Philosophy of physics

Philosophy of physics

In philosophy, the philosophy of physics studies the fundamental philosophical questions underlying modern physics, the study of matter and energy and how they interact. The philosophy of physics begins by reflecting on the basic metaphysical and epistemological questions posed by physics: causality, determinism, and the nature of physical law. It then turns to questions raised by important topics in contemporary physics:

Centuries ago, the study of causality, and of the fundamental nature of space, time, matter, and the universe were part of metaphysics. Today the philosophy of physics is essentially a part of the philosophy of science. Physicists utilize the scientific method to delineate the universals and constants governing physical phenomena, and the philosophy of physics reflects on the results of this empirical research.


  • Purpose of physics 1
  • Philosophy of space and time 2
    • Time 2.1
    • Time travel 2.2
    • Space 2.3
  • Philosophy of quantum mechanics 3
    • Determinism 3.1
    • Indeterminism 3.2
    • Uncertainty principle 3.3
    • Complementarity 3.4
  • Quotes from Einstein's work on the importance of the philosophy of physics 4
  • See also 5
  • References 6
  • Further reading 7
  • External links 8

Purpose of physics

According to Niels Bohr, the purpose of physics is:[1]

not to disclose the real essence of phenomena but only to track down (...) relations between the manifold aspects of experience.

Many, particularly realists, find this minimal formulation an inadequate formulation of the purpose of physics, which they view as providing, in addition, a deeper world picture.

Philosophy of space and time


Time, in many philosophies, is seen as change.

Time is considered to be a fundamental quantity (that is, a quantity which cannot be defined in terms of other quantities), because at present nothing is more basic than time. Thus time is defined via measurement—by its standard time interval. Currently, the standard time interval (called "conventional second", or simply "second") is defined as 9,192,631,770 oscillations of a hyperfine transition in the 133 caesium atom. (ISO 31-1). What time is and how it works follows from the above definition. Physicists use theory to predict how time is measured. Time then can be combined mathematically with the fundamental quantities of space and mass to describe and quantify motion and displacement, and to define concepts such as velocity, momentum, energy, and fields.

Both Newton and Galileo,[2] as well as most people up until the 20th century, thought that time was the same for everyone everywhere. Our modern conception of time is based on Einstein's theory of relativity and Hermann Minkowski's spacetime, in which rates of time run differently in different inertial frames of reference, and space and time are merged into spacetime. Time may be quantized, with the theoretical smallest time being on the order of the Planck time. Einstein's general relativity as well as the redshift of the light from receding distant galaxies indicate that the entire Universe and possibly space-time itself began about 13.8 billion years ago in the big bang. Whether and how the universe will ever end are open questions (see Ultimate fate of the universe).

Time travel

Some theories, most notably special and general relativity, suggest that suitable geometries of spacetime, or certain types of motion in space, may allow time travel into the past and future. Concepts that aid such understanding include the closed timelike curve.

Albert Einstein's special theory of relativity (and, by extension, the general theory) predicts time dilation that could be interpreted as time travel. The theory states that, relative to a stationary observer, time appears to pass more slowly for faster-moving bodies: for example, a moving clock will appear to run slow; as a clock approaches the speed of light its hands will appear to nearly stop moving. The effects of this sort of time dilation are discussed further in the popular "twin paradox". These results are experimentally observable and affect the operation of GPS satellites and other high-tech systems used in daily life.

A second, similar type of time travel is permitted by general relativity. In this type a distant observer sees time passing more slowly for a clock at the bottom of a deep gravity well, and a clock lowered into a deep gravity well and pulled back up will indicate that less time has passed compared to a stationary clock that stayed with the distant observer.

These effects are to some degree similar to hibernation, or cooling of live objects (which slow down the rates of chemical processes in the subject) almost indefinitely suspending their life thus resulting in "time travel" toward the future, but never backward. They do not violate causality. This is not typical of the "time travel" featured in science fiction (where causality is violated at will), and there is little doubt surrounding its existence. "Time travel" will hereafter refer to travel with some degree of freedom into the past or future of proper time.

Many in the scientific community believe that time travel is highly unlikely, because it violates causality i.e. the logic of cause and effect. For example, what happens if you attempt to go back in time and kill yourself at an earlier stage in your life (or your grandfather, which leads to the grandfather paradox)? Stephen Hawking once suggested that the absence of tourists from the future constitutes a strong argument against the existence of time travel— a variant of the Fermi paradox, with time travelers instead of alien visitors. Hitherto there is no experimental evidence of time travel, making it a mere hypothesis as opposed to an empirical fact.


Space is one of the few fundamental quantities in physics, meaning that it cannot be defined via other quantities because there is nothing more fundamental known at present. Thus, similar to the definition of other fundamental quantities (like time and mass), space is defined via measurement. Currently, the standard space interval, called a standard meter or simply meter, is defined as the distance traveled by light in a vacuum during a time interval of 1/299792458 of a second (exact).

In classical physics, space is a three-dimensional Euclidean space where any position can be described using three coordinates. Special and general relativity use spacetime rather than space; spacetime is modeled as a four-dimensional space (with the time axis being imaginary in special relativity and real in general relativity, and currently there are many theories which use more than four spatial dimensions.

Philosophy of quantum mechanics

Quantum mechanics has provided much controversy in philosophical interpretations. As it developed its theories began to contradict many of the accepted philosophies at the beginning of the 20th century. However, its mathematical predictions coincide with observations.


The 18th century saw many advances in the domain of science. After Newton, most scientists agreed on the presupposition that the universe is governed by strict natural laws that can be discovered and formalized by means of scientific observation and experiment. This position is known as determinism. However, determinism seems to preclude the possibility of free will. That is, if the universe, and thus any person in it, is governed by strict and universal laws, then that means that a person's behavior could be predicted based on sufficient knowledge of the circumstances that obtained prior to that person's behavior. This appears to contradict the person's perception of free will, except as interpreted in compatibilism. Conversely, if we accept that human beings do have (libertarian or incompatibilist) free will, then we must accept that the world is not entirely governed by natural law. Some have argued that if the world is not entirely governed by natural law, then the task of science is rendered impossible. However, the development of quantum mechanics gave thinkers alternatives to these strictly bound possibilities, proposing a model for a universe that follows general rules but never had a predetermined future.


Against the proponents of determinism like Einstein and Max Planck, indeterminism—championed by the English astronomer Sir Arthur Eddington[3]—says that a physical object has an ontologically undetermined component that is not due to the epistemological limitations of physicists' understanding. The uncertainty principle, then, would not necessarily be due to hidden variables but to an indeterminism in nature itself.

Lemaître, Reichenbach, et al. were all supporters of indeterminism.[3]

Uncertainty principle

The uncertainty principle is a mathematical relation asserting an upper limit to the accuracy of the simultaneous measurement of any pair of conjugate variables, e.g. position and momentum. In the formalism of operator notation, this limit is the evaluation of the commutator of the variables' corresponding operators.

The uncertainty principle arose as an answer to the question: How does one measure the location of an electron around a nucleus if an electron is a wave? When quantum mechanics was developed, it was seen to be a relation between the classical and quantum descriptions of a system using wave mechanics.

In March 1926, working in Niels Bohr's institute, Werner Heisenberg formulated the principle of uncertainty thereby laying the foundation of what became known as the Copenhagen interpretation of quantum mechanics. Heisenberg had been studying the papers of Paul Dirac and Pascual Jordan. He discovered a problem with measurement of basic variables in the equations. His analysis showed that uncertainties, or imprecisions, always turned up if one tried to measure the position and the momentum of a particle at the same time. Heisenberg concluded that these uncertainties or imprecisions in the measurements were not the fault of the experimenter, but fundamental in nature and are inherent mathematical properties of operators in quantum mechanics arising from definitions of these operators.[4]

The term Copenhagen interpretation of quantum mechanics was often used interchangeably with and as a synonym for Heisenberg's uncertainty principle by detractors (such as Einstein and the physicist Alfred Landé) who believed in determinism and saw the common features of the Bohr-Heisenberg theories as a threat. Within the Copenhagen interpretation of quantum mechanics the uncertainty principle was taken to mean that on an elementary level, the physical universe does not exist in a deterministic form, but rather as a collection of probabilities, or possible outcomes. For example, the pattern (probability distribution) produced by millions of photons passing through a diffraction slit can be calculated using quantum mechanics, but the exact path of each photon cannot be predicted by any known method. The Copenhagen interpretation holds that it cannot be predicted by any method, not even with theoretically infinitely precise measurements.


The idea of complementarity is critical in quantum mechanics. It says that light can behave both like a particle and like a wave. When the double-slit experiment was performed, light acted in some cases as a wave, and some cases as a particle. Physicists had no convincing theory to explain this until Bohr and complementarity came along.

Quotes from Einstein's work on the importance of the philosophy of physics

Einstein was interested in the philosophical implications of his theory.

Albert Einstein was extremely interested in the philosophical conclusions of his work. He writes:

"I fully agree with you about the significance and educational value of methodology as well as history and philosophy of science. So many people today—and even professional scientists—seem to me like somebody who has seen thousands of trees but has never seen a forest. A knowledge of the historic and philosophical background gives that kind of independence from prejudices of his generation from which most scientists are suffering. This independence created by philosophical insight is—in my opinion—the mark of distinction between a mere artisan or specialist and a real seeker after truth." Einstein. letter to Robert A. Thornton, 7 December 1944. EA 61-574.


"How does it happen that a properly endowed
"The path of scientific advance is often made impassable for a long time through such errors. For that reason, it is by no means an idle game if we become practiced in analyzing the long-commonplace concepts and exhibiting [revealing, exposing? -Ed.] those circumstances upon which their justification and usefulness depend, how they have grown up, individually, out of the givens of experience. By this means, their all-too-great authority will be broken." Einstein, 1916, "Memorial notice for Ernst Mach," Physikalische Zeitschrift 17: 101-02.

See also


  1. ^ N.Bohr, Atomic Theory and the Description of Human Knowledge (Cambridge University Press, Cambridge, 1934) p.19. Found in: R.Plaga (1997). "Proposal for an experimental test of the many-worlds interpretation of quantum mechanics". Foundations of Physics, v. 27, p. 559.
  2. ^ Roger Penrose, 2004. The Road to Reality: A Complete Guide to the Laws of the Universe. London: Jonathan Cape. ISBN 0-224-04447-8 (hardcover), 0-09-944068-7 (paperback).
  3. ^ a b  
  4. ^ Niels Bohr, Atomic Physics and Human Knowledge, p. 38

Further reading

  • David Albert, 1994. Quantum Mechanics and Experience. Harvard Univ. Press.
  • John D. Barrow and Frank J. Tipler, 1986. The Cosmological Anthropic Principle. Oxford Univ. Press.
  • Beisbart, C. and S. Hartmann, eds., 2011. "Probabilities in Physics". Oxford Univ. Press.
  • John S. Bell, 2004 (1987), Speakable and Unspeakable in Quantum Mechanics. Cambridge Univ. Press.
  • David Bohm, 1980. Wholeness and the Implicate Order. Routledge.
  • Nick Bostrom, 2002. Anthropic Bias: Observation Selection Effects in Science and Philosophy. Routledge.
  • Thomas Brody, 1993, Ed. by Luis de la Peña and Peter E. Hodgson The Philosophy Behind Physics Springer ISBN 3-540-55914-0
  • Harvey Brown, 2005. Physical Relativity. Space-time structure from a dynamical perspective. Oxford Univ. Press.
  • Butterfield, J., and John Earman, eds., 2007. Philosophy of Physics, Parts A and B. Elsevier.
  • Craig Callender and Nick Huggett, 2001. Physics Meets Philosophy at the Planck Scale. Cambridge Univ. Press.
  • David Deutsch, 1997. The Fabric of Reality. London: The Penguin Press.
  • Bernard d'Espagnat, 1989. Reality and the Physicist. Cambridge Univ. Press. Trans. of Une incertaine réalité; le monde quantique, la connaissance et la durée.
  • --------, 1995. Veiled Reality. Addison-Wesley.
  • --------, 2006. On Physics and Philosophy. Princeton Univ. Press.
  • Roland Omnes, 1994. The Interpretation of Quantum Mechanics. Princeton Univ. Press.
  • --------, 1999. Quantum Philosophy. Princeton Univ. Press.
  • Huw Price, 1996. Time's Arrow and Archimedes's Point. Oxford Univ. Press.
  • Lawrence Sklar, 1992. Philosophy of Physics. Westview Press. ISBN 0-8133-0625-6, ISBN 978-0-8133-0625-4
  • Victor Stenger, 2000. Timeless Reality. Prometheus Books.
  • Carl Friedrich von Weizsäcker, 1980. The Unity of Nature. Farrar Straus & Giroux.
  • Werner Heisenberg, 1971. Physics and Beyond: Encounters and Conversations. Harper & Row (World Perspectives series), 1971.
  • William Berkson, 1974. Fields of Force. Routledge and Kegan Paul, London. ISBN 0-7100-7626-6

External links

  • Stanford Encyclopedia of Philosophy:
    • "Absolute and Relational Theories of Space and Motion" -- Nick Huggett and Carl Hoefer
    • "Being and Becoming in Modern Physics" -- Steven Savitt
    • "Boltzmann's Work in Statistical Physics" -- Jos Uffink
    • "Conventionality of Simultaneity" -- Allen Janis
    • "Early Philosophical Interpretations of General Relativity" -- Thomas A. Ryckman
    • "Experiments in Physics" -- Allan Franklin
    • "Holism and Nonseparability in Physics" -- Richard Healey
    • "Intertheory Relations in Physics" -- Robert Batterman
    • "Naturalism" -- David Papineau
    • "Philosophy of Statistical Mechanics" -- Lawrence Sklar
    • "Physicalism" -- Daniel Sojkal
    • "Quantum Mechanics" -- Jenann Ismael
    • "Reichenbach's Common Cause Principle" -- Frank Artzenius
    • "Structural Realism" -- James Ladyman
    • "Structuralism in Physics" -- Heinz-Juergen Schmidt
    • "Symmetry and Symmetry Breaking" -- Katherine Brading and Elena Castellani
    • "Thermodynamic Asymmetry in Time" -- Craig Callender
    • "Time"-- by Ned Markosian
    • "Uncertainty principle" -- Jan Hilgevoord and Jos Uffink
    • "The Unity of Science" -- Jordi Cat