Taking turbulence models to a new level. (Fast Findings on Fluid Frenzy).From blood spurting through hearts to winds buffeting cars, fluids swirl and tumble in complex ways that scientists struggle to understand. Now, a new means to efficiently depict fluid turbulence and to calculate its effects promises to influence many branches of science and technology. For example, using the new method, car designers can compute aerodynamic simulations of full, three-dimensional vehicles at highway speeds quickly enough to incorporate the information into the design of cars, say the technique's developers. With previous methods, designers typically had time only to simulate two-dimensional flows or 3-D models for which the car was portrayed in a simplified form or was moving at a crawl. Two-thirds of the world's major automakers have begun using the new simulations, says Hudong Chen, chief scientist at EXA Corp. in Lexington, Mass., which creates and sells software based on the new simulation method. Conventional methods of calculating turbulence treat fluids not as molecular assemblages but as continuous substances. The new approach includes some of the underlying, microscopic nature of fluids, which surprisingly turns out to be advantageous. The new technique, described in the Aug. 1 Science, "should become the method of choice when fast answers are needed for fluid flows of complex geometry In mathematics, complex geometry is the study of complex manifolds and functions of many complex variables. ," comments David C. Montgomery of Dartmouth College Dartmouth College, at Hanover, N.H.; coeducational; chartered 1769, opened 1770, the ninth colonial college (see Wheelock, Eleazar). Originally a men's college, Dartmouth began admitting women in 1972. in Hanover, N.H. Such complex flows can occur as heat travels through electronic devices and as plumes of pollutants pollutants see environmental pollution. infiltrate infiltrate /in·fil·trate/ (in-fil´trat) 1. to penetrate the interstices of a tissue or substance. 2. the material or solution so deposited. in·fil·trate v. 1. an environment, scientists say. For more than 2 centuries, scientists have been using mathematical formulations called Navier-Stokes equations The Navier-Stokes equations, named after Claude-Louis Navier and George Gabriel Stokes, describe the motion of fluid substances such as liquids and gases. These equations establish that changes in momentum in infinitesimal volumes of fluid are simply the sum of dissipative viscous to calculate the precise velocity, pressure, and temperature of a fluid at any location and time. Yet those equations are impossible to solve completely in all but the simplest scenarios, in which fluids flow smoothly and steadily. To simulate more realistic flows on computers, scientists have long used approximations of the Navier-Stokes equations, but those simplified models can't duplicate certain important features of the flows. They also demand inordinate amounts of computing power. The new method relies on a different equation, called the Boltzmann equation The Boltzmann equation, also often known as the Boltzmann transport equation, devised by Ludwig Boltzmann, describes the statistical distribution of particles in a fluid. , which is typically employed to predict the behaviors of molecules in gases and liquids. More than a decade ago, researchers were surprised to learn that using the Boltzmann equation to calculate simple fluid flows didn't make the simulations more difficult or time consuming to carry out. "It's the counterintuitive coun·ter·in·tu·i·tive adj. Contrary to what intuition or common sense would indicate: "Scientists made clear what may at first seem counterintuitive, that the capacity to be pleasant toward a fellow creature is ... approach," says Steven A. Orszag 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 , a coauthor of the Science paper and an EXA consultant. "If you start from the very microscopic dynamics, you would think you'd have to compute much too much." More recently, Orszag, Chen, and their colleagues found a way to include turbulence in their Boltzmann equation-based simulations at little additional computing cost. The trick was to invent a particular mathematical representation of disruption of particle motions by disorderly flows. That last step was "really a breakthrough from my point of view," comments Roberto Benzi of the University of Rome Tor Vergata Organization These are the 6 schools in which the university is divided into:
|
|
||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion