Papers On CHAOS Available In Eprint Archives org/pdf/physics/0404014 A general Systems Theory Selvam and Suvarna Fadnavis chaos,Solitonsand numerical computations Suvarna Fadnavis research Report Number http://www.geocities.com/CapeCanaveral/Lab/5833/eprint.html
Alex Barnett: Invade My Academic Space Harvard physics Department. Rick s group specializes in quantum chaos, theoreticalchemistry, and numerical methods. general introduction to my research; See http://www.cims.nyu.edu/~barnett/phys.html
Extractions: Cambridge MA, 02138, USA. ...go home. I n October 2000 I graduated from Rick Heller's research group at the Harvard Physics Department . Rick's group specializes in quantum chaos, theoretical chemistry, and numerical methods. More about research topics... Use some computer codes I have wrote during this time...
ClayGate 000 : Computer Science, Information & General Works Public Library Online Texts 001 general Knowledge. 003, University of CanterburyLibrary Operations research. 003.857, About.com physics chaos Theory Non http://library.bendigo.latrobe.edu.au/irs/webcat/000.htm
Chaos And Complex Systems Seminar d, is unmoderated and intended for general discussion unsubscribe chaoscs (or subscribechaos-cs-d Web Pages of Academic Departments, research Centers, Programs http://sprott.physics.wisc.edu/Chaos-Complexity/
Extractions: University of Wisconsin - Madison The Chaos and Complex Systems Seminar is a weekly, campus-wide, interdisciplinary seminar series at the University of Wisconsin - Madison on the new sciences of chaos and complexity. Talks span a wide range of topics including computer science, mathematics, economics, biology, meteorology, psychology, and physics. They are aimed at a non-expert but scientific audience, and everyone is welcome. Most seminars are in 4274 Chamberlin Hall (1150 University Avenue) at 12:05 on Tuesdays during the academic year (September to May). The series is organized by a volunteer steering committee consisting of Robin Chapman (Communicative Disorders), Ian Dobson (Electrical and Computer Engineering), Lewis Leavitt (Pediatrics), Clint Sprott (Physics), Bob Wilson (Mathematics) and John Young (Atmospheric and Oceanic Sciences). Fall 2004 Spring 2004 Fall 2003 Spring 2003 ...
UT Physics Research Information dynamics; instabilities and pattern formation; chaos; phase transitions. LawrenceShepley, general relativity, cosmology, and Lagrangian Fusion research Center. http://www.ph.utexas.edu/research.html
Extractions: Atomic, Molecular, and Optical Physics FOCUS Center Home Page Todd Ditmire Intense Ultrafast Laser Interactions, AMO, Experimentalist Mike Downer Femtosecond spectroscopy in condensed matter and plasmas; surface nonlinear optics; plasma-based particle accelerators Manfred Fink Electron diffraction; neutrino physics Lothar Frommhold Atomic and molecular physics Daniel Heinzen Experimental quantum and atom optics John Keto Reactions and radiative processes of excited atoms and molecules; laser spectroscopy; high power lasers; clusters and nanoparticles Frederick Matsen Quantum mechanics, groups, and linear algebras
Duke Physics: Quantum Electronic Laboratory address this question and the more general question of are investigating methods forcontrolling chaos that occurs This research is in collaboration with Prof. http://www.phy.duke.edu/research/photon/qelectron/proj/
Extractions: Physics Home ... Duke University Our laboratory is involved in a diverse set of research projects in the areas of quantum optics, control and synchronization of chaos in optical and electronic systems, and characterizing and controlling the dynamics of biological systems. A brief overview of each general area is given below. We are generally interested in the velocity of information on optical pulses. The best-known question in this area is, of course, can information go faster than the speed of light in vacuum, c? We address this question and the more general question of how fast does information go? by creating pulses of light that travel very fast (much much faster than c) or very slow (much much slower than c) and measuring information encoded on them. For more about our information velocity research, please visit the
Duke Physics: Quantum Electronic Laboratory is involved in a diverse set of research projects in quantum optics, control andsynchronization of chaos in optical A brief overview of each general area is http://www.phy.duke.edu/research/photon/qelectron/proj/research.ptml?print
Student Research At The Physics Department At Davidson College general Relativity Simulations Using Open Source physics poster presented at theSpring research Symposium at 02), Nonlinear Dynamics and chaos, Spring 2002. http://www.phy.davidson.edu/student_research.html
Extractions: Student Research 1999-present in the Davidson College Physics Department The Davidson College Physics Department has research opportunities for undergraduates in the areas of computational, experimental, and theoretical physics. Below are recent independent study and summer projects carried out in the department. Click on a faculty member's name to find out more about the research programs available at Davidson. To learn about the equipment and facilities in our laboratories click research facilities Laura Gilbert (Physics 06), Quantum Mechanical Wave Packet Dynamics in an Asymmetric Infinite Well, Summer 2004 (work in collaboration with Richard Robinett and Michael Doncheski of Pennsylvania State University). Kevin Bell (Spanish 05), PT -Symmetric SUSY quantum mechanics, Summer 2002, Summer 2003, and Summer 2004. Determining the Energy Spectrum of a PT -Symmetric Periodic Potential, poster presented at the Gordon Research Conference on Physics Research and Education: Quantum Mechanics, South Hadley, MA. Solving PT -Symmetric Periodic Potentials Using Hills Equation, talk given at the Winter Meeting of the American Association of Physics Teachers, Austin, TX. Using Hill's Equation to Solve
Physics Resources: The Gateway related sites in astronomy, biomedicine, space, technology, biology, chaos/complexity,chemistry Other general Resources Bibliographies, research Guides, Other http://www.lib.ohio-state.edu/gateway/bib/physics.html
Extractions: Current Information ... Further Research (General and Subject Encyclopedias) Columbia Encyclopedia, Sixth Edition [WWW] Contains nearly 51,000 full text articles on a wide range of topics, including 15,000 biographies, maps, speeches, and more than 80,000 hypertext cross-references to link relevant information. Encyclopedia Britannica Online [OhioLINK users only] Access over 75,000 quality full text articles, as well as 200,000 selected Web sites and 2,000 videos on virtually every topic. Also includes special sections and resources on presidential campaigns, atlases, year in review, timelines, and highlighted research topics. Encyclopedia of Physical Sciences and Technology Eighteen volume set provides an overview of the physical sciences.
UAA Physics Dept. physics 456, Nonlinear Dynamics and chaos (3 cr physics 498, Individual research(16 cr PHYS 211, 211L, 212, 212L general physics I and II with Labs (8 credits http://hosting.uaa.alaska.edu/afjtp/physics.html
Extractions: Astronomy 103-104, Introductory Astronomy, plus Labs (4 cr). Physics 101, Physics for Poets (3 cr). Physics 123-124, Basic Physics (Algebra based)(2 x 3 cr), plus Labs (2 x 1 cr). Physics 130, Introduction to Physics (3 cr). Physics 211-212, General Physics (Calculus based)(2 x 3 cr), plus Labs (2 x 1 cr). Physics 303, Modern Physics (3 cr). Physics 314, Electromagnetics (3 cr) ( New Physics 320, Simulation of Physical Systems (3 cr) ( New Physics 456, Nonlinear Dynamics and Chaos (3 cr). Physics 498, Individual Research (1-6 cr) . MINOR:
BU Libraries | Research Guide | Nonlinear Science UP. Selected research Journals Europhysics Letters. Fractals. International Journalof Bifurcation and chaos (IJBC). Journal of physics A Mathematical general. http://www.bu.edu/library/guides/nonlinear.html
Extractions: Catalogs E-Resources E-Journals Guides ... Ref Shelf WHAT IS NONLINEAR SCIENCE? CONNECTING FROM OFF-CAMPUS Applied Science and Technology Full Text Description arXiv.org e-Print archive Research papers in physics, mathematics, computer science, and nonlinear sciences Description BIOSIS (Biological Abstracts) 1989+ Description Compendex (Engineering Index/Engineering Village) 1970+ Description General Science Full Text (WilsonWeb) 1984+ Description INSPEC Description MathSciNet (Mathematical Reviews) 1940+ Description Medline 1966+ (via Ovid: in-library use or password) Description PubMed Description SciFinder Scholar (Chemical Abstracts) 1967+ Description U.S. Patents Description Web of Science (Science Citation Index) 1988+ Description WorldCat Description
Theory Group insight into strong interaction physics in general as well interested in the studyof quantum chaos in quantum Our research is based on a reformulation of the http://www.kcl.ac.uk/kis/schools/phys_eng/physics/research/theory/theory.html
Extractions: Announcement: Workshop 8-12 July 2003 - Hidden Symmetries in Strongly Correlated Electron Systems and Low Dimensional Field Theories Elementary particle theory is a broad subject but is primarily concerned with the study of Nature on very small length scales and the formulation of formal and phenomenological models of the fundamental constituents of our Universe. We have strong interests in several areas of the subject, ranging from quantum gravity and string theory to supersymmetry and gauge field theories, and our research has implications for phenomena in strong interaction physics, cosmology and particle astrophysics, condensed matter physics and for developments beyond the standard model of particle physics.
HISTORY / PHILOSOPHY LINKS HISTORY OF physics general Collections AIP History of physics chaos Theory Classicalchaos and its Quantum Manifestations 97/05 History of research of Black http://web.mit.edu/redingtn/www/netadv/hist.html
The Net Advance Of Physics Homepage CLASSICAL MECHANICS general and Various + chaos and Complexity QUANTUM physics ANDCHEMISTRY general and Various of physics (Fields of research) + History of http://web.mit.edu/redingtn/www/netadv/97welcome.html
Penn Graduate Program In Physics Brochure physics 514 Mechanics, Fluids, and chaos A general introduction to Intended tobring students to the level of current research in elementary particle http://dept.physics.upenn.edu/guide/gradcourses.html
Extractions: NOTE: This list describes courses taught in the past few years. Most are offered on a regular basis, but in some cases this means every two years. Consult the Roster (Fall) (Spring) for current information on which courses are offered. Some courses have their own home pages; these are shown as links. Introduction to physical cosmology emphasizing recent ideas on the very early evolution of the universe. The course will introduce standard big bang cosmology, new theories of the very early universe, and the key observations that have tested and will be testing these ideas. No prior knowledge of astrophysics, cosmology, general relativity, or particle physics will be assumed, although aspects of each will be introduced as part of the course. Intended for graduate students and advanced undergraduates.
NSF RESEARCH EXPERIENCE FOR UNDERGRADUATES: theory and experimental demonstration of controlling chaos. 9. Manu Lall (Utah WaterResearch Lab) Floods from observations and from general Circulation Models http://www.physics.usu.edu/reu.html
Extractions: with assitance from the Mathematics and Statistics and Physics Departments "spatio-temporal chaos" The USU REU is a highly interdisciplinary program involving research mentors from the Departments of Mathematics and Statistics Physics Biology , Forest Resources, and Civil and Electrical Engineering . Projects deal with modeling nonlinear biological and physical phenomena, using differential equations and cellular automata. All projects emphasize numerical and visualization methods and the participants selected for this program will have some computer literacy. Participants can expect to be exposed to such tools as MatLab, Mathematica, and Stella, and, in some cases, to be responsible for generating code in some standard programming language such C, C++, or FORTRAN. Participants will: Work closely with individual faculty mentors Be housed for free in university housing Receive continued guidance on their research and on their communication skills from their mentors and other program personnel Receive course credit for attending a class dealing with the applications of nonlinear dynamics Be paid $2,500 for the eight weeks
GSAS ~ Physics optics, gas laser theory, nonlinear dynamics, and chaos. topics in physics usuallyunrelated to their research. general Degree Requirements for the MA and the http://www.brynmawr.edu/gsas/physics/
Extractions: for Prospective Students for Parents ... Faculty/Staff Quick Jump HOME Academics Administration Admissions Calendar of Events Campus Life Campus Tour Computing Services Contacting Bryn Mawr Graduate Studies Library Services News Resources/Annual Fund SEARCH Bryn Mawr Web for Prospective Students for Parents for Students for Alumnae for Faculty/Staff Undergraduate Program The program is designed to give each student both a broad background in physics and a high degree of expertise in a chosen field of research. The department is small, and to provide a breadth of coverage in physics, the faculty members have different specialties covering a variety of topics and research interests. Students and faculty members work closely together. The formal graduate course work is handled in small courses or tutorials which can be tailored to the needs of the students. Students may also take introductory or advanced graduate courses at the University of Pennsylvania or at Drexel University in nearby Philadelphia (about thirty minutes by car or train). Some research projects are of an interdisciplinary nature, involving two or more groups in the Physics, Biology Mathematics , and Chemistry Departments.
By Subject | General Science | Electronic Journals International journal of bifurcation and chaos in applied sciences and research reports/. UW restricted Includes section Current literature of physics, Jan. http://www.lib.washington.edu/subject/GeneralScience/dr/eljnl.html
Richard E. Eykholt While the general goal of our research is to At present, chaos can be controlled inthis manner only For the research on controlling chaos, the research itself http://www.physics.colostate.edu/People/faculty/eykholt
Extractions: B.A., M.S., Ph.D., University of California - Irvine, 1978, 1980, 1984. One of the two major focuses of the current research within our group is chaos in nonlinear dynamical systems. Familiar examples of this phenomenon are weak turbulence in fluid flow and the general unpredictability of the weather. However, chaos is also quite common in solid state/condensed matter systems, laser/optical systems, electronic devices, plasmas, etc., as well as chemistry, biology, physiology, economics, and many other fields. While the general goal of our research is to improve our understanding of chaos and chaotic phenomena, our current research in this area is focused on controlling or eliminating chaos. Physicists are generally interested in studying the properties of materials and devices under increasingly more extreme conditions, in which case, the nonlinear properties of the material or device become more and more important. If the conditions become sufficiently extreme, (e.g., very strong driving or very high applied fields), the behavior of the system will finally become chaotic. Beyond this point, the chaotic response of the system makes it very difficult to study its properties. However, recent research has shown that, in many cases, it may be possible to eliminate this chaotic behavior by making very small variations in the driving force or the applied field. Furthermore, the chaotic behavior may be replaced by any of a variety of steady-state or periodic behaviors. This ability to select from a variety of behaviors of the system may mean that the occurrence of chaos is actually an advantage. At present, chaos can be controlled in this manner only for very simple systems. However, we are working on ways to extend this approach to systems of much greater complexity (i.e., to the level of complexity found in real physical systems).
