Subatomic particle: Difference between revisions

A subatomic particle is an elementary or composite particle smaller than an atom. Particle physics and nuclear physics are concerned with the study of these particles, their interactions, and non-atomic matter.

Subatomic particles include the atomic constituents electrons, protons, and neutrons. Protons and neutrons are composite particles, consisting of quarks. A proton contains two up quarks and one down quark, while a neutron consists of one up quark and two down quarks; the quarks are held together in the nucleus by gluons. There are six different types of quark in all ('up', 'down', 'bottom', 'top', 'strange', and 'charm'), as well as other particles including photons and neutrinos which are produced copiously in the sun. Most of the particles that have been discovered are encountered in cosmic rays interacting with matter and are produced by scattering processes in particle accelerators. There are dozens of known subatomic particles.

Hydrogen atom (schematic)
The picture shows the first few hydrogen atom orbitals (energy eigenfunctions). These are cross-sections of the probability density with warmer colors having higher probability.

Introduction to particles

In particle physics, the conceptual idea of a particle is one of several concepts inherited from classical physics, the world we experience, that are used to describe how matter and energy behave at the molecular scales of quantum mechanics. As physicists use the term, the meaning of the word "particle" is one which understands how particles are radically different at the quantum-level, and rather different from the common understanding of the term.

The idea of a particle is one which had to undergo serious rethinking in light of experiments which showed that the smallest particles (of light) could behave just like waves. The difference is indeed vast, and required the new concept of wave-particle duality to state that quantum-scale "particles" are understood to behave in a way which resembles both particles and waves. Another new concept, the uncertainty principle, meant that analyzing particles at these scales required a statistical approach. All of these factors combined such that the very notion of a discrete "particle" has been ultimately replaced by the concept of something like wave-packet of an uncertain boundary, whose properties are only known as probabilities, and whose interactions with other "particles" remain largely a mystery, even 80 years after quantum mechanics was established.

Energy

Energy and matter we have studied from Einstein's hypotheses are analogous: matter can be austerely denoted in terms of energy. Thus, we have only discovered two mechanisms in which energy can be transferred. These are particles and waves. For example, light can be expressed as both particles and waves. Haha i edited this. lol. rotfl. who ever is reading this thinks im a dick. lol. This paradox is known as the Duality Paradox. ^[1].

Through the work of Albert Einstein, Louis de Broglie, and many others, current scientific theory holds that all particles also have a wave nature.^[2] 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; we can't detect wave properties of macroscopic objects due to their small wavelengths.^[3]

Interactions between particles have been scrutinized for many centuries, and a few simple laws underpin how particles proceed in collisions and interactions. The most angelic of these are the conservation of energy and momentum which facilitate us to elucidate calculations between particle interactions on scales of magnitude which diverge between planets and quarks^[4]. 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

G. Johnstone Stoney postulated a fundamental unit of electrical charge in 1874, and in 1891 he suggested the name electron (denoted e⁻) for this quantity.^[5] The electron as a sub-atomic particle was first observed in 1897 by J. J. Thomson. Subsequent speculation about the structure of atoms was severely constrained by the 1907 experiment of Ernest Rutherford which showed that the atom was mostly empty space, and almost all its mass was concentrated into the (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. Protons (p⁺) were known to be the nucleus of the hydrogen atom. Neutrons (n) were postulated by Rutherford and discovered by James Chadwick in 1932. The word nucleon denotes both the neutron and the proton.

Electrons, which are negatively charged, have a mass of 1/1836 of a hydrogen atom, the remainder of the atom's mass coming from the positively charged proton. The atomic number of an element counts the number of protons. Neutrons are neutral particles with a mass almost equal to that of the proton. Different isotopes of the same nucleus contain the same number of protons but differing numbers of neutrons. The mass number of a nucleus counts the total number of nucleons.

Chemistry concerns itself with the arrangement of electrons in atoms and molecules, and nuclear physics with the arrangement of protons and neutrons in a nucleus. The study of subatomic particles, atoms and molecules, their structure and interactions, involves quantum mechanics and quantum field theory (when dealing with processes that change the number of particles). The study of subatomic particles per se is called particle physics. Since many particles need to be created in high energy particle accelerators or cosmic rays, sometimes particle physics is also called high energy physics.

History

J. J. Thomson discovered electrons in 1897. In 1905 Albert Einstein demonstrated the physical reality of the photons which were postulated by Max Planck in order to solve the problem of black body radiation in thermodynamics. Ernest Rutherford discovered in 1907 in the gold foil experiment that the atom is mainly empty space, and that it contains a heavy but small atomic nucleus. The early successes of the quantum theory involved explaining properties of atoms in terms of their electronic structure. The proton was soon identified as the nucleus of hydrogen. The neutron was postulated by Rutherford following his discovery of the nucleus, but was discovered by James Chadwick much later, in 1932. Neutrinos were postulated in 1931 by Wolfgang Pauli (and named by Enrico Fermi) to be produced in beta decays (the weak interaction) of neutrons, but were not discovered till 1956. Pions were postulated by Hideki Yukawa as mediators of the 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. All currently known particles fit into the standard model.

See also

• Poincare symmetry, CPT invariance, spin statistics theorem, bosons and fermions.
• Particle physics, list of particles, the quark model and the standard model.
• Ylem

• Dark Matter
• Proton
• Neutron
• Electron

References

1. Einstein, Albert (1920). Relativity: The Special & General Theory. New York Henry Holt and Company. ISBN 1-58734-092-5. {{cite book}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
2. Walter Greiner (2001). Quantum Mechanics: An Introduction. Springer. ISBN 3540674586.
3. R. Eisberg and R. Resnick (1985). Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles (2nd ed. 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. {{cite book}}: |edition= has extra text (help)
4. Isaac Newton - Newton's Laws of Motion (Philosophiae Naturalis Principia Mathematica). 1687.
5. Klemperer, Otto (1959). Electron Physics: The Physics of the Free Electron. Academic Press.

External links

• particleadventure.org: The Standard Model
• particleadventure.org: Particle chart
• University of California: Particle Data Group
• Annotated Physics Encyclopædia: Quantum Field Theory
• Jose Galvez: Chapter 1 Electrodynamics (pdf)