Wave-particle duality: Difference between revisions

From Citizendium
Jump to navigation Jump to search
imported>J. Noel Chiappa
m (rm dup editintro - the subpages template automatically incudes ones)
mNo edit summary
 
(9 intermediate revisions by 5 users not shown)
Line 3: Line 3:
The '''wave-particle duality''' (or '''particle-wave duality''') refers to the double nature of light and matter at the [[quantum mechanics|quantum]] level.
The '''wave-particle duality''' (or '''particle-wave duality''') refers to the double nature of light and matter at the [[quantum mechanics|quantum]] level.


{{TOC-right}}
{{TOC|right}}


The debate arguably began in the 17th century with the competing theories of Christiaan Huygens and [[Isaac Newton]]. Huygen's observations led him to a wave theory of light while Newton's supported a corpuscular or particle theory. Newton's preeminence as the leading mind in related matters led to the domination of his theory.
The debate arguably began in the 17th century with the competing theories of [[Christiaan Huygens]] and [[Isaac Newton]]. Huygen's observations led him to a wave theory of light while Newton's observations supported a corpuscular or particle theory. Newton's preeminence as the leading mind in related matters led to the dominance of his theory.


Eventually, subsequent research in the 19th and 20th century proved them both correct—light was found to behave as both particle and wave, a characteristic shared by solid matter (electrons, atoms and molecules).  
Eventually, subsequent research in the 19th and 20th centuries provided compelling support for both theories—light was found to behave as both a particle and a wave, a characteristic shared by the constituents of solid matter (electrons, atoms and molecules).  


Wave theory was strongly supported and continued in optics for more than 100 years. However, in chemistry the atomic structure of light provided insight into laws of definite proportions. In physics, the atomic theories led to the development of interpretation of numerous properties of solids, liquids and gases including the kinetic theory of gases and the atomic constitution of electricity (e.g. the work of J. J. Thomson in 1899) and H. A. Lorentz’s use of atomic structure in the theory of electrons.
Wave theory was strongly supported and continued in optics for more than 100 years. However, in chemistry the atomic structure of matter provided insight into molecular laws of definite proportions. In physics, the atomic theories led to the development of interpretation of numerous properties of solids, liquids and gases including the kinetic theory of gases and the atomic constitution of electricity (e.g. the work of [[J. J. Thomson]] in 1899) and [[H. A. Lorentz]]’s use of electrons in the theory of interaction of matter with [[electromagnetic radiation]].


Thomas Young's [[Double-slit experiment|double-slit experiment]] in 1803<ref>reported in his publication ''Experiments and Calculations Relative to Physical Optics''</ref> strongly indicated that light has wave characteristics. Then in 1924, Louis-Victor de Broglie (1892-1987) presented a hypothesis positing the wave characteristics of light, and suggested that a wavelength relationship applies to other particles with non-zero rest mass as well.<ref>In his doctoral thesis submitted in 1924 to the Faculty of Sciences at Paris University entitled ''Recherches sur la Théorie des Quanta'' (Researches on the quantum theory)</ref> DeBroglie's hypothesis, strongly supported by Davisson and Germer's research in 1927<ref>Clinton J. Davisson & Lester H. Germer (1927) "Reflection of electrons by a crystal of nickel", Nature, V119, pp. 558-560 </ref> firmly established the wave-mechanics theory underlying current understanding of the wave nature of light. In 1926, Erwin Schrödinger's (1887-1961) wave equation described the behaviour of electrons and other particles employing wave concepts.
Thomas Young's [[Double-slit experiment|double-slit experiment]] in 1803<ref>reported in his publication ''Experiments and Calculations Relative to Physical Optics''</ref> strongly indicated that light has wave characteristics. Then in 1924, [[Prince Louis-Victor de Broglie]] (1892-1987) presented a hypothesis positing the wave characteristics of particles with small rest mass, such as [[electron]]s, and suggested that a wavelength relationship applies to other particles with non-zero rest mass as well.<ref>In his doctoral thesis submitted in 1924 to the Faculty of Sciences at Paris University entitled ''Recherches sur la Théorie des Quanta'' (Researches on the quantum theory)</ref> DeBroglie's hypothesis, unequivocally supported by [[Davisson-Germer experiment|Davisson and Germer's research in 1927]] on the [[diffraction]] of electron beams by nickel crystals,<ref>Clinton J. Davisson & Lester H. Germer (1927) "Reflection of electrons by a crystal of nickel", Nature, V119, pp. 558-560 </ref><ref>[http://panda.unm.edu/Courses/Fields/Phys491/Notes/DavissonGermer.pdf Davisson-Germer Experiment] Dept. of Physics and Astronomy, University of New Mexico. Retrieved April, 20th, 2008</ref> firmly established the wave-mechanics theory underlying current understanding of the wave nature of matter. In 1926, [[Erwin Schrödinger]]'s (1887-1961) [[Schrödinger equation|wave equation]] described the behaviour of electrons and other particles employing wave concepts.


Work on the theoretical basis of the particle nature of radiation received support when the granular structure of light and other types of radiation was confirmed by the discovery of the '''photoelectric effect''':<ref>[http://galileo.phys.virginia.edu/classes/252/photoelectric_effect.html The Photoelectric Effect] Michael Fowler (1997) University of Virginia. The phenomenon was first observed by J. J. Thomson in 1899 and further demonstrated by Philipp von Lenard in 1902, leading to Einstein's theory in 1905</ref> X-rays or light striking solid matter results in the emission of electrons from that matter, showing a direct relationship between the energy of the electrons and the frequency of the incident radiation (the radiation that strikes the solid matter).<ref> The relationship is independent of the intensity of the incident radiation</ref> The subsequent explanation of this phenomenon led to Albert Einstein's theory of light quanta proposed in 1905. In 1922, Arthur Compton observed and reported what is now called the [[Compton effect]], establishing the particle nature of light - photons.   
Work on the theoretical basis of the particle nature of radiation received support when the granular structure of light and other types of radiation was confirmed by the discovery of the '''photoelectric effect''':<ref>[http://galileo.phys.virginia.edu/classes/252/photoelectric_effect.html The Photoelectric Effect] Michael Fowler (1997) University of Virginia. The phenomenon was first observed by J. J. Thomson in 1899 and further demonstrated by Philipp Lenard in 1902, leading to [[Albert Einstein|Einstein]]'s theory in 1905</ref> X-rays or light striking solid matter results in the emission of electrons from that matter, showing a direct relationship between the energy of the electrons and the frequency of the incident radiation (the radiation that strikes the solid matter).<ref> The relationship is independent of the intensity of the incident radiation</ref> The subsequent explanation of this phenomenon led to Albert Einstein's theory of light quanta proposed in 1905. In 1922, Arthur Compton observed and reported what is now called the [[Compton effect]], establishing the particle nature of light - photons.<ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1929/broglie-lecture.pdf The wave nature of the electron] Louise de Broglie (1929) Nobel Lecture</ref><ref>[http://hyperphysics.phy-astr.gsu.edu/hbase/mod1.html Wave-Particle Duality] [http://hyperphysics.phy-astr.gsu.edu/Hbase/quantum/davger2.html Davisson-Germer Experiment] Rod Nave, Department of Physics and Astronomy, Georgia State University</ref><ref>[http://theory.uwinnipeg.ca/mod_tech/node154.html Wave-particle duality] University of Winnipeg</ref><ref>[http://zopyros.ccqc.uga.edu/lec_top/chem1211/lecture6/page1.html Wave Mechanics] Steven S. Wesolowski (1999). Center for Computational Chemistry, University of Georgia, USA</ref><ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1937/davisson-lecture.pdf The discovery of electron waves] Clinton Davisson Nobel lecture, Dec. 13, 1937</ref><ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1929/broglie-bio.html Louis de Broglie The Nobel Prize in Physics 1929] Nobel Prize Organization</ref><ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1905/lenard-bio.html Philipp  Lenard Biography] Nobel Foundation</ref> In 1927 [[Dirac]] [[Electromagnetic_wave#Quantization_of_the_electromagnetic_field|quantized the electromagnetic field]], thus putting photons (light quanta) on a firm theoretical foundation.


<ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1929/broglie-lecture.pdf The wave nature of the electron] Louise de Broglie (1929) Nobel Lecture</ref><ref>[http://hyperphysics.phy-astr.gsu.edu/hbase/mod1.html Wave-Particle Duality] [http://hyperphysics.phy-astr.gsu.edu/Hbase/quantum/davger2.html Davisson-Germer Experiment] Rod Nave, Department of Physics and Astronomy, Georgia State University</ref><ref>[http://theory.uwinnipeg.ca/mod_tech/node154.html Wave-particle duality] University of Winnipeg</ref><ref>[http://zopyros.ccqc.uga.edu/lec_top/chem1211/lecture6/page1.html Wave Mechanics] Steven S. Wesolowski (1999). Center for Computational Chemistry,  University of Georgia, USA</ref><ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1937/davisson-lecture.pdf The discovery of electron waves] Clinton Davisson Nobel lecture, Dec. 13, 1937</ref><ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1929/broglie-bio.html Louis de Broglie The Nobel Prize in Physics 1929] Nobel Prize Organization</ref><ref>[http://nobelprize.org/nobel_prizes/physics/laureates/1905/lenard-bio.html Philipp von Lenard Biography] Nobel Foundation</ref>
==Example==
Wavelengths of various particles with non-zero rest mass according to <font style = "vertical-align: 15%"> <math>\lambda = \frac{h}{mv}</math></font>, where &lambda; is the wavelength, ''h'' is [[Planck's constant]], ''m'' the rest mass, and ''v'' the speed of the particle.
 
<div align = "center">
<table width = "70%">
<tr><td>  '''Particle'''      <td> '''Mass''' (g)                   <td> '''Speed''' (m/s)      <td> '''Wavelength''' (pm = 10<sup>&minus;12</sup> m)  </tr>
<tr><td> 1  eV electron        <td> 9.1&times; 10<sup>&minus;28</sup> <td> 5.9&times; 10<sup>5</sup><td>1200 </tr>
<tr><td> 100 eV electron        <td> 9.1&times; 10<sup>&minus;28</sup> <td> 5.9&times; 10<sup>6</sup><td>120  </tr>
<tr><td> 10,000 eV electron    <td> 9.1&times; 10<sup>&minus;28</sup> <td> 5.9&times; 10<sup>7</sup><td>12 </tr>
<tr><td> 100 eV proton          <td>1.67&times; 10<sup>&minus;24</sup> <td>1.38&times; 10<sup>5</sup><td>2.9</tr>
<tr><td> 100 eV α-particle      <td> 6.6&times; 10<sup>&minus;24</sup> <td> 6.9&times; 10<sup>4</sup><td>1.5</tr>
<tr><td> H<sub>2</sub> at 200 °C <td> 3.3&times; 10<sup>&minus;24</sup> <td> 2.4&times; 10<sup>3</sup><td>82 </tr>
<tr><td> 22-rifle bullet        <td> 1.9                              <td> 320                      <td>1.1&times;10<sup>&minus;21</sup></tr>
<tr><td> Golf ball              <td> 45                                <td> 30                      <td>4.9&times;10<sup>&minus;22</sup></tr>
<tr><td> Baseball              <td> 140                              <td> 25                      <td>1.9&times;10<sup>&minus;22</sup></tr>
</table> </div>
 
 
From: ''W. J. Moore, Physical Chemistry, Longmans, London, 2nd edition (1956), p. 271''


==References==
==References==
Line 21: Line 39:
<references />
<references />
</div>
</div>
[[Category:Suggestion Bot Tag]]

Latest revision as of 07:00, 7 November 2024

This article is developing and not approved.
Main Article
Discussion
Related Articles  [?]
Bibliography  [?]
External Links  [?]
Citable Version  [?]
 
This editable Main Article is under development and subject to a disclaimer.

The wave-particle duality (or particle-wave duality) refers to the double nature of light and matter at the quantum level.

The debate arguably began in the 17th century with the competing theories of Christiaan Huygens and Isaac Newton. Huygen's observations led him to a wave theory of light while Newton's observations supported a corpuscular or particle theory. Newton's preeminence as the leading mind in related matters led to the dominance of his theory.

Eventually, subsequent research in the 19th and 20th centuries provided compelling support for both theories—light was found to behave as both a particle and a wave, a characteristic shared by the constituents of solid matter (electrons, atoms and molecules).

Wave theory was strongly supported and continued in optics for more than 100 years. However, in chemistry the atomic structure of matter provided insight into molecular laws of definite proportions. In physics, the atomic theories led to the development of interpretation of numerous properties of solids, liquids and gases including the kinetic theory of gases and the atomic constitution of electricity (e.g. the work of J. J. Thomson in 1899) and H. A. Lorentz’s use of electrons in the theory of interaction of matter with electromagnetic radiation.

Thomas Young's double-slit experiment in 1803[1] strongly indicated that light has wave characteristics. Then in 1924, Prince Louis-Victor de Broglie (1892-1987) presented a hypothesis positing the wave characteristics of particles with small rest mass, such as electrons, and suggested that a wavelength relationship applies to other particles with non-zero rest mass as well.[2] DeBroglie's hypothesis, unequivocally supported by Davisson and Germer's research in 1927 on the diffraction of electron beams by nickel crystals,[3][4] firmly established the wave-mechanics theory underlying current understanding of the wave nature of matter. In 1926, Erwin Schrödinger's (1887-1961) wave equation described the behaviour of electrons and other particles employing wave concepts.

Work on the theoretical basis of the particle nature of radiation received support when the granular structure of light and other types of radiation was confirmed by the discovery of the photoelectric effect:[5] X-rays or light striking solid matter results in the emission of electrons from that matter, showing a direct relationship between the energy of the electrons and the frequency of the incident radiation (the radiation that strikes the solid matter).[6] The subsequent explanation of this phenomenon led to Albert Einstein's theory of light quanta proposed in 1905. In 1922, Arthur Compton observed and reported what is now called the Compton effect, establishing the particle nature of light - photons.[7][8][9][10][11][12][13] In 1927 Dirac quantized the electromagnetic field, thus putting photons (light quanta) on a firm theoretical foundation.

Example

Wavelengths of various particles with non-zero rest mass according to , where λ is the wavelength, h is Planck's constant, m the rest mass, and v the speed of the particle.

Particle Mass (g) Speed (m/s) Wavelength (pm = 10−12 m)
1 eV electron 9.1× 10−28 5.9× 1051200
100 eV electron 9.1× 10−28 5.9× 106120
10,000 eV electron 9.1× 10−28 5.9× 10712
100 eV proton 1.67× 10−24 1.38× 1052.9
100 eV α-particle 6.6× 10−24 6.9× 1041.5
H2 at 200 °C 3.3× 10−24 2.4× 10382
22-rifle bullet 1.9 320 1.1×10−21
Golf ball 45 30 4.9×10−22
Baseball 140 25 1.9×10−22


From: W. J. Moore, Physical Chemistry, Longmans, London, 2nd edition (1956), p. 271

References

  1. reported in his publication Experiments and Calculations Relative to Physical Optics
  2. In his doctoral thesis submitted in 1924 to the Faculty of Sciences at Paris University entitled Recherches sur la Théorie des Quanta (Researches on the quantum theory)
  3. Clinton J. Davisson & Lester H. Germer (1927) "Reflection of electrons by a crystal of nickel", Nature, V119, pp. 558-560
  4. Davisson-Germer Experiment Dept. of Physics and Astronomy, University of New Mexico. Retrieved April, 20th, 2008
  5. The Photoelectric Effect Michael Fowler (1997) University of Virginia. The phenomenon was first observed by J. J. Thomson in 1899 and further demonstrated by Philipp Lenard in 1902, leading to Einstein's theory in 1905
  6. The relationship is independent of the intensity of the incident radiation
  7. The wave nature of the electron Louise de Broglie (1929) Nobel Lecture
  8. Wave-Particle Duality Davisson-Germer Experiment Rod Nave, Department of Physics and Astronomy, Georgia State University
  9. Wave-particle duality University of Winnipeg
  10. Wave Mechanics Steven S. Wesolowski (1999). Center for Computational Chemistry, University of Georgia, USA
  11. The discovery of electron waves Clinton Davisson Nobel lecture, Dec. 13, 1937
  12. Louis de Broglie The Nobel Prize in Physics 1929 Nobel Prize Organization
  13. Philipp Lenard Biography Nobel Foundation