1. VRML Gallery Of Electromagnetism (by Rob Salgado) Visualization of the electromagnetic field.Category Science Physics electromagnetism......http//physics.syr.edu/courses/vrml/electromagnetism/. VRML 2.0, VRML 1.0gz, VRML1.0. VRML Gallery of electromagnetism. Rob Salgado (salgado@physics.syr.edu). http://physics.syr.edu/courses/vrml/electromagnetism/

http://physics.syr.edu/courses/vrml/electromagnetism/ Module Content Last modified: 12 Oct 1996 Homepage Last modified: Sat Aug 18 17:50:07 2001 VRML 2.0 VRML 1.0-gz VRML 1.0 VRML Gallery of Electromagnetism Rob Salgado (salgado@physics.syr.edu) Ampere's Law anim (255 kb) Assorted anim (940 kb) A line-integral (166 kb) These pages are some of my attempts to visualize the vector (actually k-form) fields of electromagnetism. These images are inspired by the works of the authors in my references. i have updated these links These visualizations require a VRML-enabled browser. more VRML browsers Get CosmoPlayer! (install instructions) or WorldView or Blaxxun or Cortona or my new favorite: GLView (Mac: Zaptech BeOS: Breeze Linux et al... build your own: OVAL With help from Sun's Java3D Try this new Shout3D version of my Electric Dipole Since September 30, 1996, you are visitor number Addition Addition: Vector Addition: 1-Form Addition: 2-Form Wedge Product Wedge Product: Vector/Bivector Wedge Product: 1-Form/2-Form Raising and Lowering of Indices Raising and Lowering: Vector/1-Form Raising and Lowering: Bivector/2-form Unit Vectors x-hat y-hat z-hat r-hat Charged Point (Coulomb) Charged Point: Electric Vector Charged Point: Electric 1-form Charged Point: Electric twisted 2-form (vector density) Two Charged Points Two Charged Points: Electric Vector Two Charged Points: Electric 1-form Two Charged Points: Electric twisted 2-form (vector density) Charged Dipole Charged Dipole: Electric Vector Charged Dipole: The Negative Charge Charged Dipole: The Positive Charge Charged Dipole: Superposition ... Charged Dipole: Electric twisted 2-form (vector density) Charged Sphere

2. Electromagnetism Authors' web pages for the textbook electromagnetism , by G. L. Pollack and D. R. Stump, published by AddisonWesley. http://www.pa.msu.edu/people/stump/EM/

Electromagnetism by G L Pollack and D R Stump Published by Addison Wesley The site contains free materials supplementary to the textbook, including chapter summaries, useful tables, self-test questions and answers, and some additional items. To read the files you will need Adobe Acrobat Reader. Useful Tables Vector derivatives in Cartesian, cylindrical and spherical coordinates Vector identities Physical constants and other quantities The Maxwell equations and other equations of electromagnetism ... Acknowledgement of Reviewers The authors Dan Stump stump@pa.msu.edu Jerry Pollack pollack@pa.msu.edu

3. Sketches Of The History Of Electromagnetics Timeline traces the development of optics, magnetism and electricity from ancient times. With links to biographies of key physicists. Sketches of a History of. Classical electromagnetism. (Optics, Magnetism, Electricity, electromagnetism) http://history.hyperjeff.net/electromagnetism.html

Taking too long to load? Smaller screen? Try the Slim version Jeff Biggus Part of the HyperJeff Network Sketches of a History of Classical Electromagnetism (Optics, Magnetism, Electricity, Electromagnetism) last updated Sunday, 13-Jan-2002 23:20:15 MST A n t i q u i t y Many things are known about optics: the rectilinearity of light rays; the law of reflection; transparency of materials; that rays passing obliquely from less dense to more dense medium is refracted toward the perpendicular of the interface; general laws for the relationship between the apparent location of an object in reflections and refractions; the existence of metal mirrors (glass mirrors being a 19th century invention). ca BC Euclid of Alexandria (ca 325 BC - ca 265 BC) writes, among many other works, Optics, dealing with vision theory and perspective. Convex lenses in existence at Carthage. cent BC Chinese fortune tellers begin using loadstone to construct their divining boards, eventually leading to the first compasses. (Mentioned in Wang Ch'ung's Discourses weighed in the balance of 83 B.C.)

4. Anemaw -Animal Electromagnetism And Waves] © 2002 Elizabeth Gerrow A look at the ways animals use electromagnetism, luminescence, and infrasonic and ultrasonic waves. http://members.fortunecity.com/anemaw/

web hosting domain names email addresses related sites This site is set to dimensions of 1024 x 768 (17" monitor). For 800 x 600 , use the scroll bars to view the page correctly. For the best viewing of this page Microsoft Internet Explorer is advised, but will do as well. Back-up link here web hosting domain names Powered by Ampira

5. Teaching Electromagnetism Using Advanced Technologies: John W. Belcher MIT Teaching electromagnetism Using Advanced Technologies http://web.mit.edu/jbelcher/www/anim.html

Teaching Electromagnetism Using Advanced Technologies Animations created using Discreet's 3D Studio MAX This work is supported by NSF Grant #9950380 , an MIT Class of 1960 Fellowship, The Helena Foundation, the MIT Classes of 51 and 55 Funds for Educational Excellence, the MIT School of Science Educational Initiative Awards, and MIT Academic Computing. Faraday's Law (3.3 Meg QT) and Creating A Dipole (3.0 Meg QT) A Paper On The Mathematics Of These Animations A Description of the TEAL/Studio Project at MIT (pdf file) Michael Faraday was the first to realize that the shape of electromagnetic field lines is extraordinarily expressive of their dynamical effects. We can understand intuitively many things about the forces transmitted by the fields by looking at the topology of the field lines. This is especially true when the field lines are animated. The examples given here are only a few of many (if you do not have a movie player, download QuickTime 3 to view both avi and quicktime files) Experiments and Animations: Faraday's Law Electrostatics Radiation Magnetostatics ... , Developer) Physics and mathematics by Professors John Belcher and Stanislaw Olbert. 3D modeling/animations and Physics demonstrations by Mark Bessette. MAX scripting by Larry Minton.

6. Chapter 2: Electromagnetism For more information on electromagnetism, see the Recommended Reading section. http://www.scitoys.com/scitoys/scitoys/electro/electro.html

Building an electric motor in 10 minutes. The single brush motor. A bigger motor. The double brush improvement. ... A very simple ion motor A motor in 10 minutes Back in the 1960's my father taught me how to make the little electric motor we will make here. Sometime in the 1980's I saw a description of it in the magazine "Physics Teacher". Lately I have seen it described as Beakman's motor, after the science oriented TV show on which it recently appeared. The motor is simply a battery, a magnet, and a small coil of wire you make yourself. There is a secret to making it (which I will of course share with you) which is at the same time clever and delightfully simple. What you will need: A battery holder, such as Radio Shack #270-402 (holds a "C" cell) or #270-403 (holds a "D" cell). A battery to fit the holder. A magnet such as Radio Shack #64-1877, #64-1895, #64-1883, #64-1879, or #64-1888. Some magnet wire such as Radio Shack #278-1345. We want enamel coated 22 gauge (or thicker) wire. We will only need about a yard of wire, so the Radio Shack package will make a dozen motors or more. Some heavier wire such as Radio Shack #278-1217 or #278-1216. We want bare wire of 18 or 20 gauge, so we will be removing the plastic insulation from the wires listed above. We will need less than a foot of this wire per motor.

7. Electromagnetism General electromagnetic theory, including static field equations, the origins of inductance, and EMR.Category Science Physics electromagnetism Courses and Tutorials......electromagnetism. It may seem odd that I have included gyroscope theory in a sectionon electromagnetism, but gyroscopes have one highly distinctive property. http://www.mariner.connectfree.co.uk/html/electromagnetism.html

Electromagnetism email mikey Home Electrostatic Potential Energy The starting point for all electro-static interactions is that between two point electric charges such as two electrons, or between a positron and an electron. You are probably familiar with the concept that electric fields contain energy and it is the interaction between the fields of the two charges that leads to changes in their energy and hence to the forces between them, energy being simply the integral of force over distance. This paper develops the equations for the interaction at any point in space near the charges, and compares the numerical integration of these equations with the standard text-book values. Click here to view the paper on electrostatic fields and the associated potential energy. As you can see from this paper the concept of electrostatic potential energy is a Newtonian approximation that holds true only so long as the energy involved is a minuscule part of the rest energy/mass of the point charges. Changes in potential energy are equivalent to changes in the rest mass/energy of the system, which can become significant at high energies. Magnetostatic potential energy works in exactly the same way, but because magnets come only as dipoles rather than point charges the geometry is much more difficult to deal with.

8. Electromagnetism [UWA Physics] An introductory (second year university) course on electromagnetism. All of the lecture notes are Category Science Physics electromagnetism Courses and Tutorials......electromagnetism Lecturer Dr Paul Abbott Phone +61 (0) 8 9380 2734Fax +61 (0) 8 9380 1014. What is electromagnetism? Of the http://physics.uwa.edu.au/Physics/Courses/Second_Year/Electromagnetism.html

Electromagnetism Lecturer: Dr Paul Abbott Phone +61 (0) 8 9380 2734 Fax +61 (0) 8 9380 1014 What is Electromagnetism? Of the four known forces in nature, the electromagnetic force is all-pervading, being effective at subatomic distances (the realm of the strong and weak nuclear forces, each being of extremely short range) and at astronomical distances (the realm where the gravitational force is significant). A proper study of electromagnetism is therefore central to physics, being an excellent example of the evolution of a physical theory from basic experiments to a mathematical formulation of great beauty and elegance. The course will range from Coulomb's law through to electromagnetic plane waves. Relativity will be used only briefly to explain the Lorentz transformation and the transformation of electric and magnetic fields. The course aims to give students a working knowledge of electromagnetism. Course Outline The course, developed for the second year of our undergraduate physics degree, consists of 13 lectures and 3 tutorials. The combination of vector calculus and wave physics can often be difficult when first encountered. A good way to gain confidence is to apply them in problems. There will be 3 assignments, followed by a tutorial where we will work though the methods of solving the problems.

9. Electromagnetism In 2000 - Table Of Contents John Belcher's course explains what is happening in electromagnetic experiments.Category Science Physics electromagnetism Courses and Tutorials......The MIT Course in electromagnetism 2000, Vision. Motivation. Examples.Value Added. Time Frame. Table of Contents. Prepared For The MIT http://web.mit.edu/jbelcher/www/em.html

The MIT Course in Electromagnetism 2000 Vision Motivation Examples Value Added ... Table of Contents Prepared For The MIT Council On Educational Technology 1997 Vision Motivation Examples Value Added ... John Belcher Revised February 28,1997, jwb@space.mit.edu

10. History Of Electromagnetism A discussion of the development of classical electromagnetism and electrodynamics.Category Science Physics electromagnetism History......History of electromagnetism. The subsequent history of electromagnetism mergesthereafter with that of the electron (on which see the article.on Fields). http://www.chass.utoronto.ca/~sungook/hps311/BUCHWALD.htm

History of Electromagnetism Jed Z. Buchwald, 1HPST, University of Toronto I. Speculation Page 2 II. Experiment Intrudes Page 5 1. Kinds of Electric Objects Page 5 2.The Leyden Jar Renovates the Electric Laboratory Page 7 III. Quantity, Intensity and Newtonian Calculations Page 9 IV. The Voltaic Pile Page 14 V. Magnetism and the Pile Page 15 VI. The Ampi-l-re Force Law Page 17 VII. The Emergence of Electrodynamics Page 19 1. Ohm's Law Page 19 2. Electromagnetic Induction and the Neumann Potential Page 20 3. German Electrodynamics Page 21 Bibliography Page 25 I. Speculation During this century the very idea of what an experiment might be, much less that knowledge could be produced by such a thing, was only slowly and with difficulty developed and propagated. On the other hand the antique speculative tradition, which sought to plumb the world's essence, remained very much a desideratum despite the rapidly-growing rejection of Scholasticism. Seventeenth-century scholars did not usually engage in penetrating dissections of the proper nature of things, or at least these kinds of discussions were not so common as they had once been. Neither did they quantify or produce controlled laboratory effects. Instead, many scholars considered electricity to be an effect of the motions or the properties of a hidden substance. Gilbert's Scholastic understanding of magnetism contrasts markedly with what seems to be a quasi-mechanical understanding of electricity, the latter being more congenial to the post-Scholastic way of thinking about nature. However, a modem glancing back at Gilbert's work might vice versa be confused by his sophisticated experimental manipulation of terellae as opposed to the comparative poverty of his electrical work. This reflects two things: first, that there was as yet no firm union between physical discussion and experimental manipulation, no consensual understanding of how to generate knowledge about physics from experiment, and, second, the continuing belief that the business of the natural philosopher is to provide understanding of causes, however novel the causes may be in a particular case.

11. Physics 4B An online course in introductory electromagnetism.Category Science Physics electromagnetism Courses and Tutorials......Dr. David Kagan Department of Physics California State University,Chico (530) 8986259 dkagan@csuchico.edu Physics 4B. Introductory http://phys.csuchico.edu/kagan/4B/Home_Page.html

Dr. David Kagan Department of Physics California State University, Chico dkagan@csuchico.edu Physics 4B Introductory Handout and Course Schedule [ Homework Solutions (password required) Exam Archive Lecture Notes Note that the introductory handout, lecture notes, homework solutions and old exams are available as Microsoft Word ( ) files or Adobe Acrobat ( ) files. You may need to reconfigure your browser and get additional software to read them. Here is some help and some help Home page quick returns [ CSU Chico Physics Dr. Kagan This document is maintained by Dr. David Kagan ( dkagan@csuchico.edu

12. New Electromagnetism: Taking The World By Storm New electromagnetism is an improved set of models describing electromagnetic interactions.Category Science Physics electromagnetism Alternative......New electromagnetism is an improved set of models describing electromagneticinteractions. Unifies with gravity. Welcome to New electromagnetism. http://www.newelectromagnetism.com/

Welcome to New Electromagnetism Click to enter the New Electromagnetism Website New Magnetism shows that magnetic fields must be spherical (not torroidal); otherwise, anomalous effects would have been detected many years ago. New Electromagnetism is evolving into a new science called ethereal (aethereal) mechanics which provides detailed mechanisms for field phenomenon.

13. VRML Gallery Of Electromagnetism (by Rob Salgado) Syracuse University VRML Gallery of electromagnetism edu/ courses/ vrml/ electromagnetism/ / H4 . Module Content Last modified 12 Oct 1996 http://suhep.phy.syr.edu/courses/vrml/electromagnetism

http://physics.syr.edu/courses/vrml/electromagnetism/ Module Content Last modified: 12 Oct 1996 Homepage Last modified: Sat Aug 18 17:50:07 2001 VRML 2.0 VRML 1.0-gz VRML 1.0 VRML Gallery of Electromagnetism Rob Salgado (salgado@physics.syr.edu) Ampere's Law anim (255 kb) Assorted anim (940 kb) A line-integral (166 kb) These pages are some of my attempts to visualize the vector (actually k-form) fields of electromagnetism. These images are inspired by the works of the authors in my references. i have updated these links These visualizations require a VRML-enabled browser. more VRML browsers Get CosmoPlayer! (install instructions) or WorldView or Blaxxun or Cortona or my new favorite: GLView (Mac: Zaptech BeOS: Breeze Linux et al... build your own: OVAL With help from Sun's Java3D Try this new Shout3D version of my Electric Dipole Since September 30, 1996, you are visitor number Addition Addition: Vector Addition: 1-Form Addition: 2-Form Wedge Product Wedge Product: Vector/Bivector Wedge Product: 1-Form/2-Form Raising and Lowering of Indices Raising and Lowering: Vector/1-Form Raising and Lowering: Bivector/2-form Unit Vectors x-hat y-hat z-hat r-hat Charged Point (Coulomb) Charged Point: Electric Vector Charged Point: Electric 1-form Charged Point: Electric twisted 2-form (vector density) Two Charged Points Two Charged Points: Electric Vector Two Charged Points: Electric 1-form Two Charged Points: Electric twisted 2-form (vector density) Charged Dipole Charged Dipole: Electric Vector Charged Dipole: The Negative Charge Charged Dipole: The Positive Charge Charged Dipole: Superposition ... Charged Dipole: Electric twisted 2-form (vector density) Charged Sphere

14. VRML Gallery Of Electromagnetism (by Rob Salgado) http//physics.syr.edu/courses/vrml/electromagnetism/. VRML 2.0, VRML 1.0gz, VRML1.0. VRML Gallery of electromagnetism. Rob Salgado mailtosalgado@physics.syr.edu. http://physics.syr.edu/courses/vrml/electromagnetism/index3.html

http://physics.syr.edu/courses/vrml/electromagnetism/ Module Content Last modified: 12 Oct 1996 Homepage Last modified: Mon Sep 18 11:05:08 2000 VRML 2.0 VRML 1.0-gz VRML 1.0 VRML Gallery of Electromagnetism Rob Salgado mailto:salgado@physics.syr.edu Ampere's Law anim (255 kb) Assorted anim (940 kb) A line-integral (166 kb) These pages are some of my attempts to visualize the vector (actually k-form) fields of electromagnetism. These images are inspired by the works of the authors in my references. i have updated these links These visualizations require a VRML-enabled browser. more VRML browsers Get CosmoPlayer! (install instructions) or WorldView or Blaxxun or Cortona or my new favorite: GLView (Mac: Zaptech BeOS: Breeze Linux et al... build your own: OVAL With help from Sun's Java3D Try this new Shout3D version of my Electric Dipole Since September 30, 1996, you are visitor number Addition Addition: Vector Addition: 1-Form Addition: 2-Form Wedge Product Wedge Product: Vector/Bivector Wedge Product: 1-Form/2-Form Raising and Lowering of Indices Raising and Lowering: Vector/1-Form Raising and Lowering: Bivector/2-form Unit Vectors x-hat y-hat z-hat r-hat Charged Point (Coulomb) Charged Point: Electric Vector Charged Point: Electric 1-form Charged Point: Electric twisted 2-form (vector density) Two Charged Points Two Charged Points: Electric Vector Two Charged Points: Electric 1-form Two Charged Points: Electric twisted 2-form (vector density) Charged Dipole Charged Dipole: Electric Vector Charged Dipole: The Negative Charge Charged Dipole: The Positive Charge Charged Dipole: Superposition ... Charged Dipole: Electric twisted 2-form (vector density) Charged Sphere

15. SHUNDE XINGWEI ELECTRIC PORCELAIN CO.,LTD Produce piezoelectricity porcelain ignitor, automatic electromagnetism valve and related products http://www.china-xingwei.com

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16. Electromagnetism [UWA Physics] A proper study of electromagnetism is therefore central to physics, being an excellent example of the evolution of a http://www.pd.uwa.edu.au/Physics/Courses/Second_Year/Electromagnetism.html

Electromagnetism Lecturer: Dr Paul Abbott Phone +61 (0) 8 9380 2734 Fax +61 (0) 8 9380 1014 What is Electromagnetism? Of the four known forces in nature, the electromagnetic force is all-pervading, being effective at subatomic distances (the realm of the strong and weak nuclear forces, each being of extremely short range) and at astronomical distances (the realm where the gravitational force is significant). A proper study of electromagnetism is therefore central to physics, being an excellent example of the evolution of a physical theory from basic experiments to a mathematical formulation of great beauty and elegance. The course will range from Coulomb's law through to electromagnetic plane waves. Relativity will be used only briefly to explain the Lorentz transformation and the transformation of electric and magnetic fields. The course aims to give students a working knowledge of electromagnetism. Course Outline The course, developed for the second year of our undergraduate physics degree, consists of 13 lectures and 3 tutorials. The combination of vector calculus and wave physics can often be difficult when first encountered. A good way to gain confidence is to apply them in problems. There will be 3 assignments, followed by a tutorial where we will work though the methods of solving the problems.

17. Electromagnetism electromagnetism GL Pollack and DR Stump The materials linked to this page are intendedto help students who are studying electricity and magnetism from our http://www.pa.msu.edu/people/stump/EM/chaps.html

Electromagnetism G. L. Pollack and D. R. Stump The materials linked to this page are intended to help students who are studying electricity and magnetism from our book. You need Adobe Acrobat Reader to read them. Chapter 2. Vector Calculus Chapter summary Cross product and Levi-Civita tensor Self-test questions Self-test answers Chapter 3. Basic Principles of Electrostatics Chapter summary Three ways to calculate the electric field Self-test questions Dipole and Quadrupole in Color ... Benjamin Franklin Chapter 4. Electrostatics with Conductors Chapter summary Cover Art (part 1) Self-test questions Cover Art (extended field lines) [Feb. 2003] Self-test answers Chapter 5. General Method's for Laplace's Equation Chapter summary Fourier Series Self-test questions Conducting Strip by Conjugate Functions ... Self-test answers Chapter 6. Electrostatics and Dielectrics Chapter summary Boundary Conditions in Electrostatics Self-test questions Capacitance in the Nervous System ... Self-test answers Chapter 7. Electric Current Chapter summary The Continuity Equation Self-test questions Resistance in the Nervous System ... What is the resistance of this network? Chapter 8. Magnetostatics Chapter summary Magnetic Field of a Long Straight Wire Self-test questions Equilibrium of Magnetic Dipoles ... Self-test answers Chapter 9. Magnetic materials

18. Electomagnetism. A short dissertation on electromagnetism, its theory and units of measurements. http://www.hills2.u-net.com/electron/elecmag.htm

Electromagnetism. This site is under construction. Force on a Current-Carrying Conductor Placed in A Magnetic Field. EMF generated in a conductor that cuts a magnetic field of uniform flux density. Definitions of the Tesla and the Weber. Magnetomotive Force. ... Relative and Absolute Permeabilities. Force on a Current-Carrying Conductor Placed in A Magnetic Field. If a current-carrying conductor is placed in a magnetic field, it has a force exerted on it. The magnitude of this force is given by: F=BIl Where, F is the force in Newtons, N. B is the magnetic flux density in Teslas, T. I is the current in Amperes, A. l is the length of the conductor in metres, m. EMF generated in a conductor that cuts a magnetic field of uniform flux density. An emf is generated by a conductor that cuts or is cut by a magnetic field. The magnitude of the emf generated is given by: E=Blv Where, E is the emf in Volts, V. B is the magnetic flux density in Teslas, T. l is the conductor length in metres, m. v is the velocity of the conductor relative to the magnetic field in metres per second, m/s. Definitions of the Tesla and the Weber.

19. Table Of Contents electromagnetism LIFE. By. Robert O. Becker and Andrew A. Marino. CONTENTS.Publication Information. Preface. Introduction. Part One Historical Developments. http://www.ortho.lsumc.edu/Faculty/Marino/EL/ELTOC.html

By Robert O. Becker and Andrew A. Marino CONTENTS Publication Information Preface Introduction Part One: Historical Developments 1. The Origins of Electrobiology Part Two: The Role of Electromagnetic Energy in the Regulation of Life Processes 2. The Physiological Function of Intrinsic Electromagnetic Energy Introduction The Nervous System Growth Control Bone Summary References 3. Control of Living Organisms by Natural and Simulated Environmental Electromagnetic Energy Introduction Evolution of Life Biological Cycles Positional and Navigational Aids References Part Three: Laboratory Studies of the Adaptability of Organisms to Electromagnetic Energy 4. Electrical Properties of Biological Tissue Introduction Energy Bands Piezoelectricity Superconductivity Techniques of Application of Electromagnetic Fields Summary References 5. Effects of Electromagnetic Energy on the Nervous System Introduction Direct Effects Behavioral Effects Summary References 6. Effects of Electromagnetic Energy on the Endocrine System Introduction The Adrenal Cortex The Thyroid The Adrenal Medulla and the Pancreatic Islets Summary References 7. Effects of Electromagnetic Energy on the Cardiovascular and Hematological Systems

20. NASA Breakthrough Propulsion Physics Program HOME-PAGE Experiments and theories regarding the coupling of gravity and electromagnetism, the quantum vacuum, hyperfast travel, and superluminal quantum effects. http://www.grc.nasa.gov/WWW/bpp/

Welcome to the NASA Breakthrough Propulsion Physics (BPP) Project Public Information Site NEWS (January 31, 2003): There is no funding available for the Breakthrough Propulsion Physics (BPP) Project. To see more BPP artwork click on the picture ABOUT BPP - In 1996, NASA established the Breakthrough Propulsion Physics Project to seek the ultimate breakthroughs in space transportation: (1) propulsion that requires no propellant mass, (2) propulsion that attains the maximum transit speeds physically possible, and (3) breakthrough methods of energy production to power such devices. Topics of interest include experiments and theories regarding the coupling of gravity and electromagnetism, the quantum vacuum, hyper fast travel, and super luminal quantum effects. Because the propulsion goals are presumably far from fruition, a special emphasis is to identify affordable, near-term, and credible research that could make measurable progress toward these propulsion goals. This web site describes the methods and activities of the Breakthrough Propulsion Physics Project. For an introduction about the challenges of interstellar travel and some of the emerging concepts, please visit our " Warp Drive- When?

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