Dr. Feynman's doodles: how one scientist's simple sketches transformed physics.The next time you get a letter, its stamp might have printed on it examples of one the greatest conceptual tools of modern physics. The tool is a kind of line drawing, and a bunch of those drawings appear on the face of a new U.S. postage stamp postage stamp, government stamp affixed to mail to indicate payment of postage. The term includes stamps printed or embossed on postcards and envelopes as well as the adhesive labels. honoring a legendary physicist, the late Richard P. Feynman. Those drawings are ubiquitous in physics today. "If you walk into a physics building anywhere in the world, you see those [drawings] on the blackboards," says David I David I, king of Scotland David I, 1084–1153, king of Scotland (1124–53), youngest son of Malcolm III and St. Margaret of Scotland. During the reign of his brother Alexander I, whom he succeeded, David was earl of Cumbria, ruling S of the Clyde . Kaiser, a physicist and historian at the Massachusetts Institute of Technology Massachusetts Institute of Technology, at Cambridge; coeducational; chartered 1861, opened 1865 in Boston, moved 1916. It has long been recognized as an outstanding technological institute and its Sloan School of Management has notable programs in business, (MIT MIT - Massachusetts Institute of Technology ) who recently wrote a book about the sketches. Created by Feynman in the 1940s to solve one of the most vexing puzzles of theoretical physics at the time--a feat for which he would share the 1965 Nobel Prize Nobel Prize, award given for outstanding achievement in physics, chemistry, physiology or medicine, peace, or literature. The awards were established by the will of Alfred Nobel, who left a fund to provide annual prizes in the five areas listed above. in Physics--the drawings give physicists a quick, intuitive way to organize and understand difficult calculations. As scientists were uncovering droves of new subatomic particles in the 1950s and 1960s, Feynman diagrams-as the drawings came to be known--offered a means for visualizing the unfamiliar entities and their interactions. Because these cartoonish sketches seemed to depict subatomic particles breaking the established rules of quantum physics quantum physics n. (used with a sing. verb) The branch of physics that uses quantum theory to describe and predict the properties of a physical system. quantum physics See quantum mechanics. , many eminent physicists were initially reluctant to adopt them. In the 1940s, some young theorists who embraced the tool had to meet in secret to learn how to use it to tackle formidable calculations. After only a few years, however, the approach caught on. "Feynman diagrams ... revolutionized nearly every aspect of theoretical physics," Kaiser says. PICTURE PERFECT Immortalized in books and plays, Feynman is adored as a mischief maker, impulsive explorer, drummer, and blunt, eccentric personality. He is equally adored for his dazzling intellect and groundbreaking contributions to quantum physics. Like Feynman himself, the diagrams he created are both disarmingly straightforward and subtly complex, says longtime Feynman colleague and friend Barry C. Barish of the California Institute of Technology California Institute of Technology, at Pasadena, Calif.; originally for men, became coeducational in 1970; founded 1891 as Throop Polytechnic Institute; called Throop College of Technology, 1913–20. (CalTech) in Pasadena. Feynman taught at CalTech from 1950 until his death in 1988. Although inscrutable to the uninitiated, a typical Feynman diagram looks simple. It might easily be a copy of a mysterious glyph A displayed or printed image. In typography, a glyph may be a single letter, an accent mark or a ligature. See grapheme. (character) glyph - An image used in the visual representation of characters; roughly speaking, how a character looks. A font is a set of glyphs. from some prehistoric cave or a rudimentary type of trail map. For physicists, however, the diagrams offer a bare-bones way of representing extremely complicated mathematical expressions. Before World War II, the world's most brilliant physicists were frustrated by their inability to push forward understanding of quantum electrodynamics quantum electrodynamics (QED), quantum field theory that describes the properties of electromagnetic radiation and its interaction with electrically charged matter in the framework of quantum theory. , the field that considers the nature of electricity and magnetism in realms where even atoms appear large and particles move at speeds near that of light. In these realms, both quantum mechanics quantum mechanics: see quantum theory. quantum mechanics Branch of mathematical physics that deals with atomic and subatomic systems. It is concerned with phenomena that are so small-scale that they cannot be described in classical terms, and it is and relativistic rel·a·tiv·is·tic adj. 1. Of or relating to relativism. 2. Physics a. Of, relating to, or resulting from speeds approaching the speed of light: relativistic increase in mass. effects on time and space become important. Physicists began by applying fundamental physical principles to calculate particles' quantum-electrodynamic properties, but they got nonsensical answers, such as energies or masses that were infinite. Meanwhile, calculations of even the simplest of scenarios, such as a single electron absorbing a single photon, could fill pages with arcane mathematical expressions. Seeking a way through the morass, Feynman turned to pictures. "He thought of things visually," Barish says. With his sketches, Feynman found that he could visualize interactions among particles. The drawings also served as shorthand for the equations, enabling Feynman to keep track of all the mathematical terms. As he was making these pictures to visualize various terms, Feynman suddenly had an inkling of the revolutionary path he was on. "Wouldn't it be funny if this turns out to be useful, and the Physical Review would be all full of these funny-looking pictures?" he thought to himself, as quoted in QED QED abbr. Latin quod erat demonstrandum (which was to be demonstrated) QED which was to be shown or proved [Latin quod erat demonstrandum] Noun 1. and the Men Who Made It (1994, Silvan S. Schweber, Princeton University Press) from a 1966 interview. CRITICAL MASS As prescient pre·scient adj. 1. Of or relating to prescience. 2. Possessing prescience. [French, from Old French, from Latin praesci as Feynman's musing proved to be, his drawings weren't an instant hit. In fact, his first formal introduction of the diagrams to the finest minds in physics was a bust. During a heady year beginning in the spring of 1947, Julian Schwinger of Harvard University finally managed to calculate a value for the strength of the electron's magnetic field that agreed with new experimental findings. Meanwhile, Feynman, then a professor at Cornell University, learned that his diagrammatic approach could more easily yield similar answers. Others became enchanted en·chant tr.v. en·chant·ed, en·chant·ing, en·chants 1. To cast a spell over; bewitch. 2. To attract and delight; entrance. See Synonyms at charm. with Feynman's technique. Among them was a young Cornell graduate student named Freeman J. Dyson. "I just thought that it was magic and it was my job to try to understand it," recalls Dyson, now 81. In March 1948, Feynman, then 29 years old, joined other up-and-coming pioneers of the new computational approaches to attend a tete-a-tete in the Pennsylvania mountains with many of the physicists already recognized as the intellectual giants of the era. The group included Niels Bohr, Paul Dirac, Enrico Fermi, and J. Robert Oppenheimer, then director of the Institute for Advanced Study in Princeton, N.J. The audience patiently followed an elaborate presentation by Schwinger, in which he presented virtuoso manipulations of thick jungles of equations. But when Feynman stepped to the blackboard and started to scribble scribble - To modify a data structure in a random and unintentionally destructive way. "Bletch! Somebody's disk-compactor program went berserk and scribbled on the i-node table." "It was working fine until one of the allocation routines scribbled on low core. diagrams, the audience leaped to challenge him. Turning a deaf ear to the details of his method, many in the group demanded proof that the physics depicted in the diagrams wasn't violating basic principles of quantum mechanics. "The greats of quantum theory had no idea what he was doing,' MIT's Kaiser says. "They were dismissive. They took the chalk out of [Feynman's] hand." In the fall of 1948, Dyson moved to the Institute for Advanced Study, where he still is today. Initially, Oppenheimer so thoroughly disapproved of Feynman's diagrams that he would interrupt every time Dyson tried to speak about the method. When other postdoctoral students urged Dyson to give talks about the new approach, the group had to meet secretly. In time, these initiates became ambassadors for the technique, which they helped to spread throughout the particle physics community. DIAGRAMS 101 Making intuitive sense of simple Feynman diagrams requires only learning the meanings of a few lines and following some easy rules. Typically, the diagrams contain straight, solid lines representing particles of matter or antimatter antimatter: see antiparticle. antimatter Substance composed of elementary particles having the mass and electric charge of ordinary matter (such as electrons and protons) but for which the charge and related magnetic properties are opposite in sign. , such as electrons or positrons, and wavy or dashed lines representing force-carrying particles, such as photons. The particles appear as lines because those pointlike particles are moving through space and time. A common rule is that time advances from the bottom to the top of the diagram. Consider the Feynman diagram that looks a bit like a person in a spread-eagle stance. It represents electrons repelling each other. This example was one that Feynman presented at the diagrams' flop of a debut, and it was also one of the first Feynman diagrams to be published. A similar diagram appeared on Feynman's left shoulder, in the new postage stamp. In the spread-eagle diagram, an electron appearing from the bottom right emits a photon of light, the wavy line. In response to firing off that photon, the electron recoils to the right. As the electron on the left absorbs the photon, it gets a momentum kick to the left. Voila! The two particles, both with similar, negative electric charges, repel each other. While literally getting the picture can be that easy, making the diagram is typically just the beginning of a process in which the physicist uses standard rules to map each line segment and intersection of lines to specific mathematical terms. For Feynman's readily understood spread-eagle diagram, Kaiser notes, the mathematical result looks like this: [MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII ASCII or American Standard Code for Information Interchange, a set of codes used to represent letters, numbers, a few symbols, and control characters. Originally designed for teletype operations, it has found wide application in computers. ] The Feynman diagram doesn't make it any easier for physicists to actually compute a number from such a mathematical expression. What it does do, Barish says, is guide them to the correct expression and show them how to manipulate it. Before Feynman diagrams, even the simplest calculations were "a nightmare," says Toichiro (Tom) Kinoshita of Cornell. They "took months of effort, which Feynman diagrams render[ed] to a few hours of work," he says. Once physicists got the knack of using diagrams to depict interactions involving the electromagnetic force, "people could handle incredibly complicated calculations they hadn't dreamed were possible before," adds Kaiser. A new book by Kaiser entitled Drawing Theories Apart (2005, University of Chicago Press The University of Chicago Press is the largest university press in the United States. It is operated by the University of Chicago and publishes a wide variety of academic titles, including The Chicago Manual of Style, dozens of academic journals, including ), which was released July 15, chronicles the diffusion of Feynman diagrams. A condensed con·dense v. con·densed, con·dens·ing, con·dens·es v.tr. 1. To reduce the volume or compass of. 2. To make more concise; abridge or shorten. 3. Physics a. version appeared in the March-April American Scientist. As Feynman's new technique spread in the early 1950s, physicists started applying the diagrams to areas outside the theory of quantum electrodynamics. Today, those areas span a broad reach of physics, including studies of gravity, quark-containing particles such as mesons This is a list of mesons; it is not comprehensive.this is a stub Particle Symbol Anti- particle Quark Makeup Spin and parity Rest mass MeV/c² S C B Mean lifetime s Principal decays Notes Charged Pion , and many-atom systems such as solids or liquids. In each of these cases, physicists have used the diagrams to conceptualize con·cep·tu·al·ize v. con·cep·tu·al·ized, con·cep·tu·al·iz·ing, con·cep·tu·al·iz·es v.tr. To form a concept or concepts of, and especially to interpret in a conceptual way: phenomena and to translate them into mathematics. Theorists, including Feynman himself, were sometimes skeptical of such expansions. In a 1951 letter, Feynman warned Enrico Fermi, "Don't believe any calculation in meson meson (mē`zŏn) [Gr.,=middle (i.e., middleweight)], class of elementary particles whose masses are generally between those of the lepton class of lighter particles and those of the baryon class of heavier particles. theory which uses a Feynman diagram!" Nonetheless, the method proved to be highly fruitful. "The power of those diagrams and much of the reason for their resilience, is that they can be used to represent and keep track of, in a very useful way, an inordinate amount of very sophisticated physics," says CalTech theorist H. David Politzer Hugh David Politzer (born 31 August 1949) is an American theoretical physicist. He shared the 2004 Nobel Prize in Physics with David Gross and Frank Wilczek for their discovery of asymptotic freedom in quantum chromodynamics. Politzer was born in New York City. . He shared the 2004 Nobel Prize in Physics The Nobel Prize in Physics (Swedish: Nobelpriset i fysik) is awarded once a year by the Royal Swedish Academy of Sciences. It is one of the six Nobel Prizes. The first prize was awarded in 1901. for a 1970s advance that used modified Feynman diagrams to solve problems in quark theory, or quantum chromodynamics. BACK TO THE FUTURE Although physics has changed and expanded vastly since Feynman came up with his diagrams, the technique remains a major tool. It's "flourishing more and more all the time," Kaiser says. In the field of quantum electrodynamics, some researchers carry out ever-more-complex computations using ever-greater numbers of diagrams. Their aim is to predict with unprecedented precision important properties of specific particles. For example, in an ongoing effort to determine the strength of the magnetic field of the electron with increasing precision, Kinoshita and three colleagues are generating and analyzing a record-breaking 12,672 Feynman diagrams. The most precise prior calculation of that property employed 891 Feynman diagrams, which translated into more than 100 mathematical expressions called integrals, notes Kinoshita. Computing each integral, which contains tens of thousands of terms, required "more than 3 or 4 months of computation on high-speed parallel computers," he says. Kinoshita completed that computation last May after working on it with a series of graduate students for nearly 25 years and using more than a decade of computer time. Efforts to evaluate Feynman diagrams by computer date to the early 1960s. In the late 1970s, one such effort at CalTech led to a high-profile spin-off. Stephen Wolfram wolfram: see tungsten. , a physics wunderkind wun·der·kind n. pl. wun·der·kin·der 1. A child prodigy. 2. A person of remarkable talent or ability who achieves great success or acclaim at an early age. who is now renowned as the promoter of a controversial, computational approach to science (SN: 3/20/04, p. 189), was then a graduate student writing software to solve the math related to Feynman diagrams. In the process, Wolfram came up with new ways of manipulating the algebraic 1. (language) ALGEBRAIC - An early system on MIT's Whirlwind. [CACM 2(5):16 (May 1959)]. 2. (theory) algebraic - In domain theory, a complete partial order is algebraic if every element is the least upper bound of some chain of compact elements. symbols that those diagrams represent. "That led me to the realization that you could use computers to do all kinds of algebra,' recalls Wolfram. By the mid-1980s, he had created a now widely used computer-algebra software package called Mathematica. Today, researchers continue to improve the software to automate ultrahigh-precision calculations. As theoretical physics evolves, so do Feynman diagrams. For instance, a thriving branch of physics known as string theory holds that the fundamental ingredients of matter and energy are not pointlike particles but infinitesimal 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. , stringlike entities (SN: 9/25/04, p. 202). This concept has begotten be·got·ten v. A past participle of beget. begotten Verb a past participle of beget Adj. 1. novel versions of the diagrams based on those strings. In one such diagram, moving strands are pictured as made up of sheetlike, wavy surfaces. In another type of diagram, strings that are closed back on themselves as loops and moving through space-time appear as branching, tubular figures, notes string theorist Barton Zwiebach of MIT. The diagrams for string theory and their accompanying mathematics have broad applications. For instance, scientists are using them to calculate specific properties of gluons Gluons The hypothetical force particles believed to bind quarks into “elementary” particles. Although theoretical models in which the strong interactions of quarks are mediated by gluons have been successful in predicting, interpreting, and , which prevailing theory identifies as point particles, Zwiebach says. Those results, in turn, may guide future accelerator experiments seeking a new family of fundamental particles known as supersymmetric partners. Similarly, Kinoshita's quantum-electrodynamics calculations aim to uncover discrepancies between theory and experiment that could yield signs of never-before-discovered particles. Like the trail maps that they resemble, Feynman diagrams continue to point the way for physicists. "For all of Feynman's many contributions to modern physics," Kaiser says, "his diagrams have had the widest and longest-lasting influence." STAMP OF GENIUS--The diagrams surrounding young Richard Feynman's face depict interactions between subatomic particles according to a method that Feynman came up with in the 1940s. Today, physicists rely on such pictures to understand behaviors of matter and energy and to guide complex calculations. STRUNG OUT--Distinctive versions of Feynman diagrams, such as this one, arise from string theory, which proposes that infinitesimal vibrating vibrating, v using quivering hand motions made across the client's body for therapeutic purposes. strands or loops make up all matter and energy. |
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