"Constants and units in physics"의 두 판 사이의 차이

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==introduction==
 
* units form a Lauren ring !
 
* units form a Lauren ring !
 +
* 3 basic units
 +
** length
 +
** time
 +
** mass
 +
* Planck constant
 +
* speed of light
 +
* fine structure constant
 +
* units
 +
* natural units
 +
* rest energy of the proton is roughly 1 GeV
 +
* <math>10^9 eV = 1 GeV </math>
  
3 basic units
 
  
length
+
==important figures==
 +
* Stoney
 +
* Planck
 +
* Dirac, Large number hypothesis
  
time
 
  
mass
+
  
 
+
==constants of standard model==
  
 
+
masses of electron, muon, and tau leptons (3)
  
Planck constant
+
masses of six quarks: up, down, strange, charm, top, bottom (6)
  
speed of light
+
mixing matrix of the down-type quarks, which is parameterized by four independent angles. To find out more, look up "CKM Matrix" or "Cabibbo-Kobayashi-Maskawa Mixing Matrix" (4)
  
fine structure constant
+
The strong coupling constant alpha_s (1)
  
 
+
The fine structure constant alpha_em (1)
  
 
+
The Fermi constant G_F (governs weak decay rates) (1)
  
units
+
The Z boson mass M_Z (1)
  
 
+
The Higgs boson mass (1) (the W mass can be calculated from the other parameters and the theory)
  
natural units
+
Gravity has a strength parameterized by G_N, Newton’s gravitational constant (1).
  
rest energy of the proton is roughly 1 GeV
+
That’s 19. Two constants, the speed of light and Planck’s constant, define our units of length and time and energy.
  
<math>10^9 eV = 1 GeV </math>
+
The neutrino masses are another 3, and they have a mixing matrix just like the down-type quarks for another four parameters, for a total of 28.
  
 
+
These are the constants of the Standard Model, which is incomplete.
  
==constants of standard model==
+
  
masses of electron, muon, and tau leptons (3) 
+
  
masses of six quarks: up, down, strange, charm, top, bottom (6) 
+
The Standard Model fails to explain dark matter and dark energy. Dark energy may be parameterizable with just one more constant (Einstein’s famous "cosmological constant") or there may be a much richer set of things to understand about it.
  
mixing matrix of the down-type quarks, which is parameterized by four independent angles. To find out more, look up "CKM Matrix" or "Cabibbo-Kobayashi-Maskawa Mixing Matrix" (4) 
+
Dark matter is also a mystery. My favorite candidate for what it is is supersymmetric partners of ordinary matter. But then all the supersymmetric partners have masses and mixings and lots of numbers to describe them, introducing (at one count I can dig up in the Particle Data Group’s review) of 105 new parameters on top of those of the Standard Model.
  
The strong coupling constant alpha_s (1) 
+
[http://van.physics.illinois.edu/qa/listing.php?id=1249 20 constants of the universe?]
  
The fine structure constant alpha_em (1) 
+
[http://van.physics.illinois.edu/qa/listing.php?id=1249 ]
 
 
The Fermi constant G_F (governs weak decay rates) (1) 
 
  
The Z boson mass M_Z (1) 
 
  
The Higgs boson mass (1) (the W mass can be calculated from the other parameters and the theory) 
+
==books==
 +
* Johnson, Peter. The Constants of Nature: A Realist Account. Aldershot, Hants., England : Brookfield, Vt: Ashgate Publishing Limited, 1997.
  
Gravity has a strength parameterized by G_N, Newton’s gravitational constant (1). 
 
  
That’s 19. Two constants, the speed of light and Planck’s constant, define our units of length and time and energy. 
+
==related items==
 +
* [[Fine structure constant]]
 +
  
The neutrino masses are another 3, and they have a mixing matrix just like the down-type quarks for another four parameters, for a total of 28. 
 
  
These are the constants of the Standard Model, which is incomplete.
+
==expositions==
 +
* http://arxiv.org/abs/1512.07306
 +
* Solà, Joan. ‘Fundamental Constants in Physics and Their Time Variation’. Modern Physics Letters A 30, no. 22 (20 July 2015): 1502004. doi:10.1142/S0217732315020046.
 +
* Duff, M. J. “How Fundamental Are Fundamental Constants?” arXiv:1412.2040 [hep-Th, Physics:physics], December 5, 2014. http://arxiv.org/abs/1412.2040.
 +
* Chiba, Takeshi. “The Constancy of the Constants of Nature: Updates.” Progress of Theoretical Physics 126, no. 6 (December 1, 2011): 993–1019. doi:10.1143/PTP.126.993.
 +
* Cowen, Ron. “Changing One of Nature’s Constants.” U.S. News & World Report, September 2010. http://search.proquest.com.ezproxy.library.uq.edu.au/docview/807402325?pq-origsite=summon.
 +
* Okun, L. B. “Fundamental Constants of Nature.” arXiv:hep-ph/9612249, December 4, 1996. http://arxiv.org/abs/hep-ph/9612249.
 +
* Fritzsch, H. “The Constants of Nature.” Metrologia 22, no. 3 (January 1, 1986): 134. doi:10.1088/0026-1394/22/3/003.
  
 
+
  
 
+
[[particle physics and the Standard model]]
 
+
[[분류:개인노트]]
The Standard Model fails to explain dark matter and dark energy. Dark energy may be parameterizable with just one more constant (Einstein’s famous "cosmological constant") or there may be a much richer set of things to understand about it. 
+
[[분류:physics]]
 
+
[[분류:math and physics]]
Dark matter is also a mystery. My favorite candidate for what it is is supersymmetric partners of ordinary matter. But then all the supersymmetric partners have masses and mixings and lots of numbers to describe them, introducing (at one count I can dig up in the Particle Data Group’s review) of 105 new parameters on top of those of the Standard Model. 
 
 
 
[http://van.physics.illinois.edu/qa/listing.php?id=1249 20 constants of the universe?]
 
 
 
[http://van.physics.illinois.edu/qa/listing.php?id=1249 ]
 
 
 
 
 
  
 
+
== articles ==
  
[[particle physics and the Standard model]]
+
* Hao Wei, Xiao-Bo Zou, Hong-Yu Li, Dong-Ze Xue, Cosmological Constant, Fine Structure Constant and Beyond, arXiv:1605.04571 [gr-qc], May 15 2016, http://arxiv.org/abs/1605.04571
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[[분류:migrate]]

2020년 12월 28일 (월) 04:03 기준 최신판

introduction

  • units form a Lauren ring !
  • 3 basic units
    • length
    • time
    • mass
  • Planck constant
  • speed of light
  • fine structure constant
  • units
  • natural units
  • rest energy of the proton is roughly 1 GeV
  • \(10^9 eV = 1 GeV \)


important figures

  • Stoney
  • Planck
  • Dirac, Large number hypothesis



constants of standard model

masses of electron, muon, and tau leptons (3)

masses of six quarks: up, down, strange, charm, top, bottom (6)

mixing matrix of the down-type quarks, which is parameterized by four independent angles. To find out more, look up "CKM Matrix" or "Cabibbo-Kobayashi-Maskawa Mixing Matrix" (4)

The strong coupling constant alpha_s (1)

The fine structure constant alpha_em (1)

The Fermi constant G_F (governs weak decay rates) (1)

The Z boson mass M_Z (1)

The Higgs boson mass (1) (the W mass can be calculated from the other parameters and the theory)

Gravity has a strength parameterized by G_N, Newton’s gravitational constant (1).

That’s 19. Two constants, the speed of light and Planck’s constant, define our units of length and time and energy.

The neutrino masses are another 3, and they have a mixing matrix just like the down-type quarks for another four parameters, for a total of 28.

These are the constants of the Standard Model, which is incomplete.



The Standard Model fails to explain dark matter and dark energy. Dark energy may be parameterizable with just one more constant (Einstein’s famous "cosmological constant") or there may be a much richer set of things to understand about it.

Dark matter is also a mystery. My favorite candidate for what it is is supersymmetric partners of ordinary matter. But then all the supersymmetric partners have masses and mixings and lots of numbers to describe them, introducing (at one count I can dig up in the Particle Data Group’s review) of 105 new parameters on top of those of the Standard Model.

20 constants of the universe?

[1]


books

  • Johnson, Peter. The Constants of Nature: A Realist Account. Aldershot, Hants., England : Brookfield, Vt: Ashgate Publishing Limited, 1997.


related items


expositions

  • http://arxiv.org/abs/1512.07306
  • Solà, Joan. ‘Fundamental Constants in Physics and Their Time Variation’. Modern Physics Letters A 30, no. 22 (20 July 2015): 1502004. doi:10.1142/S0217732315020046.
  • Duff, M. J. “How Fundamental Are Fundamental Constants?” arXiv:1412.2040 [hep-Th, Physics:physics], December 5, 2014. http://arxiv.org/abs/1412.2040.
  • Chiba, Takeshi. “The Constancy of the Constants of Nature: Updates.” Progress of Theoretical Physics 126, no. 6 (December 1, 2011): 993–1019. doi:10.1143/PTP.126.993.
  • Cowen, Ron. “Changing One of Nature’s Constants.” U.S. News & World Report, September 2010. http://search.proquest.com.ezproxy.library.uq.edu.au/docview/807402325?pq-origsite=summon.
  • Okun, L. B. “Fundamental Constants of Nature.” arXiv:hep-ph/9612249, December 4, 1996. http://arxiv.org/abs/hep-ph/9612249.
  • Fritzsch, H. “The Constants of Nature.” Metrologia 22, no. 3 (January 1, 1986): 134. doi:10.1088/0026-1394/22/3/003.


particle physics and the Standard model

articles

  • Hao Wei, Xiao-Bo Zou, Hong-Yu Li, Dong-Ze Xue, Cosmological Constant, Fine Structure Constant and Beyond, arXiv:1605.04571 [gr-qc], May 15 2016, http://arxiv.org/abs/1605.04571