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Line 1: {{Short description\|Question of why quantum chromodynamics does seem to not break CP -symmetry}} The '''strong CP problem''' is a ~~puzzling~~ question in [[particle physics]]:, which ~~Why~~brings up the following quandary: why does [[quantum chromodynamics]] (QCD) seem to preserve [[CP violation#CP-symmetry\|CP-symmetry]]? In particle physics, '''CP''' stands for the combination of [[C-symmetry]] (charge conjugation symmetry) and [[Parity (physics)\|P-symmetry]] (parity symmetry). According to the current mathematical formulation of quantum chromodynamics, a [[CP violation\|violation of [[CP-symmetry]] in [[strong interaction]]s could occur. However, no violation of the CP-symmetry has ever been seen in any experiment involving only the strong interaction. As there is no known reason in QCD for it to necessarily be conserved, this is a "[[Fine-tuning (physics)\|fine tuning]]" problem known as the '''strong CP problem'''.▼ In particle physics, '''CP''' stands for Charge+Parity or Charge-conjugation Parity symmetry: the combination of [[charge (physics)\|charge]] [[C-symmetry\|conjugation symmetry]] (C) and [[Parity (physics)\|parity]] symmetry (P). ▲According to the current mathematical formulation of quantum chromodynamics, a violation of [[CP-symmetry]] in [[strong interaction]]s could occur. However, no violation of the CP-symmetry has ever been seen in any experiment involving only the strong interaction. As there is no known reason in QCD for it to necessarily be conserved, this is a "[[fine tuning]]" problem known as the '''strong CP problem'''. The strong CP problem is sometimes regarded as an [[List of unsolved problems in physics\|unsolved problem in physics]], and has been referred to as "the most underrated puzzle in all of physics."<ref>{{cite conference \|first=T. \|last=Mannel \|title=Theory and Phenomenology of CP Violation \|book-title=Nuclear Physics B \|volume=167 \|pages=170–174 \|publisher=Elsevier \|conference=The 7th International Conference on Hyperons, Charm, and Beauty Hadrons (BEACH 2006) \|date=2–8 July 2006 \|___location=Lancaster \|url=https://indico.cern.ch/event/427023/session/6/contribution/43/attachments/912026/1288208/Lancester-Mannel-Proc.pdf \|doi=10.1016/j.nuclphysbps.2006.12.083 \|access-date=15 Aug 2015 \|bibcode=2007NuPhS.167..170M}}</ref><ref>{{Cite web \| url=https://www.forbes.com/sites/startswithabang/2019/11/19/the-strong-cp-problem-is-the-most-underrated-puzzle-in-all-of-physics \|title = The 'Strong CP Problem' is the Most Underrated Puzzle in All of Physics\| website=[[Forbes]] }}</ref> There are several proposed solutions to solve the strong CP problem. The most well-known is [[Peccei–Quinn theory]],<ref>{{Cite journal\|author1=Peccei, R.D. \|author-link1=Roberto Peccei \|author2=Quinn, H.R. \|author-link2=Helen Quinn\|year=1977\|title=''CP'' conservation in the presence of pseudoparticles\|url=https://www.researchgate.net/publication/248549883\|journal=[[Physical Review Letters]]\|volume=38\|issue=25\|pages=1440–1443\|bibcode=1977PhRvL..38.1440P\|doi=10.1103/PhysRevLett.38.1440}}</ref> involving new [[pseudoscalar]] particles called [[axion]]s. ==Theory== Line 12 ⟶ 11: CP-symmetry states that physics should be unchanged if particles were swapped with their antiparticles and then left-handed and right-handed particles were also interchanged. This corresponds to performing a charge conjugation transformation and then a parity transformation. The symmetry is known to be broken in the [[Standard Model]] through [[weak interaction\|weak interactions]], but it is also expected to be broken through [[strong interaction\|strong interactions]] which govern [[quantum chromodynamics]] (QCD), something that has not yet been observed. To illustrate how the CP violation can come about in QCD, consider a [[Yang–Mills theory]] with a single massive [[quark]].<ref>{{cite conference\|url=https://www.osti.gov/servlets/purl/6260191\|title=A Brief Introduction to the Strong CP Problem\|last1=Wu\|first1=D.\|date=1991\|publisher=\|___location=Austin, Texas, United States\|id=SSCL-548}}</ref> The most general mass term possible for the quark is a complex mass written as <math>m e^{i\theta' \gamma_5}</math> for some arbitrary phase <math>\theta'</math>. In that case the [[Lagrangian (field theory)\|Lagrangian]] describing the theory consists of four terms: :<math> Line 18 ⟶ 17: </math> The first and third terms are the CP-symmetric [[kinetic term~~\|kinetic terms~~]]s of the [[gauge theory\|gauge]] and quark fields. The fourth term is the quark mass term which is CP violating for non-zero phases <math>\theta' \neq 0</math> while the second term is the so-called [[~~vacuum~~theta ~~angle~~vacuum\|θ-term]] or “vacuum angle”, which also violates CP -symmetry. Quark fields can always be redefined by performing a chiral transformation by some angle <math>\alpha</math> as :<math> \psi' = e^{i\alpha \gamma_5/2}\psi, \ \ \ \ \ \ \bar \psi' = \bar \psi e^{-i\alpha \gamma_5/2}, </math> Line 30 ⟶ 29: The theory would be CP invariant if one could eliminate both sources of CP violation through such a field redefinition. But this cannot be done unless <math>\theta = -\theta'</math>. This is because even under such field redefinitions, the combination <math>\theta'+ \theta \rightarrow (\theta'-\alpha) + (\theta + \alpha) = \theta'+\theta</math> remains unchanged. For example, the CP violation due to the mass term can be eliminated by picking <math>\alpha = \theta'</math>, but then all the CP violation goes to the θ-term which is now proportional to <math>\bar \theta</math>. If instead the θ-term is eliminated through a chiral transformation, then there will be a CP violating complex mass with a phase <math>\bar \theta</math>. Practically, it is usually useful to put all the CP violation into the θ-term and thus only deal with real masses. In the Standard Model where one deals with six quarks whose masses are described by the [[Yukawa interaction\|Yukawa matrices]] <math>Y_u</math> and <math>Y_d</math>, the physical CP violating angle is <math>\bar \theta = \theta - \arg \det(Y_u Y_d)</math>. Since the θ-term has no contributions to perturbation theory, all effects from strong CP violation is entirely non-perturbative. Notably, it gives rise to ana [[neutron electric dipole moment]]<ref>{{cite book\|first=M.D.\|last=Schwartz\|title=Quantum Field Theory and the Standard Model\|publisher=Cambridge University Press\|chapter=29\|~~edition~~date=92014 \|page=612\|isbn=9781107034730}}</ref> :<math> Line 36 ⟶ 35: </math> Current experimental upper bounds on the dipole moment give an upper bound of <math>d_N < 10^{-26} \text{e}\cdot</math>cm,<ref>{{Cite journal \|last1=Baker \|first1=C.A. \|last2=Doyle \|first2=D.D. \|last3=Geltenbort \|first3=P. \|last4=Green \|first4=K. \|last5=van der Grinten \|first5=M.G.D. \|last6=Harris \|first6=P.G. \|last7=Iaydjiev \|first7=P. \|last8=Ivanov \|first8=S.N. \|last9=May\|first9=D.J.R. \|date=2006-09-27 \|df=dmy-all \|title=Improved experimental limit on the electric dipole moment of the neutron \|journal=Physical Review Letters \|volume=97 \|issue=13 \|~~pages~~page=131801 \|doi=10.1103/PhysRevLett.97.131801 \|pmid=17026025 \|arxiv=hep-ex/0602020\|bibcode=2006PhRvL..97m1801B \|s2cid=119431442 }}</ref> which requires <math>\bar \theta < 10^{-10}</math>. The angle <math>\bar \theta</math> can take any value between zero and <math>2\pi</math>, so it taking on such a particularly small value is a fine-tuning problem called the strong CP problem. ==Proposed solutions== The strong CP problem is solved automatically if one of the quarks is massless.<ref>{{cite journal\|last1=Hook\|first1=A.\|date=2019-07-22\|title=TASI Lectures on the Strong CP Problem and Axions\|url=https://pos.sissa.it/333/004/pdf\|journal=Proceedings of Science\|volume=333\|page=004 \|doi=10.22323/1.333.0004\|arxiv=1812.02669\|s2cid=119073163 \|access-date=2021-12-02 \|doi-access=free }}</ref> In that case one can perform a set of chiral transformations on all the massive quark ~~field~~fields to get rid of their complex mass phases and then perform another chiral transformation on the massless quark field to eliminate the residual θ-term without also introducing a complex mass term for that field. This then gets rid of all CP violating terms in the theory. The problem with this solution is that all ~~quark masses~~quarks are known to be massive from experimental matching with [[lattice QCD\|lattice calculations]]. Even if one of the quarks was essentially massless to solve the problem, this would in itself just be another fine-tuning problem since there is nothing requiring a quark mass to take on such a small value. The most popular solution to the problem is through the ~~Peccei-Quinn~~Peccei–Quinn mechanism.<ref>{{Cite book\|author=Peccei, R. D. \|year=2008 \|chapter=The Strong CP Problem and Axions \|title=Axions: Theory, Cosmology, and Experimental Searches \|editor1-last=Kuster \|editor1-first=M. \|editor2-last=Raffelt \|editor2-first=G. \|editor3-last=Beltrán \|editor3-first=B. \|series=Lecture Notes in Physics \|volume=741 \|pages=3–17 \|arxiv=hep-ph/0607268 \|doi=10.1007/978-3-540-73518-2_1 \|isbn=978-3-540-73517-5\|s2cid=119482294 }}</ref> This introduces a new global [[anomaly (physics)\|anomalous]] symmetry which is then [[spontaneous symmetry breaking\|spontaneously broken]] at low energies, giving rise to a [[Goldstone boson\|pseudo-Goldstone]] boson called an axion. The axion ground state dynamically forces the theory to be CP -symmetric by setting <math>\bar \theta = 0</math>. Axions are also considered viable candidates for [[dark matter]] and axion-like particles are also predicted by [[string theory]]. Other less popular proposed solutions exist such as ~~Nelson-Barr~~Nelson–Barr models.<ref>{{cite journal\|last=Nelson\|first=A.\|date=1984-03-15\|title=Naturally weak CP violation\|url=https://~~www~~dx.~~sciencedirect~~doi.~~com~~org/~~science/article~~10.1016/~~pii/0370269384920252~~0370-2693%2884%2992025-2\|journal=Physics Letters B\|volume=136\|issue=5,6\|pages=~~387-391~~387–391\|doi=10.1016/0370-2693(84)92025-2\|pmid=\|arxiv=\|bibcode=1984PhLB..136..387N \|s2cid=\|access-date=2021-12-02\|url-access=subscription}}</ref><ref>{{cite journal\|last=Barr\|first=S. M.\|date=1984-04-18\|title=Solving the Strong CP Problem without the ~~Peccei-Quinn~~Peccei–Quinn Symmetry\|url=https://link.aps.org/doi/10.1103/PhysRevLett.53.329\|journal=Phys. Rev. Lett.\|volume=53\|issue=4\|pages=~~329-332~~329–332\|doi=10.1103/PhysRevLett.53.329\|pmid=\|arxiv=\|bibcode=1984PhRvL..53..329B \|s2cid=\|access-date=2021-12-02\|url-access=subscription}}</ref> These set <math>\bar \theta = 0</math> at some high energy scale where CP -symmetry is exact but the symmetry is then spontaneously broken ~~at low energies~~. The ~~tricky~~Nelson–Barr ~~part~~mechanism ofis ~~the~~a ~~models~~way ~~is to account~~of ~~for~~explaining why <math>\bar \theta</math> remains small at low energies while the CP breaking phase in the [[Cabibbo–Kobayashi–Maskawa matrix\|CKM matrix]] ~~becomes~~is large. ==See also== {{Portal\|Physics}} <!-- Please keep entries in alphabetical order ~~& add a short description [[WP:SEEALSO]]~~ --> ~~{{div col\|colwidth=15em\|small=yes}}~~ * [[Axion]] * [[CP violation]] ~~{{div col end}}~~ ~~<!-- please keep entries in alphabetical order -->~~ ==References==