 |
|
Physicists uncover new solution for cosmic collisions
January 11, 2008Troy, N.Y. - It turns out that our math teachers were right: being able to solve problems without a calculator does come in handy in the "real" world. Two theoretical physicists at Rensselaer Polytechnic Institute have used what they call "pen-and-paper math" to describe the motion of interstellar shock waves - violent events associated with the birth of stars and planets.
The findings, published recently in the Monthly Notices of the Royal Astronomical Society, could provide astronomers with important information on the history of the solar system, the formation of stars, and the creation of chemicals that may have formed the basis for planets and even life on Earth.
"Shock waves can teach us valuable information about the history of our solar system," said Wayne Roberge, lead author and professor of physics, applied physics, and astronomy at Rensselaer. "If we can understand shock waves - how they move, what leads to their formation, their temperature - we can begin to understand where we came from and what our galaxy went through five billion years ago."
The mathematical solution developed by Roberge and his colleague, adjunct professor Glenn Ciolek, reveals the force and movement of shock waves in plasma, the neutral and charged matter that makes up the dilute "air" of space. Unlike many previous studies of its kind, the researchers focused specifically on shock waves in plasma, which move matter in very different ways than the uncharged air on Earth.
According to the researchers, the findings could influence the success of research conducted by NASA's upcoming mission, the Stratospheric Observatory for Infrared Astronomy (SOFIA), a modified Boeing 747SP aircraft with an infrared telescope expected to begin test flights in the coming months. Roberge noted that the findings could also be important for studies using NASA's Spitzer Space Telescope (the infrared sister of the Hubble Telescope).
"Astronomers are now venturing into infrared telescopes, which allows you to look deeper into space," Roberge said. "But because they can only detect heat, the search for chemicals in deep space using infrared technology is greatly hindered in cold interstellar space." Super-hot shock waves are like fiery arrows in the sky when viewed through an infrared telescope, pointing out the origins and destination of chemicals throughout the universe, Roberge said.
"Our mathematical solution will help point astronomers in the right direction when they look at shock waves," he said. "It lets them know what they should discover. We hope the actual space images developed in the coming months and years prove our calculations to be correct."
As shock waves travel, they heat and condense interstellar plasma, forming new chemical compounds through intense heat and pressure. The motion of shock waves also distributes the chemical products around the galaxy. On Earth, shock waves are commonly associated with supersonic aircraft and explosions. In space, shock waves are commonly associated with the birth or death of a star.
When stars are born, they often emit jets of matter moving at hundreds of thousands of miles per hour. The impact of these jets onto surrounding material creates an extreme and sudden disturbance. This material does not have time to react to the sudden pile-up of energy and mass. Shock waves lash out into the surrounding plasma to expel the sudden force. These shock waves spread material through space, potentially "seeding" new solar systems with chemicals that may be important for life.
"Now that we understand how fast and far these waves move in space, we can begin to understand how chemicals, including chemicals necessary for life, can be formed by shock waves and spread around the universe to form new stars, planets, and life," Roberge said.
Rensselaer Polytechnic Institute
The mathematical solution developed by Roberge and his colleague, adjunct professor Glenn Ciolek, reveals the force and movement of shock waves in plasma, the neutral and charged matter that makes up the dilute "air" of space. Unlike many previous studies of its kind, the researchers focused specifically on shock waves in plasma, which move matter in very different ways than the uncharged air on Earth.
According to the researchers, the findings could influence the success of research conducted by NASA's upcoming mission, the Stratospheric Observatory for Infrared Astronomy (SOFIA), a modified Boeing 747SP aircraft with an infrared telescope expected to begin test flights in the coming months. Roberge noted that the findings could also be important for studies using NASA's Spitzer Space Telescope (the infrared sister of the Hubble Telescope).
"Astronomers are now venturing into infrared telescopes, which allows you to look deeper into space," Roberge said. "But because they can only detect heat, the search for chemicals in deep space using infrared technology is greatly hindered in cold interstellar space." Super-hot shock waves are like fiery arrows in the sky when viewed through an infrared telescope, pointing out the origins and destination of chemicals throughout the universe, Roberge said.
"Our mathematical solution will help point astronomers in the right direction when they look at shock waves," he said. "It lets them know what they should discover. We hope the actual space images developed in the coming months and years prove our calculations to be correct."
As shock waves travel, they heat and condense interstellar plasma, forming new chemical compounds through intense heat and pressure. The motion of shock waves also distributes the chemical products around the galaxy. On Earth, shock waves are commonly associated with supersonic aircraft and explosions. In space, shock waves are commonly associated with the birth or death of a star.
When stars are born, they often emit jets of matter moving at hundreds of thousands of miles per hour. The impact of these jets onto surrounding material creates an extreme and sudden disturbance. This material does not have time to react to the sudden pile-up of energy and mass. Shock waves lash out into the surrounding plasma to expel the sudden force. These shock waves spread material through space, potentially "seeding" new solar systems with chemicals that may be important for life.
"Now that we understand how fast and far these waves move in space, we can begin to understand how chemicals, including chemicals necessary for life, can be formed by shock waves and spread around the universe to form new stars, planets, and life," Roberge said.
Rensselaer Polytechnic Institute
Shock Waves News and Current Shock Waves Events RSSVisualizing atomic-scale acoustic wavesin nanostructures
Acoustic waves play many everyday roles - from communication between people to ultrasound imaging. Now the highest frequency acoustic waves in materials, with nearly atomic-scale wavelengths, promise to be useful probes of nanostructures such as LED lights.
CSI: Milky Way team works scene of dead star
Like a team of forensic detectives in a television show that could be called "CSI: Milky Way," a University of Chicago astrophysicist and his associates are piecing together how a mysterious infrared ring got left around a dead star that displays a magnetic field trillions of times more intense than Earth's.
Big quakes spark jolts worldwide
Until 1992, when California's magnitude-7.3 Landers earthquake set off small jolts as far away as Yellowstone National Park, scientists did not believe large earthquakes sparked smaller tremors at distant locations.
Earthquake in Illinois could portend an emerging threat
To the surprise of many, the earthquake on April 18, 2008, about 120 miles east of St. Louis, originated in the Wabash Valley Fault and not the better-known and more-dreaded New Madrid Fault in Missouri's bootheel.
Radiation flashes may help crack cosmic mystery
Faint, fleeting blue flashes of radiation emitted by particles that travel faster than the speed of light through the atmosphere may help scientists solve one of the oldest mysteries in astrophysics.
Leading-edge body sensor could help produce sporting champions
A revolutionary unobtrusive sensor that collects and immediately transmits data from the human body could boost British sporting success in future.
XMM-Newton reveals X-rays from gas streams around young stars
XMM-Newton has surveyed nearly two hundred stars under formation to reveal, contrary to expectations, how streams of matter fall onto the young stars' magnetic atmospheres and radiate X-rays.
Galaxy Cluster Takes It to the Extreme
Evidence for an awesome upheaval in a massive galaxy cluster was discovered in an image made by NASA's Chandra X-ray Observatory. The origin of a bright arc of ferociously hot gas extending over two million light years requires one of the most energetic events ever detected.
Liquid CO2 drives rapid thrust of diamond-bearing structures
Freeze-dried ice cream looks like the original product, and even tastes pretty good, but "drying" ice cream at room temperature would leave a sour-smelling, sloppy mess.
Hubble sees multiple star generations in a globular cluster
Hubble's observations of the massive globular cluster NGC 2808 provide evidence for three generations of stars that formed early in its life. This is a major upset for conventional theories that propose a single period of star birth.
More Shock Waves News Articles
 | Shock Wave (Dirk Pitt Adventure) by Clive Cussler In this explosive Dirk Pitt novel by the author of Inca Gold, Pitt meets the most intriguing and sinister villain of his adventurous and legendary career--a billionaire Australian diamond king with whom he must wage conflict above and below the sea for the survival of vast numbers of sea creatures and more than a million human beings. Only Clive Cussler--the Grandmaster of Adventure--could have... |
 | Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena by Ya. B. Zel'dovich, Yu. P. Raizer Physical, chemical processes in gases at high temperatures are focus of outstanding text by two distinguished physicists. Combines material from gas dynamics, shock-wave theory, thermodynamics and statistical physics, molecular physics, spectroscopy, radiation theory, other fields for comprehensive treatment. 284 black-and-white illustrations. 1966–1967 edition, originally published in two... |
 | Explosive Effects and Applications This is a broad-based text on the fundamentals of explosive behavior and the application of explosives in civil engineering, industrial processes, aerospace applications, and military uses. The book includes chapters on all aspects of explosives, each written by an expert in the field: Introduction to Explosives (W.C. Davis) Explosives Development and Fundamentals of Explosives Technology... |
| Shock Waves (Nancy Drew & Hardy Boys Super Mysteries #3) by Carolyn Keene, Franklin W. Dixon | |
 | Supersonic Flow and Shock Waves (Applied Mathematical Sciences) by Richard Courant, K.O. Friedrichs The Springer edition of this book is an unchanged reprint of Courant and Friedrich's classical treatise which was first published in 1948. The basic research for it took place during World War II, but there are many aspects which still make the book interesting as a text and as a reference. It treats basic aspects of the dynamics of compressible fluids in mathematical form, and attempts to... |
 | Shock Wave (A Billy Tasker Mystery) by James O. Born There's Die Hard action in James O. Born's second novel featuring Florida law enforcement agent Bill Tasker, who's stirring up trouble with a bomber who hasn't killed... |
 | Shock Waves: Measuring The Dynamic Response Of Materials by William M. Isbell This book presents, in a concise and comprehensive manner, the essential techniques by which shock wave physicists probe the boundaries of material response to impulsive... |
 | Shock Wave Engine Design by Helmut E. Weber Written by an author who has devoted the past twenty-five years of his life to studying and designing shock wave engines, this unique book offers comprehensive coverage of the theory and practice of shock wave engine design. The only book treating the complete preliminary design of shock wave engines, it provides engineers with practical step-by-step guidelines applicable to the design and... |
 | Unsteady Interaction of Shock & Detonation Waves in Gases by V. Korobeinikov |
 | Differential Models by Alexander Solodov, Valery Ochkov Differential equations are often used in mathematical models for technological processes or devices. However, the design of a differential mathematical model is crucial and difficult in engineering. As a hands-on approach to learn how to pose a differential mathematical model the authors have selected 9 examples with important practical application and treat them as following:- Problem-setting... |
| © 2008 BrightSurf.com |