Buried treasures: constructing--and deconstructing--cave formations.In the summer of 2003, geologist Leslie A. Melim and two of her undergrads This article is about the television show. For the educational term, see undergraduate education. This article or section does not cite its . You can Wikipedia by introducing appropriate citations. were exploring a 6-meter-by-12-m chamber deep within New Mexico's Carlsbad Caverns. As the team members were on their hands and knees conducting a detailed survey of the cave floor, one of the students blurted out, "Hey, what's this?" "This;' says Melim, was an oddly configured carpet of white minerals lining a shallow basin that had long ago, when the region's climate was wetter, held water. The sharp, wispy wisp n. 1. A small bunch or bundle, as of straw, hair, or grass. 2. a. One that is thin, frail, or slight. b. A thin or faint streak or fragment, as of smoke or clouds. 3. peaks of the carpet were less than 1 centimeter tall and 1.5 cm across at their bases, resembling crests atop a lemon meringue pie. "It was unlike any cave formation I'd seen or heard of, and I was pretty, sure no one else had seen it before either," says Melim. Considering the location of the find and its appearance, the team from Western Illinois University For another university which uses the abbreviation "WIU", see Webber International University Athletics
As at Carlsbad Caverns, many treasure vaults lie deep beneath Earth's surface in cathedral-like chambers, accessible only through narrow passages, often with fanciful names such as Contortionist's Delight or Fat Man's Squeeze. In these pitch-black and usually humid confines, mineral formations range from iciclelike deposits that can weigh tons to delicate crystals that shatter at the slightest touch. Although scientists have long understood the chemical processes that sculpt sculpt v. sculpt·ed, sculpt·ing, sculpts v.tr. 1. To sculpture (an object). 2. To shape, mold, or fashion especially with artistry or precision: many cave formations, they've only recently come up with of a mathematical model that explains some their shapes. An even fuller explanation of the intricate decor will also have a biological component, according to researchers who are characterizing the unusual bacteria that live in caves. In Mexico's Cueva de Villa Luz Cueva de Villa Luz (Cave of the Lighted House) is a cave near Tapijulapa in the southern Mexican state of Tabasco. Its thermal sulphur springs produce a rotten-egg smell, and bacteria thrive on the resulting hydrogen sulfide gas. , as in many others, moist surfaces bear gleaming coats of mineral-depositing bacteria, filmy ribbons of their microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. kin undulate undulate /un·du·late/ (-lat) 1. to move in waves or in a wavelike motion. 2. to have a wavelike appearance, outline, or form.un´dulatory in cave-floor pools and streams, and damp globs of microorganisms hang from the walls. Some types of mineral deposits that form in caves appear to be produced by communities of bacteria or by the environmental conditions that they create. On the opposite side of the coin, some of the same organisms are threatening prehistoric cave art. DANGLING DEPOSITS Cave formations come in numerous shapes and sizes, and many of their names--popcorn, cave bacon, and soda straw, for example--seem to have sprung from the minds of imaginative--and hungry--cavers. The two formations best known to noncavers, however, bear the names stalactite and stalagmite stalactite (stəlăk`tīt) and stalagmite (stəlăg`mīt), mineral forms often found in caves; sometimes collectively called dripstone. . Pity the grade school test taker who forgets that the c in stalactite sta·lac·tite n. An icicle-shaped mineral deposit, usually calcite or aragonite, hanging from the roof of a cavern, formed from the dripping of mineral-rich water. stands for "ceiling" and the g in stalagmite stalagmite: see stalactite and stalagmite. stands for "ground." Stalactites Stal`ac`ti´tes n. 1. A stalactite. , stalagmites, and other cave deposits form when water picks up minerals as it percolates through sediments and then seeps into a cave. If the water has traveled through limestone on its journey, it typically is saturated with calcium carbonate calcium carbonate, CaCO3, white chemical compound that is the most common nonsiliceous mineral. It occurs in two crystal forms: calcite, which is hexagonal, and aragonite, which is rhombohedral. and carbon dioxide carbon dioxide, chemical compound, CO2, a colorless, odorless, tasteless gas that is about one and one-half times as dense as air under ordinary conditions of temperature and pressure. , says Raymond E. Goldstein, a physicist at 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. This seepage can also contain trace amounts of a wide variety of elements. In the first fraction of a second after water seeps from a cavern ceiling, some of the gas dissolved in the seepage enters the humid air because the cave's air isn't saturated with carbon dioxide. This process, a gentle fizzing fizz intr.v. fizzed, fizz·ing, fizz·es To make a hissing or bubbling sound; effervesce. n. 1. A hissing or bubbling sound. 2. Effervescence. 3. An effervescent beverage. like that in soda pop, causes the water droplet droplet very small drop of fluid. droplet nuclei the finite particles of matter which are transmitted from animal to animal. to become more acidic, Goldstein says. As a result, some of the calcium carbonate in the droplet crystallizes on the cave ceiling, and--voila!--a stalactite is born. As seepage continues, new droplets hang from this bump and leave their crystalline residue. When droplets fall to the cavern floor, the dissolved minerals that they carry often accumulate there as stalagmites. When a stalactite and its underlying stalagmite have nearly grown together, the deposits' shapes are almost perfect mirror images. Further growth melds the formations into a column with a narrow waist, which continues to thicken thick·en tr. & intr.v. thick·ened, thick·en·ing, thick·ens 1. To make or become thick or thicker: Thicken the sauce with cornstarch. The crowd thickened near the doorway. 2. as the minerals precipitate from the water flowing over the surface. The growth of a stalactite is incredibly slow--typically, it takes a century to add a centimeter of length. At first, stalactites grow irregularly, but once they've reached a length of 5 cm or so they take on a characteristic shape. From the side, the formation doesn't look like a perfect cone but bulges like a plump carrot, says Goldstein. Although scientists had long recognized this distinct profile, no one had explained how stalactites end up with their bulging shape, he notes. Now, Goldstein and his colleagues have come up with a mathematical model that reproduces a stalactite's silhouette. Earlier experiments had shown that the rate of mineral precipitation on each small patch of stalactite correlates with the thickness of the layer of water that's dribbling down the formation. At the top of a stalactite, where the layer of flowing water may be only a few micrometers (gm) thick, calcium carbonate is deposited slowly, says Goldstein. Near the bottom of the formation, where the flowing water is spread over a smaller area, the film of water is thicker and crystals form more quickly. Because the top of the stalactite has a larger diameter and more surface area than the bottom does, more rock is deposited there overall. However, the more-rapid mineral deposition at the bottom portions widens the formation to create the characteristic carrot profile. Goldstein and his colleagues reported their findings in the August 2005 Physics of Fluids. When the seepage rate into a cave is extremely slow, mineral-laden droplets can hang on the ceiling for a long time before they fall. In such a ease, the calcium carbonate crystallizes in a ring shape. The crystals that precipitate from subsequent droplets extend the ring into a delicate tube, generating a so-called soda straw that can grow several centimeters long, says Goldstein. Only about 1 percent of the calcium carbonate that's dissolved in the water flowing down a stalactite remains on that formation, Goldstein and his colleagues estimate. The rest is carried to the cave floor within the dripping water. Over time, the deposits from drips can produce stalagmites. Although his team's model doesn't address those structures' formation, Goldstein speculates on how a stalagmite's shape develops. As stalactites do, stalagmites grow irregularly at first. The crystals accumulate in a broad, random pattern, probably because the mineral-rich droplets splash when they hit the cave floor, says Goldstein. As the mineral layers thicken and the formation grows upward, the distance through which the droplets fall becomes shorter, so the droplets splash less when they strike and the stalagmite takes on a more predictable carrot shape that's often the mirror image of the stalactite above it, he proposes. BUILT BY BUGS? Hundreds of types of rock appear in cave formations. The most abundant ones are forms of calcium carbonate deposited when mineral-rich waters seep into an open space underground. Increasingly, however, researchers are finding that many exotic cave formations are in one way or another associated with bacteria. For instance, some of the walls in New Mexico's Lechuguilla Cave are coated with guarly bumps of various sizes, a type of formation that cavers have nicknamed popcorn. The smallest bumps are 2 to 3 millimeters across and look more like bacterial colonies growing in a petri dish pe·tri dish n. A shallow circular dish with a loose-fitting cover, used to culture bacteria or other microorganisms. Petri dish a shallow, circular, glass or disposable plastic dish used to grow bacteria on solid media such as agar. than like popcorn, says Hazel A. Barton, a microbiologist at Northern Kentucky University Northern Kentucky University is a public, co-educational university located in Highland Heights, Kentucky, seven miles (11 km) southeast of Cincinnati, Ohio. Enrollment is currently about 14,200 students. in Highland Heights. The largest knobs of the hard, white rock are thumb-size replicas of the popped kernels of the snack that shares their name. Microscopic analyses of the bumps and knobs show layers of bacteria that have been fossilized fos·sil·ize v. fos·sil·ized, fos·sil·iz·ing, fos·sil·iz·es v.tr. 1. To convert into a fossil. 2. To make outmoded or inflexible with time; antiquate. v.intr. in calcium carbonate. Barton and her colleagues have scraped samples of unidentified live bacteria from cave walls and took them back to the lab. When fed a calcium containing substance, the microbes made crystals of calcium carbonate, the same material that encases their fossilized brethren. Microbes are present on most moist cave surfaces. However, because not all such bacteria can be cultured in the lab, it's often difficult to confirm which organisms, if any, are responsible for forming cave minerals, says Brian Jones, a geologist at the University of Alberta in Edmonton who has studied cave microbes. In some instances, bacteria appear to play a more indirect role, merely creating the environmental conditions under which dissolved minerals are more likely to crystallize crys·tal·lize also crys·tal·ize v. crys·tal·lized also crys·tal·ized, crys·tal·liz·ing also crys·tal·iz·ing, crys·tal·liz·es also crys·tal·iz·es v.tr. 1. . For example, quartz pebbles and rocks in many cave-floor streams are coated with a layer of manganese oxide-containing minerals that can range from fractions of a millimeter to a few millimeters thick, says William B. White, a geochemist at the Pennsylvania State University Pennsylvania State University, main campus at University Park, State College; land-grant and state supported; coeducational; chartered 1855, opened 1859 as Farmers' High School. in University Park. The predominant mineral in the coatings is birnessite, a manganese oxide compound that includes traces of sodium, calcium, and potassium. Microscopic analyses of the birnessite coatings reveal many fossilized bacteria, so White speculates that those organisms derived energy from the manganese dissolved in the water that flowed over them. During the energy exchange, the manganese ions were converted to an insoluble form that then precipitated to form the birnessite. At this stage of research, White says, it's unclear whether the microbes had a role in the coatings' formation or whether they simply inhabited the veneer after it formed. The pool-meringue formation in Carlsbad Caverns may represent a stronger link between microbes and cave minerals. Scattered throughout the meringue are smooth tubes 2 to 3 gm long and less than 1 [micro]m in diameter. That's the right size and shape to be microbial filaments, says Melim. Lab results also hint that the filaments have a microbial origin. Compared with the rock that encased en·case tr.v. en·cased, en·cas·ing, en·cas·es To enclose in or as if in a case. en·case  ment n. them, the microscale tubes are more resistant to mild acid and contain slightly more carbon. STARVATION DIET starvation diet Very low calorie diet Nutrition A fad diet that provides 300-700 kcal/day, which must be supplemented with high quality protein; given the risk of death through intractable cardiac arrhythmias Side effects Orthostatic hypotension due to loss of Ecologically, caves are some of the world's most isolated environments. That seclusion offers stability: In large caves, temperatures rarely fluctuate, and the humidity in caves receiving a steady flow of mineral-rich groundwater stays close to 100 percent. "It's like a sauna, only a lot cooler;' says Jones. The isolation and stability also make several cave features valuable recorders of geologic and even climatic history. The ratio of oxygen isotopes in a sample of carbonate can provide clues about the temperature at which the cave mineral crystallized crys·tal·lize also crys·tal·ize v. crys·tal·lized also crys·tal·ized, crys·tal·liz·ing also crys·tal·iz·ing, crys·tal·liz·es also crys·tal·iz·es v.tr. 1. . While soil temperatures at or near Earth's surface rise and fall with the seasons, these fluctuations are tempered in deep caverns. Therefore, a deep cave's temperature matches the average annual temperature at ground level directly above it. Although useful to scientists, a cave's isolation from Earth's surface causes problems for organisms living there, says Barton. It's pitch-black deep inside a cave, so no food chain can be based on photosynthesis. Many microbes obtain energy by breaking down rocks and taking advantage of the chemical energy from those reactions (SN: 11/15/03, p. 315). Most of the nutrients available to support life are those carried in by groundwater. Each liter of water seeping into a cave typically carries between 15 and 50 micrograms of organic carbon, about one-thousandth the concentration that's considered a starvation diet for microbes living at Earth's surface. Forced to make a living from such slim pickings, the cave-dwelling organisms have developed unusual techniques for extracting energy from their surroundings. "These bacteria are incredibly starved, but they're incredibly diverse" says Barton. With that variety in the face of adversity, microbes have evolved complex communities that work together to efficiently process the minuscule quantities of nutrients that flow their way, she notes. These communities take many forms, including slick films on rock walls, mats in the cave's streams and pools, and moist globs that geologists have dubbed snottites. Microbes quickly take advantage of any nutrients brought into the cave by human or animal explorers as well as by seeping water, says Penelope J. Boston, a microbiologist at the New Mexico Institute of Mining and Technology Renowned for its undergraduate and graduate educational opportunities[1], Tech offers over 30 bachelor of science degrees in mathematics, the sciences, engineering, management, and technical communication, as well as graduate degrees in areas of specialization through the in Socorro. Ropes installed by spelunkers in Lechuguilla Cave are being slowly consumed by fungi, she notes. Tubing used to siphon siphon (sī`fən, –fŏn), tube through which a liquid is lifted over an elevation by the pressure of the atmosphere and is then emptied at a lower level. drinking water drinking water supply of water available to animals for drinking supplied via nipples, in troughs, dams, ponds and larger natural water sources; an insufficient supply leads to dehydration; it can be the source of infection, e.g. leptospirosis, salmonellosis, or of poisoning, e.g. from cave pools, if left dangling into the water, soon gains a coating of microbes that derive nutrition from organic compounds that leach from the plastic. Even the hair and skin cells shed by the occasional caver cav·er n. 1. One that caves. 2. One who explores or studies caves, especially as a sport or recreational pursuit. provide a source of nutrition for cave bacteria, says Boston. The microbial penchant for consuming any substance with nutritive nutritive /nu·tri·tive/ (noo´tri-tiv) nutritional. nu·tri·tive adj. 1. Of or relating to nutrition. 2. Nutritious; nourishing. value poses a threat to some of humanity's priceless works of art, the cave paintings that are scattered across much of Europe. Some of those works date back to the midst of the last ice age. To make their paints, the prehistoric artists mixed minerals such as iron oxide The material used to coat the surfaces of magnetic tapes and lower-capacity disks. and organic substances such as charcoal into binders such as vegetable oils and fats--appetizing ingredients all, for a starving microbe microbe /mi·crobe/ (mi´krob) a microorganism, especially a pathogenic one such as a bacterium, protozoan, or fungus.micro´bialmicro´bic mi·crobe n. . Recent surveys have found a wide variety of bacteria living on or near cave paintings at several sites, says Cesareo Saiz-Jimenez, a microbiologist at the Institute of Natural Resources and Agro-biology in Seville, Spain. Some of the more-renowned masterpieces under attack include cave art in France's Laseaux Cave and Spain's Altamira, La Garma, and Tito Bustillo caves. Scientists haven't worked out lab methods to grow many of the microbes attacking the paintings, so those organisms haven't been studied in detail. However, analyses of their DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. provide hints about their family relationships and lifestyles. For example, cave paintings in Altamira Cave support microbes from the group Crenarehaeota, which can be found in many softs but also inhabit extreme environments such as near-boiling springs, Saiz-Jimenez and his colleagues reported in the January Naturwissenschaflen. The same paintings also host microbes from the genus Acidobacteria, which often thrive in acidic softs. Such microorganisms threaten not only the cave art's pigments but also the underlying rock. Attempts to kill or control the art-loving microbes with disinfectants might not work, say some cave-art conservators. They're concerned about damage by such cleansers to the rock. Furthermore, killing some of the microbes might simply shift the balance of power to an even more destructive set of organisms and thus accelerate damage rather than prevent it. The best hope for the cave art, says Saiz-Jimenez, lies in continued research, which may yield insights into how to inhibit the growth of microbial communities and how to minimize the damage they're causing.* |
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