Gritty clues: how soil can tell stories of the past.At the base of Monticello Mountain, just below Thomas Jefferson's historic estate in Charlottesville, Va., sits a 90-meter-long greenstone green·stone n. Any of various altered basic igneous rocks colored green by chlorite, hornblende, or epidote. greenstone Noun NZ a type of green jade used for Maori carvings and ornaments wall. The Rivanna River The Rivanna River is a tributary of the James River, about 50 mi (80 km) long, in central Virginia in the United States. The Rivanna's tributaries originate in the Blue Ridge Mountains; via the James River, it is part of the watershed of Chesapeake Bay. runs on one side. On the other, earth has piled up to the waifs WAIFS. Stolen goods waived or scattered by a thief in his flight in order to effect his escape. 2. Such goods by the English common law belong to the king. 1 Bl. Com. 296; 5 Co. 109; Cro. Eliz. 694. top. Built up from sediments washing down the mountain for centuries, this soil holds clues to history. But rather than bits of tools or pottery, the clues are chemical elements in the soil. A complex ecosystem, soil is home to matter animal, vegetable, and mineral. Numerous chemical, biological, and geological processes take place continuously among these players. Yet within this dynamic world, an imprint of the past appears in the variety and abundances of soil's chemical elements. People directly influence these imprints. "As people live on a landscape, they leave all kinds of chemical residues around" says geoarchaeologist Vance T. Holliday of the University of Arizona (body, education) University of Arizona - The University was founded in 1885 as a Land Grant institution with a three-fold mission of teaching, research and public service. in Tucson. Some elements build up over time, while others diminish. Studying these changes "can provide us with a record of how a landscape evolves," he says. While archaeologists have long scrutinized soils to find traces of the past, advances in analytical technologies in the past 10 to 15 years have made the detection of dozens of chemical elements rapid and cost-effective for the first time. With that additional information, archaeologists are tying chemical signatures to agricultural practices and other human activities. But while soil chemistry, offers new insights, it's most instructive in combination with artifacts artifacts see specimen artifacts. and other historical evidence. "Archaeology brings together many different lines of evidence to understand the narrative of the past," says Lisa Frink of the University of Nevada University of Nevada could refer to either of the universities in the Nevada System of Higher Education:
DIRT DIVERSITY Both dirt's parent material-the bedrock that slowly fragments into soil particles--and its living constituents affect soil's natural chemical composition. Magnesium, calcium, phosphorus, and numerous other elements can show up within chemical compounds among soil particles or as ions bound to those particles. When people occupy an area, they influence the amounts of the elements in the soil. In agriculture, fertilizer adds some elements to the soil and crops deplete de·plete v. 1. To use up something, such as a nutrient. 2. To empty something out, as the body of electrolytes. it. Furthermore, domestic activities, such as preparing food, maintaining fires, and disposing of waste, concentrate certain elements in the soil, says archaeologist T. Douglas Price of the University of Wisconsin-Madison “University of Wisconsin” redirects here. For other uses, see University of Wisconsin (disambiguation). A public, land-grant institution, UW-Madison offers a wide spectrum of liberal arts studies, professional programs, and student activities. . Archaeologists have the most experience with phosphorus, an element long recognized to indicate human activity. Burial sites, waste from people and animals, and meat, fish, and other food remains all add phosphorus to the soil, where it combines with ions to form stable phosphate minerals Phosphate minerals are those minerals that contain the tetrahedrally coordinated phosphate (PO43-) anion along with the freely substituting arsenate (AsO43-) and vanadate (VO43-). , says Holliday. Phosphorus accumulates while people occupy an area, and concentrations can rise orders of magnitude higher than those in soil relatively free of human contact, he notes. Although many scientists have suspected for decades that "there ought to be other things besides phosphorus lying around," says Price, finding additional tell tale elements has only recently become practical. For example, instruments that perform an analytical technique An analytical technique is a method that is used to determine the concentration of a chemical compound or chemical element. There are a wide variety of techniques used for analysis, from simple weighing (gravimetric) to titrations (titrimetric)to very advanced techniques using called inductively coupled plasma An inductively coupled plasma (ICP) is a type of plasma source in which the energy is supplied by electrical currents which are produced by electromagnetic induction, that is, by time-varying magnetic fields. spectroscopy are now available at many universities, notes Price. These machines identify elements extracted from a soil sample by weighing ions or by detecting characteristic wavelengths. Having identified the elements in a collection of samples, archaeologists can map a plot of ground according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the elements' concentrations. By combining that information with details of artifacts and other evidence of people's presence, scientists are deciphering chemical signatures of various human activities. For instance, potassium and magnesium tend to be higher where wood ash once entered the soil from a hearth. The evidence so far "makes us think that we are seeing some real patterns in the [chemistry] data," says Price. However, he notes that there are differences in conditions among sites, so archaeologists still "have to learn each site in a different way." EPHEMERAL ACTIVITIES Soil-chemistry data can be especially useful in detecting human activities at sites of occasional gatherings. In such places, people carried away their food vessels or tools once they ended a ceremony or broke camp, so few artifacts typically remain for archaeologists to find. An archaeological site in the northwestern part of Honduras, for example, has two main areas: a ceremonial plaza surrounded by pyramids and a residential patio encircled en·cir·cle tr.v. en·cir·cled, en·cir·cling, en·cir·cles 1. To form a circle around; surround. See Synonyms at surround. 2. To move or go around completely; make a circuit of. by dwellings. E. Christian Wells of the University of South Florida • • [ at Tampa works with his research group at this site, called Palmarejo, which dates to between A.D. 400 and 1,000. As they expected, the researchers found almost no artifacts within the boundaries of either the plaza or patio. But near the plaza, they found large serving platters, grinding stones, and incense burners. Areas just off the patio held smaller versions of these items as well as bowls and cups. This evidence suggests that the community cooked, ate, and held religious ceremonies in both places, but in larger groups in the plaza than in the patio. To get a sense of where in these open spaces the activities occurred, Wells' group turned to soil chemistry. The researchers took 324 samples--one every 2 m in the plaza and every 5 m in the patio. They sampled from about 15 centimeters below the areas' current surface, which is the level of the original patio and plaza. By identifying elements such as barium, magnesium, and phosphorus, Wells and his team discerned several patterns, which they reported at the 2006 American Chemical Society The American Chemical Society (ACS) is a learned society (professional association) based in the United States that supports scientific inquiry in the field of chemistry. Founded in 1876 at New York University, the ACS currently has over 160,000 members at all degree-levels and in meeting in Atlanta in March. Phosphorus concentrations in the plaza displayed greater variation than those in the patio did, which suggests that cooking and eating occurred throughout the patio but only in certain spots on the plaza, says Wells. The team also observed variations in barium and magnesium concentrations in the southern part of the plaza but doesn't know what activities those patterns might represent. To learn more about the ancient site, Wells' team is observing the activities and studying the soils of indigenous people currently living in the area. Such information is critical for "making inferences between soil chemistry and ancient activities that took place," says Wells. Similarly, Frink and Kelly J. Knudson of Arizona State University Arizona State University, at Tempe; coeducational; opened 1886 as a normal school, became 1925 Tempe State Teachers College, renamed 1945 Arizona State College at Tempe. Its present name was adopted in 1958. in Tempe are examining modern-day indigenous communities in Western Alaska. The people there collect enough food in the short summers to last through harsh winters. Frink, Knudson, and their colleagues work in the Yukon-Kuskokwim Delta The Yukon-Kuskokwim Delta is one of the biggest river deltas in the world, roughly the size of Oregon. It is located where the Yukon and Kuskokwim rivers empty into the Bering Sea on the west coast of the U.S. state of Alaska. , about halfway up the state's coast along the Bering Sea Bering Sea, c.878,000 sq mi (2,274,020 sq km), northward extension of the Pacific Ocean between Siberia and Alaska. It is screened from the Pacific proper by the Aleutian Islands. The Bering Strait connects it with the Arctic Ocean. , where the Yup'ik catch and process salmon and other fish at camps that exist only during the summer season. Before the researchers begin excavating archaeological sites, they're observing activities and collecting samples from present day Yup'ik fish camps. Families at the camps live in tents and set up fish-processing areas that include a fish-cutting station and covered drying racks. "If the site is ephemeral--you don't have people building large houses--then soil chemistry can be very helpful" in revealing a signature that might also locate an ancient camp, says Knudson. In 2004, the team reported on three fish camps, one a site revisited by the same family for 30 years and two others that had each been inhabited for just one summer. At the older camp, the group found that manganese, phosphorus, and strontium strontium (strŏn`shēəm) [from Strontian, a Scottish town], a metallic chemical element; symbol Sr; at. no. 38; at. wt. 87.62; m.p. 769°C;; b.p. 1,384°C;; sp. gr. 2.6 at 20°C;; valence +2. concentrations in soil were an order of magnitude A change in quantity or volume as measured by the decimal point. For example, from tens to hundreds is one order of magnitude. Tens to thousands is two orders of magnitude; tens to millions is three orders of magnitude, etc. higher under the drying racks than in soils outside the camp. Drippings from the fish probably caused the difference. The newer camps displayed a similar, but weaker, chemical signature under the drying racks. The poorly draining Alaskan soils appear ideal for retaining elements for analysis, the researchers say. The group plans to look for chemical signatures at archaeological sites in the area. Ultimately, says Knudson, the goal is to "use the data we have from the fish camps to look at the past." GROWING SEASON growing season, period during which plant growth takes place. In temperate climates the growing season is limited by seasonal changes in temperature and is defined as the period between the last killing frost of spring and the first killing frost of autumn, at which The soil also holds clues to past farming practices. Fraser D. Neiman, director of archaeology at Monticello, and his colleagues have excavated the layers of soil behind the meter-high greenstone wall at Monticello Mountain to study how changes in agricultural strategies affected the landscape as well as the lives of the plantation's slave community. Jefferson's father, Peter, began growing tobacco and corn on a small field at Monticello in the mid-18th century. His slaves used hand hoes and slashed and burned trees to clear fields, leaving behind the tree stumps. This type of agriculture typically leads to some erosion, but stumps keep much of the sediment in a field, says Neiman. Thomas Jefferson took over the farm around 1764. He continued his father's practices while establishing additional fields. In the early 1790s, Jefferson switched to growing wheat, a crop that required a completely different strategy. Because wheat fields need to be plowed, the younger Jefferson had his slaves remove the tree stumps. He also rotated the wheat crop with clover and other plants and, to keep fields fertile, added manure and gypsum gypsum (jĭp`səm), mineral composed of calcium sulfate (calcium, sulfur, and oxygen) with two molecules of water, CaSO4·2H2O. It is the most common sulfate mineral, occurring in many places in a variety of forms. , which is calcium sulfate Noun 1. calcium sulfate - a white salt (CaSO4) calcium sulphate gypsum - a common white or colorless mineral (hydrated calcium sulphate) used to make cements and plasters (especially plaster of Paris) . "The plowing totally stripped the fields and set up a process in the mountain environment for lots more erosion," says Neiman. After Jefferson's death, farming on the mountain slopes ceased. At the 2006 Society for Historical Archaeology Historical archaeology is a branch of archaeology that concerns itself with "historical" societies, i.e. those that had systems of writing. It is often distinguished from prehistoric archaeology which studies societies with no writing. meeting in Sacramento, Califi, in January, Neiman's colleagues presented their analysis of a 1-by-2-meter chunk of soil roughly 2 meters deep that they had removed from the area behind the greenstone wall. Its color and texture indicated rich, dark topsoil in both the top, modern layer and the fourth layer down, which was probably from the time when Peter Jefferson Peter Jefferson (February 29, 1708 - August 17, 1757), was the father of President Thomas Jefferson. He was the son of Thomas Jefferson I (1679-1731) and Mary Field (1680-1715) [1]. began the farm. The researchers took 50 sediment samples at regular intervals from the top to the bottom of the excavated material. The chemistry data ties the soil's layers to past events at the farm. For example, the researchers observed a spike in the sulfur concentrations between the fourth and third layers of soil, which indicated the point at which Thomas Jefferson switched to wheat. "Thomas Jefferson was a huge fan of gypsum as a fertilizer," says Neiman. "The sulfur spike tells us when we are beginning to see the use of fertilizer on permanent fields." The researchers plan to test additional sites around Monticello. In all of its work, the team incorporates soil-chemistry data, pollen analysis Analysis of the distribution of pollen grains of various species contained in surface layer deposits, especially peat bogs and lake sediments, from which a record of past climate may be inferred. , and studies of artifacts and historical documents to learn more about how changing patterns of land use affected slaves. The work "gives us physical traces of changes in slave-labor routines [such as] going from tobacco to wheat, hoeing to plowing," says Neiman. "We can begin to think about the social implications for the kind of work slaves had to do and how they did it." Soil-chemistry data also reveal how farming practices affect the soil itself. Jonathan A. Sandor of Iowa State University Academics ISU is best known for its degree programs in science, engineering, and agriculture. ISU is also home of the world's first electronic digital computing device, the Atanasoff–Berry Computer. in Ames and his colleagues study sites in New Mexico New Mexico, state in the SW United States. At its northwestern corner are the so-called Four Corners, where Colorado, New Mexico, Arizona, and Utah meet at right angles; New Mexico is also bordered by Oklahoma (NE), Texas (E, S), and Mexico (S). that the Zuni people have farmed for at least 1,000 years. These are some of the oldest agricultural fields identified in the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. . Zunis and other Native Americans still farm in these areas today. The Zuni people have farmed in the dry Southwest without using irrigation irrigation, in agriculture, artificial watering of the land. Although used chiefly in regions with annual rainfall of less than 20 in. (51 cm), it is also used in wetter areas to grow certain crops, e.g., rice. or fertilizers, says Sandor. Instead, their success rested in the placement of their fields at the base of hills. During summer in the Southwest, intense, brief rains brought water and organic debris tumbling down the slopes onto the fields. The runoff not only waters the fields but also replenishes the soil's fertility, notes Sandor. To study how this roughly 1,000-year-long farming practice affected the soil's fertility, the researchers compared soil samples from hillside sites that are still being farmed with samples from sites that have no evidence of ever having been farmed and from sites that were historically farmed but are now abandoned. The team measured the soil concentrations of phosphorus and nitrogen, two nutrients that plants need to grow. The researchers report in an upcoming Geoarchaeology that they found no significant differences in the elements' concentrations at the various sites, which suggests that the Zunis' agricultural practices maintained soil fertility. "What they did was apparently fairly sustainable over long periods of time," says Sandor. This is in contrast to some modern cultivation practices, which can degrade the soil, he notes. Sandor is also analyzing the elements in crops now grown on these fields and in the water and sediments that run off the mountains. "Soil is an important natural resource," he says, "and understanding the long-term effects of human beings on soil is important to coming up with management practices that help us conserve it." IN CONTEXT While soil chemistry is gaining ground in archaeology, scientists remain cautious about how much the data can say. "When people do chemistry work in soils, they can't do it just in that isolated context," says Sandor. He notes that soil is also a product of biological and physical processes. Neiman observes that "most of the work that's been done more recently has tended to be empirical rather than driven by a well grounded theoretical understanding of [soil] processes." To fully evaluate patterns of chemicals in the soil, scientists need a much better understanding of the mechanisms involved, he says. Chemicals' movement within soil can confound con·found tr.v. con·found·ed, con·found·ing, con·founds 1. To cause to become confused or perplexed. See Synonyms at puzzle. 2. interpretation of the data as well, says Holliday. While phosphorus tends to stay fixed, other elements, such as calcium, can be mobile. "If you are trying to make archaeological interpretations, you have to know that what you are measuring hasn't moved around," Holliday says. Despite such difficulties, many researchers still consider soil chemistry an illuminating addition to other archaeological evidence. Says Neiman, "The payoff really comes in putting all this stuff together." |
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