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Tasks, Knowledge, and Practice: Long-Distance Resource Acquisition at Goat Spring Pueblo (LA285), Central New Mexico

Published online by Cambridge University Press:  22 August 2024

Suzanne L. Eckert*
Affiliation:
Arizona State Museum, University of Arizona, Tucson, AZ, USA
Deborah L. Huntley
Affiliation:
Tetra Tech Inc., Golden, CO, USA
Judith A. Habicht-Mauche
Affiliation:
Department of Anthropology, University of California, Santa Cruz, CA, USA
Jeffrey R. Ferguson
Affiliation:
Department of Anthropology and the Archaeometry Laboratory at MURR, University of Missouri, Columbia, MO, USA
*
Corresponding author: Suzanne L. Eckert; Email: sleckert@arizona.edu
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Abstract

We examine provenance data collected from three types of geological resources recovered at Goat Spring Pueblo in central New Mexico. Our goal is to move beyond simply documenting patterns in compositional data; rather, we develop a narrative that explores how people's knowledge and preferences resulted in culturally and materially determined choices as revealed in those patterns. Our analyses provide evidence that residents of Goat Spring Pueblo did not rely primarily on local geological sources for the creation of their glaze paints or obsidian tools. They did, however, utilize a locally available blue-green mineral for creation of their ornaments. We argue that village artisans structured their use of raw materials at least in part according to multiple craft-specific and community-centered ethnomineralogies that likely constituted the sources of these materials as historically or cosmologically meaningful places through their persistent use. Consequently, the surviving material culture at Goat Spring Pueblo reflects day-to-day beliefs, practices, and social relationships that connected this village to a broader mosaic of interconnected Ancestral Pueblo taskscapes and knowledgescapes.

Resumen

Resumen

Examinamos datos de procedencia recopilados de tres tipos de recursos geológicos recuperados en Goat Spring Pueblo en el centro de Nuevo México. Además de documentar patrones en datos de composición nuestro objetivo es desarrollar una narrativa que explora cómo el conocimiento y las preferencias de las personas resultaron en elecciones determinadas por factores culturales y materiales. Nuestros análisis proporcionan evidencia de que los residentes de Goat Spring Pueblo no dependieron principalmente de fuentes geológicas locales para la creación de sus pinturas vidriadas o herramientas de obsidiana. Sin embargo, utilizaron un mineral azul verdoso disponible localmente para la creación de sus adornos. Proponemos que los artesanos de las aldeas estructuraron su uso de materias primas, al menos en parte, de acuerdo con múltiples etnomineralogías artesanales específicas y centradas en la comunidad que probablemente constituyeron las fuentes de estos materiales como lugares históricamente o cosmológicamente significativos a través de su uso persistente. Por lo tanto, los artefactos recuperados en Goat Spring Pueblo refleja creencias, prácticas y relaciones sociales cotidianas que conectaron esta aldea con un mosaico más amplio de paisajes de tareas y conocimientos interconectados de los Pueblos Ancestrales.

Type
Article
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Society for American Archaeology

Given the wide range of chemical compositional techniques available to archaeologists, our field has become increasingly successful at determining the geological provenance of materials from which objects were made. We have been less successful at adequately linking the movement of those raw geological materials and objects made from them with specific practices and how those practices materialize Indigenous knowledge systems as inscribed in the landscape and embodied in social memory. In this article, we take up the challenge of one of our coauthors (Huntley Reference Huntley, Herhahn and Ramenofsky2016) to move beyond simply documenting geospatial patterning in compositional data and toward developing a narrative that explores how people's choices and preferences resulted in those patterns. In particular, we examine how those choices were informed by (1) the complex interplay of local artisans’ understanding of the physical characteristics of raw materials from known sources, (2) the way resource collection was embedded in how community members routinely moved across the landscape as they engaged in various daily tasks or interacted with others through exchange, and (3) how the source location of specific resources may have come to be associated with places of cultural, historical, and cosmological significance.

This article summarizes our interpretations of provenance data collected from obsidian, blue-green minerals, and lead used to make glaze paint, all of which were recovered at Goat Spring Pueblo in central New Mexico (Figure 1). This Ancestral Pueblo village is an ideal case study for examining provenance data from a perspective that reimagines artifacts as consolidated taskscapes (Ingold Reference Ingold2000; Michelaki et al. Reference Michelaki, Braun and Hancock2015) that materialize and embody local ethnomineralogies (Arnold Reference Arnold1971, Reference Arnold2018). In other words, this approach allows us to ask how local systems of knowledge, history, and belief may have structured the persistent selection and use of natural resources from specific places as well as how habitual patterns of movement across and engagement with local and regional landscapes may have embedded these choices within social memory. Furthermore, we argue that because the inhabitants of Goat Spring Pueblo probably interacted regularly with peoples from other regions of the Ancestral Pueblo world, the practices of artisans within the village were defined by knowledge and beliefs that, in some cases, transcended the local and connected specific craft traditions to pan-Puebloan knowledgescapes (Herhahn and Huntley Reference Herhahn, Huntley and Spielmann2017), which were generationally sustained and widely shared over broad areas of the Southwest.

Figure 1. Map of the Ancestral Pueblo world.

The village now known as Goat Spring Pueblo was built overlooking the southern Rio Grande Valley in the mountains near the modern-day town of Magdalena and dates to the period of glaze-painted pottery production (AD 1275–1680). The village is situated near at least three geological resources (lead, obsidian, and the blue-green mineral smithsonite) that were important to Ancestral Pueblo artisans. For this reason, the site was initially of interest to us given its potential for examining how village residents may have transformed local resources from raw materials to finished products. Contrary to these initial expectations, the analyses presented here suggest that although residents of the village did make use of the local blue-green smithsonite to produce ornaments, they did not rely primarily on local geological sources for the creation of their glaze paints or obsidian tools. These unexpected patterns led us to take on Huntley's challenge to examine our data through a more inclusive assessment of the notion of movement that takes into account recent ethnoarchaeological observations that emphasize how artisans’ resource choices are often imbedded in local Indigenous knowledge systems that merge practical material constraints with notions of the historical and cosmological importance of place (Bradley Reference Bradley2000; Eckert et al. Reference Eckert, Schleher and Snow2018). Consequently, we reassess the significance of provenance data from Goat Spring Pueblo using a mix of Indigenous knowledge and material agency perspectives, in conjunction with landscape approaches that examine how people move through and utilize their physical surroundings in ways that create historically persistent and culturally meaningful places.

Ethnomineralogies, Taskscapes, and Knowledgescapes

Huntley (Reference Huntley, Herhahn and Ramenofsky2016) recently reflected that geological provenance data are the result of multiple types of movement, including of people, objects, and ideas. She argues that the real challenge for archaeologists is developing explanations that consider the multiple underlying causes behind these various types of movement (Huntley Reference Huntley, Herhahn and Ramenofsky2016:210). Part of developing such explanations is to recognize that ancestral peoples did not perceive the economic geology of their landscapes in the same way that modern archaeologists do (Arnold Reference Arnold2018). Decades of ethnoarchaeological studies (Andrefsky Reference Andrefsky1994; Arnold Reference Arnold2018; Rye Reference Rye1976) have shown that Indigenous artisans’ choices of raw materials are based on practical knowledge of those resources and their appropriateness to the task at hand. Arnold (Reference Arnold2018:218) refers to these forms of knowledge and practice as “ethnomineralogies,” which include “a practical set of categories, guidelines, problem-solving skills, and strategies” by which artisans “use visual and tactile feedback from the raw materials to make their choices” and deal with the physical consequences of those choices. That said, archaeologists often identify accessible resources with the appropriate affordances that local communities of artisans chose not to use (e.g., Michelaki et al. Reference Michelaki, Braun and Hancock2015), suggesting that artisans’ resource choices were based on more than just material considerations.

When considering why artisans chose to use one raw material source and not another, we also need to consider how resource acquisition may have been associated with other activities and the way that people moved around the landscape as they engaged in a variety of daily tasks (Huntley et al. Reference Huntley, Fenn, Habicht-Mauche, Mills, Cordell and Habicht-Mauche2012; Michelaki et al. Reference Michelaki, Braun and Hancock2015). Ingold (Reference Ingold2000) refers to this array of related tasks, as they play out routinely across both space and time, as “taskscapes” (similar to Binford's concept of imbedded procurement; see Binford Reference Binford1979). Various, although sometimes intersecting, taskscapes may have been associated with diverse groups within a community. Women potters or their family members may have gathered clay and temper close to areas where they engaged in other activities, such as gathering wild plants. Men skilled in the making of arrow points may have collected obsidian while ranging further afield as part of hunting or foraging expeditions.

Specialized minerals or pigments, important for ritual activities, may have been collected by specialists as part of pilgrimages to ancestral or sacred sites. The rhythm and routine of these taskscapes would have oriented people's perceptions of the landscape and how they moved across it, imbuing places associated with specific activities or resources with cultural meaning and embedding them in social memory.

Both ethnomineralogies and taskscapes are generally associated with highly localized and distinct communities of practice (Arnold Reference Arnold2018). Communities of practice are groups of people who come to share a collective social identity through learning, making, and doing together (Lave and Wenger Reference Lave and Wenger1991). They are characterized by sets of knowledge, techniques, and beliefs that are socially transmitted within and between generations. A group of artisans within a village, such as the potters or ornament makers of Goat Spring Pueblo, would constitute such a local community of practice. But individuals can and do belong to multiple communities of practice; at the same time, members of specific local communities of practice often have contact and interaction with members of similar communities of practice at other locales, sometimes over long distances. These intersections and interactions create much broader constellations of shared knowledge and practice than is normally associated with specific, localized ethnomineralogies, taskscapes, or communities of practice.

These broader constellations of knowledge, practice, and belief have been conceptualized as “knowledgescapes” (Herhahn and Huntley Reference Herhahn, Huntley and Spielmann2017; Shariq Reference Shariq1999). Knowledgescapes are constituted and spread within social networks of varying scales and facilitated by interactive processes such as migration, intermarriage, and trade. They may be associated with broadly shared cosmological beliefs and ritual practices—practices that may require special regalia made from materials acquired from specific cosmologically charged sources or places. In the diasporic context of the late precontact Southwest, shared knowledgescapes may have maintained connections and identity with distant Ancestral Pueblo homelands. Access to and preference for some distant raw materials may have been associated with sustaining and reaffirming connections to these broader interregional knowledgescapes.

Below we examine how these concepts of ethnomineralogies, taskscapes, communities of practice, and knowledgescapes help us to understand sets of provenance data from materials recovered from Goat Spring Pueblo—in terms of human choices and actions that attended to the material affordances of specific raw materials—and were embedded in systems of shared knowledge and practice that constituted social networks and identities of varying types and scales. Ultimately, this approach allows us to examine how artisans’ knowledge and belief systems may have helped to organize persistent choices of natural resources from specific places over time, resulting in long-term engagement with cultural landscapes that eventually embedded these choices within social memory.

Goat Spring Pueblo (LA285)

Located at a little over 1,825 m (6,000 ft.) in elevation along the eastern edge of the Bear Mountains, Goat Spring Pueblo overlooks the Plano San Lorenzo of the Rio Grande floodplain. The village consists of a U-shaped pueblo opened to the east (Figure 2). Three masonry roomblocks are estimated to have held 200 ground-floor rooms (Marshall and Walt Reference Marshall and Walt1984:215). All decorated pottery sherds recovered from the site are glaze-painted ware. Although surface sherds suggest that the village was occupied from the late 1400s to about AD 1680 (Marshall and Walt Reference Marshall and Walt1984:217; Mera Reference Mera1940:7), cross-dated ceramic types from Eckert and Huntley's recent excavations suggest that the site may have been occupied as early as the 1300s.

Figure 2. Goat Spring Pueblo. Photo taken from nearby ridge; view to the northeast. Photograph courtesy of Suzanne Eckert. (Color online)

Archaeology at Goat Spring Pueblo

Goat Spring Pueblo was first recorded by H. P. Mera in the 1930s (Mera Reference Mera1940). Along with one other highland village, Goat Spring Pueblo defines the western extent of Ancestral Piro settlement (Marshall and Walt Reference Marshall and Walt1984). The Piro are thought to be descendants of a combination of indigenous Piro speakers and immigrant Mogollon populations that came together during the late fourteenth and fifteenth centuries in the southern Rio Grande district (Cordell and McBrinn Reference Cordell and McBrinn2012; Marshall and Walt Reference Marshall and Walt1984). Some archaeologists have suggested that villages in the southern Rio Grande district played a major role in late Ancestral Pueblo period (AD 1300–1680) social dynamics. For example, the southern trail between the Western Pueblo and Rio Grande regions began at the modern-day Hopi mesas and utilized the pass between the Magdalena and Bear Mountains (near Goat Spring Pueblo) before ending near modern-day Socorro, where it joined the trail that ran north–south along the Rio Grande (Phillips et al. Reference Phillips, Franklin, Eckert, Ballagh, Brown, Barbour, Boyer and Head2021). Given this known trail, the southern Rio Grande district may have been a gateway for the movement of people, cosmological ideas and ritual practices, and goods between the Rio Grande and Western Pueblo regions.

Research by Huntley (Reference Huntley2008) has shown that lead from sources in the southern Rio Grande district were used to make paints on glaze-painted pottery produced in the Zuni region. Huntley, Habicht-Mauche, and other colleagues have argued that at least some sites in the region may have played a role in circulating this important resource (Huntley et al. Reference Huntley, Fenn, Habicht-Mauche, Mills, Cordell and Habicht-Mauche2012). Although more difficult to trace archaeologically, historic documents record that the southern Rio Grande district was also the source of cotton and tobacco for northern Rio Grande district villages (Ford Reference Ford and Ortiz1972; Snow Reference Snow, Wilcox and Bruce Masse1981).

Artifacts examined in this study come from recent excavations (2013–2017) led by Eckert and Huntley. We developed a preservation archaeology project (Doelle and Huntley Reference Doelle and Huntley2012) that combined low-impact research methods (e.g., survey, surface mapping, geophysical subsurface techniques) with limited, targeted excavations. Approximately 24 m3 of material were excavated, which sampled the trash midden, the three roomblocks, the kiva, and the plaza; additional sampling included 50 shovel test pits and clearance of two rooms previously excavated but never backfilled (Davis and Winkler Reference Davis and Winkler1960).

Once fieldwork was complete, we began basic and specialized analyses to determine the chronology of the site and to explore issues of cultural continuity and change, ritual, migration, exchange, and resistance. We have created a detailed map of the roomblocks; determined the locations and extent of trash middens; identified subsurface cultural features using a combination of electromagnetic conductivity, ground-penetrating radar, and resistivity; and extended our understanding of the village's chronology. Some of this fieldwork confirmed what we already knew; for example, the site consists of three roomblocks composed of approximately 200 ground-floor rooms constructed of rhyolite masonry. Some of this fieldwork provided additional information; for example, although five depressions were initially identified as possible pit structures by early researchers, our geophysical work and testing confirmed that only one of these depressions is a cultural feature. We are currently in the process of analyzing artifacts and writing the final report, of which this current article is a part.

Chronological reconstruction of the site is in the process of being refined but is hampered by several obstacles. Radiocarbon dates (Hood Reference Hood2012) on maize recovered from stratigraphically excavated midden units identify an early phase dating to circa AD 1470–1515 (prior to Spanish missionization of southern Rio Grande villages) and a late phase dating to circa AD 1625–1700 (post-missionization). Although some architectural evidence suggests two separate components, cross-dating of pottery and trash stratigraphy in some units suggest continuous occupation possibly with multiple construction phases. Currently, many excavation units cannot be confidently assigned to a specific phase, and stratigraphy in at least one unit shows disturbance either through pothunting or the 1950s excavations. Given that chronology building is more complex than we had anticipated, and that sample counts are too small if we only work with material from confirmed phases, the analyses presented here apply to the site as a whole in both time and space.

Culturally Significant Geological Resources in the Goat Spring Pueblo Vicinity

One of the primary reasons we were initially interested in Goat Spring Pueblo was its location near various geological resources that were potentially significant to Ancestral Pueblo artisans (Figure 3). The village and these geological resources occur in different formations in or below the Mogollon-Datil volcanic field. The geology of the region is very complex (Cather et al. Reference Cather, Chamberlin, Ratte, Chamberlin, Kues, Cather, Barker and McIntosh1994; Lasky Reference Lasky1932), and nomenclature has been revised numerous times; we are following the nomenclature recommended by Cather and colleagues (Reference Cather, Chamberlin, Ratte, Chamberlin, Kues, Cather, Barker and McIntosh1994). We limit our focus to those formations containing resources that could have been culturally significant to Ancestral Puebloans in terms of chipped stone tool production, lead for glaze-paint recipes, or blue-green minerals for ornament production.

Figure 3. Location of culturally significant geological resources discussed.

Goat Spring Pueblo is situated in the Bear Mountains of the Hells Mesa Tuff Formation of the Datil Group (Cather et al. Reference Cather, Chamberlin, Ratte, Chamberlin, Kues, Cather, Barker and McIntosh1994), which consists of 610–760 m thick volcanic deposits throughout much of the area. Various andesites, rhyolites, and quartz latites are available within the immediate vicinity of the pueblo; intrusive monzonites and granites are present within 3 km of the village. These igneous materials were used for masonry construction, lithic tool manufacture, and tempering clay for pottery production.

The nearest obsidian source to Goat Spring Pueblo is the McDaniel Tank source, which is part of the BearFootnote 1 Mountain Tuff Formation of the Datil Group (Cather et al. Reference Cather, Chamberlin, Ratte, Chamberlin, Kues, Cather, Barker and McIntosh1994). The identification of this source is relatively recent, although its distinct chemistry has been observed in numerous New Mexico lithic assemblages (LeTourneau et al. Reference LeTourneau, Ferguson and McLemore2010). The obsidian occurs as nodules weathering out of a rhyolitic parent rock, tends to be an opaque black, and exhibits excellent workability. Although observed nodules range up to 3–5 cm in diameter (the vast majority are 1 cm or less), the discovery of a Paleoindian projectile-point base made of McDaniel Tank obsidian suggests that at least some larger nodules existed (Schaefer Reference Schaefer2020). Nodule distribution is dispersed, occurring over roughly 32 km2 in scattered deposits, but at least some deposits are located as close as 20 km south of Goat Spring Pueblo and could have been collected on short foraging trips from the pueblo.

Smithsonite, a zinc-bearing, blue-green mineral that could have been worked similarly to turquoise, occurs within the Kelly Formation of the Mississippian System. This formation of approximately 30 m of marine limestone was deposited in a major advance of the ocean across the continent some 350 million years ago and is located in the Magdalena Mountains. The only known source of blue-green smithsonite in the greater Southwest is from the Kelly Formation (Eveleth and Lueth Reference Eveleth, Lueth, Hughes, Liebetrau and Staebler2010). Although the Hells Mesa Tuff Formation of the Datil Group was deposited over the Kelly Formation around 30 million years ago (Cather et al. Reference Cather, Chamberlin, Ratte, Chamberlin, Kues, Cather, Barker and McIntosh1994), various geological processes since then—including rapid uplift and tilting—have resulted in portions of this formation being exposed near or on the surface. One of these exposures is only 11 km south of Goat Spring Pueblo, where smithsonite can still be found on the surface.

Galena and other lead-bearing minerals, which were used by Ancestral Pueblo potters to make glaze paint, are available in various deposits throughout New Mexico, including two surface locations near Goat Spring Pueblo. One location is from the Kelly Formation discussed above; the other is from Miocene alteration of andesites in the La Jara Formation in an area located 15 km south-southwest of the pueblo. Given the modern economic importance of these areas, they are known as the Magdalena Mining District and North Magdalena Mining District, respectively (Lasky Reference Lasky1932). Although various mines are located within each district, our comparative samples (mostly galena and cerussite) come primarily from the Kelly Mine in the Magdalena Mining District and the Jack Frost Mine in the North Magdalena Mining District.

Chemical Compositional Analyses

Lead-Based Glaze Paints

Glaze-painted pottery from Goat Spring Pueblo is assumed to have been used in ritual and feasting contexts, with pottery decorations conveying important and highly visible messages about both identity and ritual practice. We are especially interested in examining the production and distribution of ceramic vessels, as well as the lead required to make glaze paint, because these activities were not strictly economic: the production, movement, and use of glaze-painted pottery across the Ancestral Pueblo landscape played an important role in defining local communities of practice and broader knowledgescapes specific to emerging Pueblo ritual practices during the late Ancestral Pueblo period (Eckert Reference Eckert2008; Habicht-Mauche and Eckert Reference Habicht-Mauche and Eckert2021; Mills Reference Mills, Gregory and Wilcox2007a; Spielmann Reference Spielmann and Spielmann1998). Furthermore, we were specifically interested in if and when potters at Goat Spring Pueblo began to rely on locally collected lead. This local lead would have been easily accessible and would have had physical attributes needed for making glaze paint that were indistinguishable from physical attributes of lead collected from elsewhere in New Mexico (Herhahn Reference Herhahn1995). Goat Spring Pueblo is the closest known site with locally produced glaze-painted pottery to the Magdalena Mining District and the North Magdalena Mining District, and previous studies have established that lead from both districts was used by Ancestral Pueblo potters from both the Zuni and southern Rio Grande districts (Habicht-Mauche et al. Reference Habicht-Mauche, Glenn, Schmidt, Franks, Milford and Russell Flegal2002; Huntley Reference Huntley2008; Huntley et al. Reference Huntley, Fenn, Habicht-Mauche, Mills, Cordell and Habicht-Mauche2012). We originally postulated that, at some point, residents of Goat Spring Pueblo may have controlled the distribution of lead from the area to other Pueblo villages. However, our isotopic sourcing of the lead used to produce locally made glaze-painted pots challenges this assumption.

We used inductively coupled plasma–mass spectrography (ICP-MS) to identify geographic sources of lead ores used to make glaze paints based on their stable lead isotope ratios. The application of ICP-MS to the analysis of lead glazes is based on the principle that lead ores from different geological sources—and the glaze paints made from them—can be distinguished by their stable lead isotope fingerprints, which generally differ in isotopic composition as a function of the age of the deposit (Flegal and Smith Reference Flegal and Smith1992; Habicht-Mauche et al. Reference Habicht-Mauche, Glenn, Milford and Flegal2000). We examined 48 glaze-painted sherds, the primary selection criteria being that (1) the sherds were produced at Goat Spring Pueblo as indicated by the presence of rhyolite temper identified through Eckert's petrography work as being local, and (2) each sherd contained a fairly large area of glaze paint in order to minimize destruction due to sample preparation. A small amount of glaze paint was dissolved in 1% nitric acid. Lead concentrations were measured using inductively coupled plasma-optical emission spectroscopy (ICP-OES) and then diluted with blank acid to a standard dilution. To measure lead isotope ratios, Habicht-Mauche and Eckert used the Element XR high-resolution ICP-MS instrument in the Plasma Analytical Facility, which is part of the Institute of Marine Sciences at the University of California, Santa Cruz. The results from this analysis were compared with existing data compiled by Habicht-Mauche, Huntley, and other colleagues to track the sources of lead ore used by Ancestral Pueblo potters (Habicht-Mauche et al. Reference Habicht-Mauche, Glenn, Milford and Flegal2000, Reference Habicht-Mauche, Glenn, Schmidt, Franks, Milford and Russell Flegal2002; Huntley Reference Huntley2008; Thibodeau et al. Reference Thibodeau, Habicht-Mauche, Huntley, Chesley and Ruiz2013).

Our results show that the vast majority of lead used to formulate the glaze paints found on pottery made at Goat Spring Pueblo comes from the Hansonburg Mining District, some 160+ km east of the village. The second most common source of lead is from the Cerrillos Mining District (Figures 4 and 5), located a bit less than 160 km (depending on the trail that was taken) northeast. Several of the glaze paints appear to have been made from a mix of Cerrillos and Hansonburg lead, given that their ratios fall along a line that connects the mean of the ratios recorded from both districts. Two of the glaze-paint samples had ratios that fall somewhat outside the range of the Hansonburg ore field as currently measured. Analyses of Rio Grande Glaze Ware paints on pottery produced at other sites have recorded ratios in this same range (Giomi Reference Giomi2022; Habicht-Mauche, personal communication 2022), suggesting that our comparison sample of Hansonburg lead ore (mostly sampled from a single mine) may not be representative of the full isotopic variability within that district. However, the nearest lead source (the North Magdalena Mining District) was possibly used in only one or two of the analyzed samples, whereas lead from the other local source (the Magdalena Mining District) appears not to have been used at all. Implications for these results are discussed below.

Figure 4. 208Pb/204Pb isotope data plotted against 206Pb/204Pb from 40 glaze-paint samples on locally produced pottery recovered from Goat Spring Pueblo. (Color online)

Figure 5. 207Pb/204Pb from 40 glaze-paint samples on locally produced pottery recovered from Goat Spring Pueblo. (Color online)

Obsidian Artifacts

Obsidian artifacts from Goat Spring Pueblo are primarily debitage, with only a handful of formal tools. Although obsidian tools were probably valued for their especially sharp edges, obsidian may also have been valued for its glassy shine (Munson Reference Munson, Munson and Hays-Gilpin2020a). The complete assemblage of 58 obsidian artifacts from Goat Spring Pueblo were analyzed using the Thermo Scientific ARL Quant'X Energy Dispersive X-ray Fluorescence (EDXRF) instrument at MURR. This instrument has a rhodium-based X-ray tube operated at 35 kV and a thermoelectrically cooled silicon-drift detector. The obsidian calibration uses a set of 37 very well characterized obsidian sources with data from previous ICP, XRF, and neutron activation analysis (NAA) measurements (Glascock and Ferguson Reference Glascock and Ferguson2012). Ferguson counted the samples for two minutes to measure the minor and trace elements present. The elements measured include rubidium (Rb), strontium (Sr), yttrium (Y), zirconium (Zr), and niobium (Nb). These five elements are excellent for discriminating most sources in the American Southwest. Iron (Fe) and manganese (Mn) are also reported but are less reliable in assemblages with smaller artifacts (Ferguson Reference Ferguson, Shugar and Mass2012). In most cases, source assignments for obsidian artifacts are based on visual inspection of elemental bivariate plots. XRF data tend to skew along correlation lines (largely as a function of variable sample mass), and visual inspection provides reliable source assignments (Ferguson Reference Ferguson, Shugar and Mass2012).

Our results show that residents of Goat Spring Pueblo did not rely primarily on obsidian from the nearest source (Figure 6). Almost three-quarters of the obsidian from the village is identified as being from the Mount Taylor source area (Horace Mesa and Grants Ridge sources in Figure 5), some 113 km northwest of the village. There are a few obsidian sources—Red Hill, Mule Creek, and Gwynn Canyon—that are essentially the same distance as Mount Taylor, as well as secondary deposits that may have been collected from the southern Rio Grande (Shackley Reference Shackley2021). The nearest obsidian source, McDaniel Tank, is represented by less than 10% of the assemblage. Although there is a size limitation of the McDaniel Tank source, with specimens larger than 2 cm in diameter being difficult to find on the modern surface, this size limitation did not stop residents of other sites from relying primarily on this source. For example, at the Archaic period site of Buttercup Spring in the Magdalena Mountains just east of the source area, most of the obsidian assemblage is from the McDaniel Tank source (LeTourneau et al. Reference LeTourneau, Ferguson and McLemore2010). Similarly, four twelfth-century Pueblo sites in the Lion Mountain area, located 35 km due east of Goat Spring Pueblo, have obsidian assemblages dominated by McDaniel Tank obsidian (Schaefer Reference Schaefer2020). Given that residents of some other local sites had relied primarily on McDaniel Tank obsidian, and given that other obsidian sources were available that were the same distance as the Mount Taylor source, it appears that residents of Goat Spring Pueblo were actively seeking material from the Mount Taylor area.

Figure 6. XRF results for all 58 obsidian specimens recovered from Goat Spring Pueblo with ellipses representing composition of known sources. (Color online)

Blue-Green Minerals

Blue-green minerals are, and were, used in the creation of personal ornaments and of pigments, and as offerings (Mattson Reference Mattson2016; McBrinn and Altshuler Reference McBrinn and Altshuler2015; Munson Reference Munson, Munson and Hays-Gilpin2020b). The most extensively used (and studied) blue-green mineral among Ancestral Puebloans was turquoise (Hull et al. Reference Hull, Fayek, Joan Mathien and Roberts2014; Mathien Reference Mathien2001; Thibodeau et al. Reference Thibodeau, Killick, Hedquist, Chesley and Ruiz2015). However, other blue-green minerals were available, including malachite, azurite, chrysocolla, and smithsonite. The availability of blue-green smithsonite in New Mexico from only the Magdalena Mining District, its modern workability as a gemstone, and the identification of ornaments made from smithsonite at other archaeological sites (Eveleth and Lueth Reference Eveleth, Lueth, Hughes, Liebetrau and Staebler2010) suggest that residents of Goat Spring Pueblo may have relied on it in a way similar to turquoise.

Although other blue-green minerals found in New Mexico are copper bearing, smithsonite is a zinc-bearing mineral (Pohwat Reference Pohwat, Hughes, Liebetrau and Staebler2010). This suggested that XRF analysis could be used to determine qualitatively if the blue-green minerals recovered from Goat Spring Pueblo were smithsonite. Ferguson used a portable Bruker TRACER 5i XRF spectrometer to perform the analysis. Spectra of the Goat Spring Pueblo samples were compared to those from a Kelly Mine smithsonite specimen and an unprovenienced New Mexico turquoise specimen. Again, this analysis was not used to source the blue-green minerals recovered from Goat Spring Pueblo, but to verify whether any of the samples were zinc bearing and therefore probably smithsonite.

All 14 blue-green mineral specimens recovered from Goat Spring Pueblo were analyzed (Figure 7). Although some of these artifacts were clearly worked ornaments, most represented debitage from the production process or unworked nodules of material (Arthur Vokes, personal communication 2021). Nine samples are a close match to the zinc (Zn) peaks expected of smithsonite, three samples are a close match to the copper (Cu) peaks expected of turquoise, and two samples could not be matched. All told, residents of Goat Spring Pueblo were primarily relying on the locally available smithsonite, but they appear to have had access to raw blue-green minerals from farther afield. All three specimens (468.1, 468.6, 468.7) of the copper-bearing blue-green minerals recovered from Goat Spring Pueblo were identified as “unworked nodules.” This suggests that people were bringing at least some nonlocal blue-green minerals to Goat Spring Pueblo as raw material for manufacture rather than as finished products.

Figure 7. XRF results for all 14 blue-green mineral specimens recovered from Goat Spring Pueblo. (Color online)

Summary

The original working hypothesis for our chemical compositional and isotopic studies was that local patterns of resource acquisition would follow Western principals of economic optimization; that is, that residents of Goat Spring Pueblo would have taken advantage of the geological resources that were locally available to them within a day or two's foraging range from the village. In the case of blue-green minerals, this assumption appears to be true given that residents appear to have primarily used the locally available smithsonite. Although raw turquoise was also acquired from unknown distant sources, the distant sources could also have been sources of other resources, such as the Cerrillos Hills, which is known to have been a significant source of both lead and turquoise that was widely distributed throughout the Ancestral Pueblo world. The obsidian and lead analyses presented here show that these materials were often transported some distance across the landscape to be brought to Goat Spring Pueblo. Because objects and materials “are only ‘moved’ as a result of human activity, although the behavioral processes vary” (Huntley Reference Huntley, Herhahn and Ramenofsky2016:202), we must consider potential social and cultural explanations for our observed compositional data patterns. Huntley's challenge (Reference Huntley, Herhahn and Ramenofsky2016) becomes important as we consider our findings within the framework of Goat Spring Pueblo artisans in different communities of practice negotiating their ethnomineralogies, taskscapes, and knowledgescapes.

Ethnomineralogies, Taskscapes, and Knowledgescapes at Goat Spring Pueblo

At its most basic, this research examines the obtainment of geological resources needed for the manufacture of objects by residents of Goat Spring Pueblo. There is no doubt that we are looking at the movement of geological resources into the village to make specific types of objects rather than the movement of completed objects. In the case of obsidian, there are a few finished tools, but the majority of the material is by far in the form of flakes that were the result (or perhaps goal) of toolmaking. Similarly, most of the blue-green mineral from the site is manufacturing debris. In the case of lead to make glaze paint, paints made using nonlocal lead was applied to locally produced pottery; in other words, it was the raw resource to make the paint that was moved, but the final ceramic vessels were not. In terms of context, raw geological materials were moved into Goat Spring Pueblo, and the production of finished products was occurring there.

There is also no doubt that residents of the village were aware of the existence of local resources; smithsonite, McDaniel Tanks obsidian, and North Magdalena Mining District lead are all present in the samples examined in this study. However, artisans of the village were not primarily relying on local geological sources for the creation of their glaze-painted pottery or obsidian tools, although they were for their blue-green ornaments. We believe that the question is not “why were village artisans not using some locally available resources?”; instead, it is “why were they selecting the specific sources that they did utilize?” We conceptualize the village's artisans as working within social networks that shared a technological tradition for the manufacture of specific material cultures—in other words, within communities of practice (Stark Reference Stark, Habicht-Mauche, Eckert and Huntley2006:25). As discussed above, members of a community of practice share a collective identity developed through learning, making, and doing together (Lave and Wenger Reference Lave and Wenger1991). Part of this “learning, making, and doing” would have been structured around other cultural behaviors, including ethnomineralogies, taskscapes, and knowledgescapes. Here, we consider our data more thoroughly through communities of practice while taking these behaviors into consideration. Ultimately, it should be remembered that these behaviors are not mutually exclusive. For example, if Mount Taylor obsidian was important to residents of Goat Spring Pueblo for cosmological reasons, qualitative reasons, or both, then they probably would have been pleased to procure it whenever possible and through multiple means.

Ethnomineralogies

As discussed above, ethnomineralogies are shared sets of practical knowledge and strategies within a community of practice that allow artisans to test, manipulate, and problem solve when working with raw materials (Arnold Reference Arnold1971, Reference Arnold2018). Ethnomineralogies are taught through the process of learning a craft within a community of practice but may also be expanded through an artisan's testing of new materials or through knowledge shared by individuals from a different community of practice. At Goat Spring Pueblo, and among Ancestral Pueblo potters in general, an ethnomineralogy for the testing and use of lead minerals in the production of glaze paints was a relatively recent development and was probably regionally shared (see below).

Ethnomineralogies for the testing and knapping of obsidian (local or otherwise) among flintknappers at Goat Spring Pueblo—and in the broader Ancestral Pueblo region in general—probably went back centuries, if not more. As discussed above, local obsidian had excellent workability, but nodules tend to be small (<5 cm in diameter). Most obsidian recovered from Goat Spring Pueblo was collected from nonlocal sources, primarily Mount Taylor. Mount Taylor obsidian also would have had excellent workability, but nodules 10 cm and over in diameter are “relatively common” near the top of Grants Ridge at Mount Taylor (Shackley Reference Shackley1998:1077); this larger nodule size may have been preferred by flintknappers for practical reasons and may have been sought out through various means as discussed below.

The use of smithsonite for the construction of ornaments is a good example of an expanded ethnomineralogy that was probably local to the community of practice at Goat Spring Pueblo. The importance of the color blue-green—and, by extension, blue-green minerals—in Ancestral Pueblo cosmology has been well documented and extends into historic and modern Pueblo thought (Mattson Reference Mattson2016; McBrinn and Altshuler Reference McBrinn and Altshuler2015; Munson Reference Munson, Munson and Hays-Gilpin2020b). Although the use and provenance of turquoise has been extensively studied in the US Southwest (Hull et al. Reference Hull, Fayek, Joan Mathien and Roberts2014; Mathien Reference Mathien2001; Sigleo Reference Sigleo1975; Thibodeau et al. Reference Thibodeau, Killick, Hedquist, Chesley and Ruiz2015), the source and use of other blue-green minerals are not as well understood. The evidence at Goat Spring Pueblo for limited working of smithsonite in ways similar to turquoise (Arthur Vokes, personal communication 2021) suggests that at least one artisan at the village was using an established ethnomineralogy to test and manufacture ornaments from locally available smithsonite in ways similar to the production of turquoise objects. At the same time, the limited amount of blue-green minerals currently found at Goat Spring Pueblo indicates that the village was never a workshop or a source of blue-green mineral for other Ancestral Pueblo villages. The local artisans working the smithsonite may have been making ornaments for use by residents of the village, but the presence of copper-bearing minerals (possibly turquoise) at the site indicates that these artisans were happy to use, and possibly preferred, nonlocal blue-green minerals when available.

Taskscapes

Taskscapes reflect histories of interactions of people with their cultural landscape and natural resources (Huntley et al. Reference Huntley, Fenn, Habicht-Mauche, Mills, Cordell and Habicht-Mauche2012; Michelaki et al. Reference Michelaki, Braun and Hancock2015); in other words, they are the human use of a landscape structured by the interaction of resource locales, daily tasks, and ethnomineralogies. At Goat Spring Pueblo, collection of smithsonite—and the occasional piece of galena and obsidian, according to our data patterns—would have been possible within a day's walk, and procurement probably was part of locally defined taskscapes. Collection of these resources may have occurred as part of other trips from the village to hunt, forage wild plants, or collect other geological resources such as pigments or clays. There is no reason to believe that local geological resources were moved into the village through any means other than as part of local procurement practices.

The majority of obsidian recovered from Goat Spring Pueblo was collected from nonlocal sources: primarily Mount Taylor but also the Jemez Mountains, located in the northern Rio Grande area. Obsidian provenance studies at archaeological sites across the Ancestral Pueblo landscape have shown that Mount Taylor was a popular source of material for centuries (Benedict and Hudson Reference Benedict and Hudson2008; Duff et al. Reference Duff, Moss, Windes, Kantner and Steven Shackley2012; Shackley Reference Shackley2010), including within the southern Rio Grande district (Eckert and Huntley Reference Eckert and Huntley2022; Schaefer Reference Schaefer2020). Additionally, some Mount Taylor obsidian (and Jemez Mountains obsidian), whether Ancestral Puebloans recognized it as such or not, may have been collected in secondary deposits in the Rio Grande (Shackley Reference Shackley2021). The majority of lead minerals was also collected from a nonlocal source in the Hansonburg Mining District. Procurement of obsidian and lead minerals, then, make for an interesting consideration of broader taskscapes as realized by residents of Goat Spring Pueblo.

Procurement of nonlocal obsidian and lead minerals may have been, in part, associated with longer-distance hunting or foraging expeditions by village residents moving over a regional taskscape. Evidence for short-term use of Mount Taylor by Ancestral Pueblo populations, probably for “hunting and gathering of specific resources,” has been documented (Benedict and Hudson Reference Benedict and Hudson2008:7; see also Popelish Reference Popelish1990). Similarly, long-term use of the Hansonburg Mining District region by Ancestral Puebloans comes from nonarchaeological reporting of stone hammers found in caves (MacCarthy Reference MacCarthy1918), projectile points dating to various time periods (Eveleth and Lueth Reference Eveleth, Lueth, Lueth, Lucas and Chamberlin2009), and water holes covered with flat stones (Blanchard ca. Reference Blanchard1965). Although it is impossible to tie the Ancestral Pueblo material culture recovered from Mount Taylor or the Hansonburg Mining District to a specific region or village, the presence of raw resources from these two areas at Goat Spring Pueblo makes it reasonable to speculate that at least some residents of the site were going to these locations to collect resources, quite possibly as part of larger taskscapes that would allow them to complete various activities in various locations as part of a single long-distance trip.

Although it is difficult to determine, it should be noted that part of these longer foraging expeditions may have included collecting resources with cosmological importance from their source (Benedict and Hudson Reference Benedict and Hudson2008; Mills and Ferguson Reference Mills and Ferguson1998). The long-standing importance of Mount Taylor obsidian, including the current importance of Mount Taylor in modern Pueblo cosmology, has been well documented (Benedict and Hudson Reference Benedict and Hudson2008; Berthier-Foglar Reference Berthier-Foglar2012).

Similarly, given the numerous natural caves in the Hansonburg Mining District—including the “Enchanted Cave of the Oscuras” described in 1881 as extensive, remarkably beautiful and containing spectacular stalactites, stalagmites, and flowing springs (Eveleth and Lueth Reference Eveleth, Lueth, Lueth, Lucas and Chamberlin2009)—it is possible that this region also held cosmological significance to Ancestral Pueblo peoples.

Knowledgescapes

If taskscapes are structured by landscape and natural resources, knowledgescapes are structured by contact and interaction with members of other communities that share a broad suite of practice and belief (Herhahn and Huntley Reference Herhahn, Huntley and Spielmann2017; Shariq Reference Shariq1999). These knowledgescapes are not usually associated with local ethnomineralogies or taskscapes but rather with more expansive constellations of shared knowledge that cross-cut villages, regions, and communities of practice. Knowledgescapes can be associated with broadly shared cosmological beliefs, ritual practices, and ceremonies requiring objects made from materials collected from cosmologically important places. As discussed above, Mount Taylor and caves in the Hansonburg Mining District may have been such places. A shared knowledgescape between artisans at Goat Spring Pueblo and those from other villages may have maintained connections and identity with these distant source locations; preference for such materials may have actually been a means of reaffirming these broad knowledgescapes.

If knowledgescapes are constituted and spread through participation in regular markets, feasts, and religious ceremonies sponsored by different villages, then the acquisition of at least some geological resources by residents of Goat Spring Pueblo may have been through trade networks or exchange partners. Much has been written about the expansion of trade networks during the late Ancestral Pueblo period and how access to these networks would have been made possible by visiting different villages throughout the year (Mills Reference Mills2007b; Snow Reference Snow, Wilcox and Bruce Masse1981; Spielmann Reference Spielmann and Spielmann1998). Ethnographic and historical accounts suggest that Puebloans regularly visited other villages to participate in markets, feasts, marriages, deaths, coming-of-age events, and other religious ceremonies (Ford Reference Ford and Ortiz1972; Snow Reference Snow, Wilcox and Bruce Masse1981). In addition, the southern Rio Grande district is known to have played an important role in these exchange networks. Within the Rio Grande region, southern Rio Grande villages were the source of cotton and tobacco (Snow Reference Snow, Wilcox and Bruce Masse1981:356). Many exchange networks appear to have been informal, occurring between individuals or families or artisans with a shared practice rather than controlled by a village or specific social segment (Cordell Reference Cordell1998). Consequently, residents of Goat Spring Pueblo may have acquired raw resources when visiting other villages for any number of reasons.

Visiting Goat Spring Pueblo may also have been part of the knowledgescape of residents from other villages. As described above, the village is located on a trail connecting Western Pueblo and southern Rio Grande villages. People would have been moving back and forth along the trail, and it is likely they would have stopped at Goat Spring Pueblo. During our ceramic analysis, we identified Zuni Glaze Ware and decorated Zuni Buff Ware at Goat Spring Pueblo in small quantities. We know that lead from Hansonburg and Cerrillos Mining Districts were also used in Western Pueblo glaze paint, we know that Mount Taylor obsidian is found throughout Western Pueblo and southern Rio Grande sites, and we know that blue-green minerals were moving throughout the Southwest. It is quite likely that at least some of this material was carried to Goat Spring Pueblo by short-term visitors to the village. Various other commodities could also have been traded or exchanged: salt from the Zuni Salt Lake or Salinas district, textiles, feathers, pigments, buffalo meat and hides, and obsidian and glaze paints (Ford Reference Ford and Ortiz1972).

Ultimately, our current understanding of glaze-paint production suggests that Goat Spring Pueblo potters probably obtained most of their lead minerals through trade relations associated with a broader knowledgescape. This knowledgescape would likely have been focused on the knowledge and technology transfer of glaze-paint production as well as glaze paint's association with cosmology and ritual practice (Eckert Reference Eckert2008; Habicht-Mauche and Eckert Reference Habicht-Mauche and Eckert2021; Spielmann Reference Spielmann and Spielmann1998). Nelson and Habicht-Mauche (Reference Nelson, Habicht-Mauche, Habicht-Mauche, Eckert and Huntley2006) have argued that specialized resources for pottery production such as lead for glaze paint appear to have moved between households across ethnolinguistic social groups as part of a broader network of regional interactions. Eckert and colleagues (Reference Eckert, Schleher and Snow2018) argued that the movement of these more specialized resources reflect historically contingent, kin-based relationships between households from different ethnolinguistic villages. Pottery data from Goat Spring Pueblo provides further evidence that multiple Pueblo groups, including potters in both the Salinas and Zuni regions (Huntley Reference Huntley, Habicht-Mauche, Eckert and Huntley2006, Reference Huntley2008; Huntley et al. Reference Huntley, Spielmann, Habicht-Mauche, Herhahn and Russell Flegal2007), were using lead from the Hansonburg Mining District, although this district seems to be peripheral to the glaze-producing Pueblo world. All of these communities of practice focused on the production of glaze paint were probably tied into a larger knowledgescape that allowed them access to the knowledge, technology, and materials required to produce glaze wares.

Conclusion

The logic behind performing most geochemical techniques is one of identifying provenance: understanding from where geological resources were obtained, which types of objects were made from these sources, and how far the material (raw or finished) moved. Huntley (Reference Huntley, Herhahn and Ramenofsky2016:202) stated that “identifying provenance—place of origin—is necessary before we can explain behavioral processes behind the distributions of objects across the landscape.” But once we identify provenance, understanding the behaviors is still difficult because human behavior is complex.

In this article, we have examined the acquisition of raw materials at Goat Spring Pueblo through the lens of ethnomineralogies, taskscapes, and knowledgescapes. We argue that if artisans at the village structured their taskscapes around ethnomineralogies and location of geological resources, and structured their knowledgescapes around interaction with artisans from other communities that shared a broad suite of practice and belief, then the movement of raw materials into the village was based on a complex set of cultural behaviors. The specific location of a geological resource would have been only one part of the community's greater understanding of its physical surroundings. Mountains, rivers, and other landmarks associated with stories, histories, and cultural traditions would have defined the space in which villagers lived and may also have informed preferences for certain resources. Consequently, the surviving material culture at Goat Spring Pueblo is a reflection of day-to-day practice and beliefs that were integrated into a broader Ancestral Pueblo worldview about place.

Acknowledgments

We thank our team of volunteers, graduate student crew chiefs, and field school students. We also thank the staff at the Cibola National Forest Service (CNFS) Magdalena District Office, the staff at the CNFS Albuquerque Supervisors Office, Matt Basham (previously of CNFS, now of BLM), Jeremy Kulisheck, and the staff at the Archaeological Records Management Section (ARMS). We are grateful to Arthur Vokes for the analzying our blue-green minerals, to Marion Coe for preparing our maps, and James T. Watson for translating our abstract to Spanish.

Funding Statement

Fieldwork was funded by Texas A&M University’s (TAMU) Program for the Enhancement of Creative and Scholarly Activities, TAMU’s Summer School Program, and an Ariziona State Museum 2017 Burgan Fund grant. Funding for lead isotope analysis was funded by a 2018 New Mexico Archaeological Council grant. Funding for XRF analysis was provided in part from a National Science Foundation grant (#1912776) to the Archaeometry Laboratory at MURR.

Data Availability Statement

Lead isotope data available at tDAR id: 472667; doi:10.48512/XCV8472667. XRF data available upon request from Jeffrey R. Ferguson at MURR. Excavation materials and records will be curated at the Maxwell Museum of Anthropology, Albuquerque, New Mexico, but can also be accessed by contacting Suzanne L. Eckert.

Competing Interests

The authors declare none.

Footnotes

1. On September 8, 2022, the USDI announced that “in accordance with Secretary's Order 3404, the U.S. Board on Geographic Names has approved replacement names for all official features that included the word ‘Sq---’ in their name.” In the Magdalena area, this included the newly named Bear Mountain; previous publications that discuss Bear Mountain use the inappropriate term.

References

References Cited

Andrefsky, William Jr. 1994. Raw-Material Availability and the Organization of Technology. American Antiquity 59(1):2134.10.2307/3085499CrossRefGoogle Scholar
Arnold, Dean E. 1971. Ethnomineralogy of Ticul, Yucatan Potters: Etics and Emics. American Antiquity 36(1):2040.10.2307/278020CrossRefGoogle Scholar
Arnold, Dean E. 2018. Maya Potters’ Indigenous Knowledge: Cognition, Engagement, and Practice. University Press of Colorado, Boulder.10.2307/j.ctt20061g1CrossRefGoogle Scholar
Benedict, Cynthia B., and Hudson, Erin. 2008. Mt. Taylor Traditional Cultural Property Determination of Eligibility. Heritage Resources Report No. 2008-03-021. Mt. Taylor Ranger District, Cibola National Forest, Albuquerque, New Mexico.Google Scholar
Berthier-Foglar, Susanne. 2012. Uranium Mining on Sacred Land: The Case of Mount Taylor (NM, USA). ELOHI 2:7994.10.4000/elohi.304CrossRefGoogle Scholar
Binford, Lewis R. 1979. Organization and Formation Processes: Looking at Curated Technologies. Journal of Anthropological Research 35(3):255273.10.1086/jar.35.3.3629902CrossRefGoogle Scholar
Blanchard, Ora W. ca. 1965. Blanchard Mine History: Manuscript Report Constructed from Memory, Business Papers, and William Edward Blanchard's Diaries. Unpublished manuscript courtesy of Sophia Blanchard Warner, New Mexico Bureau of Geology and Mineral Resources Mining Archives, Socorro.Google Scholar
Bradley, Richard. 2000. An Archaeology of Natural Places. Routledge, London.Google Scholar
Cather, Steven M., Chamberlin, Richard M., and Ratte, James C.. 1994. Tertiary Stratigraphy and Nomenclature for Western New Mexico and Eastern Arizona. In Mogollon Slope, West-Central New Mexico and East-Central Arizona, edited by Chamberlin, Richard M., Kues, Barry S., Cather, Steven M., Barker, James M., and McIntosh, William C., pp. 259266. New Mexico Geological Society 45th Annual Fall Field Conference Guidebook. New Mexico Geological Society, Socorro.10.56577/FFC-45.259CrossRefGoogle Scholar
Cordell, Linda S. 1998. Before Pecos: Settlement Aggregation at Rowe, New Mexico. Anthropological Papers No. 6. Maxwell Museum of Anthropology, University of New Mexico, Albuquerque.Google Scholar
Cordell, Linda S., and McBrinn, Maxine E.. 2012. Archaeology of the Southwest. 3rd ed. Left Coast Press, Walnut Creek, California.Google Scholar
Davis, Emma Lou, and Winkler, James H.. 1960. Progress Report Sites D 125 (LA 8931) and D118 (LA 8932), Cibola National Forest, New Mexico. Manuscript on file, Laboratory of Anthropology, Museum of New Mexico, Santa Fe.Google Scholar
Doelle, William H., and Huntley, Deborah L.. 2012. Teaching, Research, and So Much More through a Preservation Archaeology Field School. SAA Archaeological Record 12(1):3638.Google Scholar
Duff, Andrew I., Moss, Jeremy M., Windes, Thomas C., Kantner, John, and Steven Shackley, M.. 2012. Patterning in Procurement of Obsidian in Chaco Canyon and in Chaco-Era Communities in New Mexico as Revealed by X-Ray Fluorescence. Journal of Archaeological Science 39(9):29953007.10.1016/j.jas.2012.04.032CrossRefGoogle Scholar
Eckert, Suzanne L. 2008. Pottery and Practice: The Expression of Identity at Pottery Mound and Hummingbird Pueblo. University of New Mexico Press, Albuquerque.Google Scholar
Eckert, Suzanne L., and Huntley, Deborah L.. 2022. Community Landscapes, Identity, and Practice: Ancestral Pueblos of the Lion Mountain Area, Central New Mexico, USA. American Antiquity 87(1):142167.10.1017/aaq.2021.70CrossRefGoogle Scholar
Eckert, Suzanne L., Schleher, Kari L., and Snow, David H.. 2018. Following the Yellow Brick Road: Yellow Slip Clays and the Production of Rio Grande Glaze Ware in North Central New Mexico. Journal of Archaeological Science: Reports 21:565574.Google Scholar
Eveleth, Robert W., and Lueth, Virgil W.. 2009. Old Hansonburg, One of New Mexico's Forgotten Mining Camps. In Geology of the Chupadera Mesa, edited by Lueth, Virgil W., Lucas, Spencer G., and Chamberlin, Richard M., pp. 399406. New Mexico Geological Society 60th Annual Fall Field Conference Guidebook. New Mexico Geological Society, Socorro.10.56577/FFC-60.399CrossRefGoogle Scholar
Eveleth, Robert W., and Lueth, Virgil W.. 2010. Smithsonite from the Land of Enchantment: New Mexico, USA. In Smithsonite – Think Zinc!, MINERAL 13, edited by Hughes, Tom, Liebetrau, Suzanne, and Staebler, Gloria, pp. 7483. Lithographie, Denver, Colorado.Google Scholar
Ferguson, Jeffrey R. 2012. X-Ray Fluorescence of Obsidian: Approaches to Calibration and the Analysis of Small Samples. In Handheld XRF for Art and Archaeology, edited by Shugar, Aaron N. and Mass, Jennifer L., pp. 401422. Leuven University Press, Leuven, Belgium.Google Scholar
Flegal, A. Russell, and Smith, Donald R.. 1992. Lead Levels in Preindustrial Humans. New England Journal of Medicine 326(19):12931294.Google ScholarPubMed
Ford, Richard I. 1972. An Ecological Perspective on the Eastern Pueblos. In New Perspectives on the Pueblos, edited by Ortiz, Alfonso, pp. 118. School of American Research Advanced Seminar Series. University of New Mexico Press, Albuquerque.Google Scholar
Giomi, Evan. 2022. Exploring the Development and Persistence of the Eastern Puebloan Economy: Rio Grande Glaze Ware as a Window on Regional Interaction. PhD dissertation, School of Anthropology, University of Arizona, Tucson.Google Scholar
Glascock, Michael D., and Ferguson, Jeffrey R.. 2012. Report on the Analysis of Obsidian Source Samples by Multiple Analytical Methods. Report on file at the University of Missouri Research Reactor, Archaeometry Lab, University of Missouri, Columbia.Google Scholar
Habicht-Mauche, Judith A., and Eckert, Suzanne L.. 2021. Coalescence and the Spread of Glaze-Painted Pottery in the Central Rio Grande: The View from Tijeras Pueblo (LA581), New Mexico. American Antiquity 86(4):752772.10.1017/aaq.2021.60CrossRefGoogle Scholar
Habicht-Mauche, Judith A., Glenn, Stephen T., Milford, Homer, and Flegal, A. Russell. 2000. Isotopic Tracing of Prehistoric Rio Grande Glaze-Paint Production and Trade. Journal of Archaeological Science 27(8):709713.10.1006/jasc.1999.0495CrossRefGoogle Scholar
Habicht-Mauche, Judith A., Glenn, Stephen T., Schmidt, Mike P., Franks, Rob, Milford, Homer, and Russell Flegal, A.. 2002. Stable Lead Isotope Analysis of Rio Grande Glaze Paints and Ores Using ICP-MS: A Comparison of Acid Dissolution and Laser Ablation Techniques. Journal of Archaeological Science 29(9):10431053.10.1006/jasc.2001.0804CrossRefGoogle Scholar
Herhahn, Cynthia L. 1995. An Exploration of Technology Transfer in the Fourteenth Century Rio Grande Valley, New Mexico: A Compositional Analysis of Glaze Paints. Master's thesis, Department of Anthropology, Arizona State University, Tempe.Google Scholar
Herhahn, Cynthia, and Huntley, Deborah. 2017. Dynamic Knowledgescapes: Rio Grande and Salinas Glaze Ware Production and Exchange. In Landscapes of Social Transformation in the Salinas Province and the Eastern Pueblo World, edited by Spielmann, Katherine A., pp. 203238. University of Arizona Press, Tucson.10.2307/j.ctt1tp3c7x.13CrossRefGoogle Scholar
Hood, Darden. 2012. Radiocarbon Dating Results from Samples 2011LA2850058, 2011LA2850068, 2011LA2850079, 2011LA2850160. Letter report prepared for Suzanne L. Eckert, Department of Anthropology, Texas A&M University. Report on file at the Beta Analytic Testing Laboratory, Miami.Google Scholar
Hull, Sharon, Fayek, Mostafa, Joan Mathien, F., and Roberts, Heidi. 2014. Turquoise Trade of the Ancestral Puebloan: Chaco and Beyond. Journal of Archaeological Science 45:187195.10.1016/j.jas.2014.02.016CrossRefGoogle Scholar
Huntley, Deborah L. 2006. From Recipe to Identity: Exploring Zuni Glaze Ware Communities of Practice. In The Social Life of Pots: Glaze Wares and Cultural Dynamics in the Southwest, AD 1250–1680, edited by Habicht-Mauche, Judith A., Eckert, Suzanne L., and Huntley, Deborah L., pp. 105123. University of Arizona Press, Tucson.Google Scholar
Huntley, Deborah L. 2008. Ancestral Zuni Glaze-Decorated Pottery: Viewing Pueblo IV Regional Organization through Ceramic Production and Exchange. Anthropological Papers of the University of Arizona No. 72. University of Arizona Press, Tucson.Google Scholar
Huntley, Deborah L. 2016. Tracking Movement in the American Southwest. In Exploring Cause and Explanation: Historical Ecology, Demography, and Movement in the American Southwest, edited by Herhahn, Cynthia L. and Ramenofsky, Ann F., pp. 201212. University Press of Colorado, Boulder.10.5876/9781607324737.c012CrossRefGoogle Scholar
Huntley, Deborah L., Fenn, Thomas, Habicht-Mauche, Judith A., and Mills, Barbara J.. 2012. Embedded Networks? Pigments and Long-Distance Procurement Strategies in the Late Prehispanic Southwest. In Potters and Communities of Practice: Glaze Paint and Polychrome Pottery in the American Southwest, AD 1250 to 1700, edited by Cordell, Linda S. and Habicht-Mauche, Judith A., pp. 818. Anthropological Papers of the University of Arizona No. 75. University of Arizona Press, Tucson.Google Scholar
Huntley, Deborah L., Spielmann, Katherine A., Habicht-Mauche, Judith A., Herhahn, Cynthia L., and Russell Flegal, A.. 2007. Local Recipes or Distant Commodities? Lead Isotope and Chemical Compositional Analysis of Glaze Paints from the Salinas Pueblos, New Mexico. Journal of Archaeological Science 34(7):11351147.10.1016/j.jas.2006.10.006CrossRefGoogle Scholar
Ingold, Tim. 2000. The Perception of the Environment: Essays on Livelihood, Dwelling and Skill. Routledge, London.Google Scholar
Lasky, Samuel G. 1932. The Ore Deposits of Socorro County, New Mexico. New Mexico Bureau of Mines and Mineral Resources Bulletin 8. New Mexico Institute of Mining and Technology, Socorro.10.58799/B-8CrossRefGoogle Scholar
Lave, Jean, and Wenger, Etienne. 1991. Situated Learning: Legitimate Peripheral Participation. Cambridge University Press, Cambridge.10.1017/CBO9780511815355CrossRefGoogle Scholar
LeTourneau, Philippe D., Ferguson, Jeffrey R., and McLemore, Virginia. 2010. Alameda Spring, a Newly Characterized Obsidian Source in West-Central New Mexico. Outline and notes for paper presented at the 75th Annual Meeting of the Society for American Archaeology, St. Louis, Missouri.Google Scholar
MacCarthy, Marion S. 1918. The Property of the Western Mineral Products Company, Carthage, New Mexico. Unpublished private report on file, New Mexico Bureau of Geology and Mineral Resources Mining Archives, Socorro.Google Scholar
Marshall, Michael P., and Walt, Henry J.. 1984. Rio Abajo: Prehistory and History of a Rio Grande Province. New Mexico Historic Preservation Program, Santa Fe.Google Scholar
Mathien, Frances J. 2001. The Organization of Turquoise Production and Consumption by the Prehistoric Chacoans. American Antiquity 66(1):103118.10.2307/2694320CrossRefGoogle Scholar
Mattson, Hannah V. 2016. Ornaments as Socially Valuable Objects: Jewelry and Identity in the Chaco and Post-Chaco Worlds. Journal of Anthropological Archaeology 42:122139.10.1016/j.jaa.2016.04.001CrossRefGoogle Scholar
McBrinn, Maxine E., and Altshuler, Ross E.. 2015. Turquoise, Water, Sky: Meaning and Beauty in Southwest Native Arts. Museum of New Mexico Press, Santa Fe.Google Scholar
Mera, H. P. 1940. Population Changes in the Rio Grande Glaze-Paint Area. Technical Series Bulletin No. 9. Laboratory of Anthropology, Santa Fe, New Mexico.Google Scholar
Michelaki, Kostalena, Braun, Gregory V., and Hancock, Ronald G. V.. 2015. Local Clay Sources as Histories of Human–Landscape Interactions: A Ceramic Taskscape Perspective. Journal of Archaeological Method and Theory 22(3):783827.10.1007/s10816-014-9204-0CrossRefGoogle Scholar
Mills, Barbara J. 2007a. A Regional Perspective on Ceramics and Zuni Identity, AD 200–1630. In Zuni Origins: Toward a New Synthesis of Southwestern Archaeology, edited by Gregory, David A. and Wilcox, David R., pp. 210238. University of Arizona Press, Tucson.Google Scholar
Mills, Barbara J. 2007b. Performing the Feast: Visual Display and Suprahousehold Commensalism in the Puebloan Southwest. American Antiquity 72(2):210239.10.2307/40035812CrossRefGoogle Scholar
Mills, Barbara J., and Ferguson, T. J.. 1998. Preservation and Research of Sacred Sites by the Zuni Indian Tribe of New Mexico. Human Organization 57(1):3042.10.17730/humo.57.1.k22560377478330hCrossRefGoogle Scholar
Munson, Marit K. 2020a. Pigments and Paints in the Archaeological Record. In Color in the Ancestral Pueblo Southwest, edited by Munson, Marit K. and Hays-Gilpin, Kelley, pp. 2644. University of Utah Press, Salt Lake City.Google Scholar
Munson, Marit K. 2020b. Color in the Pueblo World. In Color in the Ancestral Pueblo Southwest, edited by Munson, Marit K. and Hays-Gilpin, Kelley, pp. 1325. University of Utah Press, Salt Lake City.Google Scholar
Nelson, Kit, and Habicht-Mauche, Judith A.. 2006. Lead, Paint, and Pots: Rio Grande Intercommunity Dynamics from a Glaze Ware Perspective. In The Social Life of Pots: Glaze Wares and Cultural Dynamics in the Southwest, AD 1250–1680, edited by Habicht-Mauche, Judith A., Eckert, Suzanne L., and Huntley, Deborah L., pp. 197215. University of Arizona Press, Tucson.Google Scholar
Phillips, David A. Jr., Franklin, Hayward H., Eckert, Suzanne L., and Ballagh, Jean H.. 2021. Revisiting the Hopi Area Connection at Pottery Mound, New Mexico. In A Friend of Kuaua: Papers in Honor of James Conder, edited by Brown, Emily J., Barbour, Matthew J., Boyer, Jeffrey L., and Head, Genevieve N., pp. 187202. Papers Vol. 47. Archaeological Society of New Mexico, Albuquerque.Google Scholar
Pohwat, Paul W. 2010. A Collector's Mineralogy of Smithsonite. In Smithsonite – Think Zinc!, MINERAL 13, edited by Hughes, Tom, Liebetrau, Suzanne, and Staebler, Gloria, pp. 415. Lithographie, Denver, Colorado.Google Scholar
Popelish, Linda A. 1990. Site Testing at Cantina Acres Roads and Damage Assessment of AR-03-03-02-488. Report No. 1990-03-078. Manuscript on file, Cibola National Forest and National Grasslands (Supervisors Office), Albuquerque, New Mexico.Google Scholar
Rye, Owen S. 1976. Keeping Your Temper under Control: Materials and the Manufacture of Papuan Pottery. Archaeology & Physical Anthropology in Oceania 11(2):106137.Google Scholar
Schaefer, Jonathan. 2020. Obsidian Procurement in the Gallinas Mountains of West Central New Mexico. Master's thesis, Department of Anthropology, University of Missouri, Columbia.Google Scholar
Shackley, M. Steven. 1998. Geochemical Differentiation and Prehistoric Procurement of Obsidian in the Mount Taylor Volcanic Field, Northwest New Mexico. Journal of Archaeological Science 25(11):10731082.10.1006/jasc.1998.0274CrossRefGoogle Scholar
Shackley, M. Steven. 2010. Source Provenance of Obsidian Small Debitage from the Water Canyon Paleoindian Site (LA 134764), Socorro County, New Mexico. Report prepared for Dr. Robert Dello-Russo, Office of Archaeological Studies, Museum of New Mexico, Santa Fe. Manuscript on file, Geoarchaeological XRF Laboratory, University of California, Berkeley.Google Scholar
Shackley, Michael S. 2021. Distribution and Sources of Secondary Deposit Archaeological Obsidian in Rio Grande Alluvium New Mexico, USA. Geoarchaeology 36(5):808825.10.1002/gea.21877CrossRefGoogle Scholar
Shariq, Syed Z. 1999. How Does Knowledge Transform as It Is Transferred? Speculations on the Possibility of a Cognitive Theory of Knowledgescapes. Journal of Knowledge Management 3(4):243251.10.1108/13673279910303998CrossRefGoogle Scholar
Sigleo, Anne C. 1975. Turquoise Mine and Artifact Correlation for Snaketown Site, Arizona. Science 189(4201):459460.10.1126/science.189.4201.459CrossRefGoogle ScholarPubMed
Snow, David H. 1981. Protohistoric Rio Grande Pueblo Economics: A Review of Trends. In The Protohistoric Period in the North American Southwest, A.D. 1450–1700, Anthropological Research Papers No. 24, edited by Wilcox, David R. and Bruce Masse, W., pp. 354377. Arizona State University, Tempe.Google Scholar
Spielmann, Katherine A. 1998. Ritual Influences on the Development of Rio Grande Glaze A Ceramics. In Migration and Reorganization: The Pueblo IV Period in the American Southwest, Anthropological Research Papers No. 51, edited by Spielmann, Katherine A., pp. 253261. Arizona State University, Tempe.Google Scholar
Stark, Miriam T. 2006. Glaze Ware Technology, the Social Lives of Pots, and Communities of Practice in the Late Prehistoric Southwest. In The Social Life of Pots: Glaze Wares and Cultural Dynamics in the Southwest, AD 1250–1680, edited by Habicht-Mauche, Judith A., Eckert, Suzanne L., and Huntley, Deborah L., pp. 1733. University of Arizona Press, Tucson.Google Scholar
Thibodeau, Alyson M., Habicht-Mauche, Judith A., Huntley, Deborah L., Chesley, John T., and Ruiz, Joaquin. 2013. High Precision Isotopic Analyses of Lead Ores from New Mexico by MC-ICP- MS: Implications for Tracing the Production and Exchange of Pueblo IV Glaze-Decorated Pottery. Journal of Archaeological Science 40(7):30673075.10.1016/j.jas.2013.02.034CrossRefGoogle Scholar
Thibodeau, Alyson M., Killick, David J., Hedquist, Saul L., Chesley, John T., and Ruiz, Joaquin. 2015. Isotopic Evidence for the Provenance of Turquoise in the Southwestern United States. Geological Society of America Bulletin 127(11–12):16171631.10.1130/B31135.1CrossRefGoogle Scholar
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Figure 1. Map of the Ancestral Pueblo world.

Figure 1

Figure 2. Goat Spring Pueblo. Photo taken from nearby ridge; view to the northeast. Photograph courtesy of Suzanne Eckert. (Color online)

Figure 2

Figure 3. Location of culturally significant geological resources discussed.

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Figure 4. 208Pb/204Pb isotope data plotted against 206Pb/204Pb from 40 glaze-paint samples on locally produced pottery recovered from Goat Spring Pueblo. (Color online)

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Figure 5. 207Pb/204Pb from 40 glaze-paint samples on locally produced pottery recovered from Goat Spring Pueblo. (Color online)

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Figure 6. XRF results for all 58 obsidian specimens recovered from Goat Spring Pueblo with ellipses representing composition of known sources. (Color online)

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Figure 7. XRF results for all 14 blue-green mineral specimens recovered from Goat Spring Pueblo. (Color online)