Canals versus Natural Channels

Historical sciences like geology and archaeology face the challenge of convergence or equifinality whereby different processes can produce similar if not identical phenomena (Glazner et al. Reference Glazner, Baker, Bartley, Bohacs and Coleman2022; Schumm Reference Schumm1991). For example, human and natural processes can produce similar material evidence such as modified stones or burned layers (e.g., Goldberg et al. Reference Goldberg, Steve Weiner, Bar-Yosef, Xu and Liu2001; Peacock Reference Peacock1991). This phenomenon also occurs in the study of canals. Early riverine canals in the Southwest were constructed of earth and used to divert water from its natural flow path in river floodplains. Each canal comprised a system with an intake at the water source, a delivery component comprising divergent channels, and a destination where the water was used, such as fields (Kelly Reference Kelly1983; Nials Reference Nials and Vint2015a). With use, canals filled with sediment and were later buried by alluvium; they are thus analogous to alluvial channels, which are formed naturally into preexisting alluvium. Both human-constructed and natural channels are subject to physical laws of flow dynamics, stream energy, and sediment transport, and both have the ability to adjust channel geometry to best accommodate flow and sediment discharge (Leopold and Maddock Reference Leopold and Maddock1953:43). Whereas initial canal channel cross sections formed by human excavation may be rectangular, trapezoidal, triangular, parabolic, or of intermediate shapes, canals and alluvial channels transecting unconsolidated materials tend to develop parabolic shapes through time via scour of the channel perimeter. Once filled with sediment and buried, both are defined stratigraphically by cut-and-fill unconformities that outline the former channel and contain waterlain deposits subject to postdepositional disturbances such as soil formation.

Canals and natural stream channels also display important differences. Stream channels develop naturally on terrestrial surfaces to efficiently convey runoff and sediment downslope, whereas canals are constructed by humans to divert water toward areas where it would otherwise not flow. In the absence of obstructions, natural streams follow maximum slope and develop channel dimensions that accommodate a wide range of discharge, often involving significant channel depths. Because gradient and flow depth strongly influence water velocity and total energy, natural streams have greater competence—the ability to transport large clasts—and greater overall sediment transport potential (Ackers Reference Ackers and Novak1983). Provided there are a wide variety of available grain sizes for transport, gravels and larger clasts are more likely to be present in natural channels, which tend to support higher water velocities than canals. When gravels are present in canals, it often implies uncontrolled flooding. Higher energy potential in natural alluvial channels allows for greater bank scour and channel mobility. As a result, natural channel width:depth ratios tend to be high, especially in coarse-textured floodplains (Leopold et al. Reference Leopold, Gordon Wolman and Miller1964:198–202), whereas lower water velocities and scour potential in canals result in channel cross sections with relatively low width:depth ratios. Higher channel mobility in natural streams also results in greater sinuosity, whereas canals tend to have straight or arcuate alignments.

Other differences between canals and natural streams relate to channel network structure. With some exceptions such as deltas and alluvial fans, most natural stream networks are convergent: tributaries supply channels that increase downstream in cross-sectional area to accommodate larger flows. In contrast, irrigation canals are distributive systems where channel capacity decreases downstream as water is lost to infiltration and diverted from the main channel to branching channels and fields. This in turn affects the types of sediments observed within canals. As discharge and velocity decrease downstream, so does the canal's ability to transport sediment, resulting in an overall downstream decrease in alluvial grain size. In contrast, downstream changes in alluvial grain size can be much more variable in natural fluvial systems due to increasing peak discharge and stream competence potential.

With respect to channel patterns, natural braided and distributary streams commonly support divergent channels in a similar way to canal systems. However, natural stream channels diverge at bifurcation angles of less than 90°. In contrast, canals may support branching channels that are aligned perpendicular to each other, resulting in rectangular channel patterns that are unlikely to occur naturally. This becomes an important line of evidence in the identification of buried agricultural fields.

In sum, canals and alluvial channels are intrinsically different at a system scale and as such can be distinguished more easily when traced across the landscape. However, early canals are likely to be buried in floodplains—often deeply—and to be revealed at single localities through erosion or artificial excavations, precluding the ability to trace them downstream. When limited to only one or a few exposed channel cross sections, determination of natural versus human construction can be difficult. Because deep channels with multimeter dimensions make human construction unlikely, the challenge lies in distinguishing smaller natural channels and canals at a single location. Indeed, cross sections of small natural stream channels may look like canals, especially in fine-grained floodplains (e.g., Figure 2). Similarly, buried canals may be misidentified as natural channels, especially when the former were affected by uncontrolled flooding that scoured the channel perimeter and deposited coarse sediments.

Figure 2. Example showing stratigraphic similarities between canals and natural channels: (A) Natural channels in the Santa Cruz River floodplain, Tucson (Huckleberry Reference Huckleberry, Vint and Lindeman2022a); (B) Hohokam canal alignment within Salt River floodplain (Phoenix) containing multiple inset parabolic channels (Anderson et al. Reference Anderson, Huckleberry, Nials and Greenwald1994).

In the end it may not be possible to unequivocally assign human agency to a buried channel feature. Instead, one can provide different lines of archaeological, geomorphic, and stratigraphic evidence to make a case for or against human construction. Three case studies are presented next from a fine-grained river floodplain in which multiple generations of canal systems have been confirmed through extensive archaeological investigations. Different lines of evidence are used to support interpretations of human construction of three small alluvial channels that likely represent some of the earliest canals in the Southwest. The approaches described here are offered as a template for identifying similar evidence in other floodplains.

Three Case Studies

Evidence of early canal irrigation agriculture is common within the Santa Cruz River floodplain of southern Arizona's Tucson Basin (Figure 1). Historically, the watercourse supported alternating perennial and ephemeral reaches within an alluvial floodplain containing fertile soils and rich riparian ecosystems (Seymour Reference Seymour2020; Webb et al. Reference Webb, Betancourt, Roy Johnson and Turner2014). Prior to historic groundwater pumping, perennial reaches occurred in areas of shallow bedrock, such as at Martinez Hill and Sentinel Peak, where lateral groundwater flow was deflected toward the surface, and at the mouths of large tributaries such as Rillito Creek and the Cañada del Oro (Nials et al. Reference Nials, Gregory and Brett Hill2011). In the Tucson area, the Santa Cruz River floodplain contains a >5 m sequence of fine-grained alluvium formed through overbank flooding and sedimentation over the past approximately 5,000 years that preserves cultural deposits dating as early as the Middle Archaic (Gregory Reference Gregory1999; Huckell et al. Reference Huckell, Birkmann and Haynes2021; Table 1). Hundreds of canal segments dating from the Early Agricultural to the Historic era have been identified within the floodplain in association with agricultural settlements (Huckleberry Reference Huckleberry, Lindeman and Wöcherl2009, Reference Huckleberry, Griset, Jerome Hesse, Rawson and Barr2018b; Nials Reference Nials and Mabry2008, Reference Nials and Vint2015a).

Table 1. Tucson Basin Cultural Chronology.

Sources: Lindeman and Wallace Reference Lindeman and Wallace2004; Vint Reference Vint and Vierra2018.

Confirmed ancient canals in the Santa Cruz River floodplain tend to have parabolic cross sections with width:depth ratios less than 5 (Figure 3). Channel deposits are usually stratified with boundaries that roughly conform to the channel shape. Evidence of canal berms may or may not be preserved (e.g., Whitney Reference Whitney2023:Figure 4.11) or visible because the upper stratigraphy is commonly bioturbated. Where preserved, berms may contain poorly sorted sediments that represent clean-out deposits associated with canal maintenance (Nials Reference Nials and Mabry2008). Santa Cruz River canals demonstrate an overall increase in cross-sectional area through time (Figure 3), indicating increased flow capacity in response to the growing population and food demand (Mabry et al. Reference Mabry, Holmlund, Nials, Palacios-Fest and Mabry2008). Canal channel fills contain mainly fine sand, silt, and clay, reflecting low-energy streamflow during canal use and subsequent post-use sedimentation from slopewash. Some canals contain coarse sandy deposits, with rip-up clasts of silt and clay suggesting uncontrolled flooding. Although also found in natural stream channels, canals commonly contain orange (iron) and black (manganese) reduction-oxidation (redox) mottles along the base of the channel (see Figure 2B for an example in a Hohokam canal), a product of past wetting and drying. Artifacts such as fire-cracked rock and flaked stone may be present within the channel fill but are usually rare. Fluvially redeposited pieces of fine (less than 4 mm diameter) charcoal are also common in canal fill, possibly reflecting the dumping of trash or burning of weeds as part of channel maintenance.

Figure 3. Time series of San Pedro, Cienega, Hohokam, and Silverbell canal cross sections documented along the Santa Cruz River in the Tucson area. Primary sources: Clearwater (Klimas et al. Reference Klimas, Williams, Homer Thiel, Thiel and Mabry2006); Las Capas (Huckleberry Reference Huckleberry and Bryce2022b; Mabry et al. Reference Mabry, Holmlund, Nials, Palacios-Fest and Mabry2008); Parque de Santa Cruz (Huckleberry Reference Huckleberry, Lindeman and Wöcherl2009); Rillito Fan (Huckleberry and Rittenour Reference Huckleberry and Rittenour2014); Valencia Road (Huckleberry and Lindeman Reference Huckleberry and Lindeman2016). Layout adapted from Mabry and colleagues (Reference Mabry, Holmlund, Nials, Palacios-Fest and Mabry2008:Figure 10.3).

Dozens of archaeological excavations within the Santa Cruz River floodplain over the past 30 years have resulted in one of the most robust alluvial chronologies in the Southwest: it is anchored by more than 400 ¹⁴C dates (Ballenger and Mabry Reference Ballenger and Mabry2011; Waters and Haynes Reference Waters and Haynes2001). These dates have helped identify early canals by focusing on age-appropriate deposits. Hundreds of canals dating to the Early Agricultural period have been identified, of which there are currently three candidates for the earliest constructions. All three are located in formerly perennial reaches of the Santa Cruz River: the Clearwater site, or AZ BB:13:6(ASM); the Rillito Fan site, or AZ AA:12:788(ASM); and the Las Capas site, or AZ AA:12:111(ASM; Figure 1).

Clearwater Site

AZ BB:13:6(ASM) is located at the base of Sentinel Peak (Figure 1) near downtown Tucson and contains buried canals ranging in age from Early Agricultural to Historic (Thiel and Mabry Reference Thiel and Mabry2006). Canal preservation/visibility is variable, with some features limited to single exposures and others traceable over several tens of meters through excavation. One of the canals, Feature 152, contains a small channel approximately 1.3 m below the modern surface and 400 m west of the modern Santa Cruz River channel. The canal was traced approximately 30 m through a combination of backhoe trenching and horizontal stripping (Klimas et al. Reference Klimas, Williams, Homer Thiel, Thiel and Mabry2006). The canal's northeastern alignment is straight and displays a uniform channel width and cross-sectional area of approximately 0.3 m² (Figures 4 and 5). Channel fill consists of stratified fine sand and silt (Supplemental Table 1) inset into a natural floodplain stratum dated by two nearby pit features, which provide a correlated age for the canal (Mabry Reference Mabry, Thiel and Mabry2006). Roasting pit Feature 572 contained mesquite charcoal dated 3280 ± 40 ¹⁴C yr BP or a 2σ calibrated age of 1628–1446 BC (p = 1.000; Table 2). Pit feature 630 contained unidentified annual plant remains that dated to 3220 ± 40 ¹⁴C yr BP or a 2σ calibrated age of 1544–1413 BC (p = 0.968). The calibrated median probability ages for features 572 and 630 are 1550 BC and 1480 BC, respectively.

Figure 4. Map showing location of Feature 151 in relation to younger canals in the western part of the Congress Street Locus at AZ BB:13:481 (adapted from Klimas et al. Reference Klimas, Williams, Homer Thiel, Thiel and Mabry2006:Figure 4.97).

Figure 5. Stratigraphic profiles of case study canals at the Clearwater (Klimas et al. Reference Klimas, Williams, Homer Thiel, Thiel and Mabry2006), Rillito Fan (Huckleberry Reference Huckleberry, Griset, Jerome Hesse, Rawson and Barr2018a), and Las Capas (Huckleberry Reference Huckleberry and Bryce2022b) sites. See Supplemental Table 1 for stratigraphic descriptions.

Table 2. Radiocarbon Ages and Context.

^a Calibrated with Calib v. 8.2 and IntCal20 database (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Ramsey and Butzin2020).

Rillito Fan

AZ AA:12:788(ASM) is located immediately upstream of the Rillito Creek and Santa Cruz River confluence (Figure 1) where the former has constructed a large tributary alluvial fan. Excavations resulted in the identification of several Early Agricultural canals and fields, some with preserved human footprints (Griset et al. Reference Griset, Jerome S, Hesse and Barr2018). Feature 49 is a small parabolic channel identified approximately 3.0 m below the modern surface in a single deep stratigraphic excavation, approximately 150 m east of the modern river channel (Huckleberry Reference Huckleberry, Griset, Jerome Hesse, Rawson and Barr2018b; Figures 5 and 6). The channel has a cross-sectional area of approximately 0.3 m² with a sandy fill containing subangular silt intraclasts suggestive of an uncontrolled flood. Due to the channel's deep burial and project area constraints, it was not feasible to trace the channel downslope to the north or northwest.

Figure 6. Oblique photograph of Feature 49 exposed through excavation at the Rillito Fan site (photograph by Gary Huckleberry).

With only a single exposure, it is difficult to determine whether Feature 49 is a canal or natural channel. However, sand mineralogy within Feature 49 contrasts with that of the surrounding matrix comprising the Rillito tributary fan. Whereas the site comprises Rillito Creek alluvium dominated by quartz and feldspar derived from granites within its catchment, sands within Feature 49 are mineralogically diverse with abundant volcanic fragments, a mineral assemblage consistent with the Santa Cruz River (Miksa Reference Miksa and Mabry2008). Thus, Feature 49 conveyed Santa Cruz River water onto the Rillito Creek fan, an alignment that deviates from the natural slope. A concentration of detrital charcoal fragments within Feature 49 yielded an age of 3230 ± 30 ¹⁴C yr BP or a 2σ calibrated age of 1539–1425 BC (p = 0.997; Table 2) and a calibrated median age of 1485 BC. Because the charcoal is detrital in a secondary context, there is the potential for fluvial reworking resulting in a measured age that predates deposition within the canal (Huckleberry and Rittenour Reference Huckleberry and Rittenour2014). However, the alluvial sequence at the Rillito Fan site is well dated with ¹⁴C ages from firm stratigraphic contexts, allowing for the construction of an age-depth model that suggests that the Feature 49 charcoal age is consistent with the floodplain depth (Huckleberry Reference Huckleberry, Griset, Jerome Hesse, Rawson and Barr2018b).

Identifying Buried Agricultural Fields

As a general rule, smaller canals such as field laterals are more difficult to see stratigraphically because they tend to have less distinct boundaries and so blend into the surrounding sedimentary matrix. Thus, buried canals located near the intakes and distal ends of a canal system are easier and difficult to identify, respectively. For decades, archaeologists working in alluvial floodplains in Arizona were unable to identify buried prehistoric field lateral canals using conventional backhoe trenching. Given that field laterals help define the size and location of agricultural fields, a critical part of prehistoric canal systems remained poorly defined. Based on archaeological and ethnographic evidence (Doolittle Reference Doolittle2000; Masse Reference Masse, Crown and Judge1991; Nials and Gregory Reference Nials, Gregory, Gregory, Deaver, Fish, Gardiner, Layhe, Nials and Teague1989), Indigenous canal-fed and flood-irrigated fields clearly vary in size, shape, or form due to local environmental and cultural factors. Nevertheless, the expectation is that those constructed in fine-grained alluvial floodplains are likely to consist of shallow basins bordered by low earth mounds to help regulate the flow of water. If so, how might such agricultural infrastructure appear stratigraphically?

In the early 2000s, archaeologists investigating Early Agricultural sites in the Santa Cruz River floodplain increasingly incorporated mechanical horizontal stripping in site excavations where backhoes carefully removed thin (<5 cm) layers of sediment resulting in large (e.g., >500 m²) plan view exposures of buried floodplain surfaces. At the Las Capas site, such excavations conducted by skilled backhoe operators revealed geometric soil patterns caused by slight differences in sedimentary texture and moisture content. This patterning, often in the form of perpendicular lineations and irregular polygons, occurred in multiple stratigraphic levels containing nearby San Pedro phase main and distribution canals. When seen outside periglacial environments, such patterned ground is unlikely to have a natural explanation. Lineations representing natural channels are common in floodplains, but they do not bifurcate at right angles. As more areas were exposed, it became clear that these geometric soil patterns represented field lateral canals and gridded agricultural fields (Herr Reference Herr2009; Figure 7A).

Figure 7. (A) Bordered agricultural fields at Las Capas (adapted from Nials Reference Nials and Vint2015a:Figure 11.7); (B) schematic cross section showing construction of canal field lateral and field berm (adapted from Huckleberry Reference Huckleberry, Griset, Jerome Hesse, Rawson and Barr2018b:Figure 15.3); (C) photo of planting hole in profile (Brack and Ruble Reference Brack, Ruble and Brack2013:Figure 2.3; photo reproduced by permission of Desert Archaeology, Inc.).

More than 1,000 discrete agricultural field cells dating to the Early Agricultural period have been identified at Las Capas (Nials Reference Nials and Vint2015a, Reference Nials2015b). Individual cells consist of shallow basins, most ranging from 10 to 30 m² in area, that are bordered by low earth berms that were formed through shallow excavation on either side of the intended berm location and piling of sediment (Figure 7B). A similar excavation procedure was used to construct field lateral canals: sediment was piled into berms producing a slightly elevated channel. In places the berms also served as field borders. Field shapes vary depending on local slope, topography, and canal system layout. Water was applied from either side of the field lateral by breaching the berms and then refilling with mud to close. Similar breaks in field borders were used to direct water downslope between cells. Natural floods often penetrated the systems and inundated these fields, depositing layers of sediment across fields and their borders. Individual canal systems at Las Capas were rebuilt multiple times with shifting canals and field borders within an aggrading floodplain that spanned several human generations.

In cross section, this agricultural infrastructure commonly appears as thinly layered alluvial deposits with wavy boundaries (Figure 8), a stratigraphic sequence that could easily be produced through natural fluvial processes. As noted by Nials (Reference Nials and Vint2015a:444), field laterals and borders were generally not visible in backhoe trench profiles and required plan view exposures to be identified. Field lateral canals exposed in cross section display broad and shallow parabolic channel shapes with deposits that are commonly bioturbated, as evidenced by root and insect channels and gradual stratigraphic boundaries. Other stratigraphic features identified within fields include small circular pits interpreted as planting holes for seeding. Previously identified elsewhere in the Santa Cruz River floodplain (Brack and Ruble Reference Brack, Ruble and Brack2013), these features generally range from 10 to 50 cm in diameter, extend more than 30 cm deep, and have conical to basinal shapes (Figure 7C). In cross section, planting holes commonly contain poorly sorted sediments suggestive of the manual removal of plants, including rootstocks, and infilling with disturbed soil. Although natural biotic processes may create similar stratigraphic features in floodplain deposits, the systematic layout, density, and stratigraphic context of these pits in relation to field laterals and borders strongly support an interpretation of intentional human activities related to cultivation.

Figure 8. Stratigraphic exposure of San Pedro phase agricultural field at the Las Capas site (photograph by Gary Huckleberry).

Buried agricultural fields at Las Capas have served as a template for subsequent canal investigations elsewhere in the region. Since these discoveries, similar excavation strategies have been successfully used to identify buried prehistoric agricultural fields and field laterals at other sites in the Santa Cruz River floodplain (Griset et al. Reference Griset, Jerome S, Hesse and Barr2018) and along the lower Salt River in Phoenix (Schaafsma Reference Schaafsma and Henderson2015), providing a more holistic picture of prehistoric canal system construction and operation.

Summary and Conclusions

The ability to capture, divert, and store water had important social and environmental consequences that helped shape human history. Early human interventions in surface hydrology mainly involved canal building in support of agriculture. In the desert Southwest, supplemental water was essential for successfully growing the primary crop, maize. However, the impact of early irrigation farming on regional subsistence, sedentism, demography, and social organization remains poorly understood. Identifying the earliest canals and understanding how they functioned are hindered by the fact that they tend to be found in geomorphically dynamic settings prone to erosion and burial. If preserved, they are likely to have low archaeological visibility. Early Indigenous canals are commonly buried in floodplains and can be difficult to distinguish from natural fluvial features. At present, three small alluvial channels identified within the Santa Cruz River floodplain of southern Arizona, interpreted as probable canals and dated 1600–1400 BC, represent some of the earliest evidence of water management (excluding wells) in the Southwest. Consisting of small parabolic earth channels, these canals had limited discharge capacities and were built primarily to support maize irrigation for household groups who mixed farming with foraging. Through time, canal systems increased in size, supporting larger irrigation communities that required higher levels of social organization for coordinating canal construction, maintenance, and water allocation.

Early canal systems in the Santa Cruz River floodplain confirm that Indigenous knowledge of hydrology and hydraulic engineering extends more than 2,000 years before construction of the large, monumental canal earthworks associated with the Hohokam. Hydraulically sophisticated channel networks constructed during the Early Agricultural period served as a template for subsequent larger canal systems. Evidence of second millennium BC canal irrigation in the US-Mexico Borderlands is consistent with the notion that the technology originated locally through a process of experimentation with surface runoff, but this hypothesis requires further testing. Much of the Southwest and areas farther south in Mexico remain unsampled. More research is needed to refine our understanding of when and where canal irrigation began in the Americas and subsequently expanded in support of food production. Such evidence is likely to be differentially preserved in Southwest floodplains due to a period of widespread erosion that overlaps with early maize cultivation. Alluvial floodplains with middle-to-late Holocene fine-grained deposits are most likely to preserve evidence of early irrigation infrastructure. Identification of such features will be favored by an understanding of local geomorphology, hydrology, and multiple lines of evidence consistent with human construction. Identification of buried agricultural fields will also be facilitated by mechanical excavations that provide plan view exposures of former floodplain surfaces. Determining the age and geography of early canal systems will in turn provide clarity and context to the many sociocultural and environmental changes associated with agricultural intensification in the Southwest and beyond.