In a scale invariant quantum field theory, by definition each operator O acquires under a dilatation a factor, where is a number called the scaling dimension of O. This implies in particular that the two point correlation function depends on the distance as. More generally, correlation functions of several local operators must depend on the distances in such a way that Most scale invariant theories are also conformally invariant, which imposes further constraints on correlation functions of local operators.
Free theories are the simplest scale-invariant quantum field theories. In free theories, one makes a distinction between the elementary operators, which are the fields appearing in the Lagrangian, and the composite operators which are products of the elementary ones. The scaling dimension of an elementary operator O is determined by dimensional analysis from the Lagrangian. This scaling dimension is called the classical dimension. A composite operator obtained by taking a product of two operators of dimensions and is a new operator whose dimension is the sum. When interactions are turned on, the scaling dimension receives a correction called the anomalous dimension.
Interacting field theories
There are many scale invariant quantum field theories which are not free theories; these are called interacting. Scaling dimensions of operators in such theories may not be read off from a Lagrangian; they are also not necessarily integer. For example, in the scale invariant theory describing the critical points of the two-dimensional Ising model there is an operator whose dimension is 1/8. Operator multiplication is subtle in interacting theories compared to free theories. The operator product expansion of two operators with dimensions and will generally give not a unique operator but infinitely many operators, and their dimension will not generally be equal to. In the above two-dimensional Ising model example, the operator product gives an operator whose dimension is 1 and not twice the dimension of.
Non-scale invariant quantum field theory
There are many quantum field theories which, while not being exactly scale invariant, remain approximately scale invariant over a long range of distances. Such quantum field theories can be obtained by adding to free field theories interaction terms with small dimensionless couplings. For example, in four spacetime dimensions one can add quartic scalar couplings, Yukawa couplings, or gauge couplings. Scaling dimensions of operators in such theories can be expressed schematically as, where is the dimension when all couplings are set to zero, while is called the anomalous dimension, and is expressed as a power series in the couplings collectively denoted as. Such a separation of scaling dimensions into the classical and anomalous part is only meaningful when couplings are small, so that is a small correction. Generally, due to quantum mechanical effects, the couplings do not remain constant, but vary with the distance scale according to their beta-function. Therefore the anomalous dimension also depends on the distance scale in such theories. In particular correlation functions of local operators are no longer simple powers but have a more complicated dependence on the distances, generally with logarithmic corrections. It may happen that the evolution of the couplings will lead to a value where the beta-function vanishes. Then at long distances the theory becomes scale invariant, and the anomalous dimensions stop running. Such a behavior is called an infrared fixed point. In very special cases, it may happen when the couplings and the anomalous dimensions do not run at all, so that the theory is scale invariant at all distances and for any value of the coupling. For example, this occurs in the N=4 supersymmetric Yang-Mills theory.