Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-22T06:28:58.727Z Has data issue: false hasContentIssue false

Resetting Archaeological Interpretations of Precontact Indigenous Agriculture: Maize Isotopic Evidence from Three Ancestral Mohawk Iroquoian Villages

Published online by Cambridge University Press:  14 September 2023

John P. Hart*
Affiliation:
Research and Collections Division, New York State Museum, Albany, NY, USA
Susan Winchell-Sweeney
Affiliation:
Research and Collections Division, New York State Museum, Albany, NY, USA
*
Corresponding author: John P. Hart; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Archaeologists working in eastern North America typically refer to precontact and early postcontact Native American maize-based agriculture as shifting or swidden. Based on a comparison with European agriculture, it is generally posited that the lack of plows, draft animals, and animal manure fertilization resulted in the rapid depletion of soil nitrogen. This required Indigenous farmers to move their fields frequently. In Northern Iroquoia, depletion of soil fertility is frequently cited as one reason why villages were moved to new locations every 20 to 40 years. Recent analysis of δ15N ratios of maize macrobotanical remains from Northern Iroquoia, however, suggests that Iroquoian farmers were able to maintain soil nitrogen in their maize fields. An expanded analysis of maize kernel δ15N ratios from three ancestral Mohawk villages indicates that farmers from those villages maintained soil nitrogen throughout the occupational spans of their villages. It further suggests that precontact Iroquoian agronomy was consistent with contemporary conservation agriculture practices.

Resumen

Resumen

Les archéologues travaillant dans l'est de l'Amérique du Nord qualifient généralement l'agriculture à base de maïs pratiquée par les Autochtones avant et après le contact avec les Européens d'agriculture itinérante ou de culture sur brûlis. Sur la base d'une comparaison avec l'agriculture européenne, il est généralement admis que l'absence de charrue, d'animaux de trait et de fumier animal a entraîné un épuisement rapide de l'azote du sol. Les agriculteurs autochtones devaient donc déplacer fréquemment leurs champs. Dans l'Iroquoianie nordique, l'épuisement de la fertilité du sol est souvent cité comme l'une des raisons pour lesquelles les villages étaient déplacés tous les 20 à 40 ans. Une analyse récente des rapports de δ15N dans les restes macrobotaniques de maïs de l'Iroquoianie nordique suggère toutefois que les agriculteurs iroquoiens étaient en mesure de maintenir l'azote du sol dans leurs champs de maïs. Une analyse poussée des rapports de δ15N des grains de maïs provenant de trois villages mohawks ancestraux, présentée ici, indique que les agriculteurs de ces villages ont maintenu l'azote du sol tout au long de la période d'occupation de leurs villages. Elle suggère en outre que l'agronomie iroquoienne pré-contact était compatible avec les pratiques contemporaines de l'agriculture de conservation.

Type
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 (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), 2023. Published by Cambridge University Press on behalf of the Society for American Archaeology

Maize (Zea mays ssp. mays) is one of the world's most important agricultural crops, accounting for an estimated 39% of all grain production in 2017–2019, with approximately one-third of all farms producing it (Erenstein et al. Reference Erenstein, Chamberlin and Sonder2021). The crop evolved from an annual teosinte (Zea mays ssp. parviglumis) in the central Balsas River Valley of Mexico some 7,000–9,000 years ago (Matsuoka et al. Reference Matsuoka, Vigouroux, Goodman, Sanchez G., Buckler and Doebley2002). It gradually spread throughout the Western Hemisphere, reaching temperate northeastern North America about 2,300 years ago (Albert et al. Reference Albert, Kooiman, Clark and Lovis2018; Gates St-Pierre Reference Gates St-Pierre and Thompson2015; Hart et al. Reference Hart, Brumbach and Lusteck2007). Some 1,600 years later, maize had become the dominant source of calories in the diets of Iroquoian-speaking peoples in parts of present-day New York, southern Ontario, and southern Québec, a region generally referred to as Northern Iroquoia (Birch Reference Birch2015). Isotopic analyses of fourteenth- to seventeenth-century AD human teeth and bone from southern Ontario indicate that maize accounted for 50% to more than 70% of diets (e.g., Feranec and Hart Reference Feranec and Hart2019; Pfeiffer et al. Reference Pfeiffer, Sealy, Williamson, Needs-Howarth and Lesage2016). This high degree of dependence on a single grain crop required major commitments of time and energy to agricultural production. As in other parts of the Western Hemisphere, Iroquoian agronomic practices were adapted to regional climatic and local edaphic and hydrological conditions (Hart and Feranec Reference Hart and Feranec2020; Mt. Pleasant Reference Mt. Pleasant2011).

Archaeologists (e.g., Baden and Beekman Reference Baden and Beekman2001; Schroeder Reference Schroeder1999) have typically discounted the productivity of precontact Indigenous agriculture in eastern North America, given the lack of plows and draft animals and the consequent lack of fertilization with draft animal manure to replace soil nitrogen.Footnote 1 The depletion of soil nitrogen, resulting in poor maize production, is thought to have required the clearing of new fields on a regular basis, contributing to the Iroquoian practice of relocating villages every 20 to 40 years (e.g., Birch and Williamson Reference Birch and Williamson2012). To the contrary, Doolittle (Reference Doolittle2000, Reference Doolittle2004) and Mt. Pleasant (Reference Mt. Pleasant2011, Reference Mt. Pleasant2015) suggested that Indigenous agriculture in eastern North America was permanent and that Indigenous agronomic practices maintained soil nitrogen.

Because centuries of Euro-American and Euro-Canadian plow-based agriculture have obliterated Iroquoian agricultural fields and changed soil chemistry, the most direct evidence for Iroquoian agronomic practices is macrobotanical remains, generally in the form of charred maize kernels and squash (Cucurbita pepo) and common bean (Phaseolus vulgaris) seeds. Recent analysis of maize macrobotanical remains nitrogen isotope ratios (15N/14N or δ15N) from primarily fifteenth- and sixteenth-century sites in Northern Iroquoia suggests that Iroquoian farmers were able to maintain nitrogen in their agricultural fields (Hart and Feranec Reference Hart and Feranec2020) consistent with Mt. Pleasant's and Doolittle's scenarios. This article builds on that analysis by focusing on three fifteenth- to sixteenth-century ancestral Mohawk village sites located in the watershed of a tributary to the Mohawk River in east-central New York (Funk and Kuhn Reference Funk and Kuhn2003). We obtained δ15N ratios on additional samples of maize kernels from these three sites located near one another, which allowed an assessment of ancestral Mohawk farmers’ abilities to maintain soil fertility in their agricultural fields. If these farmers were able to maintain soil fertility, then δ15N ratios on maize macrobotanical remains should be significantly higher than those of plants outside agricultural fields throughout the occupational histories of those sites (Hart and Feranec Reference Hart and Feranec2020).

Soil Nitrogen and Indigenous Agriculture

Nitrogen is a limiting nutrient for plants (Kraiser et al. Reference Kraiser, Gras, Gutiérrez, González and Gutiérrez2011). Plants obtain nitrogen from soil, the air, or both through symbiotic relationships with mycorrhizal fungi or endophytic bacteria (Gosling et al. Reference Gosling, Hodge, Goodlass and Bending2006). Although maize is mycorrhizal (Wang and Qiu Reference Wang and Y. L.2006), it is associated with arbuscular mycorrhizae, which have little effect on nitrogen uptake but enhance phosphorus uptake (Gosling et al. Reference Gosling, Hodge, Goodlass and Bending2006). With the known exception of a few landraces in Mexico associated with endophytic bacteria (Estrada et al. Reference Estrada, Mavingui, Cournoyer, Fontaine, Balandreau and Caballero-Mellado2002; Van Deynze et al. Reference Van Deynze, Zamora, Delaux, Heitmann, Jayaraman, Rajasekar and Graham2018), maize obtains all its nitrogen from the soil (Osterholz et al. Reference Osterholz, Rinot, Liebman and Castellano2017).

Soil nitrogen is derived from soil organic matter (SOM). For soil nitrogen to be available to plants it must be mineralized through microbial decomposition. Craine and colleagues (Reference Craine, Elmore, Aidar, Bustamante, Dawson, Hobbie and Kahmen2009) found a global positive correlation between increased soil nitrogen and higher δ15N ratios in plants (also see Kahmen et al. Reference Kahmen, Wanek and Buchmann2008). Various processes related to soil nitrogen discriminate against 15N, which results in higher δ15N ratios in soil and therefore in plants (Kahmen et al. Reference Kahmen, Wanek and Buchmann2008; Pardo and Nadelhoffer Reference Pardo, Nadelhoffer, West, Bowen, Dawson and Tu2010; for technical overviews, see Craine et al. Reference Craine, Brookshire, Cramer, Hasselquist, Koba, Marin-Spiotta and Wang2015; Szpak Reference Szpak2014). By exposing SOM to air, plowing results in its oxidation, which in turn depletes nitrogen, as does soil erosion, which increases under plowing (Kassam et al. Reference Kassam, Friedrich, Shaxson and Pretty2009; Mt. Pleasant Reference Mt. Pleasant2011). As a result, after a number of years depending on its original density, SOM must be replaced through fertilization. From the Neolithic period onward in the Eastern Hemisphere, replacement was often in the form of draft animal manure (e.g., Bogaard et al. Reference Bogaard, Heaton, Poulton and Merbach2007; Tao et al. Reference Tao, Zhang, Xu, Wu, Wei, Gu and Zhang2022). Experiments have documented that increased manuring results in increased δ15N ratios in the grains of both C3- and C4-pathway plants (e.g., Bogaard et al. Reference Bogaard, Fraser, Heaton, Wallace, Vaiglova, Charles and Jones2013; Christensen et al. Reference Christensen, Jensen, Dong and Bogaard2022; Fraser et al. Reference Fraser, Bogaard, Heaton, Charles, Jones, Christensen and Halstead2011).

North American archaeologists often use European agronomy as a baseline of comparison for precontact Indigenous agriculture. Native Americans did not have draft animals and plows prior to the often-forced adoptions of Euro-American and Euro-Canadian agronomic practices in the eighteenth and nineteenth centuries (Hurt Reference Hurt1987). The lack of plows and domesticated animal manure for fertilizing has been the basis for discounting the ability of Iroquoian farmers to permanently cultivate fields. The practice of village communities abandoning established settlements after 20 to 40 years is commonly attributed to the depletion of agricultural soil fertility, among other factors (e.g., Birch Reference Birch2012:650; Jones and Wood Reference Jones and Wood2012:2595). Some propose that agricultural clearings were continually expanded during the occupation of a village to bring new soil under cultivation as the originally cultivated soils were depleted in nitrogen and maize productivity fell (Snow Reference Snow1996:70). This scenario results in projected clearings of many hundreds to more than 2,000 acres for large villages (Birch and Williamson Reference Birch and Williamson2012:98–100).

Contrary to these interpretations, Doolittle (Reference Doolittle1992, Reference Doolittle2000, Reference Doolittle2004), based on an analysis of the ethnohistorical record, suggested that Indigenous agriculture in eastern North America, including Northern Iroquoia, was intensive, rather than shifting or extensive. Historical, tropical swidden or slash-and-burn agriculture is often used as an analogy for prehistoric eastern North American agriculture (e.g., Bamann et al. Reference Bamann, Kuhn, Molnar and Snow1992; Creese Reference Creese2016; Jones Reference Jones2010; Snow Reference Snow, Douglass and Gonlin2012; Sykes Reference Sykes1980). Swidden fields are generally small and productive for only a few years. Doolittle (Reference Doolittle2004:184) cited difficulties in clearing forests to create agricultural fields, the gradual removal of tree stumps from fields, reforestation as a long-term process, fallowed fields covered in grass rather than trees when brought back under cultivation, and the cultivation of large fields as ethnohistorical evidence for permanent rather than swidden agriculture in eastern North America: “Fields were cultivated for multiple years, perhaps even permanently or semipermanently, and not for short periods of time as is characteristic of swidden systems” (Doolittle Reference Doolittle2004:186). How was this possible if the fertility of soils was depleted after a short span of time?

Based on actualistic experiments, agronomic knowledge, and the ethnohistorical record, Mt. Pleasant (Reference Mt. Pleasant2011, Reference Mt. Pleasant2015; Mt. Pleasant and Burt Reference Mt. Pleasant and Burt2010) suggested that Iroquoian agronomic practices were well adapted to edaphic contexts and to maize as a crop. According to Mt. Pleasant, hand tools (e.g., digging sticks, hoes) had advantages over plows, and Iroquoian agriculture was more productive per unit of land than contemporaneous European and Euro-American/Canadian plow-based agriculture. In naturally fertile Alfisols and Inceptisols, Iroquoian agronomic practices, resulting in minimal disturbance to soils, maintained SOM and therefore soil fertility over extended time spans. The creation of small mounds (“corn hills”) using hoes and the subsequent planting of a few maize kernels in each mound with minimal disturbance using digging sticks resulted in the retention of SOM, soil microbiota, and therefore nitrogen (Coban et al. Reference Coban, De Deyn and van der Ploeg2022). SOM can also increase soil water-holding capacity, buffering water availability against fluctuating rainfall (Habbib et al. Reference Habbib, Verzeaux, Nivelle, Roger, Lacoux, Catterou, Hirel, Dubois and Tétu2016; Williams et al. Reference Williams, Hunter, Kammerer, Kane, Jordan, Mortensen and Smith2016). Mt. Pleasant (Reference Mt. Pleasant2015) suggested that such agronomic practices in naturally fertile soils resulted in highly productive, stable agricultural systems. Using actualistic experiments in present-day New York, Mt. Pleasant and Burt (Reference Mt. Pleasant and Burt2010) obtained yields of 22–76 bushels of maize per acre, with the higher yields in naturally fertile soils. Mt. Pleasant (Reference Mt. Pleasant2015:406) further suggested that across eastern North America Indigenous farmers were likely to have sustained yields of 25–50 bu/acre by cultivating naturally fertile Alfisols, Inceptisols, and Mollisols. She proposed this as “a new paradigm for Native American agriculture in Eastern North America” (Mt. Pleasant Reference Mt. Pleasant2015:375).

Mt. Pleasant's estimates of maize yields stand at odds with those that have continuing influence on archaeological interpretations of Iroquoian agriculture, which suggest mean productivity of 10 (Schroeder Reference Schroeder1999) or 8–12 (Baden and Beekman Reference Baden and Beekman2001) bu/acre. Baden and Beekman (Reference Baden and Beekman2001:513) estimated optimal yields of 18–30 bu/acre, which were not sustainable because of soil nitrogen depletion, which they modeled as a monotonically decreasing function. They suggested that because soil fertilization was not practiced, yields decreased by 50% over the course of a few years as plant-available nitrogen in soils was depleted and not replaced. Native American farmers then shifted production to new fields to gain higher yields.

Although their focus is precontact Indigenous agriculture, these competing models are not based on archaeological evidence. Both models identified plant-available nitrogen as a critical component in the sustainability of Indigenous agriculture. Even though there is a distinct lack of preserved Iroquoian maize fields because of centuries of Euro-American/Canadian agriculture, it is possible to assess soil fertility through stable isotopic analyses of maize macrobotanical remains (Hart and Feranec Reference Hart and Feranec2020). Here we provide isotopic analysis of maize macrobotanical remains from three ancestral Mohawk village sites.

Three Ancestral Mohawk Villages along Caroga Creek

From 1960 through 1970 crews from the New York State Museum with the aid of university field schools extensively excavated three ancestral Mohawk village sites in the Caroga Creek drainage basin. Caroga Creek is a tributary of the Mohawk River in eastern New York (Figure 1). The sites—Smith-Pagerie, Klock, and Garoga—are in defensive positions on peninsula-like ridges, with three sides having sheer drop-offs to Caroga Creek; the fourth side, from which the villages were accessed, was defended by palisades having posts with diameters up to 60 cm (Funk and Kuhn Reference Funk and Kuhn2003; Ritchie and Funk Reference Ritchie and Funk1973). Smith-Pagerie occupies approximately 4 acres of which 21,000 m2 (13.0%) were excavated. Klock occupies an area of approximately 4 acres of which 1.950 m2 (12.05%) were excavated. Garoga occupies 2.5 acres of which 1.5 acres (60.0%) were excavated. Multiple longhouses were identified at each site along with more than 150 pit features and hearths at Klock and Garoga and more than 450 at Smith-Pagerie (Funk and Kuhn Reference Funk and Kuhn2003). Many of the pits at each site likely functioned as produce-storage facilities based on their size (diameter and depth; DeBoer Reference DeBoer1988). Several large pits at each site had charred grass, tree bark linings, or both, further supporting this interpretation.

Figure 1. Locations of the Smith-Pagerie, Klock, and Garoga sites.

Although the sites were not completely excavated, they are the most extensively excavated ancestral Mohawk villages. They are also among the most intensively radiocarbon-dated Northern Iroquoian sites; Bayesian analyses of recently obtained and legacy radiocarbon dates place the Smith-Pagerie occupation at AD 1478–1498, Klock at AD 1499–1521, and Garoga at AD 1550–1582 (68.3% highest posterior density), with their occupations lasting 20–30 years (Manning et al. Reference Manning, Lorentzen and Hart2021). Although often interpreted as a sequence of villages representing the same community over the course of several generations (Funk and Kuhn Reference Funk and Kuhn2003; Ritchie and Funk Reference Ritchie and Funk1973), recent social network analysis suggests that the sites represent separate communities (Hart Reference Hart2020).

Materials and Methods

Two sources of data are used to test the hypothesis that farmers at the three sites were able to maintain agricultural soil fertility: the distribution of naturally fertile soils in the vicinity of each site and isotope ratio mass spectrometry (IRMS) measurements of maize, other macrobotanical remains, and white-tailed deer collagen. All statistics were calculated in PAST 4.11 (Hammer et al. Reference Hammer, Harper and Ryan2001).

Soils Data

Alfisols and Inceptisols are the two soil orders exploited by Iroquoian farmers for their natural fertility (Mt. Pleasant and Burt Reference Mt. Pleasant and Burt2010). Mt. Pleasant (Reference Mt. Pleasant2015) used the National Commodity Crop Productivity Index (NCCPI) for corn (maize) to standardize comparisons of inherent soil fertility for non-irrigated maize production across eastern North America (Natural Resources Conservation Service 2022). Alfisols and Inceptisols orders and the NCCPI for maize acreage in proximity to the three Caroga Creek sites were calculated using GIS technology.

Soils datasets were derived from the Soil Survey Geographic Database (SSURGO; https://data.nal.usda.gov/dataset/soil-survey-geographic-database-ssurgo), which comprises digitized soils information collected across the United States since 1899. These datasets are available as map packages for ArcGIS Pro through the SSURGO Downloader and are organized by watershed sub-basins. Using the SSSURGO Downloader application, the Mohawk River Valley sub-basin soils map package was downloaded, extracted, and opened in ArcGIS Pro 2.9.1, the GIS software in which all calculations were made. Two of the 173 soil attributes were of interest: Dominant Soil Order (specifically, the soil orders Alfisols and Inceptisols) and NCCPI v3—Corn, a soil productivity index for growing maize.

Using the Dominant Soil Order field in the attribute table, the text values Alfisols and Inceptisols were selected and exported to a new soil map unit polygon layer. The minimum and maximum range of the NCCPI v3—Corn (maize) values were identified, and the soil polygons were separated into four classes using the NCCPI v3 Corn Soil Map Unit Classification: (1) less than 20% productivity for corn, (2) >20%–55%, (3) >55%–75%, and (4) >75%–85%.

Point locations for Klock, Smith-Pagerie, and Garoga were added to the GIS map. The Buffer tool was then employed to create a 2 km catchment area around each site following Jones (Reference Jones, Jones and Creese2016; Jones and Wood Reference Jones and Wood2012). The Summarize Within tool was then used on each catchment to calculate the total acreage of Alfisols and Inceptisols and the acreage of soil map units having an NCCPI class 3 (>55%–75%); class 4 is not present in the Caroga Creek drainage basin.

Isotope Data

IRMS δ15N and δ13C measures were obtained for 28 maize kernels (Hart and Winchell-Sweeney Reference Hart and Winchell-Sweeney2023:Table S1). Also included in the analysis are δ15N and δ13C measures for nine maize kernels and two maize cobs obtained from previously reported radiocarbon-dated specimens (Manning and Hart Reference Manning and Hart2019; Manning et al. Reference Manning, Lorentzen and Hart2021). Maize for IRMS measurement was taken from feature macrobotanical assemblages held in the New York State Museum collections, which have multiple maize specimens. These included hearths and large, presumably storage, pit features. Hearths were located within longhouse postmold patterns. We assume that the hearths were used throughout the occupation span of the longhouses and were cleaned out occasionally. As a result, the maize remains from these features represent the later stages of use and village occupation (Manning et al. Reference Manning, Lorentzen and Hart2021). The large pit features generally had multiple strata representing post-use fill. In some instances, basal layers of charred grass, bark linings, or both were documented, presumably representing the original pit functions (Funk and Kuhn Reference Funk and Kuhn2003). For Garoga and Klock it was possible in many instances to determine from profile drawings and field notes where in the large pit features the specimens originated. Maize recovered from on or immediately above a pit lining likely represented use of a pit for its original storage function.Footnote 2 Strata above the lining to the top of the pit represent post-use filling, presumably toward the end of a site's occupational span (Manning et al. Reference Manning, Lorentzen and Hart2021).

Macrobotanical sampling for IRMS was done in the New York State Museum's geochemistry lab. We removed approximately 10–15 mg from each specimen, which was weighed, placed in a labeled plastic tube with a lid, and shipped to the W. M. Keck Carbon Cycle lab at the University of California-Irvine for IRMS measurement. At Keck, samples were subjected to acid-base-acid (ABA) pretreatment before combustion. Isotope ratio measurements were made on the pretreated aliquots with a Frisons NA1500NC elemental analyzer/Finnigan Delta Plus isotope ratio mass spectrometer, with precisions of <0.1‰ for δ13C and <0.2‰ for δ15N. These measurements were combined with previously obtained δ15N and δ13C measures done on maize at Keck for the three sites, as reported in Hart and Feranec (Reference Hart and Feranec2020) and listed in Hart and Winchell-Sweeney (Reference Hart and Winchell-Sweeney2023:Table S1). Charring discriminates against 15N elevating δ15N ratios in grains (Nitsch et al. Reference Nitsch, Charles and Bogaard2015; Styring et al. Reference Styring, Manning, Fraser, Wallace, Jones, Charles and Heaton2013). Charring experiments of maize kernels resulted in a mean offset of +0.54‰ (Hart and Feranec Reference Hart and Feranec2020), which was subtracted from maize macrobotanical δ15N values.

Also listed in Hart and Winchell-Sweeney (Reference Hart and Winchell-Sweeney2023:Table S2) are δ15N and δ13C ratios for 27 samples of white-tail deer (Odocoileus virginianus) bone collagen from the Caroga Creek and other Mohawk Valley sites, as previously reported in Manning and Hart (Reference Manning and Hart2019). White-tailed deer have broad diets that vary throughout the year and include woody and herbaceous plants, as well as fruits and nuts (Averill et al. Reference Averill, Mortensen, Smithwick, Kalisz, McShea, Bourg and Parker2018; Horsley et al. Reference Horsley, Stout and DeCalesta2003). Average δ15N ratios for plants consumed by white-tailed deer were obtained by subtracting a trophic enrichment factor of 3.8‰ from the deer collagen ratios (Hart and Feranec Reference Hart and Feranec2020). The resulting δ15N ratios provide a mean for the ratios of plants consumed outside agricultural fields (Hart and Feranec Reference Hart and Feranec2020), assuming a C3-pathway (non-maize) plant diet; elevated δ13C ratios provide a method for assessing whether a given deer had a diet with substantial C4-pathway plant component, most likely maize from agricultural fields.

IRMS measurements were obtained on six American plum (Prunus americana) and six chokecherry (P. virginiana) endocarps from Garoga and Smith-Pagerie, respectively, as a second means of determining the range of δ15N ratios of uncultivated plants (Hart and Winchell-Sweeney Reference Hart and Winchell-Sweeney2023). P. americana grows in a wide range of habitats from floodplains to upland forests in New York, whereas P. virginiana grows in hardwood forests and forest edges (Weldy et al. Reference Weldy, Werier and Nelson2023). It was expected that these samples would provide δ15N ratios in the range of the deer browse estimates.

Heating experiments were conducted on plum endocarps to determine whether charring results in increased δ15N ratios, as it does on maize and other grains. Endocarps were extracted from 10 fresh, commercially grown plums (P. domestica). These were broken into pieces, and the seed was removed. Following previously established protocols, one piece of each endocarp was loosely wrapped in aluminum foil and placed in a ceramic crucible, which was then filled with sand. The samples were placed in the center of a muffle furnace preheated to 260°C and heated for two hours. The temperature and length of time were chosen based on experience in other charring experiments that this would likely result in completely charred specimens (Hart Reference Hart2021; Hart and Feranec Reference Hart and Feranec2020), which did occur. A fraction of each fully charred and uncharred endocarp piece was submitted to the Keck facility for IRMS measurements. Unlike the archaeological specimens, these contemporary specimens, following laboratory protocols, were not subjected to ABA pretreatment.

Results

Soils

Naturally fertile soils are present near each of the three sites (Table 1). Acreages for Alfisols and Inceptisols were substantially larger than NCCPI 55%–75%, with the index taking slope into account. Were the acreages for agricultural fields sufficiently large enough for ancestral Mohawk farmers to produce enough maize to support the dietary needs of their villages?

Table 1. Required Acreage at Productivity Levels and NCCPI 55%–75% and Total of Alfisols and Inceptisols (Soils) Acreages in 2 km Catchments for the Caroga Creek Sites.

Snow (Reference Snow1995) estimated a population of 1,350 at Smith-Pagerie, 900 at Klock, and 820 at Garoga. Funk and Kuhn (Reference Funk and Kuhn2003), in contrast, estimated populations of 1,760–2,325, 790–845, and 1,400–3,010, respectively. Regardless of these discrepancies and the large ranges in the Funk and Kuhn estimates, each community required large amounts of agricultural produce for sustenance. We assumed a daily diet in which an average 65% came from maize, resulting in the need for 8.5 bu/person/year (Heidenreich Reference Heidenreich1971). Using Snow's (Reference Snow1995) population estimates, farmers needed to produce 11,475 bu of maize for annual consumption at Smith-Pagerie, 7,650 at Klock, and 6,970 at Garoga. These figures do not consider spoilage and the need to store surplus for poor production years. Following Birch and Williamson (Reference Birch and Williamson2012:100) we assumed the need to raise an additional 20% per annum, resulting in annual production needs of 13,770 bu for Smith-Pagerie, 9,180 for Klock, and 8,364 for Garoga. NCCPI soil categories are plotted in Figure 2 with 2 km catchments for the three sites. Table 1 indicates the number of acres needed to produce the required amount of maize at 25 and 50 bu/acre, suggested by Mt. Pleasant (Reference Mt. Pleasant2015) as the range of productivity for Indigenous agriculture in eastern North America. There was ample acreage of soils with the highest natural potential for maize production in the Caroga Creek valley within 2 km of each site and a substantial excess of Alfisols and Inceptisols.

Figure 2. NCCPI corn (maize) soil categories and 2 km site catchments.

Maize Isotopes

Although adequate acreages of naturally fertile soils were present, community farmers needed to maintain the productivity of these soils in their fields for two to three decades to support Doolittle's and Mt. Pleasant's interpretations of Indigenous agronomy. Summary statistics for δ15N and δ13C ratios are provided in Table 2, and the ratios for each specimen are given in Hart and Winchell-Sweeney (Reference Hart and Winchell-Sweeney2023:Tables S1 and S2). Of note, the highest value for white-tailed deer collagen (4.60‰) was from a specimen that had an elevated δ13C ratio (−14.9‰), which indicates that a large fraction of its diet came from C4 plants, presumably maize. As a result, this individual is excluded from the data in Table 2. Guiry and associates (Reference Guiry, Orchard, Royle, Cheung and Yang2020) noted that contemporaneous Passenger pigeon (Ectopistes migratorius) bone collagen from ancestral Huron-Wendat sites in southern Ontario with high δ15N ratios also had high δ13C ratios and attributed this to maize consumption.

Table 2. Summary Statistics for δ15N and δ13C Ratios on Caroga Creek Samples and Estimated Mohawk Valley Deer Browse.

Figure 3 is a scatterplot of δ13C and δ15N ratios obtained on maize from the three Caroga Creek sites with the δ15N ratio mean and one and two standard deviations for estimated deer browse. None of the maize ratios fall within two standard deviations of the estimated δ15N ratio mean for plants consumed by white-tailed deer in the Mohawk River basin (excluding the value from the specimen with a C4-plant diet). The mean maize ratio is significantly higher than the mean of the estimated deer browse ratio (unequal variance t-test t = 15.685, p = 0.0000). This indicates that the plant-available nitrogen in the agricultural fields was greater than that available for the plants in deer browse.

Figure 3. Scatterplot of δ13C and δ15N ratios for the Smith-Pagerie, Klock, and Garoga sites with mean and standard deviations of estimated δ13C and δ15N ratios for white-tailed deer browse.

Figure 4 is a boxplot of δ15N ratios from Klock and Garoga maize remains recovered from different contexts within features; summary data are presented in Table 3. The lowest values come from contexts that can be considered to represent the original functions of the pits and general fill strata. The δ15N ratios of the presumed end-of-site occupation are not statistically different than those for maize recovered from on or immediately above grass or tree bark pit linings, thus representing the original functions of the pits (Mann-Whitney U = 31.5, z = 0.99305, exact permutation p = 0.3193).

Figure 4. Boxplots of maize δ15N ratios recovered from differing feature contexts at the Klock and Garoga sites. Dots represent individual maize sample δ15N ratios: Garoga black, Klock gray.

Table 3. Feature Context Maize δ15N Ratios.

The IRMS measurements that we obtained add to a growing database of measurements on maize macrobotanical remains from Northern Iroquoia that includes 129 δ15N ratios, all but two of which were obtained on kernels (Hart and Winchell-Sweeney Reference Hart and Winchell-Sweeney2023:Table S3). Figure 5 is a boxplot of maize δ15N ratios from Caroga Creek and elsewhere in Northern Iroquoia. The mean of the ratios obtained on the Caroga Creek samples is not significantly different from the mean of the samples obtained on samples from other sites in Northern Iroquoia (t = 0.68508, p = 0.49545).

Figure 5. Boxplot of δ15N ratios from Smith-Pagerie, Klock, and Garoga sites and ratios obtained for maize from sites elsewhere in Northern Iroquoia. Dots represent individual maize sample δ15N ratios.

Exceptionally Elevated δ15N Ratios

δ15N ratios of one maize kernel (13.76‰) and four cherry endocarps (8.30‰–15.30‰) from Smith-Pagerie are substantially higher than the next highest ratio for maize (7.96‰) and estimated ratios for deer browse. Four plum endocarps from Garoga (6.00‰–9.40‰) have substantially higher δ15N ratios than the estimated range for deer browse. Soils in the region fall within a band with estimated bulk soil δ15N ratios of 3.5‰–4.8‰ (Amundson et al. Reference Amundson, Austin, Schuur, Yoo, Matzek, Kendall, Uebersax, Brenner and Troy Baisden2003). The inorganic components of soil nitrogen generally have lower δ15N ratios than bulk soil, and there is little fractionation during plant uptake of inorganic nitrogen: “In most non-boreal sites, plants mainly acquire NH4+ and NO3 from soil and this uptake occurs without any large isotopic fractionation” (Craine et al. Reference Craine, Brookshire, Cramer, Hasselquist, Koba, Marin-Spiotta and Wang2015:9). Therefore, these elevated values cannot be the result of unaltered soils.

Charring of plant tissues can result in increased δ15N ratios. To determine whether charring has the potential to substantially increase δ15N ratios in Prunus spp. endocarps, heating experiments were conducted for 10 contemporary domesticated plum (P. domestica) endocarps. These experiments produced no statistically significant difference in δ15N ratios between charred and uncharred fractions of 10 endocarps (Wilcoxon test, W = 32, z = 1.8226, exact p = 0.078125; Hart and Winchell-Sweeney Reference Hart and Winchell-Sweeney2023:Table S4)

The most likely source of nitrogen resulting in the exceptionally elevated δ15N ratios in the Caroga Creek samples is Passenger pigeon guano. Animal manure and bird guano deposits and applications as fertilizer increase δ15N ratios in plants; both seabird (Szpak Reference Szpak2014; Szpak et al. Reference Szpak, Longstaffe, Millaire and White2012) and passerine (Finity Reference Finity2011) guano can have exceptionally elevated δ15N ratios. Passenger pigeons migrated in massive flocks across eastern North America (Ellsworth and McComb Reference Ellsworth and McComb2003). The species’ bones have been identified in several ancestral Mohawk village faunal assemblages including Garoga (Kuhn and Funk Reference Kuhn and Funk2000:33; Ritchie and Funk Reference Ritchie and Funk1973:329), and its presence in the Mohawk Valley is attested by the eighteenth-century ethnohistoric record (Snow et al. Reference Snow, Gehring and Starna1996:256).

Passenger pigeon roosting sites, generally in hardwood forests, often included millions of individual birds that produced massive amounts of guano, killing the trees within the roosting area. Nesting sites, although not as densely occupied, also produced substantial amounts of guano (Ellsworth and McComb Reference Ellsworth and McComb2003:1552). Passenger pigeons were omnivorous, consuming worms and snails in addition to annual plant products. They were largely dependent on mast, primarily Beechnut (Fagus grandifolia), acorn (Quercus spp.), and Chestnut (Castanea dentata; Bucher Reference Bucher and Power1992:4), all of which are native to New York and occur in the Mohawk Valley (Weldy et al. Reference Weldy, Werier and Nelson2023). Guiry and colleagues (Reference Guiry, Orchard, Royle, Cheung and Yang2020:9) suggest that a correlation between high δ15N and δ13C ratios in the collagen of Passenger pigeon bone recovered from Iroquoian sites in southern Ontario resulted in part from the pigeons feeding on maize.

Fruit was an important Passenger pigeon food source in summer (Bucher Reference Bucher and Power1992:4). Feeding episodes on fruit trees and shrubs also resulted in guano deposits, although not as substantial as in roosting and nesting sites, given the relatively short duration of feeding. Because of fluctuations in mast production and previous damage to forests, migration patterns were inconsistent (Bucher Reference Bucher and Power1992). Given that P. virginiana and P. americana are shade-intolerant and are early successional species after disturbances such as forest fires (Francis Reference Francis and Francis2004; Welch Reference Welch and Francis2004), the exceptionally elevated δ15N endocarp ratios likely represent plants that grew in previous Passenger pigeon roosting or nesting areas. Bird guano can be an important source of nitrogen in early successional stages, with consequent elevated δ15N ratios in plants (Schrama et al. Reference Schrama, Jouta, Berg and Olff2013; also see Guiry et al Reference Guiry, Orchard, Royle, Cheung and Yang2020:11). The elevated maize kernel δ15N ratio likely represents encroachment of a maize field on a previous pigeon roosting or nesting area.

Summary

The δ15N measurements presented here expand the archaeological evidence for Iroquoian agronomy. Comparison of δ15N ratios of maize macrobotanical remains and estimates of deer browse indicate higher nitrogen levels within than outside agricultural fields. δ15N ratios on maize from different contexts within features suggest no decrease in nitrogen ratios over the course of site occupation. Exceptionally elevated δ15N ratios for one maize kernel and cherry and plum endocarps suggest plant growth within previous Passenger pigeon roosts or nesting areas. The maize δ15N ratios from the Caroga Creek sites are not significantly different from those obtained on maize from other sites in Northern Iroquoia.

Discussion and Conclusions

Archaeological models of precontact Indigenous agriculture in eastern North America have used plow-based European and Euro-American/Canadian agriculture as baselines for comparisons. These models focus on the lack of evidence for fertilization of agricultural soils by Indigenous farmers and posit that nitrogen was rapidly depleted after the establishment of new fields, resulting in substantially decreased maize productivity (Baden and Beekman Reference Baden and Beekman2001). This in turn resulted in the clearance of new fields or the expansion of existing fields to restore maize productivity to levels sufficient to support village communities. Doolittle (Reference Doolittle2000, Reference Doolittle2004) and Mt. Pleasant (Reference Mt. Pleasant2011, Reference Mt. Pleasant2015; Mt. Pleasant and Burt Reference Mt. Pleasant and Burt2010) suggested instead that Indigenous agricultural practices in eastern North America included permanent fields and the maintenance of soil fertility over multiple decades. Yet, archaeological evidence for Indigenous agronomic practices has been lacking to support their proposals. The current and previous (Hart and Feranec Reference Hart and Feranec2020) analyses of maize macrobotanical δ15N ratios provide the first evidence that is consistent with Doolittle's and Mt. Pleasant's propositions. Elevated δ15N ratios suggest that ancestral Mohawk farmers were able to maintain soil fertility in their agricultural fields, likely through agronomic practices adapted to naturally fertile Alfisols and Inceptisols, which were present in ample amounts for agricultural fields within 2 km of each site explored in this study.

Guiry and associates (Reference Guiry, Orchard, Royle, Cheung and Yang2020:9) suggested that elevated maize δ15N ratios from ancestral Huron-Wendat sites in southern Ontario were “due to δ15N shifts in soil nitrogen associated with differing symbiotic mycorrhizal fungi relationships and increased nitrogen cycle openness” in agricultural fields relative to forests. However, more of an explanation is needed for Iroquoian agronomic practices that evidently resulted in the maintenance of soil nitrogen. Hart and Feranec (Reference Hart and Feranec2020) suggested several possible agronomic practices that would result in nitrogen maintenance. Here we offer as a hypothesis that Iroquoian agronomy was equivalent to contemporary conservation agriculture.

Conservation agriculture comprises a series of agronomic practices that are used to maintain soil health and fertility, including nitrogen levels (e.g., Friedrich et al. Reference Friedrich, Derpsch and Kassam2012; Kassam et al. Reference Friedrich, Derpsch and Kassam2009, Reference Kassam, Friedrich and Derpsch2019). This system has three primary components: (1) no or minimal soil disturbance (no-till), (2) maintenance of organic mulch over a minimum of 30% of soil, and (3) crop rotation or balanced mixes of legumes and nonlegume crops (Kassam et al. Reference Kassam, Friedrich and Derpsch2019:2). Mulch can consist of crop residue and stubble, as well as cover crops, all of which contribute to SOM and, therefore, the maintenance of soil nitrogen. These systems produce many sustainable benefits for soil health, fertility, and water retention and filtration by increasing soil organic matter (for an analysis of how no-till farming with crop residue restores SOM in previously plowed fields, see Prairie et al. Reference Prairie, King and Francesca Cotrufo2023) and soil microbial biodiversity and activity, which can increase or maintain crop productivity over extended spans of time without external inputs when the system is properly adapted to local edaphic, hydrological, and societal contexts (Kassam et al. Reference Kassam, Friedrich, Shaxson and Pretty2009; Page et al. Reference Page, Dang and Dalal2020).

Page and associates (Reference Page, Dang and Dalal2020:8) summarize conservation agriculture's (CA) effects on nutrients: “Where CA successfully leads to greater residue addition and thus input of nutrient containing organic material into the soil, this can lead to higher plant nutrient stores, with greater nitrogen” and other nutrient concentrations as a response to increased SOM. They continue that such results are not absolute and various localized conditions can result in negative effects to nutrients. Kassam and associates (Reference Kassam, Friedrich, Shaxson and Pretty2009:304) list four primary benefits of conservation agriculture: “(a) physical: better characteristics of porosity for root growth, movement of water and root-respiration gases; (b) chemical: raised CEC [cation exchange capacity] gives better capture, release of inherent and applied nutrients: greater control/release of nutrients; (c) biological: more organisms, organic matter and its transformation products; (d) hydrological: more water available.”

Contemporary conservation agriculture is similar to the ethnohistorically documented Iroquoian agronomic practices, which involved the intercropping of maize, common bean, and squash, and sometimes sunflower (Helianthus annuus). Iroquoian farmers initially created small mounds of soil (“corn hills”) in which they planted maize, common bean, and squash seeds. Once the mounds were established, seeds were planted in them annually, with the large maize, common bean, and squash seeds planted with minimal disturbance using digging sticks. Maize stalks provided climbing poles for bean vines, and squash vines with large leaves acted as mulch. As described by Mt. Pleasant (Reference Mt. Pleasant2011, Reference Mt. Pleasant2015) these agronomic systems obviated the need for fertilization, as is required in plow-based agronomy, by maintaining SOM and soil microbes that converted organic nitrogen into inorganic nitrogen available to plants.

Iroquoian maize harvesting generally involved stripping ears from the stalks and leaving the stalks in place until the next year (Waugh Reference Waugh1916:39), although they were sometimes removed with the ears (Parker Reference Parker1910:31). As described by Waugh (Reference Waugh1916:20), the only “cultivation given formerly was to chop down the weeds, or to clear away the last year's cornstalks.” The Iroquoian agronomy, then, was the equivalent of contemporary conservation agriculture in that it involved minimal disturbance to agricultural soils, maintenance of mulch (squash vines during the growing season, maize stalks during the winter, and potentially the use of other crop residues) that contributed to SOM, and intercropping of maize with a legume (common bean). The isotopic evidence suggests that these systems maintained soil fertility in precontact Iroquoian agricultural fields.

In effect, precontact Iroquoian agronomy is an example of sustainable eastern North American Indigenous agriculture. Given the consistent high maize kernel δ15N ratios, Iroquoian agronomic practices successfully implemented the equivalent of contemporary conservation agriculture practices: nitrogen depletion was apparently not a problem for Iroquoian farmers. This is a hypothesis that will be best tested through actualistic experiments using traditional maize varieties and monitoring soil chemistry over the course of several years with and without soil amendments other than the continuous addition of organic matter from the previous year's crops.

Acknowledgments

We thank Robert Feranec for laboratory and equipment access and supplies. We thank Jennifer Birch for permission to include isotope data from unpublished AMS dates on maize.

Funding Statement

The New York State Museum funded the new IRMS measurements from the three Caroga Creek sites.

Data Availability Statement

All data used in the analyses are available in Hart and Winchell-Sweeney (Reference Hart and Winchell-Sweeney2023) on Zenodo: https://doi.org/10.5281/zenodo.7946328.

Competing Interests

The authors declare none.

Footnotes

1. Archaeologists often refer to Indigenous agronomic practices as horticulture because they did not include plows and draft animals. However, the term “horticulture” is generally equated with gardening in the general English lexicon (e.g., Jewell and Abate Reference Jewell and Abate2001:822) and anthropological literature (e.g., Morris Reference Morris2012:122) and thus does not accurately reflect Iroquoian cultivation practices. We prefer a behavioral definition following Rindos (Reference Rindos1984:256): “an integrated set of . . . behaviors that affect the environment inhabited by domesticated plants throughout the whole life cycle of those plants.”

2. Although Morgan (Reference Morgan1851:319) described a Haudenosaunee practice of caching “charred green corn” in storage pits, most likely he was referring to parched green maize kernels (see Parker Reference Parker1910:35). The recovery of massive deposits of charred maize at the bottom of storage pits on Iroquoian sites suggests burning in place during the pit's primary use, especially when charred grass and/or bark linings were also present. Small numbers of kernels found on or immediately above a charred organic lining also suggest burning in place at the end of the pit's use life before filling the pit with debris and soil. Parker (Reference Parker1910:35) claimed that “after the corn had been removed the pit was filled with rubbish and the entire matter burned or charred.” It is likely that some maize kernels on the lining would be overlooked before burning.

References

References Cited

Albert, Rebecca K., Kooiman, Susan M., Clark, Caitlin A., and Lovis, William A.. 2018. Earliest Microbotanical Evidence for Maize in the Northern Lake Michigan Basin. American Antiquity 83:345355.CrossRefGoogle Scholar
Amundson, Ronald, Austin, Amy T., Schuur, Edward A. G., Yoo, Kyungsoo, Matzek, Virginia, Kendall, Carol, Uebersax, Anneliese, Brenner, D., and Troy Baisden, W.. 2003. Global Patterns of the Isotopic Composition of Soil and Plant Nitrogen. Global Biogeochemical Cycles 17(1):1031.CrossRefGoogle Scholar
Averill, Kristine M., Mortensen, David A., Smithwick, Erica A. H., Kalisz, Susan, McShea, William J., Bourg, Norman A., Parker, John D., et al. 2018. A Regional Assessment of White-Tailed Deer Effects on Plant Invasion. AoB PLANTS 10(1):plx047.CrossRefGoogle Scholar
Baden, William W., and Beekman, Christopher S.. 2001. Culture and Agriculture: A Comment on Sissel Schroeder, Maize Productivity in the Eastern Woodlands and Great Plains of North America. American Antiquity 66:505515.CrossRefGoogle Scholar
Bamann, Susan, Kuhn, Robert, Molnar, James, and Snow, Dean. 1992. Iroquoian Archaeology. Annual Review of Anthropology 21:435460.CrossRefGoogle Scholar
Birch, Jennifer. 2012. Coalescent Communities: Settlement Aggregation and Social Integration in Iroquoian Ontario. American Antiquity 77:646670.CrossRefGoogle Scholar
Birch, Jennifer. 2015. Current Research on the Historical Development of Northern Iroquoian Societies. Journal of Archaeological Research 23:263323.CrossRefGoogle Scholar
Birch, Jennifer, and Williamson, Ronald F.. 2012. The Mantle Site: An Archaeological History of an Ancestral Wendat Community. AltaMira Press, Lanham, Maryland.Google Scholar
Bogaard, Amy, Fraser, Rebecca, Heaton, Tim H. E., Wallace, Michael, Vaiglova, Petra, Charles, Michael, Jones, Glynis, et al. 2013. Crop Manuring and Intensive Land Management by Europe's First Farmers. PNAS 110:1258912594.CrossRefGoogle Scholar
Bogaard, Amy, Heaton, Tim H. E., Poulton, Paul, and Merbach, Ines. 2007. The Impact of Manuring on Nitrogen Isotope Ratios in Cereals: Archaeological Implications for Reconstruction of Diet and Crop Management Practices. Journal of Archaeological Science 34:335343.CrossRefGoogle Scholar
Bucher, Enrique H. 1992. The Causes of Extinction of the Passenger Pigeon. In Current Ornithology, Vol. 9, edited Power, by Denis M., pp. 136. Plenum, New York.Google Scholar
Christensen, Bent T., Jensen, Johannes L., Dong, Yu, and Bogaard, Amy. 2022. Manure for Millet: Grain δ15N Values as Indicators of Prehistoric Cropping Intensity of Panicum miliaceum and Setaria italica. Journal of Archaeological Science 139:105554.CrossRefGoogle Scholar
Coban, Oksana, De Deyn, Gerlinde B., and van der Ploeg, Martine. 2022. Soil Microbiota as Game-Changers in Restoration of Degraded Lands. Science 375:abe0725.CrossRefGoogle Scholar
Craine, Joseph M., Brookshire, E. N. J., Cramer, Michael D., Hasselquist, Niles J., Koba, Keisuke, Marin-Spiotta, Erika, and Wang, Lixin. 2015. Ecological Interpretations of Nitrogen Isotope Ratios of Terrestrial Plants and Soils. Plant and Soil 396:126.CrossRefGoogle Scholar
Craine, Joseph M., Elmore, Andrew J., Aidar, Marcos P. M., Bustamante, Mercedes, Dawson, Todd E., Hobbie, Erik A., Kahmen, Ansgar, et al. 2009. Global Patterns of Foliar Nitrogen Isotopes and Their Relationships with Climate, Mycorrhizal Fungi, Foliar Nutrient Concentrations, and Nitrogen Availability. New Phytologist 183:980992.CrossRefGoogle Scholar
Creese, John L. 2016. Emotion Work and the Archaeology of Consensus: The Northern Iroquoian Case. World Archaeology 48(1):1434.CrossRefGoogle Scholar
DeBoer, Warren R. 1988. Subterranean Storage and the Organization of Surplus: The View from Eastern North America. Southeastern Archaeology 7:120.Google Scholar
Doolittle, William E. 1992. Agriculture in North America on the Eve of Contact: A Reassessment. Annals of the Association of American Geographers 82:386401.CrossRefGoogle Scholar
Doolittle, William E. 2000. Cultivated Landscapes of Native North America. Oxford University Press, Oxford.CrossRefGoogle Scholar
Doolittle, William E. 2004. Permanent vs. Shifting Cultivation in the Eastern Woodlands of North America prior to European Contact. Agriculture and Human Values 21:181189.CrossRefGoogle Scholar
Ellsworth, Joshua W., and McComb, Brenda C.. 2003. Potential Effects of Passenger Pigeon Flocks on the Structure and Composition of Presettlement Forests of Eastern North America. Conservation Biology 17:15481558.CrossRefGoogle Scholar
Erenstein, Olaf, Chamberlin, Jordan, and Sonder, Kai. 2021. Estimating the Global Number and Distribution of Maize and Wheat Farms. Global Food Security 30:100558.CrossRefGoogle Scholar
Estrada, Pauline, Mavingui, Patrick, Cournoyer, Benoit, Fontaine, Fanette, Balandreau, Jacques, and Caballero-Mellado, Jesus. 2002. N-2-Fixing Endophytic Burkholderia sp. associated with Maize Plants Cultivated in Mexico. Canadian Journal of Microbiology 48:285294.CrossRefGoogle Scholar
Feranec, Robert S., and Hart, John P.. 2019. Fish and Maize: Bayesian Mixing Models of Fourteenth- through Seventeenth-Century AD Ancestral Wendat Diets, Ontario, Canada. Scientific Reports 9:16658.CrossRefGoogle Scholar
Finity, Leah. 2011. The Role of Habitat and Dietary Factors in Chimney Swift (Chaetura pelagica) Population Declines. Master's thesis, Environmental and Life Sciences Program, Trent University, Peterborough, Ontario.Google Scholar
Francis, John K. 2004. Prunus americana Marsh. In Wildland Shrubs of the United States and Its Territories: Thamnic Descriptions: Vol. 1, edited by Francis, John K., pp. 586588. US Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fort Collins, Colorado.CrossRefGoogle Scholar
Fraser, Rebecca A., Bogaard, Amy, Heaton, Tim, Charles, Michael, Jones, Glynis, Christensen, Bent T., Halstead, Paul, et al. 2011. Manuring and Stable Nitrogen Isotope Ratios in Cereals and Pulses: Towards a New Archaeobotanical Approach to the Inference of Land Use and Dietary Practices. Journal of Archaeological Science 38:27902804.CrossRefGoogle Scholar
Friedrich, Theodor, Derpsch, Rolf, and Kassam, Amir. 2012. Overview of the Global Spread of Conservation Agriculture. Field Actions Science Reports (special issue) 6:18.Google Scholar
Funk, Robert E., and Kuhn, Robert D.. 2003. Three Sixteenth-Century Mohawk Iroquois Village Sites. New York State Museum Bulletin 503. University of the State of New York, Albany.Google Scholar
Gates St-Pierre, Christian, and Thompson, Robert G., 2015. Phytolith Evidence for the Early Presence of Maize in Southern Quebec. American Antiquity 80:408415.CrossRefGoogle Scholar
Gosling, P., Hodge, A., Goodlass, G., and Bending, G. D.. 2006. Arbuscular Mycorrhizal Fungi and Organic Farming. Agriculture, Ecosystems & Environment 113:1735.CrossRefGoogle Scholar
Guiry, Eric J., Orchard, Trevor J., Royle, Thomas C. A., Cheung, Christina, and Yang, Dongya Y.. 2020. Dietary Plasticity and the Extinction of the Passenger Pigeon (Ectopistes migratorius). Quaternary Science Reviews 233:106225.CrossRefGoogle Scholar
Habbib, Hazzar, Verzeaux, Julien, Nivelle, Elodie, Roger, David, Lacoux, Jérôme, Catterou, Manuella, Hirel, Bertrand, Dubois, Frédéric, and Tétu, Thierry. 2016. Conversion to No-Till Improves Maize Nitrogen Use Efficiency in a Continuous Cover Cropping System. PLoS ONE 11(10):e0164234.CrossRefGoogle Scholar
Hammer, Øyvind, Harper, David A. T., and Ryan, Paul D.. 2001. PAST: Paleontological Statistics Software Package for Education and Data Analysis. Palaeontologia Electronica 4:9.Google Scholar
Hart, John P. 2020. Reassessing an Inferred Iroquoian Village Removal Sequence in the Mohawk River Basin, New York, USA. Journal of Anthropological Archaeology 60:101236.CrossRefGoogle Scholar
Hart, John P. 2021. The Effects of Charring on Common Bean (Phaseolus vulgaris L) Seed Morphology and Strength. Journal of Archaeological Science: Reports 37:102996Google Scholar
Hart, John P., Brumbach, Hetty Jo, and Lusteck, Robert. 2007. Extending the Phytolith Evidence for Early Maize (Zea mays ssp. mays) and Squash (Cucurbita sp.) in Central New York. American Antiquity 72:563583.CrossRefGoogle Scholar
Hart, John P., and Feranec, Robert S.. 2020. Using Maize δ 15N Values to Assess Soil Fertility in Fifteenth- and Sixteenth-Century AD Iroquoian Agricultural Fields. PLoS ONE 15(4):e0230952.CrossRefGoogle Scholar
Hart, John P., and Winchell-Sweeney, Susan. 2023. Supplemental Data File for Resetting Archaeological Interpretations of Precontact Indigenous Agriculture: Maize Isotopic Evidence from Three Ancestral Mohawk Iroquoian Villages, Tables S1–S4. https://doi.org/10.5281/zenodo.7946328.CrossRefGoogle Scholar
Heidenreich, Conrad E. 1971. Huronia: A History and Geography of the Huron Indians, 1600–1650. McClelland & Stewart, Toronto.Google Scholar
Horsley, Stephen B., Stout, Susan L., and DeCalesta, David S.. 2003. White-Tailed Deer Impact on the Vegetation Dynamics of a Northern Hardwood Forest. Ecological Applications 13:98118.CrossRefGoogle Scholar
Hurt, R. Douglas. 1987. Indian Agriculture in America: Prehistory to the Present. University Press of Kansas, Topeka.Google Scholar
Jewell, Elizabeth J., and Abate, Frank (editors). 2001. The New Oxford American Dictionary. Oxford University Press, New York.Google Scholar
Jones, Eric E. 2010. Sixteenth- and Seventeenth-Century Haudenosaunee (Iroquois) Population Trends in Northeastern North America. Journal of Field Archaeology 35:518.CrossRefGoogle Scholar
Jones, Eric E. 2016. Refining Our Understanding of Sixteenth- and Seventeenth-Century Haudenosaunee Settlement Location Choices. In Process and Meaning in Spatial Archaeology, edited by Jones, Eric E. and Creese, John L., pp. 145170. University Press of Colorado, Boulder.Google Scholar
Jones, Eric E., and Wood, James W.. 2012. Using Event-History Analysis to Examine the Causes of Semi-Sedentism among Shifting Cultivators: A Case Study of the Haudenosaunee, AD 1500–1700. Journal of Archaeological Science 39:25932603.CrossRefGoogle Scholar
Kahmen, Ansgar, Wanek, Wolfgang, and Buchmann, Nina. 2008. Foliar δ15N Values Characterize Soil N Cycling and Reflect Nitrate or Ammonium Preference of Plants along a Temperate Grassland Gradient. Oecologia 156:861870.CrossRefGoogle Scholar
Kassam, Amir, Friedrich, Theodor, and Derpsch, Rolf. 2019. Global Spread of Conservation Agriculture. International Journal of Environmental Studies 76:2951.CrossRefGoogle Scholar
Kassam, Amir, Friedrich, Theodor, Shaxson, Francis, and Pretty, Jules. 2009. The Spread of Conservation Agriculture: Justification, Sustainability and Uptake. International Journal of Agricultural Sustainability 7:292320.CrossRefGoogle Scholar
Kraiser, Tatiana, Gras, Diana E., Gutiérrez, Alvaro G., González, Bernardo, and Gutiérrez, Rodrigo A.. 2011. A Holistic View of Nitrogen Acquisition in Plants. Journal of Experimental Botany 62:14551466.CrossRefGoogle Scholar
Kuhn, Robert D., and Funk, Robert E.. 2000. Boning up on the Mohawk: An Overview of Mohawk Faunal Assemblages and Subsistence Patterns. Archaeology of Eastern North 28:2962.Google Scholar
Manning, Sturt W., and Hart, John P.. 2019. Radiocarbon, Bayesian Chronological Modeling and Early European Metal Circulation in the Sixteenth-Century AD Mohawk River Valley, USA. PLoS ONE 14(12):e0226334.CrossRefGoogle Scholar
Manning, Sturt W., Lorentzen, Britta, and Hart, John P.. 2021. Resolving Indigenous Village Occupations and Social History across the Long Century of European Permanent Settlement in Northeastern North America: The Mohawk River Valley ~ 1450–1635 CE. PLoS ONE 16(10):e0258555.CrossRefGoogle Scholar
Matsuoka, Yoshihiro, Vigouroux, Yves, Goodman, Major M., Sanchez G., Jesus, Buckler, Edward, and Doebley, John. 2002. A Single Domestication for Maize Shown by Multilocus Microsatellite Genotyping. PNAS 99:60806084.CrossRefGoogle Scholar
Morgan, Lewis Henry. 1851. League of the HO-DÉ-NO-SAU-NEE, or Iroquois. Sage & Brother, Rochester, New York.Google Scholar
Morris, Michael A. 2012. Concise Dictionary of Social and Cultural Anthropology. John Wiley & Sons, Hoboken, New Jersey.Google Scholar
Mt. Pleasant, Jane M. 2011. The Paradox of Plows and Productivity: An Agronomic Comparison of Cereal Grain Production under Iroquois Hoe Culture and European Plow Culture in the Seventeenth and Eighteenth Centuries. Agricultural History 85:460492.CrossRefGoogle Scholar
Mt. Pleasant, Jane M. 2015. A New Paradigm for Pre-Columbian Agriculture in North America. Early American Studies 13:3745412.CrossRefGoogle Scholar
Mt. Pleasant, Jane M., and Burt, Robert F.. 2010. Estimating Productivity of Traditional Iroquoian Cropping Systems from Field Experiments and Historical Literature. Journal of Ethnobiology 30:5279.CrossRefGoogle Scholar
Natural Resources Conservation Service 2022. User Guide National Commodity Crop Productivity Index (NCCPI). US Department of Agriculture, Washington, DC.Google Scholar
Nitsch, E. K, Charles, Mike, and Bogaard, Amy. 2015. Calculating a Statistically Robust δ13C and δ15N Offset for Charred Cereal and Pulse Seeds. STAR: Science and Technology of Archaeological Research 1:18.CrossRefGoogle Scholar
Osterholz, William R., Rinot, Oshri, Liebman, Matt, and Castellano, Michael J.. 2017. Can Mineralization of Soil Organic Nitrogen Meet Maize Nitrogen Demand? Plant Soil 415:7384.CrossRefGoogle Scholar
Page, Kathryn Louise, Dang, Yash P., and Dalal, Ram C.. 2020. The Ability of Conservation Agriculture to Conserve Soil Organic Carbon and the Subsequent Impact on Soil Physical, Chemical, and Biological Properties and Yield. Frontiers in Sustainable Food Systems 4:31.CrossRefGoogle Scholar
Pardo, Linda H., and Nadelhoffer, Knute J.. 2010. Using Nitrogen Isotope Ratios to Assess Terrestrial Ecosystems at Regional and Global Scales. In Isoscapes: Understanding Movement, Pattern, and Process on Earth through Isotope Mapping, edited by West, Jason B., Bowen, Gabriel J., Dawson, Todd E., and Tu, Kevin P., pp. 221249. Springer, Dordrecht, Netherlands.CrossRefGoogle Scholar
Parker, Arthur C. 1910. Iroquois Uses of Maize and Other Food Plants. New York State Museum Bulletin 144. University of the State of New York, Albany.CrossRefGoogle Scholar
Pfeiffer, Susan, Sealy, Judith C., Williamson, Ronald F., Needs-Howarth, Suzanne, and Lesage, Louis. 2016. Maize, Fish, and Deer: Investigating Dietary Staples among Ancestral Huron-Wendat Villages, as Documented from Tooth Samples. American Antiquity 81:515532.CrossRefGoogle Scholar
Prairie, Aaron M., King, Alison E., and Francesca Cotrufo, M.. 2023. Restoring Particulate and Mineral-Associated Organic Carbon through Regenerative Agriculture. PNAS 120(21):e2217481120.CrossRefGoogle Scholar
Rindos, David. 1984. The Origins of Agriculture: An Evolutionary Perspective. Academic Press, New York.Google Scholar
Ritchie, William A., and Funk, Robert E.. 1973. Aboriginal Settlement Patterns in the Northeast. New York State Museum Memoir 20. University of the State of New York, Albany.Google Scholar
Schrama, Maarten, Jouta, Jeltje, Berg, Matty P., and Olff, Han. 2013. Food Web Assembly at the Landscape Scale: Using Stable Isotopes to Reveal Changes in Trophic Structure during Succession. Ecosystems 16:627638.CrossRefGoogle Scholar
Schroeder, Sissel. 1999. Maize Productivity in the Eastern Woodlands and Great Plains of North America. American Antiquity 64:499516.CrossRefGoogle Scholar
Snow, Dean R. 1995. Microchronology and Demographic Evidence Relating to the Size of Pre-Columbian North American Indian Populations. Science 268:16011604.CrossRefGoogle Scholar
Snow, Dean R. 1996. The Iroquois, Vol. 9. John Wiley & Sons, Hoboken, New Jersey.Google Scholar
Snow, Dean R. 2012. Iroquoian Households. In Ancient Households of the Americas, edited by Douglass, John G. and Gonlin, Nancy, pp. 117139. University Press of Colorado, Boulder.Google Scholar
Snow, Dean R., Gehring, Charles T., and Starna, William A. (editors). 1996. In Mohawk Country: Early Narratives about a Native People. Syracuse University Press, Syracuse, New York.Google Scholar
Styring, Amy K., Manning, Harriet, Fraser, Rebecca A., Wallace, Michael, Jones, G., Charles, Mike, Heaton, T. H., et al. 2013. The Effect of Charring and Burial on the Biochemical Composition of Cereal Grains: Investigating the Integrity of Archaeological Plant Material. Journal of Archaeological Science 40:47674779.CrossRefGoogle Scholar
Sykes, Clark M. 1980. Swidden Horticulture and Iroquoian Settlement. Archaeology of Eastern North America 8:4552.Google Scholar
Szpak, Paul. 2014. Complexities of Nitrogen Isotope Biogeochemistry in Plant-Soil Systems: Implications for the Study of Ancient Agricultural and Animal Management Practices. Frontiers in Plant Science 5:288.CrossRefGoogle Scholar
Szpak, Paul, Longstaffe, Fred J., Millaire, Jean-François, and White, Christine D.. 2012. Stable Isotope Biogeochemistry of Seabird Guano Fertilization: Results from Growth Chamber Studies with Maize (Zea mays). PLoS ONE 7(3):e33741.CrossRefGoogle Scholar
Tao, Dawei, Zhang, Ruijin, Xu, Junjie, Wu, Qian, Wei, Qingli, Gu, Wanfa, and Zhang, Guowen. 2022. Agricultural Extensification or Intensification: Nitrogen Isotopic Investigation into Late Yangshao Agricultural Strategies in the Middle Yellow River area. Journal of Archaeological Science: Reports 44:103534.Google Scholar
Van Deynze, Allen, Zamora, Pablo, Delaux, Pierre-Marc, Heitmann, Cristobal, Jayaraman, Dhileepkumar, Rajasekar, Shanmugam, Graham, Danielle, et al. 2018. Nitrogen Fixation in a Landrace of Maize Is Supported by a Mucilage-Associated Diazotrophic Microbiota. PLoS Biology 16(8):e2006352.CrossRefGoogle Scholar
Wang, B., and Y. L., Qiu 2006 Phylogenetic Distribution and Evolution of Mycorrhizas in Land Plants. Mycorrhiza 16:299363.CrossRefGoogle Scholar
Waugh, F. W. 1916. Iroquis [sic] Foods and Food Preparation. Canada Department of Mines Geological Survey Memoir 86, No. 12. Anthropological Series. Government Printing Bureau, Ottawa, Ontario.CrossRefGoogle Scholar
Welch, Bruce L. 2004. Prunus virginiana L. In Wildland Shrubs of the United States and Its Territories: Vol. 1, Thamnic Descriptions, edited by Francis, John K., pp. 594596. US Department of Agriculture, Forest Service. Rocky Mountain Research Station, Fort Collins, Colorado.Google Scholar
Weldy, Troy, Werier, David, and Nelson, Andrew. 2023. New York Flora Atlas. Electronic document, http://newyork.plantatlas.usf.edu/, accessed January 28, 2023.Google Scholar
Williams, Alwyn, Hunter, Mitchell C., Kammerer, Melanie, Kane, Daniel A., Jordan, Nicholas R., Mortensen, David A., Smith, Richard G., et al. 2016. Soil Water Holding Capacity Mitigates Downside Risk and Volatility in US Rainfed Maize: Time to Invest in Soil Organic Matter? PLoS ONE 11(8):e0160974.CrossRefGoogle Scholar
Figure 0

Figure 1. Locations of the Smith-Pagerie, Klock, and Garoga sites.

Figure 1

Table 1. Required Acreage at Productivity Levels and NCCPI 55%–75% and Total of Alfisols and Inceptisols (Soils) Acreages in 2 km Catchments for the Caroga Creek Sites.

Figure 2

Figure 2. NCCPI corn (maize) soil categories and 2 km site catchments.

Figure 3

Table 2. Summary Statistics for δ15N and δ13C Ratios on Caroga Creek Samples and Estimated Mohawk Valley Deer Browse.

Figure 4

Figure 3. Scatterplot of δ13C and δ15N ratios for the Smith-Pagerie, Klock, and Garoga sites with mean and standard deviations of estimated δ13C and δ15N ratios for white-tailed deer browse.

Figure 5

Figure 4. Boxplots of maize δ15N ratios recovered from differing feature contexts at the Klock and Garoga sites. Dots represent individual maize sample δ15N ratios: Garoga black, Klock gray.

Figure 6

Table 3. Feature Context Maize δ15N Ratios.

Figure 7

Figure 5. Boxplot of δ15N ratios from Smith-Pagerie, Klock, and Garoga sites and ratios obtained for maize from sites elsewhere in Northern Iroquoia. Dots represent individual maize sample δ15N ratios.