The Early Brown Ware Horizon

We identify three distinct periods associated with this shift to sedentary agriculture: a well-defined preceramic farming interval, called Basketmaker II; a less well-understood, somewhat later but overlapping interval, termed the Early Brown Ware Horizon (EBWH); and finally, Basketmaker III, with its wholesale adoption of the Neolithic package. Throughout the EBWH, farmers adopted components of the Neolithic package in a piecemeal fashion, yet retained a mosaic of subsistence strategies and cultural practices associated with high mobility (see Table S1 in the online supplementary material (OSM)).

Our research and a synthesis of earlier work suggests that the pace at which early farmers adopted specific components of the Neolithic package was contingent upon diverse local histories and traditions (Table S1). Securely dated AD 200–400 EBWH sites in the Puerco Valley and Navajo Mountain areas, for example, have produced early ceramic assemblages, but contemporaneous groups dwelling on Cedar Mesa to the north-east did not adopt ceramic technology (Figure 1). Moreover, unlike their ceramic-producing neighbours to the south, farmers occupying Cedar Mesa and nearby Grand Gulch raised domesticated turkeys—a practice that became common across the entire region only after AD 550 (Lipe et al. Reference Lipe2016). Even within early ceramic-producing areas, the adoption of ceramics and other new technologies was far from uniform (Geib Reference Geib2011: 280–84). Nevertheless, a general trajectory distinguishing EBWH sites from earlier and later settlements is apparent.

Figure 1. The northern US Southwest (figure by R.J. Sinensky).

Similar to many open-air Basketmaker II settlements, EBWH sites are characterised by unstructured layouts, shallow pit-houses, subterranean storage facilities and a lack of discrete refuse middens (Figure 2a). Unlike Basketmaker II settlements, EBWH sites often contain communal architecture, ceramics fired under poorly controlled conditions and other components of the Neolithic package (Figure 2b). Conversely, Basketmaker III sites usually have organised site layouts, discrete refuse middens, abundant, above-ground storage structures fronted by deep residential pit-houses, larger and more formal communal architecture, and contain ceramics produced using consistent paste recipes and controlled firing conditions (Figure 2c–d).

Figure 2. Neolithic Transition site layouts: a) Basketmaker II (400 BC–AD 400); b) Early Brown Ware Horizon (AD 250–550); c) Basketmaker III (AD 550–750); d) Basketmaker III communal architecture (figure by R.J. Sinensky).

Climate and agriculture

The temperate, yet arid, high-elevation Colorado Plateau presents risks for agriculture due to the moisture and temperature requirements of maize. Mean precipitation is greater and temperatures are cooler in the higher elevations of the northern US Southwest than in the lower elevation basin and range province to the south, and perennial water sources suitable for irrigation are rare. Most ancient farmers on the Colorado Plateau relied on direct rainfall, the moisture retaining capacity of soils and the diversion of runoff to supplement direct precipitation (Dominguez & Kolm Reference Dominguez and Kolm2005). Only upland areas above 2300m asl, which are seldom occupied by farmers, regularly receive insufficient accumulated heat during the summer growing season to produce a successful maize crop. Consequently, most recent studies of the relationship between regional demography and climate in the arid plateau Southwest have portrayed fluctuating precipitation as the key variable affecting farmers (e.g. Bocinsky & Kohler Reference Bocinsky and Kohler2014). Since precipitation increases along an elevation gradient in the northern Southwest, and moisture is the primary limiting factor for agriculture region-wide, high-elevation areas served as refugia during frequent droughts (Bocinsky & Kohler Reference Bocinsky and Kohler2014; Vierra & Carvalho Reference Vierra and Carvalho2019).

Crops, however, can fail even if they receive sufficient moisture and accumulated heat, if, for example, a field does not maintain an adequate number of consecutive frost-free days, or a single hard freeze terminates plant growth (Adams Reference Adams, Ingram and Hunt2015). Petersen (Reference Petersen, Petersen and Orcutt1987) argued that the demographic trajectories of well-watered, higher elevation areas were closely tied to fluctuating growing season lengths (also see Thomson et al. Reference Thomson, Balkovič, Kirsztin and MacDonald2019). Here, we posit that rare, extreme and prolonged cooling events would have adversely affected farmers across the Colorado Plateau due to shortened growing seasons, decreased accumulated heat and more frequent hard frosts. These periods would have required a unique response by farming communities, since high-elevation locations that served as refugia during more-frequent droughts were even more susceptible to crop failure caused by infrequent, extreme cooling events, such as those triggered by volcanic eruptions.

Volcanic events and extreme cold in the regional palaeoclimate record

Climate forcing from the eruptions of AD 536 and 541 is conspicuous in tree-ring chronologies across western North America (Salzer & Hughes Reference Salzer and Hughes2007; Salzer et al. Reference Salzer, Bunn, Graham and Hughes2014). Of importance to the current study, these effects are visible as frost-terminated growth rings in the temperature-sensitive San Francisco Peaks bristlecone pine chronology from northern Arizona (Table S2). We rely on the San Francisco Peaks chronology for temperature reconstruction (Salzer Reference Salzer2000) and the El Malpais chronology from western New Mexico for precipitation reconstruction (Grissino-Mayer Reference Grissino-Mayer1995), as these represent the highest-quality temperature- and precipitation-sensitive chronologies covering the period of interest (Van West & Grissino-Mayer Reference Van West, Grissino-Mayer, Huber and Van West2005; Stahle & Dean Reference Stahle, Dean, Hughes, Swetnam and Diaz2011: 321). They are also located close to the southern plateau—an area that hosted a dense, contemporaneous EBWH population (Figure 1). Van West & Grissino-Mayer (Reference Van West, Grissino-Mayer, Huber and Van West2005) converted the standardised mean annual temperature and precipitation departures from these respective chronologies to z-scores, which represent standard deviations from the 2100-year mean. A value of 0 is equivalent to the mean, while a value of +1 or −1 represents one standard deviation above or below the mean. We also present growing degree-day reconstructions, an agronomy term shorthand for the total amount of accumulated heat units necessary for a plant to reach maturity. Our growing degree-day reconstruction uses methods developed by Bocinsky et al. (Reference Bocinsky, Rush, Kintigh and Kohler2016), which draw on numerous regional tree-ring chronologies (for accessible web-based modelling tools, see https://www.openskope.org).

The AD 536 and 541 eruptions are associated with one of the most significant cold periods on record in the San Francisco Peaks chronology. Salzer (Reference Salzer2000) designates AD 534–553 as the sixth coldest interval, while Van West & Grissino-Mayer (Reference Van West, Grissino-Mayer, Huber and Van West2005) describe a seven-year cold and dry interval spanning AD 538–545 as the single coldest. Regardless, for 15 consecutive years (AD 538–553), temperature indices were over one standard deviation below the 2100-year mean—a pattern that does not occur at any other point in the San Francisco Peaks chronology (Figure 3). Moreover, nine of the 20 years with the lowest accumulated heat units on record since AD 1 occurred between AD 536–553. Temperatures finally rebounded in AD 555, but this was immediately followed by a 14-year drought between AD 556 and 569. Some 30 years later—only a single generation removed from these extreme events—the Colorado Plateau experienced four decades of the most productive and stable conditions for agriculture on record (AD 584–625). Both the extreme cold that followed the eruptions and the subsequent stable, warm and wet interval must have had important consequences for farming groups. The question is whether the effects of these events are visible in the archaeological tree-ring and radiocarbon records.

Figure 3. Temperature and precipitation reconstructions fitted with LOESS smoothed regression lines and 95% confidence intervals (span = 0.05). Numbered years indicate frost-terminated growth rings and black circles represent the timing and intensity of volcanic forcing (see Table S2) (figure by R.J. Sinensky).

Archaeological chronologies

Baillie (Reference Baillie1994: 214) appears to be the first to argue that the fallout of sixth-century climate forcing was visible in the archaeological dendrochronology record of the US Southwest. Here, we explore whether this remains the case, with an expanded dataset that includes 4886 outer-ring dates from the Colorado Plateau that fall between AD 200 and 800 (Figure 4). Of these, 1274 are cutting dates (indicative of the year a tree died) and 429 are near-cutting dates, to within one or two years of the true final cutting date (Speer Reference Speer2010: 163). We expect the count and density of cutting and near-cutting dates to correlate with shifting demography and agricultural productivity (Bocinsky et al. Reference Bocinsky, Rush, Kintigh and Kohler2016).

Figure 4. Tree-ring dates from the Colorado Plateau, AD 200–800. Histogram bins represent five-year intervals (figure by R.J. Sinensky).

The earliest spike in construction activity evident from the archaeological tree-ring dates (AD 460–488) occurred in a limited number of high-elevation areas and locations with access to perennial water on the Colorado Plateau, at the end of a prolonged drought (AD 419–488). During a favourable interval that followed (AD 489–525), migrants from drought refugia introduced core components of the Neolithic package to vast expanses of the Colorado Plateau (Windes Reference Windes2018; Vierra & Carvalho Reference Vierra and Carvalho2019: 212; Figure S1). Although precipitation varied during this early spike in construction, temperatures remained consistent from AD 468–521 (Salzer Reference Salzer2000: 76), enabling demographic expansion into new regions. The overall density of dates begins a precipitous decline during a short, warm, dry period (AD 526–532), and reaches its lowest point during the initial, intensely cold and dry portion of the anomaly (AD 538–545), for which no cutting dates have been recovered (Table S3). Date density remains low during the cold and wet portion of the anomaly (AD 546–553), throughout a period of drought (AD 556–569) and during a wet, cool period (AD 570–583), before the number of cutting dates increases over tenfold during the stable wet, warm interval (AD 584–629).

The combined archaeological tree-ring data offer considerable evidence for the influence of the anomaly, as it coincides with the most pronounced decline in construction and the lowest density of cutting dates. Radiocarbon data also must be examined to provide coverage in lower elevation areas that less frequently produce wood suitable for tree-ring dating, and during earlier periods when it was less common for Ancestral Pueblo peoples to build with substantial timbers conducive to tree-ring dating.

We compiled a database of 682 radiocarbon dates from the northern US Southwest with calibrated, unmodelled medians (calibrated using IntCal20 (Reimer et al. Reference Reimer2020)) falling between AD 200 and 800—a range well before and after the climate event of interest. To visualise varying radiocarbon measurement density, yet minimise bias introduced by the calibration curve, we present a kernel density estimation (KDE) model that incorporates 648 measurements from 230 archaeological sites, with measurement errors of ±100 radiocarbon years or fewer, and a second model that only includes a subset of 334 dates derived from higher-quality materials (Figure 5 & Figures S2–3). We believe that such models are appropriate, as they offer independent lines of evidence for comparison with the trends noted in the higher resolution tree-ring data.

Figure 5. KDE_model-derived radiocarbon probability densities (Bronk Ramsey Reference Bronk Ramsey2017) displayed with the temperature and precipitation indices presented in Figure 3 (for additional model details, see Figures S2 & S3) (figure by R.J. Sinensky).

Our models display comparable patterns to the tree-ring dates. These comprise increasing radiocarbon measurement density during the late fifth and early sixth centuries, followed by a sharp decrease associated with the climate anomaly, and a sustained increase during the late sixth and early seventh centuries. Similar to the tree-ring dates, the minimum radiocarbon density corresponds with the peak effects of volcanic climate forcing, whereas the initial decline begins prior to the peak effects. Although the end of a plateau in the radiocarbon curve (c. AD 445–525) potentially influences the apparent timing of the declining radiocarbon density, close agreement between the modelled radiocarbon data and tree-ring cutting dates strongly suggests that this plateau is not solely responsible (Figure 6). Given these results, we now explore the timing and tempo of the phase transition that ultimately led to the widespread adoption of the Neolithic package and the transformation of Ancestral Pueblo societies.

Figure 6. Densities of tree-ring cutting and radiocarbon dates using modelled ¹⁴C medians as point estimates (figure by R.J. Sinensky).

Disentangling the chronology of the sixth century

As groups adopted the Neolithic package in a piecemeal fashion, it is important to consider the potential temporal overlap between the EBWH and the Basketmaker II and III periods. Archaeologists have previously argued that the EBWH overlaps with the earlier Basketmaker II (Geib Reference Geib2011) and later Basketmaker III periods (e.g. Wilson & Blinman Reference Wilson and Blinman1994; Reed et al. Reference Reed, Wilson, Hays-Gilpin and Reed2000). An overlapping phase Bayesian model (Bronk Ramsey Reference Bronk Ramsey2009: 348) reveals differences between phase transitions, with up to 65 years of overlap between the end of Basketmaker II and the onset of the EBWH, yet a gap spanning 33–87 years between the end of the EBWH and start of Basketmaker III (Figure 7 & Figure S4). Moreover, the model strongly suggests that the end of the EBWH coincided with the climate anomaly (AD 522–545 [68.3%]; AD 506–555 [95.4%]), while the socio-economic and demographic changes associated with the Basketmaker III period are not evident until the climate improved. This interpretation is corroborated by the tree-ring data discussed previously.

Figure 7. An overlapping phase Bayesian model that includes 402 radiocarbon measurements derived from annual plants, textiles and bone (for further discussion, see Figure S4): a) start and end boundaries for select phases; b) probability distributions for the span of phase transitions (dates calibrated and modelled using OxCal v4.4.2 and the IntCal20 atmospheric curve (Bronk Ramsey Reference Bronk Ramsey2020; Reimer et al. Reference Reimer2020)) (figure by R.J. Sinensky).

We find the gap between the EBWH and Basketmaker III to be particularly significant, as it matches patterns that we have noted on the southern plateau, in which long-lived ceramic traditions and architectural styles used throughout the EBWH were abruptly disused and do not appear subsequently alongside material culture or architecture typical of the Basketmaker III period. This break is also evident in the dendrochronological record of numerous regions of the Colorado Plateau with well-documented Basketmaker II and Basketmaker III occupations (Reed Reference Reed2000; Wilshusen et al. Reference Wilshusen, Schachner and Allison2012; Young & Herr Reference Young and Herr2012; see also Figure S5). This suggests that the disruption caused by extreme cooling could not be alleviated with farmers’ existing risk-mitigation strategies.

Mobility and risk

In small-scale farming societies, strong social ties between groups living in different environmental zones help to minimise risk (Rautman Reference Rautman1993; Borck et al. Reference Borck, Mills, Peeples and Clark2015). During periods of acute environmental disturbance or social strife, these ties also facilitate population movements that can last for several months, or even decades (Waddell Reference Waddell1975). Ephemeral residential architecture, unstructured site layouts and a lack of dedicated storage facilities during the EBWH suggest that residential moves were frequent and anticipated, and therefore probably occurred within well-developed social networks. Insufficient growing-season moisture is the most common variable affecting interannual crop yields on the Colorado Plateau. Consequently, social networks connected groups living in low-elevation areas with high-elevation drought refugia. Such locations were particularly important to farmers during the EBWH, due to long and persistent droughts between AD 290 and 488 (Figure 3). Archaeological evidence from sites of this era suggests that farmers moved between high- and low-elevation locations as necessary; such movements formed a flexible, yet stable settlement system (Burton Reference Burton2007; Rogge et al. Reference Rogge and Herr2016; cf. Vierra & Carvalho Reference Vierra and Carvalho2019: 212). In contrast, the extreme cooling brought on by the sixth century eruptions—and particularly the initial cold and dry interval of the anomaly (AD 538–545)—could not be addressed by drought-resilient strategies, since high-elevation refugia were even more susceptible to crop failure caused by extreme cooling. Indeed, growing degree-day reconstructions show that high-elevation areas across the Colorado Plateau and regions immediately to the south fell below critical thresholds for successful maize agriculture, affecting regions well beyond the social networks of EBWH farmers (Figure 8 & Figure S6).

Figure 8. AD 200–800 May–September growing degree-day reconstructions fitted with LOESS smoothed regression lines (span = 0.05): a) annual reconstructions for regions of the Colorado Plateau. Note that the western plateau encompasses arid and lower elevation areas unsuitable for rain-fed agriculture, and including these areas inflates the plateau-wide reconstruction (displayed in black); b) annual reconstructions for select high-elevation drought refugia (figure by R.J. Sinensky).

Given the close correspondence between the climate anomaly and the hiatus evident in the radiocarbon and dendrochronological data (Figure 9), we conclude that the suddenness, severity and length of mid sixth-century extreme cooling triggered large-scale population movements beyond the limits of established social networks, along with significant population decline among groups that remained on the Colorado Plateau. Diverse populations across this region were uniformly affected. Prior to the anomaly, farmers on the southern plateau had rapidly adopted ceramic technology and built larger settlements with greater population densities compared with regions to the north (Table S4); during and after the anomaly, abrupt changes in pottery traditions, architecture and settlement patterns occurred. More sparsely populated areas that did not exhibit similar sharp changes in material culture were still affected, as occupational gaps and unexpected disruptions to previously stable settlement patterns occurred (Hovezak & Sesler Reference Hovezak and Sesler2006; Geib Reference Geib2011).

Figure 9. Temporal correspondence between sixth-century extreme cooling and chronometric data. The dashed red line represents the end of the extreme cold and dry interval (AD 545): a) growing degree-day reconstruction; b) cutting and near-cutting tree-ring date density; c) modelled radiocarbon density (figure by R.J. Sinensky).