User talk:Ancheta Wis/p

We have the permittivity of free space as a starting point for your proposal. As Feynman points out, the name of something is not as important as the concept it represents; a plain-language description of the topic ought to be our goal. In this way, we can build an encyclopedia which endures. If the point is that we ought to reduce the number of articles simply to make a topic in physics manageable, then we could address this with navigation templates and overview articles. Then obscure or redundant articles would simply be unused or untouched. But if the concern is to simply get across the understandability of physics, then why isn't there more emphasis on equations. As compressed expressions of our knowledge, they are unsurpassed, in my opinion. This would also tend to reduce duplication and overlap because one writes an equation at his peril, here, or in physics in general; it then becomes much easier to be proven wrong. --Ancheta Wis 10:43, 8 August 2007 (UTC)Reply

Hans Christian Ørsted (1777-1851) was heavily influenced by Kant's Metaphysische Anfangsgründe der Naturwissenschaft (Metaphysical Foundations of Natural Science)^[1]. In 1799, Ørsted's Philosophisk Repertorium noted

Ørsted observed the deflection of a compass from a voltaic circuit in 1820

"In order to achieve completeness in our knowledge of nature, we must start from two extremes, from experience and from the intellect itself. ... The former method must conclude with natural laws, which it has abstracted from experience, while the latter must begin with principles, and gradually, as it develops more and more, it becomes ever more detailed. Of course, I speak here about the method as manifested in the process of the human intellect itself, not as found in textbooks, where the laws of nature which have been abstracted from the consequent experiences are placed first because they are required to explain the experiences. When the empiricist in his regression towards general laws of nature meets the metaphysician in his progression, science will reach its perfection." ^[2]

Ørsted's "First Introduction to General Physics" (1811) exemplified the steps of observation^[3], hypothesis ^[4], deduction^[5] and experiment. In 1805, based on his researches on electromagnetism Ørsted came to believe that electricity is propagated by undulatory action (i.e., fluctuation). By 1820, he felt confident enough in his beliefs that he resolved to demonstrate them in a public lecture, and in fact observed a small magnetic effect from a galvanic circuit (i.e., voltaic circuit), without rehearsal^[6],^[7]

{{PhysicsTOC}}

1. Definition

-- See list of topics to the right, or see the categories

1.1 Originally, physics (from the Greek, φύσις (phúsis), "nature" and φυσική (phusiké), "knowledge of nature") was the science of nature^{[8] [9]}.

1.2 Over the course of twenty-five hundred years, physics has become known for a series of fundamental laws^[10]. Called natural philosophy^{[11] [12]}, physics was the science for identifying the constituents of the natural world^[13].

1.2.1 The role of energy was identified by the eighteenth century, and precisely defined by the nineteenth century.

1.2.2 The atom^[14] of matter was successfully subsumed into the infrastructure of the sciences, which are indebted to physics. During this time, science became professionalized and specialized; physical explanations for various complex systems were formulated, for chemistry^[15], for biology^[16],^[17], and more recently for neuroscience^[18].

1.2.2.1 Now that E=mc² has publicized the equivalence of matter and energy, any definition of the mass noun "matter" must also state the energy levels involved in that physical system, for matter can be created or destroyed, at the cost of that energy.

1.2.3 The role of information, or negative entropy in a open system was first recognized in physics in the late nineteenth century and explicated in the twentieth century, with expression in engineering hardware, software agents, and in biological systems, in our time.

1.3 It is difficult to state a prospective or even current definition for physics, for each researchers' focus defines their subject of study. Thus we can talk retrospectively of Galileo's physics or Einstein's physics, but we cannot talk of a current researcher's physics, or a future researcher's physics without determining their philosophy^{[19] [20]} . For example, Murray Gell-Mann's contribution to complex systems should be noted^[21].

1.3.0.1 In an aggregate definition of physics, such as in a list of items (in the TOC at right), the items serve to name something which is incompressible, which cannot be further reduced, such as the Greek concept of the atom of matter. This was Newton's conception of matter. But physics has discovered energy regimes where atoms have parts, and the definition of fundamental can then be questioned, for the energy regime must also be stated for such a definition to hold, whether it be room temperature or ${\displaystyle 10^{32}}$  kelvin at the instant of the big bang.

1.3.0.2 But an aggregate need not have tensile strength; then the slightest pull would separate the components. Thus a proper definition of physics should also include a unifying agent, to bind it into a subject.

1.3.0.3 One candidate for that unifier is Nature itself. Nature, to man, seems welcoming, our home, the source of our life. But overall, the universe is hostile to life and to us. Indeed, life itself is a huge competition of life-forms for their individual advantage. And Nature, with its enormous powers, can be hostile to us as well. Thus we cooperate in symbiosis to survive it.

1.3.0.3.1 Earth is part of that Nature which holds us. But Earth is built largely from iron, an ash of stellar nucleosynthesis in the burning of the stars; thus our earth is composed of stellar ash, and we were made from the stars, because gravitation kept the elements from which we were made on this planet. The lighter elements which we breathe are kept here by virtue of gravitation. One of the problems in the exercise books of the Feynman Lectures on Physics asks "what is the probability that we have drunk from the water which our forebears drank?" and the answer depends on your philosophy.

1.3.1 Physics itself is further developing, both inward (beyond the atomic nucleus, which requires the use of ever-higher energy regimes) and outward (by consideration of the circumstances for big bangs and the development of our own universe from the multiplicity of multiverses which could have been ours). But the two realms are currently not unified under one theory.

Physics need not be considered an arcane or difficult subject. Classical mechanics can be amply illustrated on children's playground equipment or in a sports stadium. Read on for more --

Note to the reader: You may, without loss of generality, skip any point marked by a bullet below, e.g.

• This denotes a detail.
• "Truth is ever to be found in the simplicity, and not in the multiplicity and confusion of things." —Isaac Newton
• "To explain all nature is too difficult a task for any one man or even for any one age. 'Tis much better to do a little with certainty, and leave the rest for others that come after you, than to explain all things." —Isaac Newton

2. Introduction

Physics can explain the system of the world   An example of the system of the world: -- looking to the west, clouds are moving toward us, in an illustration of the rotation of the Earth. The clouds are part of an atmosphere with a uniform temperature across the sky at a single altitude, but with temperature which varies with altitude. The clouds have condensed from vapor to water droplet at a precise temperature, uniformly, thus causing a flat-bottomed cloud. The air is not mixing at these altitudes, which we see as a straight line, parallel to the horizon. Thus gravitation is influencing the shape of the flat-bottomed clouds. At other locations in the sky, the clouds are subject to turbulence and mixing. The density of the atmosphere also is varying with altitude, causing a continuum of hue, with deeper blue at the zenith and lighter blue at the horizon (obscured by the trees). The blue color of the sky is due to Rayleigh scattering, which also explains the red color of the sunsets (not shown). Characterization: the Nature of things The basic program for physics was instituted most noticeably by the time of the scientific revolution. In this program, a 'system of the world' was demonstrated by Newton[22], by which ever simpler constructs could be examined. This was the basis for several revolutions over the succeeding centuries during which physics became more and more exact and also more and more abstract. The program for mechanics, instituted by Newton, basically answered 'where' and 'when'[23]. This was the triumph of the geometrization of mechanics begun by Galileo. Characterization of successive elements of nature then proceeded as physics developed.   This parabola-shaped lava flow illustrates Galileo's law of falling bodies as well as blackbody radiation -- you can tell the temperature from the color of the blackbody.   Cassiopeia A - a spherically symmetric remnant of the 1680 supernova   The Astronaut and Earth are both in free-fall. File:PrismAndLight.jpg Diffraction of light by a prism.   Lightning is electric current. Experiment. Historically, physics has developed hand-in-hand with technology; the experimental devices of the scientists of each era had features which were consistent with the physics of that time. For example, Walter Bothe built the AND gate for a coincidence detector for use in Compton scattering. For this work he got the Nobel prize, 30 years later, in 1954. Today, Boolean logic is routinely used in engineering and information technology. Galileo built his own telescope (but not the lenses) - philosopher Baruch Spinoza was a lens grinder. Isaac Newton, accounted the greatest physicist in history, built his own telescopes by grinding his own mirrors with pitch (from which we routinely use Newton's rings to judge the quality of a telescope's mirror), and performed his own optical and alchemical experiments. The following list of technology which has been used in experiments can serve as a chronicle for the history of experimentation, as applied in an experiment (sorted by date of invention) 4500 BCE - the astronomical observatory is ancient enough for observations in India to document the precession of the constellations, 2700 BCE - a simple machine - the inclined plane - used by Galileo to determine the acceleration of gravity in the early 1600s, 2000 BCE - mirrors were exploited by Isaac Newton to minimize the abberation in the telescope in the 1670s, 600 BCE - Archimedes' screw, imaginative use of the simple machines 300 BCE - the pump was used by Otto von Guericke to produce a vacuum in 1654, 200 BCE - the astrolabe was used in navigation, 80 BCE - the gear was used in the engine, 975 - the pendulum was used by Galileo to measure time, 1280 - the lens was used to build telescopes, 1600 - the telescope was used by Ole Rømer to measure the speed of light by observing the motion of Io across Jupiter, 1680 - a prism was used by Newton to determine a theory of light, 1700 - the bell jar was used to study vacuum and the atmosphere, 1745 - the Leyden jar was used to store electrical charge, 1761 - the chronometer was used to measure time at sea, 1824 - the engine was used to provide energy and do work, 1821 - a railroad car was crucial for the development of relativity, 1860 - the spectroscope was to be used in quantum theory, 1903 - the airplane has been used to measure the cosmic microwave background, 1906 - the vacuum tube was used as an electrical circuit element, 1924 - Walter Bothe builds the AND gate, an electrical circuit element, as a coincidence detector for use in Compton scattering in 1924, 1929 - the cyclotron was used to accelerate charged particles, 1935 - the magnetron was built as a source of microwave radiation (suitable for radio frequency direction finding and a crucial element of the technology disclosed by the British to the Americans on the eve of WWII), 1945 - the digital computer was used to solve equations, 1947 - the transistor was used as a circuit element, 1957 - Isaac Newton proposed a thought experiment for a artificial satellite as part of his demonstration of the free-fall of the planets (1687), 1959 - the integrated circuit could miniaturize and commoditize circuits, 1960 - the laser was built as a source of photons, 1969 - the internet could commoditize knowledge, giving rise to the world wide web and to systems based on trust, 1978 - the global positioning system of artificial satellites could commoditize the determination of position and time, 1986 - the atomic force microscope could manipulate atoms, 1999 - NIST-F1 could serve as a time standard 2006 - People discover they can walk upon a swimming pool filled with a non-newtonian fluid. (This could also be dangerous - don't do this at home.) 2006 - John Cramer is preparing an experiment to determine whether quantum entanglement is also nonlocal in time as it is in space. This can also be stated as 'sending a signal back in time'. The experiment is still in preparation as of 10:57, 16 November 2006 (UTC). more... File:Archimedes' screw.jpg Archimedes' screw uses the simple machines to lift water. The hands-on experience with the devices of technology is an essential part of physics. Richard Feynman, blunt-spoken and not known for diplomacy, once remarked that the 1930's era cyclotron at MIT was hand-built and well-used, while the cyclotron at Princeton, was more professionally built, and therefore little-used during his term of study there. Forty years later, building cyclotrons was a high-school level activity, which can cause signficant drain on the electrical grid of the neighborhood. Physicists have used the technology of each era to further their own scientific predictions, as well as to further the development of mathematics, in each era, in a cooperative effort. Mathematical notation is the writing system of mathematics, a technology to which physicists have contributed and in which the theories of physics are often expressed. In physics, however, the constructs of physics are paramount in the use of any notation, liberally interspersed with visual diagrams of the physical situation. It has been the custom to retain a standard set of symbols when writing in a mathematical notation, which allows a 'feel' for the subject and permits common representations of the same things. And physicists learn mnemonics (see right-hand rule) and other informal representations (such as those which show how to multiply matrices, or how a dimension might be rolled-up) as well. "3 candlesticks times 5 cab-drivers is 15 candlestick cab-drivers" -- George Gamow Part of a series on Classical mechanics ${\displaystyle {\textbf {F}}={\frac {d}{dt}}(m{\textbf {v}})}$  Second law of motion History Timeline Textbooks Branches Applied Celestial Continuum Dynamics Kinematics Kinetics Statics Statistical mechanics Fundamentals Acceleration Angular momentum Couple D'Alembert's principle Energy kinetic potential Force Frame of reference Inertial frame of reference Impulse Inertia / Moment of inertia Mass Mechanical power Mechanical work Moment Momentum Space Speed Time Torque Velocity Virtual work Formulations Newton's laws of motion Analytical mechanics Lagrangian mechanics Hamiltonian mechanics Routhian mechanics Hamilton–Jacobi equation Appell's equation of motion Koopman–von Neumann mechanics Core topics Damping Displacement Equations of motion Euler's laws of motion Fictitious force Friction Harmonic oscillator Inertial / Non-inertial reference frame Mechanics of planar particle motion Motion (linear) Newton's law of universal gravitation Newton's laws of motion Relative velocity Rigid body dynamics Euler's equations Simple harmonic motion Vibration Rotation Circular motion Rotating reference frame Centripetal force Centrifugal force reactive Coriolis force Pendulum Tangential speed Rotational frequency Angular acceleration / displacement / frequency / velocity Scientists Kepler Galileo Huygens Newton Horrocks Halley Maupertuis Daniel Bernoulli Johann Bernoulli Euler d'Alembert Clairaut Lagrange Laplace Poisson Hamilton Jacobi Cauchy Routh Liouville Appell Gibbs Koopman von Neumann   Physics portal   Category v t e Theory. The current constructs of physics include space, time, mass, charge, energy, fields, entropy, information, the parameters of the standard model. Step by step, the constructs took basic mathematical models of physicists -- Galileo, Newton, Lagrange, Hamilton, Faraday, Maxwell, Boltzmann, Gibbs, Planck, Einstein, Bohr, Dirac, and others and applied them with ever greater precision. The interplay between theory and the real world (as experimentalists like to say) has been fruitful for physics: new physical phenomena can serve as challenges to theoreticians to be explained in their theories because that theory is incomplete, or to show that a hypothesis has been disproved and the theoretician must select another realm of possibility, or a theory has been corroborated -- and the theory is not yet disproven. The thought experiment need not be expensive, but the people who are able to create them are required, for their publication. (See TOC, right) One technique used in physics research involves Carnap-Ramsey sentences. The free and bold construction of mental models has existed from the inception of the science of physics; this technique shows specifically how to side-step questions of ontology by focusing on the gist rather on potentially irrelevant detail: "every time a theoretical term appears in a theory one should substitute a variable x for it and the theory should be preceded by the expression 'there exists a certain thing x, such that ... '"[24]. For example, a brane can be fruitfully applied in this way, without worry whether branes 'exist' -- thus Henry Tye can theorize that the Big Bang was produced by the collision of a brane and its anti-brane, which is a statement that would apply before the emergence of spacetime. This free mode of thought can be used, for example to solve any differential equation (as Feynman liked to put it[25]), but it requires imagination. Today, even the most basic concepts such as space and time are known to their theoretical limits; in physics we can even conceive of a smallest space and a smallest time which are known to be nonzero. Today, experimentation has progressed to the point that single atoms can be imaged in their positions in materials, and single atoms can be positioned at will, where earlier physicists from two thousand years before could only speculate on the existence of atoms on the grounds of ontology. Although it takes enormous amounts of energy (i.e., money), particles can even be artificially created or destroyed. But the mass points of Newton are now the target for even closer scrutiny and require the consideration of stupefyingly high-energy realms which we cannot investigate experimentally on Earth, leaving us only the cosmos as our laboratory for particle physics. What are under investigation are basic properties of the Standard Model and the symmetry exposed by the model. The process of development in physics continues to this day, with no limits in sight. Categories of physics Physics Physics by country Subfields of physics Physicists Concepts in physics Eponyms in physics Physics-related lists Physical modeling Physics in society Works about physics Physics stubs

Prerequisites
scientific notation natural units algebra geometry vector notation optics operators differential equations partial differential equations mechanical engineering electrical engineering probability statistics Venn diagram for Physics   Diagram by User:David R. Ingham.

3. History & Foundations

4. Principles/Concepts

5. Current Topics/Current Research

6. Applications and Influence

7. References and Notes

1. Karen Jelved, Andrew D. Jackson, and Ole Knudsen, (1997) translators for Selected Scientific Works of Hans Christian Ørsted, ISBN 0-691-04334-5, p. x. The succeeding Ørsted references are contained in this book.
2. "Fundamentals of the Metaphysics of Nature Partly According to a New Plan", a special reprint of Hans Christian Ørsted (1799), Philosophisk Repertorium, printed by Boas Brünnich, Copenhagen, in Danish. Kirstine Meyer's 1920 edition of Ørsted's works, vol.I, pp.33-78. English translation by Karen Jelved, Andrew D. Jackson, and Ole Knudsen, (1997) ISBN 0-691-04334-5 pp. 46-47.
3. "The foundation of general physics ... is experience. These ... everyday experiences we do not discover without deliberately directing our attention to them. Collecting information about these is observation." --Hans Christian Ørsted("First Introduction to General Physics" ¶13, part of a series of public lectures at the University of Copenhagen. Copenhagen 1811, in Danish, printed by Johan Frederik Schulz. In Kirstine Meyer's 1920 edition of Ørsted's works, vol.III pp. 151-190. ) "First Introduction to Physics: the Spirit, Meaning, and Goal of Natural Science". Reprinted in German in 1822, Schweigger's Journal für Chemie und Physik 36, pp.458-488, ISBN 0-691-04334-5 p. 292
4. "When it is not clear under which law of nature an effect or class of effect belongs, we try to fill this gap by means of a guess. Such guesses have been given the name conjectures or hypotheses."--Hans Christian Ørsted(1811) "First Introduction to General Physics" ¶18. Selected Scientific Works of Hans Christian Ørsted, ISBN 0-691-04334-5 p.297
5. "The student of nature ... regards as his property the experiences which the mathematican can only borrow. This is why he deduces theorems directly from the nature of an effect while the mathematician only arrives at them circuitously."--Hans Christian Ørsted(1811) "First Introduction to General Physics" ¶17. Selected Scientific Works of Hans Christian Ørsted, ISBN 0-691-04334-5 p.297
6. Hans Christian Ørsted(1820) ISBN 0-691-04334-5 preface, p.xvii
7. Hans Christian Ørsted(1820) ISBN 0-691-04334-5 1820 and other public experiments, pp.421-445
8. "Greek Physics", in "Physical Sciences, History of" Encyclopædia Britannica, 15th ed.
9. Nature also has the meaning of characterization, which was Homer's first recorded use.
10. "Physical Theories, Mathematical Aspects of", Encyclopædia Britannica, 15th ed.
11. The definitive work is Newton's The Mathematical Principles of Natural Philosophy, in Latin Philosophiae Naturalis Principia Mathematica
12. Doctorates in the sciences are often Doctor of Philosophy, abbreviated Ph.D.
13. "Physics", Encyclopædia Britannica, 15th ed.
14. Atom is Greek ἄτομος or átomos meaning "uncuttable"
15. For chemistry, the periodic table of the elements can be explained directly by quantum mechanics
16. For biology, the discovery of the structure of DNA was made by concrete modelling, based on x-ray diffraction experiments. Based on this result, Francis Crick immediately noted its significance for the explanation of life.
17. Before the 1800s, physic also referred to physiology, as evidenced by the term physician for medical clinicians.
18. For neuroscience, the time-sequenced operation of the visual system is predicated on the action of mirror neurons, which anticipate actions of the subjects in view. Jeff Hawkins predicted "enhanced neural activity in anticipation of a sensory event" one year (2004) before experimental confirmation (2005) by Giacomo Rizzolatti, Leonardo Fogassi, Vittorio Galles. "Mirrors in the Mind", Scientific American November 2006, pp.54-61.
19. G. Toraldo di Francia (1976), The Investigation of the Physical World ISBN 0-521-29925-X p.6
20. Stanislaw Ulam noted that the physicists he encountered during the Manhattan Project were not exactly anti-intellectual, but rather, anti-philosophical. See: Stanisław Ulam, Adventures of a Mathematician, New York, Charles Scribner's Sons, 1983 (autobiography)
21. This was motivated in part by Gell-Mann's commitment to preserving the natural world
22. Newton (1687) Philosophiae Naturalis Principia Mathematica
23. Richard Feynman (1963) The Feynman Lectures on Physics 1 p.5-1.
24. G. Toraldo di Francia (1976), The Investigation of the Physical World ISBN 0-521-29925-X p.74
25. Laurie M. Brown (ed.) (2005), Feynman's [Ph.D.] Thesis: A new approach to Quantum Theory ISBN 981-256-366-0 p.13

8. External Links

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Word counts:

1. Definition, not including the citations or italicized words -- 312 words

1.3.0.x -- 150 words

Further development from a tutorial point of view might place the physics of the playground (i.e., classical mechanics) under section 3 or section 4 depending on consensus.

Interrelationships of the topics of physics might go in section 3 or section 4 depending on consensus.

Some of the contributions to complex systems by Murray Gell-Mann and others might be placed in section 5.

It would be a shame not to highlight David R. Ingham's venn diagram for physics.

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Filll, as you undoubtedly know, there is a difference between all of science and new science. It is quite telling that physicists tend to gravitate to whatever is new, and to leave the rest for those who wish to follow. It's like the development of the transistor; they were physicists in large part; the person who brought transistor technology to Sony/Japan was -- a geophysicist; one of the pair who discovered the structure of DNA was -- a converted physicist; the World Web Web was invented -- at CERN, not to mention arXiv.org. What is common to all of this is a wide-open viewpoint and the willingness to go the extra distance to the new knowledge, whereever it lies. But it can be a hard road. This hardship might also be noted in the article.

MIght I create a formal section for the nomination of a moderator? --Ancheta Wis 00:32, 26 January 2007 (UTC)Reply

Category:seismology

There is no formal definition of physics; many people have their own definitions in order to satisfy their specific requirement. Some definitions of physics include:

1. A practical description of the remit
2. One that gives you a feel for the subject
3. A more rigourous definition of physics, however, is
4. Essential, informative, and relevant beyond the characteristics of current physics
5. Physics is a general set of principles thought to be obeyed by all known systems in nature. Practicing physicists traditionally study a limited (albeit rather broad) set of phenomena which are most amenable to direct study using the aforementioned concepts. Most notably this involves fundamental properties of matter, energy, space, and time (which are now all known to be intricately related). As human knowledge has advanced, the set of physical principles and the phenomena fruitfully studied with them have both increased, leading to active interdisciplinary fields such as biophysics and geophysics. Nonetheless direct application of the laws of physics is (currently) prohibitively difficult in many cases. Thus fields like biology, chemistry and others have their own methods and concepts which cannot be directly derived from the presumed underlying physical laws. So physics is not any study of nature; that is natural science, different fields of which have developed their own tools and language. But, importantly, should any field of science discover some phenomena which violates basic laws of physics, the laws would have to be modified in order to retain their general, encompassing stature. Finally, this article is for the general reader, not an expert, and should be written so. Joshua Davis 04:46, 26 November 2006 (UTC)

Position D

1. Rutherford's Definition

"All science is either physics or stamp collecting" --Ernest Rutherford ^[D]

[D] Ernest Rutherford in J. B. Birks Rutherford at Manchester (1962)

8 words.

84 word paraphrase: Science is not merely a collection of facts, but more importantly, a consistent, coherent structure of interconnected results which follow scientific method.

At the time Rutherford spoke, only physics could claim this position. Anything else became a series of ad-hoc positions (stamp collecting: matter, energy, atoms, penguins). Biology had not yet discovered the structure of DNA; the atoms of chemistry had not yet been explained by quantum mechanics. Progress has come by using the constructs of physics.

Confer with Joshua Davis' statement included in #Position B.

Position E

1. Einstein's Definition

"Physics constitutes a logical system of thought which is in a state of evolution, and whose basis cannot be obtained through distillation by any inductive method from the experiences lived through, but which can only be attained by free invention." ^[E]

39 words - [E] Albert Einstein (1936), Physics and Reality, summarized in his Essays in Physics (1950) New York, Philosophical Library p. 51

Confer with Noetica's and Krea's statements above. I do not have a copy of Einstein's Ideas and Opinions which actually dovetail with Position B above. --Ancheta Wis 01:56, 25 November 2006 (UTC)Reply

"[The] general laws on which the structure of theoretical physics is based claim to be valid for any natural phenomenon whatsover. With them, it ought to be possible to arrive at the description, that is to say, the theory, of every natural process, including life, by means of pure deduction ... " ^[E2]

48 words. [E2] Albert Einstein (1918, Max Planck's 60th birthday) "Principles of Research" in Ideas and Opinions, ISBN 0-517-55601-4 (1954) p.226. --Ancheta Wis 08:24, 29 November 2006 (UTC)Reply

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v t e Orders of magnitude
Quantity	Acceleration Angular momentum Area Bit rate Charge Computing Current Data Density Energy / Energy density Entropy Force Frequency Illuminance Length Luminance Magnetic field Mass Molarity Numbers Power Pressure Probability Radiation Sound pressure Specific heat capacity Speed Temperature Torque Time Voltage Volume
See also	Back-of-the-envelope calculation Best-selling electronic devices Fermi problem Powers of 10 and decades 10th 100th 1000000th Metric (SI) prefix Macroscopic scale Microscopic scale
Related	Astronomical system of units Earth's location in the Universe Cosmic View (1957 book) To the Moon and Beyond (1964 film) Cosmic Zoom (1968 film) Powers of Ten (1968 and 1977 films) Cosmic Voyage (1996 documentary) The Scale of the Universe (2010) Cosmic Eye (2012)
Category

Space or distance, length

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Time or duration

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Mass or measure of matter

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Charge a property of matter

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Frequency Feynman 1 2-5 Units of Hertz, or oscillation/sec

Units	Exponent	Example	Construct
1	10^2	Electric field	field
5	10^5 - 10^6	Radio	wave
5	10^14 - 10^15	Light	wave
1	10^27	Cosmic rays	particle

Energy

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Temperature

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Entropy

Unit	Exponent	Example	F
C	D	g	h
C	D	g	h
C	D	g	h
C	D	g	h

Well, what does physics have that no other science does?

1. Sets of well-known equations, some with centuries of use. A community of researchers who know what to do with them. Sets of industries which have applied them. Chemistry and Biology are slowly coming on-line with computational chemistry, etc
2. Some history of investigation: some of the data has been accumulated over millennia. Now biology especially has an analog of this with species with billions of years of evolution in their genetic code, and with primates, with species perhaps 10 million years old, with their super-fast visual processing. So the species can be viewed as a database of DNA investigation of a hostile Earth.
3. A philosophical base. Sorry Joshua if that seems too pro-philosophical.
4. A community of technologists in symbiosis with the science. This is a clear advantage over the biologists, who currently do not produce artificial life. or artificial brains.
5. A symbiosis with mathematics.
6. A history of community with like-minded researchers. This does not excuse the obverse, such as hostility to researchers like Ludwig Boltzmann
7. Strong foundation in scientific method. Other sciences such as biology have not undergone the reductionist revolutions.

Well, Krea, the past weeks have served to solidify a proposed definition. It has some distinct positions in it, but the other versions do as well:

• Physics can be defined as that science which seeks those fundamental laws to which the universe is subject.

Now fundamental refers to those equations which can be expressed as differential equations, typically in an inertial frame, but with respect to some well-defined transformation law, defined by the symmetries of the system under discussion.

Topics in Physics Mechanics Classical mechanics Quantum mechanics Relativity Electromagnetism Thermodynamics Statistical Mechanics Fluid Mechanics Mathematical Physics Bulk matter

Let's please not dismiss the concepts behind systems far from equilibrium. They need not be biological. What if this discussion were encapsulated for the future. --Ancheta Wis 01:17, 17 October 2006 (UTC)Reply

Krea, I have a small definition for you:

• A physicist is someone who discovers a law of nature.

Now that could include a lot of people, if they knew nothing beforehand. So one would have to qualify it to make it more conventional and sharper

• A physicist is someone who discovers a new law of nature.

In other words, physicist is a badge of honor, in my book. A child who understands something on her own, and does right by it, has accomplished something.

M, It is not shameful not to have attained the title. If you want to accomplish something noteworthy, how about starting here and now. Work with us, by helping us converge on a suitable definition.

There is no choice. Noetica's idea of Ecumenism and pluralism are the only visible route out of this labyrinth of words. Might we heed the words of Galileo, the physicist, quoted above, and listen to the message that Nature is speaking to us, loud and clear, right now.

SFC9394, if we consider the productivity of this page, might I suggest that something be restructured. It is not right that we continue in this fashion. We need something else. Failing that, we should remove the note at the top of the Physics article, perhaps leaving it on the talk page, with a slightly more modest font and box size, in keeping with the accomplishments so far.

This effort of definition has re-hashed things over 3 times. Since some of us appear to specialize in commentary, perhaps we might present less the of type of argumentation that diverts and diverges, at a time when we are trying to converge. Might I request that we take such commentary 'under advisement', during definition phase. There is nothing wrong with any of the arguments on the page above. But the timing of the contributions is wrong, if the article is to be developed in the specified sequence.

This page appears to be re-creating Nupedia in miniature. In other words, it is wasting a lot of people's time. But strident insistence on 'Physics is x, y, and z' is uncomfortably close to the arguments about the four humors of the western ancients. Now how would that look to anyone in the future? How would anyone who then believed in the five essences of Chinese civilization accept such categorical statements? How would any progress get made in any kind of science? Answer: by reconciling conflict. Perhaps by reaching common ground. May I ask us all to avoid Wikipedia:Tendentious editing and place your comments in the context of the article's current phase and stage of development.

As an aside, what would be wrong with Newton's method as applied to article definition; in other words, give up the insistence on strict sequential development, and simply let the editors work on the wip page directly?

Krea, there appears to be an analogy to a reactor vessel here: the Pressure, Temperature, Volume, Mixing ratio, and chemical population are currently not producing the expected chemical reaction. M points out that 3 editors are insufficent. At Wikimania, User:fuzheado noted that the number needs to be about 35 for satisfactory pages. --Ancheta Wis 00:44, 3 November 2006 (UTC)Reply