Spontano narušavanje simetrije — разлика између измена

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Spontano narušavanje simetrije je spontan proces narušavanja simetrije, po kome fizički sistem u simetričnom stanju završava u asimetričnom stanju.^[1]^[2]^[3] Posebno, to može da opisuje sisteme gde jednačine kretanja^[4]^[5] ili Lagranžijani poštuju simetrije,^[6]^[7]^[8] ali vakuumska rešenja^[9] sa najmanjom energijom ne pokazuju istu simetriju. Kada sistem pređe na jedno od ovih vakuumskih rešenja, simetrija se narušava zbog perturbacija oko tog vakuuma, iako celokupan Lagranžijan zadržava tu simetriju.

Pregled

U eksplicitnom kršenju simetrije,^[10]^[11] ako se uzmu u obzir dva ishoda, verovatnoća para ishoda može biti različita. Po definiciji, spontano narušavanje simetrije zahteva postojanje simetrične raspodele verovatnoće - bilo koji par ishoda ima istu verovatnoću. Drugim rečima, osnovni zakoni su invarijantni u okviru transformacije simetrije.

Sistem u celini se menja pod takvim transformacijama.

Faze materije, poput kristala, magneta i konvencionalnih superprovodnika, kao i jednostavni fazni prelazi mogu se opisati spontanim razbijanjem simetrije. Uočljivi izuzeci uključuju topološke faze materije poput frakcijskog kvantnog Holovog efekta.^[12]^[13]

Primeri

Potencijal meksičkog šešira

Razmotrite simetričnu kupolu sa koritom koje je okružuje pri dnu. Ako se kugla postavi na sam vrh kupole, sistem je simetričan u odnosu na rotaciju oko središnje ose. Međutim kugla može da spontano naruši ovu simetriju ako se otkotrlja niz kupolu u korito, tačku najniže energije. Nakon toga, kugla se zaustavlja u nekoj fiksnoj tački na obodu. Kupola i kugla zadržavaju svoju individualnu simetriju, ali sistem to ne čini.^[14]

U najjednostavnijem idealizovanom relativističkom modelu, spontano narušena simetrija se sumira pomoću ilustrativne teorije skalarnog polja. Relevantan Lagranžijan skalarnog polja $\phi$ , koji u suštini diktira kako se sistem ponaša, može se podeliti na kinetičke i potencijalne članove,

${\mathcal {L}}=\partial ^{\mu }\phi \partial _{\mu }\phi -V(\phi ).$

(1)

Upravo u ovom potencijalnom članu $V(\phi )$ dolazi do prekida simetrije. Jedan primer potencijala, koji je dao Džefri Goldston^[15] prikazan je na grafukonu.

$V(\phi )=-10|\phi |^{2}+|\phi |^{4}\,$ .

(2)

Ovaj potencijal ima neograničen broj mogućih minimuma (stanja u vakuumu) datih izrazom:

$\phi ={\sqrt {5}}e^{i\theta }$ .

(3)

za svako realno θ između 0 i 2π. Sistem takođe ima nestabilno vakuumsko stanje, što odgovara Φ = 0. Ovo stanje ima U(1) simetriju. Međutim, kad sistem jednom padne u specifično stabilno vakuumsko stanje (zavisno od izbora θ), dolazi do nestanka ove simetrija ili „spontanog narušavanja”.

Zapravo, svaki drugi izbor θ bi imao potpuno istu energiju, što implicira postojanje bezmasenog Nambu-Goldstonovog bozona, moda kretanja u krug na minimumu ovog potencijala, i ukazuje da postoji vid memorije na izvornu simetriju Lagranžijana.

Nobelova nagrada

Dana 7. oktobra 2008, Švedska kraljevska akademija nauka dodelila je Nobelovu nagradu za fiziku 2008. godine trojici naučnika za njihov rad na narušavanju simetrije u subatomskoj fizici. Joičiro Nambu, sa Univerziteta u Čikagu, dobio je polovinu nagrade za otkriće mehanizma spontanog narušavanja simetrije u kontekstu jakih interakcija, specifično hiralnog narušavanja simetrije. Fizičari Makoto Kobajaši i Tošihide Masukava, sa Kjoto univerziteta, podelili su drugu polovinu nagrade za otkriće porekla eksplicitnog narušavanja CP simetrije usled slabih interakcija.^[16] Ovo poreklo ultimatno počiva na Higsovom mehanizmu, ali, do tada je bilo shvaćeno kao „upravo tako” svojstvo Higsovih spega, a ne kao spontano narušen fenomen simetrije.

Reference

^ Miransky, Vladimir A. Dynamical Symmetry Breaking in Quantum Field Theories. стр. 15. ISBN 9810215584.
^ Arodz, Henryk; Dziarmaga, Jacek; Zurek, Wojciech Hubert (ур.). Patterns of Symmetry Breaking. стр. 141.
^ Cornell, James (ур.). Bubbles, Voids and Bumps in Time: The New Cosmology. стр. 125.
^ R.G. Lerner; George L. Trigg (1991). Encyclopedia of Physics (second изд.). New York: VCH Publishers. ISBN 0-89573-752-3. OCLC 20853637.
^ Hand, Louis N.; Janet D. Finch (1998). Analytical Mechanics. Cambridge: Cambridge University Press. ISBN 978-0-521-57572-0. OCLC 37903527.
^ Ralph Abraham and Jerrold E. Marsden, (1967) "Foundations of Mechanics"
^ David Bleecker, (1981) "Gauge Theory and Variational Principles" Addison-Wesley
^ Jurgen Jost, (1995) "Riemannian Geometry and Geometric Analysis", Springer
^ H. Stephani, et al., "Exact solutions of Einstein's field equations" (2003) Cambridge University Press
^ Castellani, E. (2003) "On the meaning of Symmetry Breaking" in Brading, K. and Castellani, E. (eds) Symmetries in Physics: New Reflections, Cambridge: Cambridge University Press
^ Sinha & Amaratunga (2016) "Explicit Symmetry Breaking in Electrodynamic Systems and Electromagnetic Radiation" Morgan Claypool, Institute of Physics, UK
^ „The Nobel Prize in Physics 1998”. www.nobelprize.org. Приступљено 28. 3. 2018.
^ Schwarzschild, Bertram (1998). „Physics Nobel Prize Goes to Tsui, Stormer and Laughlin for the Fractional Quantum Hall Effect”. Physics Today. 51 (12): 17—19. Bibcode:1998PhT....51l..17S. doi:10.1063/1.882480. Архивирано из оригинала 15. 4. 2013. г. Приступљено 20. 4. 2012.
^ Edelman, Gerald M. (1992). Bright Air, Brilliant Fire: On the Matter of the Mind. New York: BasicBooks. стр. 203.
^ Goldstone, J. (1961). „Field theories with " Superconductor " solutions”. Il Nuovo Cimento. 19 (1): 154—164. Bibcode:1961NCim...19..154G. doi:10.1007/BF02812722.
^ The Nobel Foundation. „The Nobel Prize in Physics 2008”. nobelprize.org. Приступљено 15. 1. 2008.

Literatura

Lederman, L.; Hill, C.T. (2011). Symmetry and the Beautiful Universe. Prometheus Books. ISBN 9781615920419.
Schumm, B. (2004). Deep Down Things: The Breathtaking Beauty of Particle Physics. Johns Hopkins University Press. ISBN 978-0-8018-7971-5.
Stenger, V.J. (2000). Timeless Reality: Symmetry, Simplicity, and Multiple Universes. Prometheus Books. ISBN 9781573928595. Chapter 12 is a gentle introduction to symmetry, invariance, and conservation laws.
Zee, A. (2007). Fearful Symmetry: The search for beauty in modern physics (2nd изд.). Princeton University Press. ISBN 978-0-691-00946-9.
Brading, K.; Castellani, E. (2003). Symmetries in Physics: Philosophical Reflections. Cambridge University Press. ISBN 978-1-139-44202-2.
Brading, K.; Castellani, E. (2007). „Symmetries and Invariances in Classical Physics”. Ур.: Butterfield, J.; Earman, J. Philosophy of Physic Part B. North Holland. стр. 1331—68. ISBN 978-0-08-046665-1.
Debs, T.; Redhead, M. (2007). Objectivity, Invariance, and Convention: Symmetry in Physical Science. Harvard University Press. ISBN 978-0-674-03413-6.
Earman, J. (2002), Laws, Symmetry, and Symmetry Breaking: Invariance, Conservations Principles, and Objectivity. (PDF) Address to the 2002 meeting of the Philosophy of Science Association.
Kalmbach H.E., G. (2014). Quantum Mathematics: WIGRIS. RGN Publications.
Mainzer, K. (1996). Symmetries of Nature: A Handbook for Philosophy of Nature and Science. de Gruyter. ISBN 978-3-11-088693-1.
Mouchet, A. (2013). „Reflections on the four facets of symmetry: how physics exemplifies rational thinking”. European Physical Journal H. 38 (5): 661—702. Bibcode:2013EPJH...38..661M. CiteSeerX 10.1.1.400.2867 . S2CID 14475702. arXiv:1111.0658 . doi:10.1140/epjh/e2013-40018-4.
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Spoljašnje veze

For a pedagogic introduction to electroweak symmetry breaking with step by step derivations, not found in texts, of many key relations, see http://www.quantumfieldtheory.info/Electroweak_Sym_breaking.pdf
Spontaneous symmetry breaking
Physical Review Letters – 50th Anniversary Milestone Papers
In CERN Courier, Steven Weinberg reflects on spontaneous symmetry breaking
Englert–Brout–Higgs–Guralnik–Hagen–Kibble Mechanism on Scholarpedia
History of Englert–Brout–Higgs–Guralnik–Hagen–Kibble Mechanism on Scholarpedia
The History of the Guralnik, Hagen and Kibble development of the Theory of Spontaneous Symmetry Breaking and Gauge Particles
International Journal of Modern Physics A: The History of the Guralnik, Hagen and Kibble development of the Theory of Spontaneous Symmetry Breaking and Gauge Particles
Guralnik, G S; Hagen, C R and Kibble, T W B (1967). Broken Symmetries and the Goldstone Theorem. Advances in Physics, vol. 2 Interscience Publishers, New York. pp. 567–708 Архивирано на сајту Wayback Machine (23. април 2012) ISBN 0-470-17057-3
Spontaneous Symmetry Breaking in Gauge Theories: a Historical Survey

[1] Miransky, Vladimir A. Dynamical Symmetry Breaking in Quantum Field Theories. стр. 15. ISBN 9810215584.

[2] Arodz, Henryk; Dziarmaga, Jacek; Zurek, Wojciech Hubert (ур.). Patterns of Symmetry Breaking. стр. 141.

[3] Cornell, James (ур.). Bubbles, Voids and Bumps in Time: The New Cosmology. стр. 125.

[Physics_1991-4] R.G. Lerner; George L. Trigg (1991). Encyclopedia of Physics (second изд.). New York: VCH Publishers. ISBN 0-89573-752-3. OCLC 20853637.

[Analytical_Mechanics_2008-5] Hand, Louis N.; Janet D. Finch (1998). Analytical Mechanics. Cambridge: Cambridge University Press. ISBN 978-0-521-57572-0. OCLC 37903527.

[6] Ralph Abraham and Jerrold E. Marsden, (1967) "Foundations of Mechanics"

[Bleecker-7] David Bleecker, (1981) "Gauge Theory and Variational Principles" Addison-Wesley

[jost-8] Jurgen Jost, (1995) "Riemannian Geometry and Geometric Analysis", Springer

[9] H. Stephani, et al., "Exact solutions of Einstein's field equations" (2003) Cambridge University Press

[10] Castellani, E. (2003) "On the meaning of Symmetry Breaking" in Brading, K. and Castellani, E. (eds) Symmetries in Physics: New Reflections, Cambridge: Cambridge University Press

[11] Sinha & Amaratunga (2016) "Explicit Symmetry Breaking in Electrodynamic Systems and Electromagnetic Radiation" Morgan Claypool, Institute of Physics, UK

[12] „The Nobel Prize in Physics 1998”. www.nobelprize.org. Приступљено 28. 3. 2018.

[ptoday1998-13] Schwarzschild, Bertram (1998). „Physics Nobel Prize Goes to Tsui, Stormer and Laughlin for the Fractional Quantum Hall Effect”. Physics Today. 51 (12): 17—19. Bibcode:1998PhT....51l..17S. doi:10.1063/1.882480. Архивирано из оригинала 15. 4. 2013. г. Приступљено 20. 4. 2012.

[14] Edelman, Gerald M. (1992). Bright Air, Brilliant Fire: On the Matter of the Mind. New York: BasicBooks. стр. 203.

[15] Goldstone, J. (1961). „Field theories with " Superconductor " solutions”. Il Nuovo Cimento. 19 (1): 154—164. Bibcode:1961NCim...19..154G. doi:10.1007/BF02812722.

[16] The Nobel Foundation. „The Nobel Prize in Physics 2008”. nobelprize.org. Приступљено 15. 1. 2008.

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@@ Ред 1: / Ред 1: @@
 {{Short description|Fizički proces}}
-'''Spontano narušavanje simetrije''' je [[spontaneous process|spontan proces]] [[symmetry breaking|narušavanja simetrije]], po kome fizički sistem u [[Symmetry (physics)|simetričnom]] stanju završava u asimetričnom stanju.<ref>{{cite book |first=Vladimir A. |last=Miransky |title=Dynamical Symmetry Breaking in Quantum Field Theories |page=15 |url=https://books.google.com/books?id=UOpY9kmL3YQC&pg=PA15 |isbn=9810215584 }}</ref><ref>{{cite book |title=Patterns of Symmetry Breaking |editor-first=Henryk |editor-last=Arodz |editor2-first=Jacek |editor2-last=Dziarmaga |editor3-first=Wojciech Hubert |editor3-last=Zurek |url=https://books.google.com/books?id=uF1P7cFFsNMC&pg=PA141 |page=141 }}</ref><ref>{{cite book |title=Bubbles, Voids and Bumps in Time: The New Cosmology |editor-first=James |editor-last=Cornell |url=https://books.google.com/books?id=vRIs8mY1yZcC&pg=PA125 |page=125 }}</ref> Posebno, to može da opisuje sisteme gde [[Equations of motion|jednačine kretanja]] ili [[Lagrangian (field theory)|Lagranžijani]] poštuju simetrije, ali [[Vacuum solution (general relativity)|vakuumska rešenja]] sa najmanjom energijom ne pokazuju istu simetriju. Kada sistem pređe na jedno od ovih vakuumskih rešenja, simetrija se narušava zbog perturbacija oko tog vakuuma, iako celokupan Lagranžijan zadržava tu simetriju.
+'''Spontano narušavanje simetrije''' je [[spontaneous process|spontan proces]] [[symmetry breaking|narušavanja simetrije]], po kome fizički sistem u [[Symmetry (physics)|simetričnom]] stanju završava u asimetričnom stanju.<ref>{{cite book |first=Vladimir A. |last=Miransky |title=Dynamical Symmetry Breaking in Quantum Field Theories |page=15 |url=https://books.google.com/books?id=UOpY9kmL3YQC&pg=PA15 |isbn=9810215584 }}</ref><ref>{{cite book |title=Patterns of Symmetry Breaking |editor-first=Henryk |editor-last=Arodz |editor2-first=Jacek |editor2-last=Dziarmaga |editor3-first=Wojciech Hubert |editor3-last=Zurek |url=https://books.google.com/books?id=uF1P7cFFsNMC&pg=PA141 |page=141 }}</ref><ref>{{cite book |title=Bubbles, Voids and Bumps in Time: The New Cosmology |editor-first=James |editor-last=Cornell |url=https://books.google.com/books?id=vRIs8mY1yZcC&pg=PA125 |page=125 }}</ref> Posebno, to može da opisuje sisteme gde [[Equations of motion|jednačine kretanja]]<ref name="Physics 1991">{{Cite book | url = https://www.worldcat.org/oclc/20853637 | title = Encyclopedia of Physics | date = 1991 | publisher = VCH Publishers | author1 = R.G. Lerner | author1-link = Rita G. Lerner | author2 = George L. Trigg | isbn = 0-89573-752-3 | edition = second | location = New York | oclc = 20853637}}</ref><ref name="Analytical Mechanics 2008">{{cite book | last = Hand | first = Louis N. | author2 = Janet D. Finch | url = https://www.worldcat.org/oclc/37903527 | title = Analytical Mechanics | date = 1998 | publisher = Cambridge University Press | isbn = 978-0-521-57572-0 | location = Cambridge | oclc = 37903527}}</ref> ili [[Lagrangian (field theory)|Lagranžijani]] poštuju simetrije,<ref>Ralph Abraham and Jerrold E. Marsden, (1967) "Foundations of Mechanics"</ref><ref name="Bleecker">David Bleecker, (1981) "Gauge Theory and Variational Principles" Addison-Wesley</ref><ref name="jost">Jurgen Jost, (1995) "Riemannian Geometry and Geometric Analysis", Springer</ref> ali [[Vacuum solution (general relativity)|vakuumska rešenja]]<ref>H. Stephani, ''et al.'', "[https://www.loc.gov/catdir/samples/cam033/2002071495.pdf Exact solutions of Einstein's field equations]" (2003) Cambridge University Press</ref> sa najmanjom energijom ne pokazuju istu simetriju. Kada sistem pređe na jedno od ovih vakuumskih rešenja, simetrija se narušava zbog perturbacija oko tog vakuuma, iako celokupan Lagranžijan zadržava tu simetriju.
 == Pregled ==
-U [[Explicit symmetry breaking|eksplicitnom kršenju simetrije]], ako se uzmu u obzir dva ishoda, verovatnoća para ishoda može biti različita. Po definiciji, spontano narušavanje simetrije zahteva postojanje simetrične raspodele verovatnoće - bilo koji par ishoda ima istu verovatnoću. Drugim rečima, osnovni zakoni su [[Invariant (physics)|invarijantni]] u okviru transformacije [[Симетрије (физика)|simetrije]].
+U [[Explicit symmetry breaking|eksplicitnom kršenju simetrije]],<ref>Castellani, E. (2003) "On the meaning of Symmetry Breaking" in Brading, K. and Castellani, E. (eds)  Symmetries in Physics: New Reflections, Cambridge: Cambridge University Press</ref><ref>Sinha & Amaratunga (2016) "Explicit Symmetry Breaking in Electrodynamic Systems and Electromagnetic Radiation" Morgan Claypool, Institute of Physics, UK</ref> ako se uzmu u obzir dva ishoda, verovatnoća para ishoda može biti različita. Po definiciji, spontano narušavanje simetrije zahteva postojanje simetrične raspodele verovatnoće - bilo koji par ishoda ima istu verovatnoću. Drugim rečima, osnovni zakoni su [[Invariant (physics)|invarijantni]] u okviru transformacije [[Симетрије (физика)|simetrije]].
 Sistem u celini se menja pod takvim transformacijama.
@@ Ред 36: / Ред 36: @@
 == Reference ==
 {{Reflist}}
+== Literatura ==
+{{refbegin|30em}}
+* {{cite book |author1-link=Leon Lederman |first1=L. |last1=Lederman |author2-link=Christopher T. Hill |first2=C.T. |last2=Hill |title=Symmetry and the Beautiful Universe |publisher=Prometheus Books |date=2011 |isbn=9781615920419 |url={{GBurl|e9AQ5zH13qQC|p=7}}}}
+* {{cite book |first=B. |last=Schumm |title= Deep Down Things: The Breathtaking Beauty of Particle Physics |publisher=Johns Hopkins University Press |date=2004 |isbn=978-0-8018-7971-5 |url={{GBurl|IxwAEAAAQBAJ|pg=PR7}}}}
+* {{cite book |author-link=Victor J. Stenger |first=V.J. |last=Stenger |title=Timeless Reality: Symmetry, Simplicity, and Multiple Universes |publisher=Prometheus Books |date=2000 |isbn=9781573928595 }} Chapter 12 is a gentle introduction to symmetry, invariance, and conservation laws.
+* {{cite book |author-link=Anthony Zee |first=A. |last=Zee |title=Fearful Symmetry: The search for beauty in modern physics |publisher=Princeton University Press |edition=2nd |date=2007 |isbn=978-0-691-00946-9 |url=http://press.princeton.edu/titles/8509.html}}
+* {{cite book |last1=Brading |first1=K. |last2=Castellani |first2=E. |title=Symmetries in Physics: Philosophical Reflections |publisher=Cambridge University Press |date=2003 |isbn=978-1-139-44202-2 |url={{GBurl|fB38Q9D-WdwC|pg=PR5}}}}
+* {{cite book |last1=Brading |first1=K. |last2=Castellani |first2=E. |chapter=Symmetries and Invariances in Classical Physics |editor1-last=Butterfield |editor1-first=J. |editor2-first=J. |editor2-last=Earman |editor2-link=John Earman |title=Philosophy of Physic Part B |publisher=North Holland |date=2007 |isbn=978-0-08-046665-1 |pages=1331–68 |url={{GBurl|UGpJEFA5zXcC|pg=PR10}} }}
+* {{cite book |last1=Debs |first1=T. |last2=Redhead |first2=M. |title=Objectivity, Invariance, and Convention: Symmetry in Physical Science |publisher=Harvard University Press |date=2007 |isbn=978-0-674-03413-6 |url={{GBurl|lx0XQHtvdjoC|pg=PP1}} }}
+* {{citation |first=J. |last=Earman |author-link=John Earman |date=2002 |url=http://philsci-archive.pitt.edu/878/1/PSA2002.pdf |title=Laws, Symmetry, and Symmetry Breaking: Invariance, Conservations Principles, and Objectivity.}} Address to the 2002 meeting of the [[Philosophy of Science Association]].
+* {{cite book |first=G. |last=Kalmbach H.E. |title=Quantum Mathematics: WIGRIS |publisher=RGN Publications |date=2014 |isbn= |pages= |url=}}
+* {{cite book |first=K. |last=Mainzer |title=Symmetries of Nature: A Handbook for Philosophy of Nature and Science |publisher=de Gruyter |date=1996 |isbn=978-3-11-088693-1 |url={{GBurl|QekhAAAAQBAJ|pg=PP11}}}}
+* {{cite journal |first=A. |last=Mouchet |title=Reflections on the four facets of symmetry: how physics exemplifies rational thinking |journal=European Physical Journal H |volume=38 |issue= 5|pages=661–702 |date=2013 |doi=10.1140/epjh/e2013-40018-4 |arxiv=1111.0658 |bibcode=2013EPJH...38..661M |url=http://hal.archives-ouvertes.fr/hal-00637572 |citeseerx=10.1.1.400.2867|s2cid=14475702 }}
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+{{refend}}
 == Spoljašnje veze ==