 identified pollens, spores, starch granules, vascular materials, biogenic silica and calcium oxalate (CaOx) crystals in light microscopy, including micro-particles cf. I. batatas and C. esculenta (OSM Methods; Horrocks Reference Horrocks2004: 328; Horrocks et al. Reference Horrocks, Shane, Barber, D'Costa and Nichol2004: 155; Barber Reference Barber2024: app. 1). L2 pollens include intrusive post-contact pine (Pinus sp.) and ribwort plantain (Plantago lanceolata), a single hue (Lagenaria siceraria) grain, and edible, native sow thistle (Sonchus sp.) (the latter often considered an indicator of disturbance; cf. Prebble et al. Reference Prebble2019). Secure L4 sediments at N70 E31 incorporate native palynomorphs only (Figure 6A). These are dominated by forest pollens and considerably fewer grass phytoliths than L2 samples, consistent with a primary context (Barber Reference Barber2024: app. 1).

Results

Light microscopy palynomorph analysis

The relatively well-preserved, semi-crystalline plant starch granules of our study were identified optically. In most cases this followed recognition of a birefringent (double refracted light) extinction cross in polarisation (Figures 7, 8, S4, S5). For species identification purposes we considered environment, context and known plant biogeography alongside specimen anatomy, allowing for limitations in Aotearoa starch granule reference work (Prebble et al. Reference Prebble2020; OSM Methods). Helpfully at M24/11, floral diversity is constrained in the predominantly young, dry, shallow, sandy topsoils, while starches of important local food plants have been documented in earlier light microscopy work (Barber & Higham Reference Barber and Higham2021: 11–12; OSM Methods).

Figure 7. Photomicrographs (brightfield left, polarisation right) of polygonal, circular and cupule starch granules from M24/11 archaeological contexts cf. I. batatas. Diagnostic features resolved (cf. reference specimens from Figure S5, Table S1) include small, round or ovate cavities at the hila (round in A, N21 E4, L4 channel fill; B, N21 E4–5, L4, SD2, with visual distortion in brightfield through bubble; faint ovate in C, SD2); a prominent circular to oval cavity at the hilum enclosed by marked central lamellae (D, in channel fill), and fissures from cavities at the hila (E, winged from prominent cavity; F, faint, by arrow, partly obscured extinction cross. Scales 10μm in each panel (photographs by Ian Barber & Rebecca Benham; figure by Les O'Neill & Chris Jennings).

Figure 8. Photomicrographs (brightfield left, polarisation right) of grouped to semi-compound starch granules cf. I. batatas (e.g. Barber & Higham Reference Barber and Higham2021: fig. 6D–F) from archaeological planting pits with arrows pointing to fissures from hila: A) N41 E15, lower L2; and B) N21 E4–5, SD2, L4, scales at slightly different magnification each 10μm (photographs by Ian Barber & Rebecca Benham; figure by Les O'Neill & Chris Jennings).

Hundreds of single, semi-compound and occasionally compound granules measuring 7–35μm in diameter, consistent with Ipomoea, presented in samples from L4 below dense mollusc sediments, and from L2 (e.g. Figures 6B, 7, 8, S4, S5). The granules are circular, subcircular and polygonal (multi-faceted) and present cavities or fissures at the hilum (granule origin) and on occasion, several lamellar growth rings (see OSM Methods). Granules of native, starchy Mohua plants lack cavities at hila, except in seeds from naturalised (pre-contact) karaka (Corynocarpus laevigatus) trees introduced from northern Aotearoa. However, karaka granules are <13.2μm and have no visible lamellae. Moreover, multiple lamellae are not diagnostic in laboratory starch contaminants that present cavities or fissures at hila (Type 1 in Crowther et al. Reference Crowther, Haslam, Oakden, Walde and Mercader2014), nor reported in granules from L. siceraria rind. Large uwhi (Dioscoreaceae) granules and lab starch contaminants do present lamellae but are easily differentiated (see OSM Methods and discussion below). Accordingly, eight L4 granules with lamellae around vacuoles or fissures in circular, cupule or polygonal shapes, one semi-compound, are most likely I. batatas (Figures 7, 8 & Table S1). Individual and semi-compound granules with cavities or fissures cf. I. batatas from L2 suggest local persistence of cultivation (Figures 8 & S4).

In contrast, the starch granules of a deep, asymmetric, L4 planting pit in N70 E31 are predominantly smaller (<6μm), often aggregated, or enclosed in tiny (<4μm) granule masses. These forms resemble reference C. esculenta amyloplasts, and similar granules from northern Te-Ika-a-Māui taro soils (Figure 6; Horrocks et al. Reference Horrocks, Shane, Barber, D'Costa and Nichol2004: 155; Barber Reference Barber2020; Prebble et al. Reference Prebble2020). There are comparable granular masses in L4 channel and SD2 fill, along with birefringent microcrystals that are bright and sometimes pleochroic (presenting variable colours) in polarisation (Figure S7; Barber Reference Barber2024).

These birefringent L4 microcrystals resemble CaOx raphides and druses (needle-like and larger group formations of crystals, respectively) from C. esculenta corms and northern Te-Ika-a-Māui taro soils (Figures 6C–D & S8; OSM Methods). CaOx crystals do occur in other plant families and native Aotearoa Araceae, including duckweeds (Lemna sp.) with starch granules less than 10μm (albeit not in tiny-granule masses). Context and association therefore become more determinative at M24/11. Of note, a smaller granule aggregate encloses druses from fill of the deep N70 E31 pit, while microcrystals are incorporated within tiny-granule masses in channel and contiguous SD2 fills. Epidermal fragments cf. C. esculenta leaf in these L4 samples strengthen the interpretation of taro presence (Figures 6D, S7A–C & S8B–C; OSM Methods).

One granule group from SD2 includes large elongate, flattened ovoid shapes, individually >30μm, with no facets and highly eccentric extinction crosses. Collectively these features characterise larger starch granules of greater yam/uwhi (D. alata) that present individually and in aggregate (Figure 9, Table S2; cf. Allen & Ussher Reference Allen and Ussher2013: fig. 10c–d; see also OSM Methods). Large-granule lab contaminants with eccentric hila are uncommon and typically singular (Type III in Crowther et al. Reference Crowther, Haslam, Oakden, Walde and Mercader2014), while Dioscoreaceae are not native to Aotearoa (see OSM Methods). Accordingly, this group is attributed as likely D. alata, representing the pre-modern world's southernmost credible Dioscorea cultivation datum (40°S, previously 38°S at Anaura Bay, eastern Te-Ika-a-Māui; Leach Reference Leach1984: 64–66, 68). It is plausible that uwhi were composted (if not planted) in the contiguous channel and subsequently incorporated into the shallow SD2 as detritus, along with C. esculenta.

Figure 9. Photomicrograph (brightfield left, polarisation right) of grouped SD2 starch granules presenting flattened, ovate shapes with highly eccentric crosses cf. D. alata. Scale 10μm (photographs by Ian Barber; figure by Les O'Neill).

Radiocarbon analysis

Carbonised branches and twigs containing intact vascular structures and without fungal hyphae—indicating that they were fresh when burnt—were radiocarbon dated using accelerator mass spectrometry (AMS) (Figure S9). Three single dating entities were selected from a primary concentration of well-preserved twigs in the L4 channel fill. Wood was also dated from an intact surface of discarded charcoal and cooking stone materials capping the L4 channel. These capping samples were short-life outer sections of a carbonised puka (Griselinia lucida) branch and a southern rātā (Metrosideros umbellata) branchlet. These outer stem samples were processed at different radiocarbon laboratories as NZA 62661 and Wk-55215, respectively (Figures 4, S2 & S9C–D). Three angiosperm twigs were also dated from L2, where a previous AMS age had been derived (Figure S3).

These nine atmospheric AMS determinations are analysed around five standard L3 marine ages in a four-phase Bayesian model. Calibration curves Marine20 (with a local marine offset) and SHCal20 are applied with outlier analysis in OxCal v.4.4 (Bronk Ramsey Reference Bronk Ramsey2009 for Heaton et al. Reference Heaton2020 and Hogg et al. Reference Hogg2020, respectively; also OSM Methods, Tables S3–S5). A historical terminus ante quem of 1836 mitigates the effect of multimodal L2 distributions across the wiggly post-1600 atmospheric curve (Figure 10, Tables S3 & S5).

Figure 10. Bayesian radiocarbon model for M24/11 phases calibrated by SHCal20 (Hogg et al. Reference Hogg2020) and Marine20 (Heaton et al. Reference Heaton2020) with local marine ΔR -166 ± 25 and outlier analysis (O: prior probability 0.05 or 5%) in OxCal v. 4.4 (Bronk Ramsey Reference Bronk Ramsey2009 with data and references in Tables S3–S5). Posterior distributions in darker histogram fill are grey for atmospheric and green for marine above 68.3% and 95.4% ranges (figure formatted by Les O'Neill).

All prior and posterior L4 distributions including capping ages from different laboratories fall within the interval AD 1285–1405 at 95.4% probability (rounded to five, as below). No outliers are identified beyond 0.05, or 5% (Figure 10). Lower modelled L4 distributions for NZA 66620, 62797 and 62799 span 1290–1385 at 95.4% probability and 1300–1365 at 68.2% probability (Table 1). This secure fourteenth-century chronology covers granules cf. I. batatas from channel fill and the contiguous pit SD2 with its mixed crop remains (Figure 4). For radiocarbon ages above L4, highest posterior density intervals begin around the mid-fifteenth century from the L3 midden, and from the end of the seventeenth century for L2 soil (Figure 10, Table S3).

Table 1. Calibrations for atmospheric Conventional Radiocarbon Ages (CRA), L4, with Bayesian radiocarbon model outputs in OxCal v. 4.4.

* Gl = Griselinia lucida; Mu = Metrosideros umbellata.

Rounded to 5 in OxCal v.4.4.

SHCal20 after Bronk Ramsey Reference Bronk Ramsey2009; Hogg et al. Reference Hogg2020; see also Table S3.

Discussion

This study contributes the first credible evidence of pre-AD 1400 I. batatas on Te Waipounamu (cf. Anderson & Petchey Reference Anderson and Petchey2020: 362–64) and the southernmost identification of D. alata in pre-contact Oceania. Moreover, the modelled L4 transition at M24/11 (AD 1310–1390; Figure 10) closely brackets the dates for the earliest, secure archaeological chronology in Aotearoa—the moa-hunting era Wairau Bar site (1320–1360; cf. Table 1 and Jacomb et al. Reference Jacomb, Holdaway, Allentoft, Bunce, Oskam, Walter and Brooks2014). The proximity of silcrete rock and regular local whale strandings help explain the appeal of early M24/11 settlement (Anderson et al. Reference Anderson, Binney and Harris2014: 81; Barber Reference Barber2024). We infer that Te Tau Ihu moa-hunting and multi-cultigen (including I. batatas) cultivation were probably contemporary.

These results illustrate the more complete picture that combined archaeological and microbotanical analyses provide (cf. Barber & Higham Reference Barber and Higham2021). Archaeological excavation and radiocarbon dating identified shallow, dry fourteenth-century planting pits that are indicative of kūmara cultivation. The deep pit in N70 E31, with its concave surface, is also suggestive of semiaquatic taro cultivation. The dominance of palynomorphs cf. I. batatas in the shallow pits and cf. C. esculenta in deeper N70 E31 is consistent. And microbotany alone has identified likely D. alata in SD2 from possible compost applications.

What should one make of this early multi-crop evidence? If the M24/11 channel is considered a likely crop detritus catchment, then there are fewer than 10 palynomorphs cf. C. esculenta compared with tens of granules of cf. I batatas in each analysed sample from channel fill. Moreover, fewer than 10 granules of cf. D. alata are present in any sample. This dominance of I. batatas from the outset of channel use resonates with the “relative frequency” of sweet potato starch on fourteenth-century tools from the homeland-region Marquesan Anaho site (Allen & Ussher Reference Allen and Ussher2013: 2811). Kūmara are also prominent in Māori accounts of crop introductions from Hawaiki, homeland of tradition and mythic abode of atua (deities) and the dead (cf. Figure 1; Anderson et al. Reference Anderson, Binney and Harris2014: 60–62, 67). In one stream of lore, original if not autochthonous non-agricultural inhabitants are so impressed by kūmara introduced from a Hawaiki visitor that they send waka (canoes) for new roots. The visitor's core name is frequently Rongo (southern var. Roko), the ancient Polynesian atua of agriculture, and of kūmara for Māori (Barber Reference Barber2012b; Anderson & Petchey Reference Anderson and Petchey2020: 354–56; Barber & Higham Reference Barber and Higham2021: 13–15).

Given the advantages of the hardy, fast-growing I. batatas in areas of marginal agricultural productivity, contemporaneous attempts at uwhi and taro cultivation at M24/11 might seem curious. One possibility is that the site was a social production experiment to replicate high-value, multi-crop ‘Hawaiki’ settings (Leach Reference Leach1984: 54–56). Here one might compare founding Wairau Bar settlers who assiduously reproduced high status homeland artefacts in local materials (Anderson et al. Reference Anderson, Binney and Harris2014: 37, 78). But with the American new outperforming the Asia-Pacific old, uwhi and perhaps even taro disappeared from pre-contact Te Waipounamu (cf. Leach Reference Leach1984: 105–6). Māori kūmara planting rituals continued, imposing potent tapu (supernatural separation) on cultivation fields (Barber Reference Barber2012b). Tapu-removing activities, people and cooked food were strictly prohibited, perhaps explaining why raw beach mollusc rather than cooked midden mulch was applied to māra at M24/11 (e.g. Figures 4 & 5; Barber Reference Barber2013: 49–50). In our new chronology this ritual preference has fourteenth-century roots.

In examining change over time, the more frequent cold and wet conditions affecting late Holocene Aotearoa (c. AD 1500–1900) need to be considered. These conditions correspond approximately to the global ‘Little Ice Age’ climate convergence (Lorrey & Bostock Reference Lorrey, Bostock and Shulmeister2017: 117). After AD 1600, Aotearoa was influenced further by “harsh” winds during one of the “strongest periods of westerly flow” for 4000 years (Lorrey et al. Reference Lorrey2008: 71). Such adverse conditions may have affected marginal cultivation outputs and influenced the abandonment of extensive kūmara fields at Palliser Bay, south-eastern Te-Ika-a-Māui (Leach Reference Leach1984: 35–43, 61–63; Barber & Higham Reference Barber and Higham2021). But if so, microclimate M24/11 kūmara and, perhaps, limited hue (L. siceraria) cultivation persisted after 1650 (Barber Reference Barber2024). Hundreds of starch granules cf. I. batatas are identified in a lower L2 planting pit below mounded beach shells. Extensive, stabilising eighteenth-century shelly surfaces may have been spread above pits to counter increasing wind effects (Figures 5A, 10, S4 & S5B–C; Barber Reference Barber2013).

Coastal southern kūmara agronomy during the Little Ice Age likely relied on the crop's tolerance of impoverished sandy soils that enabled cultivation in warm, if less fertile, dune settings. Moreover, the low, spreading, wind-resistant canopy and fast-setting roots of I. batatas would facilitate greater storm resilience than plants with larger, exposed leaves such as C. esculenta (Yen Reference Yen1974: 70–72; Iese et al. Reference Iese2018: tab. 1; Gatto et al. Reference Gatto, Naziri, San Pedro and Béné2021). Repeated re-introduction may have improved kūmara stock further. One nineteenth-century authority from the post-1600 Te Waipounamu iwi (tribe) Ngāi Tahu recalled that later waka introduced “better kinds” of kūmara (Barber & Higham Reference Barber and Higham2021: 14). Original southern varieties have not survived, unfortunately (Leach Reference Leach1984: 103–04), but archaeological evidence of leeward, eastern Te Waipounamu kūmara field systems and stores indicates some success (Barber Reference Barber, Furey and Holdaway2004: 177–78, 185–86; Barber & Higham Reference Barber and Higham2021). Ngāi Tahu traditions also acknowledge kūmara food and social production values, naming the crop in accounts of reciprocal ceremonial feasts (kaihaukai). In one history, kūmara were stored against an eighteenth-century east coast siege, just 12km north of Pūrākaunui's fifteenth-century rua kūmara (Barber & Higham Reference Barber and Higham2021: 2, 13–15, 16, S1 Text 10–13). Kūmara persistence through changing southern seasons and climate underscores Kirch's (Reference Kirch2017: 238) observation that sweet potato came “preadapted” to Aotearoa.

This research may even have applied uses. Today, sweet potato is the world's fifth most important comestible crop (Heider et al. Reference Heider2021: 64). But adverse impacts of climate and other environmental changes, including cyclones, drought and desertification, have affected twenty-first century production. In response, new agronomies focused on natural I. batatas hardiness seek to maintain, if not improve on, the geophyte's naturally high nutritional value (Heider et al. Reference Heider2021; Rosero et al. Reference Rosero2022). The ancient knowledge (ngā mātauranga o mua hei in Māori) and archaeology of marginal Oceanic I. batatas persistence might encourage if not inform these modern food security developments.

Conclusion

Dating of early cultivation and composting contexts containing proposed I. batatas palynomorphs in Te Tau Ihu points to a pre-1300 presence of sweet potato in the Polynesian homeland. From that Hawaiki, a pre-adapted I. batatas resilience, bequeathed by continental evolution, may have helped motivate early migrants to cross cooler waters for southern Polynesian isles (Barber Reference Barber2012a). Certainly, the presence of shallow planting pits and large numbers of starch granules suggest that fast-growing I. batatas was the primary fourteenth-century crop at the temperate-climate M24/11 site. A colonising experimental strategy that prioritised hardy kūmara over taro and uwhi is indicated. In time, wider amplification of that strategy would support social and subsistence kūmara production in selected areas of Te Waipounamu (Barber Reference Barber2010; Barber & Higham Reference Barber and Higham2021). This ancient southern Oceanic agronomy underscores the modern food security value of sweet potato.

Acknowledgements

Fran Allen identified and Justin Maxwell pretreated selected AMS plant samples. Julie Clark and Monica Tromp advised on palynomorph sample preparation. Statutory permissions are identified in the OSM. Representative Māori iwi body Manawhenua ki Mohua are recognised for customary jurisdiction over, and consent to investigate, site M24/11.

Funding statement

A Royal Society of New Zealand Marsden award (UOO1415) funded laboratory work and AMS determinations.

Online supplementary materials (OSM)

To view supplementary material for this article, please visit https://doi.org/10.15184/aqy.2024.143 and select the supplementary materials tab.

References

Allen, M. & Ussher, E.. 2013. Starch analysis reveals prehistoric plant translocations and shell tool use, Marquesas Islands, Polynesia. Journal of Archaeological Science 40: 2799–812. https://doi.org/10.1016/j.jas.2013.02.011CrossRefGoogle Scholar
Anderson, A. & Petchey, F.. 2020. The transfer of kūmara (Ipomoea batatas) from East to South Polynesia and its dispersal in New Zealand. Journal of the Polynesian Society 129: 351–82.CrossRefGoogle Scholar
Anderson, A.J., Binney, J. & Harris, A.. 2014. Tangata whenua: an illustrated history. Wellington: Bridget Williams.Google Scholar
Ballard, C., Brown, P., Bourke, R.M. & Harwood, T.. (ed.) 2005. The sweet potato in Oceania: a reappraisal (Ethnology Monograph 19, Oceania Monograph 56). Sydney: University of Sydney.Google Scholar
Barber, I.G. 1996. Loss, change, and monumental landscaping: towards a new interpretation of the ‘classic’ Maaori emergence. Current Anthropology 37: 868–80. https://doi.org/10.1086/204572CrossRefGoogle Scholar
Barber, I.G. 2004. Crops on the border: the growth of archaeological knowledge of Polynesian cultivation in New Zealand, in Furey, L. & Holdaway, S. (ed.) Change through time: 50 years of New Zealand archaeology (New Zealand Archaeological Association Monograph 26): 169–92. Auckland: New Zealand Archaeological Association.Google Scholar
Barber, I.G. 2010. Diffusion or innovation? Explaining extensive lithic cultivation fields on the southern Polynesian margins. World Archaeology 41: 7590. https://doi.org/10.1080/00438240903429755Google Scholar
Barber, I.G. 2012a. A fast yam to Polynesia: new thinking on the problem of the American sweet potato in Oceania. Rapa Nui Journal 26: 3142.Google Scholar
Barber, I.G. 2012b. Gardens of Rongo: applying cross-field anthropology to explain contact violence in New Zealand. Current Anthropology 53: 799808. https://doi.org/10.1086/667834CrossRefGoogle Scholar
Barber, I.G. 2013. Molluscan mulching at the margins: investigating the development of a South Island Māori variation on Polynesian hard mulch agronomy. Archaeology in Oceania 48: 4052. https://doi.org/10.1002/arco.5005Google Scholar
Barber, I.G. 2017. New radiocarbon ages clarify chronology of Waimea Plains Māori settlement and dry agronomy, northern Te Waipounamu. Journal of Pacific Archaeology 8: 103–7.Google Scholar
Barber, I.G. 2020. Further wet-taro evidence from Polynesia's southernmost Neolithic production margins. Proceedings of the National Academy of Sciences USA 117: 1257–58. https://doi.org/10.1073/pnas.1918374117Google ScholarPubMed
Barber, I.G. 2024. Archaeological investigations at Triangle Flat, western Golden Bay/Mohua. Report to Heritage New Zealand Pouhere Taonga, Wellington.Google Scholar
Barber, I.G. & Higham, T.F.G.. 2021. Archaeological science meets Māori knowledge to model pre-Columbian sweet potato (Ipomoea batatas) dispersal to Polynesia's southernmost habitable margins. PLoS ONE 16(4): e0247643. https://doi.org/10.1371/journal.pone.0247643CrossRefGoogle ScholarPubMed
Berenguer, P., Clavero, C., Saldarriaga-Córdoba, M., Rivera-Hutinel, A., Seelenfreund, D., Martinsson-Wallin, H., Castañeda, P. & Seelenfreund, A.. 2024. Identification of breadfruit (Artocarpus altilis) and South American crops introduced during early settlement of Rapa Nui (Easter Island), as revealed through starch analysis. PLoS ONE 19(3): e0298896. https://doi.org/10.1371/journal.pone.0298896CrossRefGoogle ScholarPubMed
Bronk Ramsey, C. 2009. Bayesian analysis of radiocarbon dates. Radiocarbon 51: 337–60. https://doi.org/10.1017/S0033822200033865Google Scholar
Crowther, A., Haslam, M., Oakden, N., Walde, D. & Mercader, J.. 2014. Documenting contamination in ancient starch laboratories. Journal of Archaeological Science 49: 90104. https://doi.org/10.1016/j.jas.2014.04.023CrossRefGoogle Scholar
Gatto, M., Naziri, D., San Pedro, J. & Béné, C.. 2021. Crop resistance and household resilience – the case of cassava and sweetpotato during super-typhoon Ompong in the Philippines. International Journal of Disaster Risk Reduction 62. https://doi.org/10.1016/j.ijdrr.2021.102392CrossRefGoogle Scholar
Green, R.C. 2005. Sweet potato transfers in Polynesian prehistory, in Ballard, C., Brown, P., Bourke, R.M. & Harwood, T. (ed.) The sweet potato in Oceania: a reappraisal (Ethnology Monograph 19, Oceania Monograph 56): 4362. Sydney: University of Sydney.Google Scholar
Gumbley, W. & Laumea, M.. 2019. T12/3 – The Cabana Site, Whangamatā, New Zealand: results of the 2016 investigation. Report to Heritage New Zealand Pouhere Taonga. Hamilton: W. Gumbley.Google Scholar
Hather, J. & Kirch, P.V.. 1991. Prehistoric sweet potato (Ipomoea batatas) from Mangaia Island, Central Polynesia. Antiquity 65: 887–93. https://doi.org/10.1017/S0003598X00080613CrossRefGoogle Scholar
Heaton, T.J. et al. 2020. Marine20—the marine radiocarbon age calibration curve (0–55,000 cal BP). Radiocarbon 62: 779820. https://doi.org/10.1017/RDC.2020.68Google Scholar
Heider, B. et al. 2021. Intraspecific diversity as a reservoir for heat-stress tolerance in sweet potato. Nature Climate Change 11: 6469. https://doi.org/10.1038/s41558-020-00924-4CrossRefGoogle Scholar
Hogg, A.G. et al. 2020. SHCal20 Southern Hemisphere calibration, 0–55,000 years cal BP. Radiocarbon 62: 759–78. https://doi.org/10.1017/RDC.2020.59CrossRefGoogle Scholar
Horrocks, M. 2004. Polynesian plant subsistence in prehistoric New Zealand: a summary of the microfossil evidence. New Zealand Journal of Botany 42: 321–34. https://doi.org/10.1080/0028825X.2004.9512907CrossRefGoogle Scholar
Horrocks, M. & Wozniak, J.. 2008. Plant microfossil analysis reveals disturbed forest and a mixed-crop, dryland production system at Te Niu, Easter Island. Journal of Archaeological Science 35: 126–42. https://doi.org/10.1016/j.jas.2007.02.014CrossRefGoogle Scholar
Horrocks, M., Shane, P.A., Barber, I.G., D'Costa, D.M. & Nichol, S.L.. 2004. Microbotanical remains reveal Polynesian agriculture and mixed cropping in early New Zealand. Review of Palaeobotany and Palynology 131: 147–57. https://doi.org/10.1016/j.revpalbo.2004.03.003CrossRefGoogle Scholar
Horrocks, M. et al. 2012. Microfossils of Polynesian cultigens in lake sediment cores from Rano Kau, Easter Island. Journal of Paleolimnology 47: 185204. https://doi.org/10.1007/s10933-011-9570-5CrossRefGoogle Scholar
Ioannidis, A.G. et al. 2020. Native American gene flow into Polynesia predating Easter Island settlement. Nature 583: 572–77. https://doi.org/10.1038/s41586-020-2487-2CrossRefGoogle ScholarPubMed
Iese, V. et al. 2018. Facing food security risks: the rise and rise of the sweet potato in the Pacific Islands. Global Food Security 18: 4856. https://doi.org/10.1016/j.gfs.2018.07.004CrossRefGoogle Scholar
Jacomb, C., Holdaway, R.N., Allentoft, M.E., Bunce, M., Oskam, C.L., Walter, R. & Brooks, E.. 2014. High-precision dating and ancient DNA profiling of moa (Aves: Dinornithiformes) eggshell documents a complex feature at Wairau Bar and refines the chronology of New Zealand settlement by Polynesians. Journal of Archaeological Science 50: 2430. https://doi.org/10.1016/j.jas.2014.05.023CrossRefGoogle Scholar
Kirch, P.V. 2017. On the road of the winds: an archaeological history of the Pacific Islands before European contact. Oakland: University of California Press.CrossRefGoogle Scholar
Kirch, P.V., Hather, J.G. & Horrocks, M.. 2017. Archaeobotanical assemblages from Tangatatau Rockshelter, in Kirch, P.V. (ed.) Tangatatau Rockshelter: the evolution of an Eastern Polynesian socio-ecosystem: 157–73. Los Angeles: Cotsen Institute of Archaeology.CrossRefGoogle Scholar
Ladefoged, T.N., Graves, M.W. & Coil, J.H.. 2005. The introduction of sweet potato in Polynesia: early remains in Hawai‘i. Journal of the Polynesian Society 114: 359–73.Google Scholar
Leach, H.M. 1984. 1,000 years of gardening in New Zealand. Wellington: Reed.Google Scholar
Lorrey, A. & Bostock, H.. 2017. The climate of New Zealand through the Quaternary, in Shulmeister, J. (ed.) Landscape and Quaternary environmental change in New Zealand (Atlantis Advances in Quaternary Science 3): 67139. https://doi.org/10.2991/978-94-6239-237-3_3Google Scholar
Lorrey, A. et al. 2008. Speleothem stable isotope records interpreted within a multi-proxy framework and implications for New Zealand palaeoclimate reconstruction. Quaternary International 187: 5275. https://doi.org/10.1016/j.quaint.2007.09.039Google Scholar
Muñoz-Rodríguez, P. et al. 2018. Reconciling conflicting phylogenies in the origin of sweet potato and dispersal to Polynesia. Current Biology 28: 1246–56. https://doi.org/10.1016/j.cub.2018.03.020Google ScholarPubMed
Muñoz-Rodríguez, P., Wood, J.R.I. & Scotland, R.W.. 2022. Sweet potato on Rapa Nui: insights from a monographic study of the genus Ipomoea, in Rull, V. & Stevenson, C. (ed.) The prehistory of Rapa Nui (Easter Island): towards an integrative interdisciplinary framework (Developments in Paleoenvironmental Research 22): 6383. Cham: Springer. https://doi.org/10.1007/978-3-030-91127-0_4Google Scholar
Niespolo, E.M., Sharp, W.D. & Kirch, P.V.. 2019. 230Th dating of coral abraders from stratified deposits at Tangatatau Rockshelter, Mangaia, Cook Islands: implications for building precise chronologies in Polynesia. Journal of Archaeological Science 101: 2133. https://doi.org/10.1016/j.jas.2018.11.001CrossRefGoogle Scholar
Pereira, D.A., Ferreira Nunes, H., Ruiz Pessenda, L.C. & Oliveira, G.C.X.. 2020. Seawater resistance in sweet potato (Ipomoea batatas) seeds: a key factor for natural dispersal from the Americas to Oceania. Frontiers of Biogeography 12. https://doi.org/10.21425/F5FBG46169Google Scholar
Prebble, M. et al. 2019. Early tropical crop production in marginal subtropical and temperate Polynesia. Proceedings of the National Academy of Sciences USA 116: 8824–33. https://doi.org/10.1073/pnas.1821732116Google ScholarPubMed
Prebble, M. et al. 2020. Reply to Barber: marginal evidence for taro production in northern New Zealand between 1200 and 1500 CE. Proceedings of the National Academy of Sciences USA 117: 1259–60. https://doi.org/10.1073/pnas.1919037117CrossRefGoogle ScholarPubMed
Roullier, C., Benoit, L., McKey, D.B. & Lebot, V.. 2013. Historical collections reveal patterns of diffusion of sweet potato in Oceania obscured by modern plant movements and recombination. Proceedings of the National Academy of Sciences USA 110: 2205–10. https://doi.org/10.1073/pnas.1211049110Google ScholarPubMed
Rosero, A. et al. 2022. Assessment of the current state of in situ conservation and use of sweet potato (Ipomoea batatas L.) in Colombia. Culture, Agriculture, Food and Environment 44: 7689. https://doi.org/10.1111/cuag.12293CrossRefGoogle Scholar
Scaglion, R. 2005. Kumara in the Equadorian Gulf of Guayaquil?, in Ballard, C., Brown, P., Bourke, R.M. & Harwood, T. (ed.) The sweet potato in Oceania: a reappraisal (Ethnology Monograph 19, Oceania Monograph 56): 3541. Sydney: University of Sydney.Google Scholar
Stevenson, C.M., Jackson, T.L., Mieth, A., Bork, H. & Ladefoged, T.N.. 2006. Prehistoric and early historic agriculture at Maunga Orito, Easter Island (Rapa Nui), Chile. Antiquity 80: 919–36. https://doi.org/10.1017/S0003598X00094515Google Scholar
Temmen, J., Montenegro, A., Juras, S., Field, J.S. & DeGrand, J.. 2022. Floating the sweet potato to Polynesia: considering the feasibility of oceanic drift for the prehistoric introduction of the sweet potato (Ipomoea batatas) to Pacific Islands. Quaternary Science Reviews 295. https://doi.org/10.1016/j.quascirev.2022.107709CrossRefGoogle Scholar
Yen, D.E. 1974. The sweet potato in Oceania: an essay in ethnobotany. Honolulu: Bishop Museum.Google Scholar
Figure 0

Figure 1. Location maps for places and regions of this study: A) Polynesia, including Eastern Polynesian homeland ‘ellipse’ region identified in grey fill (after Yen 1974; Green 2005); B) central Aotearoa (base data CC BY 4.0) (figure by Les O'Neill).

Figure 1

Figure 2. Location map of modelled and unmodelled chronometric ages for plausible reported pre-Columbian Polynesian I. batatas remains including related data and crop names. Report sources by location are: Anaho, Allen & Ussher (2013); Anakena, Berenguer et al. (2024); Kohala, Ladefoged et al. (2005); Pūrākaunui, Barber & Higham (2021, modelled); Tangatatau, Niespolo et al. (2019, modelled); Te Niu, Horrocks & Wozniak (2008); Whangamatā, Gumbley & Laumea (2019, modelled) (figure by Les O'Neill & Chris Jennings).

Figure 2

Figure 3. Triangle Flat site M24/11 from: A) western hill looking east over woolshed (cf. Figure S1); B) inland shelly ridge edge looking south over N21 E5 (by arrow) (photographs by Ian Barber; figure by Les O'Neill).

Figure 3

Figure 4. M24/11 excavation plan for units N19 E3–N21 E5 (from Figure S1), with lower section A'–B' (below, see also Figure S2) and inset photograph for N21 E3–E5 north (photo by Ian Barber; figure by Les O'Neill).

Figure 4

Figure 5. M24/11 sections presenting shelly mounded surfaces above planting pits filled with post-harvest beach shell (indicated within broken lines): A) lower L2 context between oblique baulk edges below discrete but disturbed beach mollusc cap (ii) and extensive mollusc deposit (i), N41 E15 (location Figure S1; also in Barber 2013: figs. 4, 6B–B'); B) L4 context at border of N21 E3–E4 (SD3, see Figure 2). Scale 100mm in each section (photographs by Ian Barber; figure by Les O'Neill).

Figure 5

Figure 6. Deep, proposed taro planting pit with surface depression in L4 context, N70 E31: A) stratigraphic section and inset photograph for texture; B–D) photomicrographs from surface depression fill including B) large (35μm) faceted starch granule with central fissures cf. I. batatas, scale, 10μm; C) bundles of needle-like structures 80μm long in brightfield (left) and polarised (right) light, cf. ‘short thick’ C. esculenta raphide bundles (see Figure S9A caption), scale 10μm; D) a granular aggregate (individually <7μm, e.g. by arrow) with dark tissue in brightfield (left) and polarisation (right) around projecting CaOx druses cf. C. esculenta, scale 20μm (photographs by Ian Barber & Rebecca Benham; figure by Les O'Neill).

Figure 6

Figure 7. Photomicrographs (brightfield left, polarisation right) of polygonal, circular and cupule starch granules from M24/11 archaeological contexts cf. I. batatas. Diagnostic features resolved (cf. reference specimens from Figure S5, Table S1) include small, round or ovate cavities at the hila (round in A, N21 E4, L4 channel fill; B, N21 E4–5, L4, SD2, with visual distortion in brightfield through bubble; faint ovate in C, SD2); a prominent circular to oval cavity at the hilum enclosed by marked central lamellae (D, in channel fill), and fissures from cavities at the hila (E, winged from prominent cavity; F, faint, by arrow, partly obscured extinction cross. Scales 10μm in each panel (photographs by Ian Barber & Rebecca Benham; figure by Les O'Neill & Chris Jennings).

Figure 7

Figure 8. Photomicrographs (brightfield left, polarisation right) of grouped to semi-compound starch granules cf. I. batatas (e.g. Barber & Higham 2021: fig. 6D–F) from archaeological planting pits with arrows pointing to fissures from hila: A) N41 E15, lower L2; and B) N21 E4–5, SD2, L4, scales at slightly different magnification each 10μm (photographs by Ian Barber & Rebecca Benham; figure by Les O'Neill & Chris Jennings).

Figure 8

Figure 9. Photomicrograph (brightfield left, polarisation right) of grouped SD2 starch granules presenting flattened, ovate shapes with highly eccentric crosses cf. D. alata. Scale 10μm (photographs by Ian Barber; figure by Les O'Neill).

Figure 9

Figure 10. Bayesian radiocarbon model for M24/11 phases calibrated by SHCal20 (Hogg et al.2020) and Marine20 (Heaton et al.2020) with local marine ΔR -166 ± 25 and outlier analysis (O: prior probability 0.05 or 5%) in OxCal v. 4.4 (Bronk Ramsey 2009 with data and references in Tables S3–S5). Posterior distributions in darker histogram fill are grey for atmospheric and green for marine above 68.3% and 95.4% ranges (figure formatted by Les O'Neill).

Figure 10

Table 1. Calibrations for atmospheric Conventional Radiocarbon Ages (CRA), L4, with Bayesian radiocarbon model outputs in OxCal v. 4.4.

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