Knot possible: better ways to tell a tangled circle from a knotted loop.Magicians are experts at tying knots that look intractable yet unravel on command. Befuddled spectators find it difficult to distinguish between such phony tangles and truly knotted ropes. Mathematicians also tussle with knots, but their task has an additional constraint. Unlike a knotted piece of rope, a mathematical knot has no free ends. In this context, text, a knot is a one-dimensional curve that winds through itself in three-dimensional space Three-dimensional space is the physical universe we live in. The three dimensions are commonly called length, width, and breadth, although any three mutually perpendicular directions can serve as the three dimensions. Pictures are commonly two dimensional, they lack depth. , finally catching its tail to form a closed loop. You can untie a shoelace and untangle a fishing line, but you can't get rid of the knot in a mathematician's loop without cutting the strand. If a particular tangled loop doesn't really have a knot in it and the loop can be unraveled and smoothed out to a circle, mathematicians call the configuration an unknot. Determining at a glance or two whether a given tangled loop is a knot or an unknot can be as difficult for mathematicians as it is for spectators of a masterly magician's knotty knot·ty adj. knot·ti·er, knot·ti·est 1. Tied or snarled in knots. 2. Covered with knots or knobs; gnarled. 3. Difficult to understand or solve. See Synonyms at complex. prestidigitations. Knot theorists have long sought practical procedures for distinguishing knotted curves from unknotted ones. Two recent developments provide some new hints. This research activity is just one thread of a resurgent re·sur·gent adj. 1. Experiencing or tending to bring about renewal or revival. 2. Sweeping or surging back again. Adj. 1. interest in mathematical knots, not only for mathematicians but also among other scientists. Molecular biologists have used insights from knot theory knot theory Mathematical theory of closed curves in three-dimensional space. The number of times and the manner in which a curve crosses itself distinguish different knots. to understand how 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. strands can be broken and then recombined into knotted forms (SN: 11/16/96, p. 310). Other investigators have explored potential roles for knotted looks in theoretical physics (SN: 5/3/97, p. 270). One way to tell whether a certain tangled loop is really an unknot is to model it out of string, then try twisting and pulling it in various ways. If you manage to untangle the loop, you know it's an unknot. Failure to untangle the loop even after hours Adv. 1. after hours - not during regular hours; "he often worked after hours" of fruitless labor, however, doesn't prove that the loop is truly knotted. It's possible you somehow overlooked the right combination of manipulations to undo the tangle. To distinguish among complicated loops, mathematicians imagine knots to be constructed out of perfectly flexible, stretchable, and infinitesimally in·fin·i·tes·i·mal adj. 1. Immeasurably or incalculably minute. 2. Mathematics Capable of having values approaching zero as a limit. n. 1. thin string. For convenience, they focus on the shadow cast by such loops on a flat, two-dimensional surface. These shadows, technically called projections, are often drawn with small breaks indicating where one part of the loop crosses over or under another part. Knot theorists use the number of crossings in such a diagram as one way to characterize a given knot projection. Depending on the viewpoint and configuration, the same knot or unknot can be represented by many different projections, which may also have different numbers of crossings. It's easy to tell that a knot projection with just two crossings is always an unknot. The problem of determining what a given diagram represents becomes increasingly difficult as the number of crossings goes up. In 1926, mathematician Kurt Reidemeister Kurt Werner Friedrich Reidemeister (October 13, 1893 - July 8, 1971) was a mathematician born in Brunswick, Germany. He received his doctorate in 1921 with a thesis in algebraic number theory at the University of Hamburg under the supervision of Erich Hecke. proved that if you have two distinct projections of the same knot, you can get from one projection to the other using a sequence of basic moves. There are three such operations, and they are now known as Reidemeister moves. In the case of an unknot, some combination of these fundamental moves will inevitably untangle even a messy loop. Finding the appropriate moves for unwinding a complicated configuration, however, is generally no simple matter. That it is always possible to identify an unknot, even without specifying the precise sequence of Reidemeister moves, was firmly established in 1961 by Wolfgang Haken Wolfgang Haken (born June 21, 1928) is a mathematician who specializes in topology, in particular 3-manifolds. In 1976 together with colleague Kenneth Appel at the University of Illinois at Urbana-Champaign, Haken solved one of the most famous problems in mathematics, the of the University of Illinois at Urbana-Champaign Early years: 1867-1880 The Morrill Act of 1862 granted each state in the United States a portion of land on which to establish a major public state university, one which could teach agriculture, mechanic arts, and military training, "without excluding other scientific . He came up with a procedure for deciding whether a given knot is really an unknot. Haken's algorithm involves not the tangled loop itself but the imagined surface for which the loop serves as a boundary. To visualize such a surface, consider the soap film Noun 1. soap film - a film left on objects after they have been washed in soap film - a thin coating or layer; "the table was covered with a film of dust" that spans a ring or a twisted loop after it emerges from a soap solution. In the case of a ring, which represents the circular form of the unknot, the surface is simply a flat disk. Twisted loops that are not actually knotted also serve as boundaries of disklike surfaces--but here the disks may be extremely convoluted convoluted /con·vo·lut·ed/ (kon?vo-lldbomact´ed) rolled together or coiled. . Haken's method mathematically replicates the process of flattening out an exceedingly crumpled crum·ple v. crum·pled, crum·pling, crum·ples v.tr. 1. To crush together or press into wrinkles; rumple. 2. To cause to collapse. v.intr. 1. surface to end up with a flat disk. If the process succeeds, the original tangled loop was certainly an unknot. The method that Haken formulated, however, is so complicated that no one has yet been able to write a fully practical computer program to follow the necessary steps and, for a given projection, give a "yes" or "no" answer to the question of whether it's an unknot. Several groups have tried to implement Haken's algorithm. These implementations "are too bulky at present to allow for analysis of more than a very small number of crossings," says mathematician Joel Hass of the University of California, Davis The University of California, Davis, commonly known as UC Davis, is one of the ten campuses of the University of California, and was established as the University Farm in 1905. . In a striking new development, Haken's approach has proved useful in tackling another important question: What are the maximum number of Reidemeister steps that would remove all the crossings in a given projection of a tangle to arrive at an unknot? In general, there's no easy way to tell in advance how many moves it would take to untangle a given loop and render it recognizable. Moreover, it isn't obvious that the number of required moves is always finite. Now, Hass and Jeffrey C. Lagarias of AT&T Labs-Research in Florham Park, N.J., have for the first time established a ceiling on the number of Reidemeister moves required to unravel a tangle. The mathematicians reported their findings in the February JOURNAL OF THE AMERICAN MATHEMATICAL SOCIETY The Journal of the American Mathematical Society, often referred to by its acronym JAMS, is a mathematics journal published quarterly by the American Mathematical Society. . Like Haken, Hass and Lagarias looked at the mathematical characteristics of convoluted disklike surfaces to obtain their proof. They established that if a string crosses itself n times, you can untangle it in no more than [2.sup.(100,000,000,000n)] Reidemeister moves. Although this ceiling is an enormous number, just putting a cap on the untangling process represents a notable achievement, comments knot theorist Colin C. Adams of Williams College Williams College, at Williamstown, Mass.; coeducational; chartered 1785, opened as a free school 1791, became a college 1793, named for Ephraim Williams. The Williams campus, noted for its fine old buildings, includes West College (1790), the Van Rensselaer Manor in Williamstown, Mass. "The bound is currently so large that no algorithm using these ideas will be forthcoming for quite a while, but perhaps the upper bound can be brought down," he notes. "The hardest step, getting any bound at all, has been done." Mathematicians have already started to lower the ceiling. Topologist Andrew R. Casson of Yale University Yale University, at New Haven, Conn.; coeducational. Chartered as a collegiate school for men in 1701 largely as a result of the efforts of James Pierpont, it opened at Killingworth (now Clinton) in 1702, moved (1707) to Saybrook (now Old Saybrook), and in 1716 was , for instance, has proposed one possible avenue that would significantly reduce the upper bound on the number of moves. While mathematicians now know an upper bound on the number of Reidemeister moves, they still do not know which ones to use and where to use them. In other words Adv. 1. in other words - otherwise stated; "in other words, we are broke" put differently , says Joan S. Birman of Barnard College Barnard College: see Columbia University. at Columbia University Columbia University, mainly in New York City; founded 1754 as King's College by grant of King George II; first college in New York City, fifth oldest in the United States; one of the eight Ivy League institutions. , "they do not have an algorithm based upon Reidemeister moves." Mathematicians have also sought more tractable tractable easy to manage; tolerable. alternatives to the Haken algorithm for recognizing an unknot. One promising scheme was originally proposed in 1998 by Birman and computer scientist Michael D. Hirsch, then at Emory University Emory University (ĕm`ərē), near Atlanta, Ga.; coeducational; United Methodist; chartered as Emory College 1836, opened 1837 at Oxford. It became Emory Univ. in 1915 and in 1919 moved to Atlanta. in Atlanta. Birman and Hirsch took advantage of the fact that knots can be represented as braids. You can picture a mathematical braid as a set of strings, each one attached to a bar at the top and another bar at the bottom. Each string heads downward but may cross over or weave among the other strings along the way before reaching the bottom. You can then pull the bottom bar around and glue it to the top bar, connecting the strings in corresponding locations on the bars to form a closed braid. It turns out that every such braid corresponds to a knot, an unknot, or a set of linked knots. In general, mathematicians have found that braids are easier to understand and work with than knots. Moreover, they have a convenient scheme for coding a braid diagram in terms of a few numerical parameters, which enables them to readily reconstruct a knot from those values. Departing significantly from Haken's approach, Birman and Hirsch's novel algorithm for identifying unknots is built upon the idea of considering a knot or an unknot as a closed braid. In the Birman-Hirsch scheme, the braid's parameters can indicate whether it represents an unknot. A closed braid with given parameters serves as the boundary of a wrinkled disk with a particular type of folding and layering. Such layering patterns simplify the mathematicians' task. Initially, it wasn't entirely clear whether this idea could be translated into a workable recipe for identifying an unknot. Birman and her collaborators Marta Rampichini, Paolo Boldi, and Sebastiano Vigna of the University of Milan The university is a member of the League of European Research Universities. Throughout Milan, the University is normally known as Statale to avoid confusion with other academic institutions in the city. in Italy have now worked out a way to perform the systematic enumerations of unknots required to make the scheme practical. "It's definitely exciting to have an approach other than Haken's," Adams remarks. However, "we have yet to see whether this will be a fruitful approach computationally," he adds. Foolproof identification of unknots is only the first step, however. "The unknot is simply the easiest knot to study," Birman says. "Ultimately," Adams notes, "we would like an algorithm and computer program that would tell us whether any two knots are equivalent." That goal, however, remains elusive. Mathematicians have already developed some very fast, practical algorithms for distinguishing knots that belong to certain large classes, but these methods do not cover every possible type of knot. Identification and classification of knots is linked to an intriguing notion that geometrical structures known as 3-manifolds could serve as models of physical space in the universe (SN: 2/21/98, p. 123). The general theory of relativity Noun 1. general theory of relativity - a generalization of special relativity to include gravity (based on the principle of equivalence) Einstein's general theory of relativity, general relativity, general relativity theory posits that gravity is essentially a geometric effect--in other words, the theory links mass with the local curvature of space. Interestingly, it says nothing about the shape of the universe--the overall form, or topology, of the three-dimensional spatial component of relativity's four-dimensional space-time. An important example of a 3-manifold is the so-called complement of a knot, which can be imagined as all of space minus the knot. It's almost as if a microscopically thin worm had bored a hole through space leaving a twisty tunnel in its wake. "Knot complements are the most easily visualized 3-manifolds, so their study is a fundamental aspect of 3-manifold topology," Birman says. In the course of developing computer programs to help survey all types of 3-manifolds, mathematicians have inevitably also delved into the business of distinguishing knots. For example, the program known as SnapPea, developed by freelance geometer Jeffrey R. Weeks of Canton, N.Y., has been a remarkably successful tool for identifying knots. Although there is no mathematical guarantee that the method works in every case, it has yet to fail for an important class of knots, Haas notes. As a result of such mathematical efforts, cosmologists This is a list of cosmologists.
Studies of braids themselves have proved helpful in elucidating phenomena such as intriguing twists in the rings of Saturn The rings of Saturn are a system of planetary rings around the planet Saturn. They consist of countless small particles, ranging in size from microns to meters, each on its own individual orbit about Saturn. . Knots arise in the study of equations describing weather systems and in other mathematical models used in physics. "Often the knots play a fairly subtle role," Birman says. With intriguing applications in molecular biology molecular biology, scientific study of the molecular basis of life processes, including cellular respiration, excretion, and reproduction. The term molecular biology was coined in 1938 by Warren Weaver, then director of the natural sciences program at the Rockefeller and theoretical physics, along with surprising new results in solving long-standing mathematical conundrums, knot theory promises to keep mathematicians tied up for many years to come. |
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