Difference between revisions of "Quantum"
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| − | In [[physics]], a '''quantum''' (plural: ''quanta'') is the minimum unit of any [[physical]] [[entity]] involved in an interaction. An example of an entity that is quantized is the [[energy]] transfer of [[elementary]] particles of [[matter]] (called [ | + | In [[physics]], a '''quantum''' (plural: ''quanta'') is the minimum unit of any [[physical]] [[entity]] involved in an interaction. An example of an entity that is quantized is the [[energy]] transfer of [[elementary]] particles of [[matter]] (called [https://en.wikipedia.org/wiki/Fermions fermions]) and of [https://en.wikipedia.org/wiki/Photons photons] and other [https://en.wikipedia.org/wiki/Bosons bosons]. The [[word]] comes from the [[Latin]] "quantus", for "how much." Behind this, one finds the fundamental notion that a physical property may be "quantized", referred to as "quantization". This means that the magnitude can take on only certain discrete numerical values, rather than any value, at least within a range. There is a related term of quantum number. |
A photon, for example, is a single quantum of [[light]], and may thus be referred to as a "light quantum". The [[energy]] of an [[electron]] bound to an [[atom]] (at rest) is said to be quantized, which results in the stability of atoms, and of [[matter]] in general. | A photon, for example, is a single quantum of [[light]], and may thus be referred to as a "light quantum". The [[energy]] of an [[electron]] bound to an [[atom]] (at rest) is said to be quantized, which results in the stability of atoms, and of [[matter]] in general. | ||
| − | As incorporated into the [[theory]] of [[quantum mechanics]], this is regarded by physicists as part of the fundamental framework for understanding and describing [[nature]] at the infinitesimal level, for the very [[practical]] [[reason]] that it works. It is "in the nature of things", not a more or less [[arbitrary]] [[human]] preference.[ | + | As incorporated into the [[theory]] of [[quantum mechanics]], this is regarded by physicists as part of the fundamental framework for understanding and describing [[nature]] at the infinitesimal level, for the very [[practical]] [[reason]] that it works. It is "in the nature of things", not a more or less [[arbitrary]] [[human]] preference.[https://en.wikipedia.org/wiki/Quanta] |
==History and Discovery== | ==History and Discovery== | ||
| − | The [[concept]] of quantization was [[discovered]] in 1900 by German physicist [ | + | The [[concept]] of quantization was [[discovered]] in 1900 by German physicist [https://en.wikipedia.org/wiki/Max_Planck Max Planck], who had been trying to [[understand]] the emission of [[radiation]] from [[heat]]ed objects, known as [https://en.wikipedia.org/wiki/Black_body_radiation black body radiation]. By [[assuming]] that [[energy]] can only be absorbed or released in tiny, differential, [[discrete]] packets he called "quanta," Planck accounted for the [[fact]] that certain objects [[change]] [[color]] when heated. On December 14, 1900, Planck reported his [[revolutionary]] findings about quanta to the German Physical Society and introduced the [[idea]] of quantization for the first time as a part of his [[research]] on black body radiation. As a result of his [[experiments]], Planck deduced the [[numerical]] [[value]] of h, known as the [https://en.wikipedia.org/wiki/Planck_constant Planck constant], and could also report a more precise [[value]] for the [https://en.wikipedia.org/wiki/Avogadro%27s_number Avogadro-Loschmidt number], the number of real [[molecules]] in a [https://en.wikipedia.org/wiki/Mole_(unit) mole], and the [[unit]] of [[electrical]] charge, to the German Physical Society. After his [[theory]] was [[validated]], Planck was awarded the [[Nobel Prize]] in Physics in 1918 for his [[discovery]]. |
==References== | ==References== | ||
| − | # [ | + | # [https://www.scienceagogo.com/news/20050110221715data_trunc_sys.shtml Real-World Quantum Effects Demonstrated] February 11, 2005 |
==Further Reading== | ==Further Reading== | ||
Latest revision as of 02:32, 13 December 2020
In physics, a quantum (plural: quanta) is the minimum unit of any physical entity involved in an interaction. An example of an entity that is quantized is the energy transfer of elementary particles of matter (called fermions) and of photons and other bosons. The word comes from the Latin "quantus", for "how much." Behind this, one finds the fundamental notion that a physical property may be "quantized", referred to as "quantization". This means that the magnitude can take on only certain discrete numerical values, rather than any value, at least within a range. There is a related term of quantum number.
A photon, for example, is a single quantum of light, and may thus be referred to as a "light quantum". The energy of an electron bound to an atom (at rest) is said to be quantized, which results in the stability of atoms, and of matter in general.
As incorporated into the theory of quantum mechanics, this is regarded by physicists as part of the fundamental framework for understanding and describing nature at the infinitesimal level, for the very practical reason that it works. It is "in the nature of things", not a more or less arbitrary human preference.[1]
History and Discovery
The concept of quantization was discovered in 1900 by German physicist Max Planck, who had been trying to understand the emission of radiation from heated objects, known as black body radiation. By assuming that energy can only be absorbed or released in tiny, differential, discrete packets he called "quanta," Planck accounted for the fact that certain objects change color when heated. On December 14, 1900, Planck reported his revolutionary findings about quanta to the German Physical Society and introduced the idea of quantization for the first time as a part of his research on black body radiation. As a result of his experiments, Planck deduced the numerical value of h, known as the Planck constant, and could also report a more precise value for the Avogadro-Loschmidt number, the number of real molecules in a mole, and the unit of electrical charge, to the German Physical Society. After his theory was validated, Planck was awarded the Nobel Prize in Physics in 1918 for his discovery.
References
- Real-World Quantum Effects Demonstrated February 11, 2005
Further Reading
- B. Hoffmann, The Strange Story of the Quantum, Pelican 1963.
- Lucretius, "On the Nature of the Universe", transl. from the Latin by R.E. Latham, Penguin Books Ltd., Harmondsworth 1951. There are, of course, many translations, and the translation's title varies. Some put emphasis on how things work, others on what things are found in nature.
- J. Mehra and H. Rechenberg, The Historical Development of Quantum Theory, Vol.1, Part 1, Springer-Verlag New York Inc., New York 1982.
- M. Planck, A Survey of Physical Theory, transl. by R. Jones and D.H. Williams, Methuen & Co., Ltd., London 1925 (Dover editions 1960 and 1993) including the Nobel lecture.
