 |
|
New accelerator technique doubles particle energy in just one meter
February 15, 2007Imagine a car that accelerates from zero to 60 in 250 feet, and then rockets to 120 miles per hour in just one more inch.
That's essentially what a collaboration of more than a dozen accelerator physicists has accomplished, using electrons for their racecars and plasma for the afterburners. Because electrons already travel at near light's speed in an accelerator, the physicists actually doubled the energy of the electrons, not their speed.
The researchers-from the Department of Energy's Stanford Linear Accelerator Center (SLAC), the UCLA Henry Samueli School of Engineering and Applied Science and the University of Southern California Viterbi School of Engineering-published their work in the Feb. 15 issue of Nature.
The achievement demonstrates a technology that may drive the future of accelerator design. To reach the high energies required to answer the new set of mysteries confronting particle physics-such as dark energy and the origin of mass-the newest accelerators are vastly larger, and consequently more expensive, than their predecessors. Very high-energy particle beams will be needed to detect the very short-lived particles that have eluded scientists so far.
"We hope that someday these breakthroughs will make future generations of accelerators feasible and affordable," said SLAC Deputy Director Persis Drell, who is not an author of the Nature study. "It's wonderful to see the tremendous progress in understanding the underlying physics for fundamentally new methods of accelerating particles."
While still in early stages of development, the research shows that acceleration using plasma, or ionized gas, can dramatically boost the energy of particles in a short distance.
"The scale is pretty remarkable," said SLAC physicist and study co-author Mark Hogan. "You need an airplane to take a picture of the 2-mile linear accelerator here. Yet in a space shorter than the span of your arms, we doubled the electrons' energy to the highest ever made here. I hope in the long term it leads to extending the capabilities of existing and upcoming machines at modest costs."
The electrons first traveled 2 miles through the linear accelerator at SLAC, gaining 42 billion electron volts (GeV) of energy. Then they passed through a 33-inch long (84-centimeter) plasma chamber and picked up another 42 GeV of energy. Like an afterburner on a jet engine, the plasma provides extra thrust. The plasma chamber is filled with lithium gas. As the electron bunch passes through the lithium, the front of the bunch creates plasma. This plasma leaves a wake that flows to the back of the bunch and shoves it forward, giving electrons in the back more energy.
The experiment created one of the biggest acceleration gradients ever achieved. The gradient is a measure of how quickly particles amass energy. In this case, the electrons hurtling through the plasma chamber gained almost 1,000 times more energy per foot (or about 3,000 times more energy per meter) than usual in the accelerator.
The recent advance is the culmination of almost a decade of work, led by SLAC Professor Robert Siemann, UCLA electrical engineering Professor Chan Joshi and USC engineering Professor Thomas Katsouleas.
"Physicists use particle accelerators to answer some of the most profound questions about the nature of the universe," said Joshi. "I am hopeful that plasma acceleration will enable us to continue the rich tradition of discovery."
Said study co-author and USC engineering Professor Patric Muggli: "We are all heartened that we are continuing to climb the plasma acceleration learning curve."
A current experimental limitation is that most of the electrons in a bunch lose their energy to the plasma.
"We take energy out of one part of the beam and put it into another part," Hogan said.
During the last two years, the team has improved the plasma acceleration gradient by a factor of 200. One of the next steps is to attempt a two-bunch system, where the first bunch provides all the energy to the trailing bunch. In a full-scale plasma accelerator, physicists would use those second bunches to create high-energy particle collisions in their detectors.
Stanford University
The achievement demonstrates a technology that may drive the future of accelerator design. To reach the high energies required to answer the new set of mysteries confronting particle physics-such as dark energy and the origin of mass-the newest accelerators are vastly larger, and consequently more expensive, than their predecessors. Very high-energy particle beams will be needed to detect the very short-lived particles that have eluded scientists so far.
"We hope that someday these breakthroughs will make future generations of accelerators feasible and affordable," said SLAC Deputy Director Persis Drell, who is not an author of the Nature study. "It's wonderful to see the tremendous progress in understanding the underlying physics for fundamentally new methods of accelerating particles."
While still in early stages of development, the research shows that acceleration using plasma, or ionized gas, can dramatically boost the energy of particles in a short distance.
"The scale is pretty remarkable," said SLAC physicist and study co-author Mark Hogan. "You need an airplane to take a picture of the 2-mile linear accelerator here. Yet in a space shorter than the span of your arms, we doubled the electrons' energy to the highest ever made here. I hope in the long term it leads to extending the capabilities of existing and upcoming machines at modest costs."
The electrons first traveled 2 miles through the linear accelerator at SLAC, gaining 42 billion electron volts (GeV) of energy. Then they passed through a 33-inch long (84-centimeter) plasma chamber and picked up another 42 GeV of energy. Like an afterburner on a jet engine, the plasma provides extra thrust. The plasma chamber is filled with lithium gas. As the electron bunch passes through the lithium, the front of the bunch creates plasma. This plasma leaves a wake that flows to the back of the bunch and shoves it forward, giving electrons in the back more energy.
The experiment created one of the biggest acceleration gradients ever achieved. The gradient is a measure of how quickly particles amass energy. In this case, the electrons hurtling through the plasma chamber gained almost 1,000 times more energy per foot (or about 3,000 times more energy per meter) than usual in the accelerator.
The recent advance is the culmination of almost a decade of work, led by SLAC Professor Robert Siemann, UCLA electrical engineering Professor Chan Joshi and USC engineering Professor Thomas Katsouleas.
"Physicists use particle accelerators to answer some of the most profound questions about the nature of the universe," said Joshi. "I am hopeful that plasma acceleration will enable us to continue the rich tradition of discovery."
Said study co-author and USC engineering Professor Patric Muggli: "We are all heartened that we are continuing to climb the plasma acceleration learning curve."
A current experimental limitation is that most of the electrons in a bunch lose their energy to the plasma.
"We take energy out of one part of the beam and put it into another part," Hogan said.
During the last two years, the team has improved the plasma acceleration gradient by a factor of 200. One of the next steps is to attempt a two-bunch system, where the first bunch provides all the energy to the trailing bunch. In a full-scale plasma accelerator, physicists would use those second bunches to create high-energy particle collisions in their detectors.
Stanford University
IBEX spacecraft detects fast neutral hydrogen coming from the moon
NASA's Interstellar Boundary Explorer (IBEX) spacecraft has made the first observations of very fast hydrogen atoms coming from the moon, following decades of speculation and searching for their existence.
More Particle Energy Current Events and Particle Energy News Articles
 |
Introduction to Elementary Particles by David Griffiths (Author) In Introduction to Elementary Particles, Second, Revised Edition, author David Griffiths strikes a balance between quantitative rigor and intuitive understanding, using a lively, informal style. The first chapter provides a detailed historical introduction to the subject, while subsequent chapters offer a quantitative presentation of the Standard Model. A simplified introduction to the Feynman rules, based on a "toy" model, helps readers learn the calculational techniques without the complications of spin. It is followed by accessible treatments of quantum electrodynamics, the strong and weak interactions, and gauge theories. New chapters address neutrino oscillations and prospects for physics beyond the Standard Model. The book contains a number of worked examples and many end-of-chapter... |
 |
Fool Me Once: A New World Order Agenda for 2012 Starring: Ian Crane, Ian R. Crane Directed By: World Wide Multi Media Also With: Ian Crane (Producer), Ian Crane (Writer) "Fool Me Once" is the latest offering from one of the UK's most active Truth Proponents. Ian R. Crane, the immediate past Chair of the UK 9/11 Truth Campaign, reflects upon Gordon Brown's overt commitment to the agenda of the New World Order and offers a startling prediction of what is being planned to accelerate implementation of the One World Government, with particular focus on the 2012 London Olympics.Recorded live at the Glastonbury Symposium in July, 2007An ex-oilfield executive, Ian R. Crane now lectures and writes on the geo-political webs that are being spun; with particular focus on US hegemony and the NWO agenda for control of global resources. Prior to his retirement from the corporate arena, Ian enjoyed a career of 25 years in telecommunications and international oilfield... |
 |
Energy Particles in a Molecule Photographic Poster Print by Panoramic Images, 60x20 by AllPosters.com AllPosters.com is the world's #1 seller of posters, prints, photographs, specialty products and framed art. We're dedicated to bringing our customers the best selection of high quality wall décor that is perfect for their home or office. Browse our catalog of over 300,000 items that include entertainment and specialty posters, decorative prints, and art reproductions. Whether you're looking for your favorite movie or music poster, a framed Monet reproduction, or a print of the Eiffel Tower you will find it at AllPosters.com. Visit our Amazon store today at www.amazon.com/allposters to find Special Offers and search by subject category or artist. AllPosters.com provides unmatched service with a 100% satisfaction guarantee. We ship internationally to over 80 countries. Decorate your... |
 |
But A Machine That Was Powerful Enough To Accelerate Particles To The Grand Unification Energy Would Have To Be As Big As The Solar System - And Would Be Unlikely To Be Funded In The Present Economic Knut Olaf Sunde (Primary Contributor) |
|
Cloudseeder (2CD) by Wave World | |
 |
Deep Down Things: The Breathtaking Beauty of Particle Physics by Bruce A. Schumm (Author) A useful scientific theory, claimed Einstein, must be explicable to any intelligent person. In Deep Down Things, experimental particle physicist Bruce Schumm has taken this dictum to heart, providing in clear, straightforward prose an elucidation of the Standard Model of particle physics—a theory that stands as one of the crowning achievements of twentieth-century science. In this one-of-a-kind book, the work of many of the past century's most notable physicists, including Einstein, Schrodinger, Heisenberg, Dirac, Feynman, Gell-Mann, and Weinberg, is knit together in a thorough and accessible exposition of the revolutionary notions that underlie our current view of the fundamental nature of the physical world. Schumm, who has spent much of his life emmersed in the subatomic world, goes... |
 |
Broan SmartSense 110 CFM Fan Kit with Controller Switch by Broan-Nutone Having fresh air in your home is essential to the health of you and your family. The Broan SmartSense 110 CFM Fan creates proper ventilation, moving 110 cubic feet of air per minute (CFM), replacing stale air, minimizing mold and mildew growth and removing gases and particles not trapped by filtration units. Additionally it will reduce indoor pollutants such as household cleaners, VOCs, carbon monoxide, and off-gassing formaldehyde from building materials, carpets and other furnishings, making it ideal for both home and commercial applications. While a single fan can handle larger homes, it is recommended to use multiple units for homes with multiple bathrooms to provide distributed ventilation throughout. The included Smartsense controller switch looks and installs just like any normal... |
 |
Dove Energy Glow Shimmering Lotion With Soft Shimmer Particles, All Skin Tones, Packaging May Vary, 10.8 Oz (320 Ml) by Dove Gives skin a subtle radiant glow. Dove believes that real beauty can be genuinely stunning. That's why Dove developed Energy Glow Shimmering Lotion. Enriched with delicate skin brighteners, it gives your skin a subtle radiant glow. |
 |
Elementary Particles and the Laws of Physics: The 1986 Dirac Memorial Lectures by Richard P. Feynman (Author), Steven Weinberg (Author) Developing a theory that seamlessly combines relativity and quantum mechanics, the most important conceptual breakthroughs in twentieth century physics, has proved to be a difficult and ongoing challenge. This book details how two distinguished physicists and Nobel laureates have explored this theme in two lectures given in Cambridge, England, in 1986 to commemorate the famous British physicist Paul Dirac. Given for nonspecialists and undergraduates, the talks transcribed in Elementary Particles and the Laws of Physics focus on the fundamental problems of physics and the present state of our knowledge. Professor Feynman examines the nature of antiparticles, and in particular the relationship between quantum spin and statistics. Professor Weinberg speculates on how Einstein's theory... |
 |
Particle Physics: A Very Short Introduction by Frank Close (Author) In Particles: A Very Short Introduction, best-selling author Frank Close provides a compelling and lively introduction to the fundamental particles that make up the universe. The book begins with a guide to what matter is made up of and how it evolved, and goes on to describe the fascinating and cutting-edge techniques used to study it. The author discusses particles such as quarks, electrons, and the neutrino, and exotic matter and antimatter. He also investigates the forces of nature, accelerators and detectors, and the intriguing future of particle physics. This book is essential reading for general readers interested in popular science, students of physics, and scientists at all levels. |
| © 2009 BrightSurf.com |