 |
|
Bon MOT: Innovative atom trap catches highly magnetic atoms
April 03, 2008A research team from the National Institute of Standards and Technology (NIST) and the University of Maryland has succeeded in cooling atoms of a rare-earth element, erbium, to within two millionths of a degree of absolute zero using a novel trapping and laser cooling technique. Their recent report* is a major step towards a capability to capture, cool and manipulate individual atoms of erbium, an element with unique optical properties that promises highly sensitive nanoscale force or magnetic sensors, as well as single-photon sources and amplifiers at telecommunications wavelengths. It also may have applications in quantum computing devices.
The strongly counterintuitive technique of "laser cooling" to slow down atoms to very low speeds-temperatures close to absolute zero-has become a platform technology of atomic physics. Laser cooling combined with specially arranged magnetic fields-a so-called magneto-optical trap (MOT)-has enabled the creation of Bose-Einstein condensates, the capture of neutral atoms for experiments in quantum computing and ultra-precise time-keeping and spectroscopy experiments. The technique originally focused on atoms that were only weakly magnetic and had relatively simple energy structures that could be exploited for cooling, but two years ago a NIST team showed that the far more complex energy structures of erbium, a strongly magnetic element, also could be manipulated for laser cooling.
The typical MOT uses a combination of six tuned laser beams converging on a point that is in a low magnetic field but surrounded by stronger fields. Originally, the lasers were tuned near a strong natural energy oscillation or resonance in the atom, a condition that provides efficient cooling but to only moderately low temperatures. In the new work, the research team instead used much gentler forces applied through a very weak resonance in order to bring erbium atoms to within a few millionths of a degree of absolute zero. Such weak resonances are only available in atoms with complex energy structures, and previously have been used only with a select group of non-magnetic atoms. When a strongly magnetic atom like erbium is used, the combination of strong magnetic forces and weak absorption of laser photons makes a traditional MOT unstable.
To beat this, the NIST/UM team turned classic MOT principles on their heads. Rather than shifting the laser frequency towards the red end of the spectrum-to impact fast, high-temperature atoms more than slow, cold ones-they shifted the laser towards the blue side to take advantage of the effects of the magnetic field on the highly magnetic erbium. Magnetism holds the atoms stably trapped while the lasers gently pushed them against the field, all the while extracting energy and cooling them. The delicate balancing act not only cools and traps the elusive erbium atoms, it does it more efficiently. The team's modified trap design uses only a single laser and can cool erbium atoms to within two millionths of a degree of absolute zero. By contrast, a conventional MOT only brings rubidium atoms to about one ten-thousandth of a degree.
Erbium commonly is used in optical communications components for its convenient magneto-optical properties. The new trapping technique raises the possibility of using erbium and similar lanthanide elements for unique nanoscale magnetic field detectors, atomic resolution metrology, optical computing systems and quantum computing.
###
* A.J. Berglund, J.L. Hanssen and J.J. McClelland. Narrow-line magneto-optical cooling and trapping of strongly magnetic atoms. Physical Review Letters, V. 100, p. 113002 , March 18, 2008.
National Institute of Standards and Technology (NIST)
To beat this, the NIST/UM team turned classic MOT principles on their heads. Rather than shifting the laser frequency towards the red end of the spectrum-to impact fast, high-temperature atoms more than slow, cold ones-they shifted the laser towards the blue side to take advantage of the effects of the magnetic field on the highly magnetic erbium. Magnetism holds the atoms stably trapped while the lasers gently pushed them against the field, all the while extracting energy and cooling them. The delicate balancing act not only cools and traps the elusive erbium atoms, it does it more efficiently. The team's modified trap design uses only a single laser and can cool erbium atoms to within two millionths of a degree of absolute zero. By contrast, a conventional MOT only brings rubidium atoms to about one ten-thousandth of a degree.
Erbium commonly is used in optical communications components for its convenient magneto-optical properties. The new trapping technique raises the possibility of using erbium and similar lanthanide elements for unique nanoscale magnetic field detectors, atomic resolution metrology, optical computing systems and quantum computing.
###
* A.J. Berglund, J.L. Hanssen and J.J. McClelland. Narrow-line magneto-optical cooling and trapping of strongly magnetic atoms. Physical Review Letters, V. 100, p. 113002 , March 18, 2008.
National Institute of Standards and Technology (NIST)
Neutron researchers discover widely sought property in magnetic semiconductor
Researchers working at the National Institute of Standards and Technology (NIST) have demonstrated for the first time the existence of a key magnetic-as opposed to electronic-property of specially built semiconductor devices.
Cheaper LEDs from breakthrough in zinc oxide (ZnO) nanowire research, Nano Letters study says
Engineers at UC San Diego have synthesized a long-sought semiconducting material that may pave the way for an inexpensive new kind of light emitting diode (LED) that could compete with today's widely used gallium nitride LEDs, according to a new paper in the journal Nano Letters.
New theory explains enhanced superconductivity in nanowires
Superconducting wires are used in magnetic resonance imaging machines, high-speed magnetic-levitation trains, and in sensitive devices that detect variations in the magnetic field of a brain.
Scientists build 'magnetic semiconductors' one atom at a time
In a stride that could hasten the development of computer chips that both calculate and store data, a team of Princeton scientists has turned semiconductors into magnets by the precise placement of metal atoms within a material from which chips are made.
Scientists Image 'Magnetic Semiconductors' On The Nanoscale
In a first-of-its-kind achievement, scientists at the University of Iowa, the University of Illinois at Urbana-Champaign and Princeton University have directly imaged the magnetic interactions between two magnetic atoms less than one nanometer apart (one billionth of a meter) and embedded in a semiconductor chip.
More Magnetic Atoms Current Events and Magnetic Atoms News Articles
 |
Magnetic Atoms and Molecules (Dover Books on Physics and Chemistry) by William Weltner Jr. (Author) The most comprehensive, up-to-date reference source available in the field, this graduate-level text by a leading researcher in atomic and molecular spectroscopy introduces and explores the electron-spin-resonance theory of randomly-oriented molecules, utilizing exceptionally clear mathematical formulations throughout. "I recommend it highly."—American Scientist. Extensive editorial apparatus. 119 line illustrations. |
 |
Horizontal Leather Case with Belt Clip/Loop for the O2 XDA Atom by Gomadic Gomadic's new Horizontal Leather Carrying Case w/ Optional Belt Clip was specifically created to fill the aperture between utilitarian need and aesthetic excellence; making it a must-have for the urbane nomadic user. In today's competitive marketplace; the choices you make define your commitment to your occupation. The Gomadic leather case says you care about both your appearance and the devices on which you have come to depend. Hand-made from smooth; premium black leather with a felt lining that feels silken to the touch; Gomadic's leather case will neatly store and transport your mobile device; providing an elegant way to protect your PDA from the potentially-damaging elements. Uniquely designed with a quick release magnetic closure system; you will gain fast; convenient access to your... |
 |
Magna Atom Magnetic Chalkboard Model TDCT by Keller Bros. & Miller, Inc. Free standard shipping - Appropriate for Grades 4-12 The Magentic Atom Model is a great visual representation for demonstrating the relationships between atoms and isotopes. Developed by Teacher Catherine Skye, this model uses blue protons, yellow neutrons, and red electrons to help you show your students how to identify the atomic number and mass number of atoms (up to chromium), distinguish various isotopes of an atom, compare covalent and ionic bonds between atoms, and more. Rearrange the Magna-Atom protons, neutrons, electrons to form different atoms or isotopes to demonstrate the relationships between them. Great for warm-up or test questions, class discussions, review sessions, and elemental bingo. Includes enough materials to simulate all isotopes of elements with atomic numbers up... |
|
Atoms in Strong Magnetic Fields: Quantum Mechanical Treatment and Applications in Astrophysics and Quantum Chaos (Astronomy and Astrophysics Library) by H. Ruder (Author), G. Wunner (Author), H. Herold (Author), F. Geyer (Author) Gives a clear and accessible introduction to quantum mechanical methods used to calculate properties of atoms exposed to strong magnetic fields in both laboratory and stellar environments. DLC: Atomic transmission probabilities. | |
|
Manipulating diamond's impurities may lead to finer-scale microscopes: nitrogen atoms could be used as magnetic field detectors.(Matter & Energy): An article from: Science News by Davide Castelvecchi (Author) This digital document is an article from Science News, published by Science Service, Inc. on October 25, 2008. The length of the article is 425 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available immediately after purchase. You can view it with any web browser. Citation Details Title: Manipulating diamond's impurities may lead to finer-scale microscopes: nitrogen atoms could be used as magnetic field detectors.(Matter & Energy) Author: Davide Castelvecchi Publication: Science News (Magazine/Journal) Date: October 25, 2008 Publisher: Science Service, Inc. Volume: 174 Issue: 9 Page: 9(1) Distributed by Gale, a part of Cengage... | |
|
MAGNETIC ATOMS AND MOLECULES by William Weltner (Author) | |
|
MAGNETIC ATOMS AND MOLECULES by Unknown (Publisher) | |
|
QUANTUM MECHANICS AND THE MAGNETIC MOMENT OF ATOMS by Enrico. Nobel Laureate in Physics. FERMI (Author) | |
|
Resonance Phenomena in Electron-Atom Collisions (Springer Series on Atoms and Plasmas, Vol 11) by V. I. Lengyel (Author), E. P. Sabad (Author), V. T. Navrotsky (Author) Depending on the energy of the collision, the scattering of electrons by atoms or atomic ions is the fundamental process in plasma physics, in laser cavities, nuclear fusion reactions, quantum chemistry, astrophysics and the physics of the upper atomosphere. The positions and intensities of resonances yield information on the formation of quasi-stationary autoionizing states. The first two-thirds of this text is devoted to a detailed exposition of the methods of calculating such scattering resonances, introducing a simplified Feshback diagonalization method. Comparisons with other calculational techniques are drawn. The final third is a comprehensive review of electron scattering experiments, with data on hydrogen, the alkalis, group II elements, and rare gases (both neutral atoms and... | |
|
Nonlinear Behaviour of Molecules, Atoms and Ions in Electric, Magnetic or Electromagnetic Fields by Louis Neel (Editor) |
| © 2009 BrightSurf.com |