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Line 1: {{short description\|Class of operators in quantum field theory}} ~~{{refimprove\|date=November 2010}}~~ In [[statistical mechanics]] and [[quantum field theory]], a '''dangerously irrelevant operator''' (or '''dangerous irrelevant operator''') is an [[operator (mathematics)\|operator]] which is irrelevant at a renormalization group fixed point, yet affects the [[infrared]] (IR) physics significantly (e.g. because the [[vacuum expectation value]] (VEV) of some field depends sensitively upon the ~~dangerously~~coefficient of ~~irrelevant~~this operator).▼ ~~{{Orphan\|date=December 2009}}~~ == Critical phenomena == ~~This is extremely dangerous! Approach angry bananas with care!~~ In the theory of critical phenomena, free energy of a system near the critical point depends analytically on the coefficients of generic (not dangerous) irrelevant operators, while the dependence on the coefficients of dangerously irrelevant operators is non-analytic (<ref name=":0">{{Cite book\|last=Cardy\|first=John\|title=Scaling and Renormalization in Statistical Physics\|publisher=Cambridge University Press\|year=1996}}</ref> p. 49). The presence of dangerously irrelevant operators leads to the violation of the hyperscaling relation <math>\alpha=2-d\nu</math> between the critical exponents <math>\alpha</math> and <math>\nu</math> in <math>d</math> dimensions. The simplest example (<ref name=":0" /> p. 93) is the critical point of the Ising ferromagnet in <math>d\ge4</math> dimensions, which is a gaussian theory (free massless scalar <math>\phi</math>), but the leading irrelevant perturbation <math>\phi^4</math> is dangerously irrelevant. Another example occurs for the Ising model with random-field disorder, where the fixed point occurs at zero temperature, and the temperature perturbation is dangerously irrelevant (<ref name=":0" /> p. 164). ▲In [[statistical mechanics]] and [[quantum field theory]], a '''dangerously irrelevant operator''' (or '''dangerous irrelevant operator''') is an [[operator (mathematics)\|operator]] which is irrelevant, yet affects the [[infrared]] physics significantly because the [[vacuum expectation value]] of some field depends sensitively upon the dangerously irrelevant operator. ==Quantum field theory== ~~==Example==~~ Let us suppose there is a field <math>\phi</math> with a [[potential]] depending upon two parameters, ''<math>a''</math> and ''<math>b''</math>. :<math>V\left(\phi\right)=-a \phi^\alpha + b\phi^\beta</math> Let us also suppose that ''<math>a''</math> is positive and nonzero and <math>\beta</math> > <math>\alpha</math>. If ''<math>b''</math> is zero, there is no stable equilibrium. If the [[scaling dimension]] of <math>\phi</math> is ''<math>c''</math>, then the scaling dimension of ''<math>b''</math> is <math>d-\beta c</math> where ''<math>d''</math> is the number of dimensions. It is clear that if the scaling dimension of ''<math>b''</math> is negative, ''<math>b''</math> is an irrelevant parameter. However, the crucial point is, that the ~~[[Vacuum expectation value\|<math>\mathrm{~~VEV~~}</math>]]~~ :<math>\langle\phi\rangle=\left(\frac{a\alpha}{b\beta}\right)^{\frac{1}{\beta-\alpha}}=\left(\frac{a\alpha}{\beta}\right)^{\frac{1}{\beta-\alpha}}b^{-\frac{1}{\beta-\alpha}}</math>. depends very sensitively upon ''<math>b''</math>, at least for small values of ''<math>b''</math>. Because the nature of ~~the IR~~infrared physics also depends upon the ~~<math>\mathrm{~~VEV~~}</math>~~, ~~the IR physics~~it looks very different even for a tiny change in ''<math>b''</math> not because the physics in the vicinity of <math>\phi=0</math> changes much — it hardly changes at all — but because the ~~<math>\mathrm{~~VEV~~}</math>~~ we are expanding about has changed enormously. In [[supersymmetry\|~~supersymmetric~~Supersymmetric]] models with a [[moduli space\|a modulus]]~~, we~~ can often have dangerously irrelevant parameters. == Other uses of the term == Consider a renormalization group (RG) flow triggered at short distances by a relevant perturbation of an ultra-violet (UV) fixed point, and flowing at long distances to an infra-red (IR) fixed point. It may be possible (e.g. in perturbation theory) to monitor how dimensions of UV operators change along the RG flow. In such a situation, one sometimes<ref>{{Cite journal\|last=Gukov\|first=Sergei\|date=2016-01-05\|title=Counting RG flows\|journal=Journal of High Energy Physics\|language=en\|volume=2016\|issue=1\|pages=20\|arxiv=1503.01474\|doi=10.1007/JHEP01(2016)020\|bibcode=2016JHEP...01..020G \|s2cid=23582290\|issn=1029-8479}}</ref> calls dangerously irrelevant a UV operator whose scaling dimension, while irrelevant at short distances: <math>\Delta_{\rm UV}>d</math> , receives a negative correction along a renormalization group flow, so that the operator becomes relevant at long distances: <math>\Delta_{\rm IR}<d</math>. This usage of the term is different from the one originally introduced in statistical physics.<ref>{{Cite journal\|last1=Amit\|first1=Daniel J\|last2=Peliti\|first2=Luca\|date=1982\|title=On dangerous irrelevant operators\|journal=Annals of Physics\|language=en\|volume=140\|issue=2\|pages=207–231\|doi=10.1016/0003-4916(82)90159-2\|bibcode=1982AnPhy.140..207A }}</ref> ==References== {{Reflist}} ~~{{cite doi\|10.1016/0003-4916(82)90159-2}}~~ {{DEFAULTSORT:Dangerously Irrelevant Operator}} [[Category:Renormalization group]] {{~~Phys~~quantum-stub}}▼ ▲{{Phys-stub}}