- Subatomic particle
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In physics or chemistry, subatomic particles are the smaller particles composing nucleons and atoms. There are two types of subatomic particles: elementary particles, which are not made of other particles, and composite particles. Particle physics and nuclear physics study these particles and how they interact.[1]
The elementary particles of the Standard Model include:[2]
- Six "flavors" of quarks: up, down, bottom, top, strange, and charm
- Six types of leptons: electron, electron neutrino, muon, muon neutrino, tau, tau neutrino
- Thirteen gauge bosons (force carriers): the graviton of gravity, the photon of electromagnetism, the three W and Z bosons of the weak force, and the eight gluons of the strong force.
Composite subatomic particles (such as protons or atomic nuclei) are bound states of two or more elementary particles. For example, a proton is made of two up quarks and one down quark, while the atomic nucleus of helium-4 is composed of two protons and two neutrons. Composite particles include all hadrons, a group composed of baryons (e.g., protons and neutrons) and mesons (e.g., pions and kaons).
Contents
Particles
In particle physics, the conceptual idea of a particle is one of several concepts inherited from classical physics. This describes the world we experience, used (for example) to describe how matter and energy behave at the molecular scales of quantum mechanics. For physicists, the word "particle" means something rather different from the common sense of the term, reflecting the modern understanding of how particles behave at the quantum scale in ways that differ radically from what everyday experience would lead us to expect.
The idea of a particle underwent serious rethinking in light of experiments that showed that light could behave like a stream of particles (called photons) as well as exhibit wave-like properties. These results necessitated the new concept of wave-particle duality to reflect that quantum-scale "particles" are understood to behave in a way resembling both particles and waves. Another new concept, the uncertainty principle, concluded that analyzing particles at these scales would require a statistical approach. In more recent times, wave-particle duality has been shown to apply not only to photons but to increasingly massive particles.[3]
All of these factors ultimately combined to replace the notion of discrete "particles" with the concept of "wave-packets" of uncertain boundaries, whose properties are known only as probabilities, and whose interactions with other "particles" remain largely a mystery, even 80 years after the establishment of quantum mechanics.
Energy
In Einstein's hypotheses, energy and mass are analogous. That is, mass can be simply expressed in terms of energy and vice-versa. Consequently, there are only two known mechanisms by which energy can be transferred. These are particles and waves. For example, light can be expressed as both particles and waves. This paradox is known as the Wave–particle Duality Paradox.[4]
Through the work of Albert Einstein, Louis de Broglie, and many others, current scientific theory holds that all particles also have a wave nature.[5] This phenomenon has been verified not only for elementary particles but also for compound particles like atoms and even molecules. In fact, according to traditional formulations of non-relativistic quantum mechanics, wave–particle duality applies to all objects, even macroscopic ones; wave properties of macroscopic objects can not be detected due to their small wavelengths.[6]
Interactions between particles have been scrutinized for many centuries, and a few simple laws underpin how particles behave in collisions and interactions. The most fundamental of these are the laws of conservation of energy and conservation of momentum, which enable us to make calculations of particle interactions on scales of magnitude that range from stars to quarks.[7] These are the prerequisite basics of Newtonian mechanics, a series of statements and equations in Philosophiae Naturalis Principia Mathematica originally published in 1687.
Dividing an atom
The negatively-charged electron has a mass equal to 1/1836 of that of a hydrogen atom. The remainder of the hydrogen atom's mass comes from the positively charged proton. The atomic number of an element is the number of protons in its nucleus. Neutrons are neutral particles having a mass slightly greater than that of the proton. Different isotopes of the same element contain the same number of protons but differing numbers of neutrons. The mass number of an isotope is the total number of nucleons (neutrons and protons collectively).
Chemistry concerns itself with how electron sharing binds atoms into molecules. Nuclear physics deals with how protons and neutrons arrange themselves in nuclei. The study of subatomic particles, atoms and molecules, and their structure and interactions, requires quantum mechanics. Analyzing processes that change the numbers and types of particles requires quantum field theory. The study of subatomic particles per se is called particle physics. Since most varieties of particle occur only as a result of cosmic rays, or in particle accelerators, particle physics is also called high-energy physics.
History
In 1905, Albert Einstein demonstrated the physical reality of the photons, hypothesized by Max Planck in 1900, in order to solve the problem of black body radiation in thermodynamics.
In 1874, G. Johnstone Stoney postulated a minimum unit of electrical charge, for which he suggested the name electron in 1891.[8] In 1897, J. J. Thomson confirmed Stoney's conjecture by discovering the first subatomic particle, the electron (now denoted e−). Subsequent speculation about the structure of atoms was severely constrained by Ernest Rutherford's 1907 gold foil experiment, showing that the atom is mainly empty space, with almost all its mass concentrated in a (relatively) tiny atomic nucleus. The development of the quantum theory led to the understanding of chemistry in terms of the arrangement of electrons in the mostly empty volume of atoms. In 1918, Rutherford confirmed that the hydrogen nucleus was a particle with a positive charge, which he named the proton, now denoted p+. Rutherford also conjectured that all nuclei other than hydrogen contain chargeless particles, which he named the neutron. It is now denoted n. James Chadwick discovered the neutron in 1932. The word nucleon denotes neutrons and protons collectively.
Neutrinos were postulated in 1931 by Wolfgang Pauli (and named by Enrico Fermi) to be produced in beta decays of neutrons, but were not discovered until 1956. Pions were postulated by Hideki Yukawa as mediators of the residual strong force, which binds the nucleus together. The muon was discovered in 1936 by Carl D. Anderson, and initially mistaken for the pion. In the 1950s the first kaons were discovered in cosmic rays.
The development of new particle accelerators and particle detectors in the 1950s led to the discovery of a huge variety of hadrons, prompting Wolfgang Pauli's remark: "Had I foreseen this, I would have gone into botany". The classification of hadrons through the quark model in 1961 was the beginning of the golden age of modern particle physics, which culminated in the completion of the unified theory called the standard model in the 1970s. The discovery of the weak gauge bosons through the 1980s, and the verification of their properties through the 1990s is considered to be an age of consolidation in particle physics. Among the standard model particles, the existence of the Higgs boson remains to be verified— this is seen as the primary physics goal of the accelerator called the Large Hadron Collider in CERN. 22th Sep. 2011 CERN claimed to have measured sub-atomic particles faster than the speed of light, putting Einstein's theory in question.[9][10]
See also
- Atom: Journey Across the Subatomic Cosmos (book)
- Boson
- CPT invariance
- Dark Matter
- Electron
- Elementary particle
- Fermion
- Hot spot effect in subatomic physics
- List of fictional elements, materials, isotopes and atomic particles
- List of particles
- Neutron
- Particle physics
- Poincare symmetry
- Proton
- Quark model
- Spin statistics theorem
- Standard model
- Ylem
References
- ^ Fritzsch, Harald (2005). Elementary Particles. World Scientific. pp. 11–20. ISBN 9789812561411. http://books.google.com/?id=KFodZ8oHz2sC&printsec=frontcover&dq=elementary+particles+subject:%22Science+/+Nuclear+Physics%22.
- ^ Cottingham, W. N.; Greenwood, D. A. (2007). An introduction to the standard model of particle physics. Cambridge University Press. p. 1. ISBN 9780521852494. http://books.google.com/?id=Dm36BYq9iu0C&printsec=frontcover&dq=particle+physics.
- ^ Arndt, Markus; Nairz, Olaf; Vos-Andreae, Julian; Keller, Claudia; Van Der Zouw, Gerbrand; Zeilinger, Anton (2000). "Wave-particle duality of C60 molecules". Nature 401 (6754): 680–682. Bibcode 1999Natur.401..680A. doi:10.1038/44348. PMID 18494170.
- ^ Einstein, Albert; Lawson, Robert W. (1920). Relativity: The Special &vGeneral Theory. Henry Holt and Company. ISBN 1-58734-092-5.
- ^ Walter Greiner (2001). Quantum Mechanics: An Introduction. Springer. p. 29. ISBN 3540674586. http://books.google.com/?id=7qCMUfwoQcAC&pg=PA29&dq=wave-particle+all-particles.
- ^ R. Eisberg and R. Resnick (1985). Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles (2nd ed.). John Wiley & Sons. pp. 59–60. ISBN 047187373X. "For both large and small wavelengths, both matter and radiation have both particle and wave aspects. [...] But the wave aspects of their motion become more difficult to observe as their wavelengths become shorter. [...] For ordinary macroscopic particles the mass is so large that the momentum is always sufficiently large to make the de Broglie wavelength small enough to be beyond the range of experimental detection, and classical mechanics reigns supreme."
- ^ Isaac Newton (1687). Newton's Laws of Motion (Philosophiae Naturalis Principia Mathematica)
- ^ Klemperer, Otto (1959). Electron Physics: The Physics of the Free Electron. Academic Press.
- ^ http://www.reuters.com/article/2011/09/22/us-science-light-idUSTRE78L4FH20110922
- ^ http://www.telegraph.co.uk/science/science-news/8783011/Speed-of-light-broken-at-CERN-scientists-claim.html
Further reading
General readers
- Feynman, R.P. & Weinberg, S. (1987). Elementary Particles and the Laws of Physics: The 1986 Dirac Memorial Lectures. Cambridge Univ. Press.
- Brian Greene (1999). The Elegant Universe. W.W. Norton & Company. ISBN 0-393-05858-1.
- Oerter, Robert (2006). The Theory of Almost Everything: The Standard Model, the Unsung Triumph of Modern Physics. Plume.
- Schumm, Bruce A. (2004). Deep Down Things: The Breathtaking Beauty of Particle Physics. John Hopkins Univ. Press. ISBN 0-8018-7971-X.
- Martinus Veltman (2003). Facts and Mysteries in Elementary Particle Physics. World Scientific. ISBN 981-238-149-X.
Textbooks
- Coughlan, G. D., J. E. Dodd, and B. M. Gripaios (2006). The Ideas of Particle Physics: An Introduction for Scientists, 3rd ed. Cambridge Univ. Press. An undergraduate text for those not majoring in physics.
- Griffiths, David J. (1987). Introduction to Elementary Particles. Wiley, John & Sons, Inc. ISBN 0-471-60386-4.
- Kane, Gordon L. (1987). Modern Elementary Particle Physics. Perseus Books. ISBN 0-201-11749-5.
External links
- particleadventure.org: The Standard Model.
- cpepweb.org: Particle chart.
- University of California: Particle Data Group.
- Annotated Physics Encyclopædia: Quantum Field Theory.
- Jose Galvez: Chapter 1 Electrodynamics (pdf).
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