Wilson-Fisher fixed points for any dimension

The critical behavior of a non-local scalar field theory is studied. This theory has a non-local quartic interaction term which involves a real power -\beta of the Laplacian. The parameter \beta can be tuned so as to make that interaction marginal for any dimension. The lowest order Feynman diagrams corresponding to coupling constant renormalization, mass renormalization, and field renormalization are computed. In all cases a non-trivial IR fixed point is obtained. Remarkably, for dimensions different from 4, field renormalization is required at the one-loop level. For d=4, the theory reduces to the usual local \phi^{4} field theory and field renormalization is required starting at the the two-loop level. The critical exponents \nu and \eta are computed for dimensions 2,3,4 and 5. For dimensions greater than four, the critical exponent \eta turns out to be negative for \epsilon>0, which indicates a violation of the unitarity bounds.


Introduction
The computation of critical exponents for the 3-dimensional Ising model using the ǫexpansion provides a concrete example of the relevance of the renormalization group ideas [1] [2]. This is done by considering a self -interacting φ 4 theory in d = 4 − ǫ dimensions, where ǫ is allowed to take real values. This procedure led to a qualitative understanding of the 3-dimensional Ising model physics, and to predictions for critical exponents in reasonable agreement with the exact values.
The renormalization group consists in the study of the evolution of a system under scale transformations. This system involves all possible interactions of any range for all kinds of dynamical variables. Different physical systems correspond to the study of particular fixed points in this huge space of couplings. This paper studies a particular example of system described near the corresponding fixed point by a non-local field theory. Non-local field theories appear in various aspects of physics. These include proposals for dealing with quantum gravity [3], field theories based on non-commutative geometry [4], and in critical phenomena. The use of non-local field theories in the description of critical phenomena is not new [5], [6], [7], [8]. Such models appear in statistical systems with long range interactions. In a previous paper [9], the critical behavior of a φ 4 theory with a non-local kinetic term was studied. That theory has asymptotic freedom in the UV. In this paper, the critical behavior of a field theory which includes a non-local interaction is studied. This interaction consists in a φ 4 term which involves a power −β of the Laplacian. The parameter β allows to tune the dimensions of the corresponding coupling constant. This is done in such a way that for any space dimension n the coupling is a-dimensional. Thus reproducing for any spatial dimension n what happens for the local φ 4 theory in n = 4 dimensions. The theory is formulated using an auxiliary field ρ , which renders the interaction local, at the cost of having a non-local kinetic term. The renormalization and critical properties of this theory are studied at the one-loop level. The features and results of this work are summarized as follows, • The theory to be considered is a scalar field theory involving a non-local φ 4 interaction term, which includes a power −β of the Laplacian. • The theory is dimensionally regularized, and the contribution of the one-loop Feynman diagrams which present poles when ǫ → 0 is computed. • These one-loop computations show that mass and coupling constant renormalization are required at this level in order to render the theory finite. In addition, and contrasting with local φ 4 theory, field renormalization is required at this one-loop level for any dimension different from 4. • The previous calculation allows to compute the fixed point value for the coupling constant, and the critical exponents ν and η. In all cases a non-trivial IR fixed point is obtained for ǫ > 0. • For dimensions d = n − ǫ with n less than 4, non-trivial fixed points are obtained describing consistent quantum theories. • For dimensions d = n − ǫ with n greater than 4, the critical exponent η turns out to be negative for ǫ > 0, which indicates a violation of the unitarity bounds. The paper is organized as follows. Section 2. presents the model and explains how to tune β in order to get an a-dimensional coupling. Section 3 contains the computations of Feynman diagrams. Subsection 3.1 presents the one-loop corrections to the two-point function, which involve the contribution of two diagrams. Subsection 3.2 deals with the one-loop corrections to the four-point function, which involve the contribution of three diagrams. Subsection 3.3 computes the critical exponents ν and η for these theories. Finally, section 4 presents some concluding remarks and additional research motivated by this work.

The action
The Euclidean action for the field φ to be considered is given by, In what follows, bare mass and coupling will be indicated by m 0 and λ 0 , the corresponding renormalized quantities will be m and λ. Using an auxiliary field ρ, the actionS can be replaced by the following equivalent action, functionally integrating over ρ leads back to the actionS , i.ê The free energy is given by, The Fourier transform of the free ρ and φ two-point functions are therefore given by, < ρρ > (p) = − 1 (p 2 + M 2 ) β , < φφ > (p) = 1 (p 2 + m 2 0 ) the mass M has been included in order to regulate infrared divergencies.
It is noted that the dimension of the field φ and coupling [λ 0 ] are, for d = n − ǫ choosing, makes the coupling dimension equal to ǫ, i.e. [λ 0 ] = ǫ. This choice will be adopted from now on. This is exactly what happens for the coupling of the local φ 4 theory in d = 4 − ǫ.
Thus the non-local coupling parametrized by β inS I can be considered as a device to reproduce the same situation in other dimensions. It is also noted that for n > 4 then β > 0, which for M → 0 produces infrared divergencies in these cases. This motivates the choice M = M n , where,

Effective Couplings
3.1. One-loop correction to the two-point function. The one-loop corrections to the two-point function are given by the following diagrams, It is noted that the internal ρ line in the first diagram carries zero momentum. Thus, taking into account the relation (2.1), this line gives a factor, which recalling (2.2) shows that this line vanishes for n < 4, gives −1 for n = 4 and is non-vanishing for n > 4. Indeed the motivation for introducing the mass M n for the ρ field, was to regulate the infrared divergence appearing from this propagator at zero momentum for n > 4, i.e. β > 0. The contribution of the first diagram without external legs is, ) the quantity µ T = 4 is the multiplicity of this diagram. Introducing the Feynman parametrization and integrating over the momenta q, leads to, where in the second equality the result has been expressed in terms of the a-dimensional coupling g 0 = µ d−2(β+2) λ 0 . For n odd, this contribution presents no divergence for ǫ → 0. For d = n − ǫ with n a positive even integer, the gamma function can be expanded as follows, where R denotes terms that present no singularities when ǫ → 0. This leads to, For n = 2 and 3 , because of the remarks at the beginning of this subsection, this diagram gives no contribution, which is also the case for any odd n. Thus for n < 6 the singular part of a T is given by, The integral corresponding to the second diagram is, for the cases considered in this work (d = n − ǫ, β = n 2 − 2) this gives ω(I F ) = 2 − ǫ . This implies that there is a divergent term proportional to p 2 , i.e. that this diagram requires a field renormalization. Below it is shown that the coefficient of p 2 vanishes for d = 4, this should be so because for n = 4 , β = 0 and the theory coincides with the usual local φ 4 field theory, which requires no field renormalization at the one-loop level. Introducing the Feynman parametrization and integrating over the momenta q, leads to, The power of the parenthesis in the integrand is −β + d 2 − 1 = 1 − ǫ 2 , which therefore presents no singularities in the integration region. Thus ǫ = 0 is taken in this power. The integral can be evaluated leading to, which leads to the following expression for its singular part, this result is quite remarkable because it shows that for n = 4 ⇒ β = 0 field renormalization is required at the one-loop level to absorb the divergences. It is recalled that for the n = 4 local φ 4 theory, field renormalization is first required at two loops. The diagram contributing to field renormalization is the second one in fig. 3.1, and it requires field renormalization because of the non-zero momentum carried by the auxiliary field ρ line. Alternatively this can be seen from the fact that the non-local interaction introduces momentum at each non-local vertex. It is remarked that the general result (3.2) shows that starting from n = 5 the sign of the term proportional to p 2 changes, this sign change will affect the sign of the critical exponent η, leading to a violation of the unitarity bounds for n ≥ 5. The effective two-point function to one-loop order is, 1 , where, The effective mass is therefore given by, The free energy is, therefore the order 0 free energy goes as S 0 , and the corrections carry a minus sign in front. 2 The gamma function is given by, √ π g 0 (4π)  Removing external legs, the integral to be computed is, n ) β the quantity µ V = 96 4! is the multiplicity of this diagram. The overall factor 2 3 in front of this contribution comes from, µ V 4!12 2 = 2 3 The degree of divergence of this integral is, for the cases considered in this work (d = n−ǫ, β = n 2 −2) this gives ω(A V ) = d−4−2β = −ǫ . Therefore, taking derivatives with respect to M 2 n makes the integral convergent, thus making a series expansion in powers of M 2 n , only the first term can produce a divergence when ǫ → 0, i.e. M n = 0 is taken in the calculation below. The same reasoning applies for 2 It is noted that for d = 4 − ǫ the expression for the effective mass is, which is the well-known result for the local φ 4 theory.
the dependence of A V (r, t, m 0 , M n , d, β) on the external momenta r and t, thus only zero external momenta is relevant for the singular part of this contribution. This leads to, β Introducing the Feynman parametrization and integrating over the moment q, leads to, 2. ρ-self energy correction. The diagram to be considered is the following, The integral to be computed is, ) for this diagram µ ρ = 96 4! leading to the same overall factor 2 3 , as in the previous diagram. Introducing the Feynman parametrization and integrating over q, leads to, the integral over x gives a finite result for any n, since the integrand is well-behaved in the entire integration region. Therefore Γ 2 − d 2 is the one that can produce a pole for ǫ → 0, this does not happen for d = n − ǫ with n odd neither for n = 2. Thus, only even values of n with n ≥ 4 produce poles. For n = 4 the original integral is logarithmically divergent, and therefore in getting the pole term, only the value of the integral for p 2 = 0 should be computed, this gives, For n ≥ 6 even, the integral A(p, m 0 , d) has degree of divergence greater than zero, given by ω(A) = n − ǫ − 4 . This means that the derivatives of A(p, m 0 , d) with respect to p 2 have divergent coefficients when ǫ → 0 up to order ω(A)/2. The number of these divergent coefficients matches the number of parameters needed to specify the ρ free field action. Indeed, for n = 6 then β = 1 which means that the coefficient of ρ 2 and the coefficient of ρ△ρ get renormalized in this case. The cases with n ≥ 6 even will not be further studied in this work. Thus for n < 6 the following result for the pole term of I ρ (p, m 0 , d) is obtained, The diagram to be considered is the following, The integral to be computed is, which for the cases considered in this work d = n − ǫ, β = n 2 − 2 is, ω B = 4 − n − ǫ This shows that for n > 4 there is no divergence for ǫ → 0. Introducing the Feynman parametrization , leads to, is positive definite in the x, y, z integration region. The integral in the last expression can be done leading to, it is noted that for n ≤ 4 the power appearing in P (k, p, l, x, y, z) is positive or goes to zero for ǫ → 0. In addition, P (k, p, l, x, y, z) is well defined and positive in the x, y, z integration region. Thus, the integral in (3.4) is bounded from above by the integral of P (k, p, l, x, y, z) multiplied by the following positive integral, therefore the singularities of A B (p, k, l, m 0 , d) for ǫ → 0 only arise from the factor, this produces singularities only for n = 4. For this value of n and in the limit ǫ → 0, P (k, p, l, x, y, z)/Γ − d 2 + 2β + 2 can be replaced by 1, leading to, which presents a pole term in ǫ only for n = 4, given by, 3.2.4. Effective quartic coupling and its β-function. Summing up the contributions from the ρφ 2 vertex correction, the ρ-self energy correction and the box and including the field renormalization in (3.3), leads to, where, the beta function corresponding to the a-dimensional coupling g, is, which leads to, β(g) = −ǫg + 4gγ + g 2 c g (n) (4π) n 2 = −ǫg + g 2 (4π) n 2 (2c φ (n) + c g (n)) (3.5) the fixed points defined by β(g ⋆ ) = 0 are given by, For n = 2, 3, 4, 5, C(n) > 0, so that for ǫ > 0, g ⋆ 1 is positive and corresponds to a IR fixed point , also for ǫ > 0, g ⋆ 0 corresponds to a UV fixed point. The figures below shows these β-functions,  3.3. The critical exponents η and ν. The γ m (n) function is given by, γ m (n) = γ − c m 2 (n) (4π) • From the Wilson renormalization group point of view, there is no restriction on the range of interactions. Therefore it makes sense to study the renormalization of a non-local field theory. In this work, this has been done using the field theoretic version of this procedure. This was done for the first corrections to the two and four-point functions. It was shown that the resulting critical theories are consistent for dimensions d < 5. • For dimensions d ≥ 5 the theories have a critical index η < 0 which implies a violation of the unitarity bounds. • It would be interesting to identify concrete statistical models whose criticality is described by these fixed points and critical exponents. Summarizing, it is believed that the study of non-local field theories can enlarge our knowledge about the fixed points, and renormalization group flows in the space of all possible couplings mentioned in the introduction. In particular, the study presented in this work shows the existence of new non-trivial fixed points in dimensions 2 and 3.