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Late Holocene Climate and Cultural Changes in the Southwestern United States

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Science  05 Oct 2001:
Vol. 294, Issue 5540, pp. 148-151
DOI: 10.1126/science.1062771

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Abstract

Columnar stalagmites in caves of the Guadalupe Mountains during the late Holocene record a 4000-year annually resolved climate history for the southwestern United States. Annual banding, hiatuses, and high-precision uranium-series dating show a present day–like climate from 4000 to 3000 years ago, following a drier middle Holocene. A distinctly wetter and cooler period from 3000 to 800 years ago was followed by a period of present day–like conditions, with the exception of a slightly wetter interval from 440 to 290 years before the present. The stalagmite record correlates well with the archaeological record of changes in cultural activities of indigenous people. Such climate change may help to explain evidence of dwelling abandonment and population redistribution.

We present high-resolution late Holocene climate reconstruction for the southwestern United States on the basis of variations in annual band thickness, growth–no growth records, differences in mineralogy, and high-precision uranium-series (U-series) dating of stalagmites. These stalagmites, from Carlsbad Cavern and Hidden Cave, Guadalupe Mountains, New Mexico (Fig. 1), show evidence of primary features such as aragonite layers, well-preserved delicate fossils, and growth banding, indicating a lack of diagenetic alteration. Aragonite layers in calcitic stalagmites generally form at the typically low cave temperature (i.e., 20°C) under conditions of higher-than-normal evaporation from already elevated Mg/Ca in cave waters, and can therefore be regarded (in comparison to calcite layers) as indicators of more evaporative conditions in caves (1–4). Changes in species of well-preserved fossil mites and other microarthropod parts may also be broad indicators of climate change (5). Annual growth banding in stalagmites, documented elsewhere by only a few reports (3, 6–9), has the potential to reveal highly resolved climate change. In this semi-arid region with seasonal-dependent precipitation, stalagmite growth is moisture limited, and with relative humidity of 75 to 95% in these caves, the stalagmites—although not yet useful for stable isotope work (10), unlike other settings (2,11)—preserve well-defined, climate-revealing, annual bands.

Figure 1

Location of Carlsbad Cavern, Hidden Cave, and the Guadalupe Mountains in relation to the puebloan Southwest (dashed line). Samples from Carlsbad Cavern came from the entrance to Bat Cave near the commercial trail. Collection location of Hidden Cave samples is given in (5).

Layers of altering clear and inclusion-rich calcite [couplets (8, 9)] define annual banding in the stalagmites, which can be detected by optical microscopy (Fig. 2). Our darker inclusion-rich portions of each couplet appear to consist of a mixture of water and organics probably formed by a dry-seasonal deposition of microflora. The clear portion of each band represents faster growth during seasonal periods of increased drip rates. To establish that the bands constitute annual deposition of calcite, we measured thicknesses of >1600 bands (from a possible ∼2000 bands, 2796 ± 88 to 835 ± 25 years B.P.) in stalagmite BC2. The average measured band thickness equals 0.106 ± 0.002 mm/year, and the growth rate derived from U-series dating equals 0.100 ± 0.006 mm/year, which are within their 2σ errors (12, 13). There are no apparent hiatuses in this segment of stalagmite BC2, and it is clear that the bands represent annual deposition of calcite, and that band thickness represents the growth rate. This agreement was strengthened by supporting data from all five stalagmites (13). It is also apparent that decreased annual precipitation usually results in thinner bands, aragonite layers, or no-growth scenarios. For instance, a sequence of thinner bands in stalagmite BC2 was deposited coeval with aragonite layers in stalagmites 89029 and 89037. In our climatic setting, thicker calcite bands are therefore interpreted as relative indicators of increased annual precipitation like that reported by Brook et al. (9).

Figure 2

Micrograph showing examples of typical well-formed annual banding preserved in small columnar stalagmites.

A significantly cooler, wetter climate in the southwestern United States during the late Pleistocene (14) produced massively large stalagmites in caves of the Guadalupe Mountains [some of the world's largest (15)], whereas virtually no speleothem growth in these caves has been reported during the drier Holocene. Growth of the small columnar stalagmites during the late Holocene, although minute in comparison, marks the beginning of increased annual precipitation at ∼4000 years B.P. (13). The apparent lack of stalagmite growth before 4000 years ago (4 ka) supports a drier middle Holocene for the southwestern United States, consistent with other published reports (16–19). Some packrat midden studies show the increasing spread of the American deserts after 5 ka, which seems to imply an overall decrease in effective moisture from the early to late Holocene (20, 21). However, intervals of increased moisture during the late Holocene in the southwestern United States are reported by numerous studies (5, 22–30) and seem to support an interpretation favoring greater effective moisture at least during the core of the late Holocene. Geologic and archaeologic evidence for the Colorado Plateau indicates several drier and wetter intervals for the last 2000 years (22). A wetter period from 4 to 2.2 ka for the northern Chihuahua Desert, west of the Guadalupe Mountains, was reported on the basis of stable isotopes and soil geomorphology (27). A neopluvial at 3370 14C years B.P. in the Guadalupe Mountains region from the aeolian record was also reported (28). In addition, fossil northern or highland mammals from Pratt Cave sediment at 2560 14C years B.P., and Honest Injun Cave sediment at 3 to 1 ka in the Guadalupe Mountains, indicated more mesic conditions than at present (29,30). Somewhat similar results have been reported elsewhere in the southwestern United States. High lake levels at Cloverdale Lake, southwestern New Mexico (between 5 and 2 ka); expansion of ponderosa pines near Chaco Canyon, New Mexico [at 2.2 (14C) ka]; increase in lake levels at Potato Lake, central Arizona (by 3 ka); and increased effective moisture at Bear Lake, northwestern Arizona (after 4 ka) were all reported after a drier middle Holocene (23–26).

Our stalagmite record (five stalagmites) consistently provides a century- and annually resolved history of climate. Growth of stalagmites from 4 to ∼3 ka lacks good representation but suggests at least intervals of slightly greater effective annual moisture than at present. Thicker annual bands in four of the five stalagmites from ∼3000 to 1700 years B.P. indicate significantly greater effective annual moisture than at present (average growth rate represented byFig. 3, bar A). A 200-year period of thicker bands at 2800 to 2600 years B.P. in these stalagmites appears to depict the wettest interval of the late Holocene for this region. This is synchronous with a reported abrupt change to cooler and wetter conditions in Europe, and globally in temperate and boreal zones, at ∼2650 years B.P. (31). Another period of thicker bands represents sizable increased effective moisture around 2000 years B.P. This is followed by a distinctly drier interval from ∼1700 to 1300 years B.P. defined by thinner bands in stalagmite BC2 and BC4 and aragonite layers in the Hidden Cave stalagmites (Fig. 3, bar B) (13). Stalagmite growth during this period indicates that the climate was near its present-day conditions, but overall slightly wetter. Termination of growth of three of the five stalagmites near 700 to 800 years B.P. (hiatuses just above the following dates: 835 ± 25, 819 ± 82, and 888 ± 144 years B.P.) and thinner bands in stalagmite BC4 starting at this time define the beginning of a period of decreased annual precipitation equal to or drier than at present. Our results show that this period of near–present-day climate extends to the present and is interrupted by a brief <300-year period of slightly increased precipitation, as shown by the continued growth of the Bat Cave stalagmites. This growth in stalagmite BC2 is best represented by a continuous sequence of 292 bands and two U-series dates (432 ± 13 and 236 ± 50 years B.P.), with the thickest banding from 440 to 290 years B.P. The top of stalagmite BC2 is ∼170 years B.P. Interpolated ages for the tops of stalagmites BC3 (336 ± 86 years B.P.) and BC4 (250 ± 56 years B.P.) are at or soon after the abrupt thinning of banding at ∼290 years B.P. in stalagmite BC2. This interval of stalagmite growth from 440 to 290 years B.P. occurred during a brief period of global cooling referred to as the Little Ice Age (32). Comparably, the period of the Little Ice Age was defined by a study of stalagmites from Madagascar as 425 to 230 years B.P. (9) and was reported as beginning at 450 years B.P. on the basis of stalagmites from Nepal (2).

Figure 3

Comparison of annual band data for stalagmites BC2 (Carlsbad Cavern) and 89037 (Hidden Cave) as band thickness versus age. The two time scales are synchronized. These data are compared to the archaeological record for the southwestern United States. The orange curve (stalagmite BC2) is 5-year smoothed data. BM III is Basketmaker III; P I, II, III, IV are the Pueblo I, II, III, and IV periods of the Pecos classification. The colored boxes indicate the approximate chronologic occurrence and duration of these periods (33, 34). Bars A and B, which designate average growth rate, enhance correlations between important sequences within the two stalagmites.

Our overall interpretation is that the climate in the southwestern United States from the mid- to late Holocene became wetter at ∼4 ka and comparable to or slightly wetter than the present climate until ∼3 ka. The most significant period of increased moisture occurred from ∼3 to 1.7 ka, with distinct pulses at 2.8 and 2.0 ka. Greater than present-day wetness persisted until ∼800 years B.P., after which conditions became as dry as or drier than present-day conditions. A ∼300-year period of slightly greater than present-day moisture occurred between 460 and 170 years B.P., with the most notable increase in annual precipitation during the interval from 440 to 290 years B.P.

The stalagmite record shows changes in annual precipitation at an annual to decadal resolution, allowing for comparison of the archaeological records with the Pecos classification of cultural periods for the southwestern United States (Fig. 3). Earliest evidence for the growth of corn by ancestral Americans in the southwestern United States (33) is coeval with the beginning of the late Holocene wet period defined by our data. This is also when the Late Archaic period is reported to begin in most areas (33,34). Evidence from Pendejo Cave in the adjacent Sacramento Mountains shows the use of corn from 2950 to 1665 years B.P. (35), which coincides with our wettest interval. Ceramics and cotton appeared at the same time that we report a slight decrease in effective moisture around 1700 years B.P. (33). These somewhat drier conditions lasted from ∼1700 to ∼1300 years B.P., which overlaps with the Basketmaker III period (33, 34). Population increases during the last 2000 years in areas of the Colorado Plateau that are currently very dry have been interpreted as indicators of periods of increased annual precipitation (22). An apparent increase in effective moisture at 1250 years B.P. that lasted until 1100 years B.P. (Fig. 3) marks a time of population expansion on the Colorado Plateau (22) and is coeval with the Pueblo I period for most areas of the southwestern United States, when cultures moved from pithouses to above-ground dwellings (33). Population redistribution from higher elevations and population growth of lower elevation areas took place during the Pueblo II period (33, 34), corresponding to a drying trend in our record at 1100 years B.P. that becomes increasingly wetter up to 900 years B.P. and drier again by 850 years B.P. The Pueblo III period represents a higher elevation population redistribution at ∼850 years B.P. and a lower elevation redistribution around 750 to 700 years B.P. (33, 34), which compares well with our data showing a wetter period from ∼850 to 800 years B.P. followed by abrupt drying conditions. Timing of the onset of significantly drier conditions, represented by no stalagmite growth from ∼670 to 460 years B.P., is also coincident with the Pueblo IV period of significant abandonment of higher elevation dwellings and population redistribution to river areas (22, 33, 34). The historic period starts near the beginning of the Little Ice Age (∼500 years B.P.). Climate change, although not the sole reason, is an important underlying explanation for cultural shifts and evolution in the arid southwestern United States during the late Holocene.

  • * To whom correspondence should be addressed. E-mail: polyak{at}unm.edu

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