Field operator

A linear weakly-continuous mapping $ f \rightarrow \phi _ {f} $, $ f \in D ^ {L} ( \mathbf R ^ {4} ) $, of the space $ D ^ {L} ( \mathbf R ^ {4} ) $ of basic functions $ f ( x) $, $ x \in \mathbf R ^ {4} $, that take values in a finite-dimensional vector space $ L $, to the set of operators (generally speaking, unbounded) defined on a dense linear manifold $ D _ {0} \in H $ of some Hilbert space $ H $. Here it is assumed that both in $ L $ and in $ H $ certain representations $ g \rightarrow T _ {g} $( in $ L $) and $ g \rightarrow U _ {g} $( in $ H $), $ g \in G $, of the inhomogeneous Lorentz group $ G $ act in such a way that the equation

$$ \tag{* } U _ {g} \phi _ {f} U _ {g} ^ {-1} = \ \phi _ {\tau _ {g} f } ,\ \ g \in G,\ \ f \in D ^ {L} ( \mathbf R ^ {4} ), $$

holds, where

$$ ( \tau _ {g} f ) ( x) = \ T _ {g} f ( g ^ {-1} x),\ \ x \in \mathbf R ^ {4} . $$

Depending on the representation (scalar, vector, spinor, etc.) in $ L $, the field $ \{ {\phi _ {f} } : {f \in D ^ {L} ( \mathbf R ^ {4} ) } \} $ is called, respectively, scalar, vector or spinor. A family of field operators $ \{ {\phi _ {f} } : {f \in D ^ {L} ( \mathbf R ^ {4} ) } \} $ together with representations $ \{ {T _ {g} } : {g \in G } \} $ and $ \{ {U _ {g} } : {g \in G } \} $ for which condition (*) holds together with several general conditions (see [1]) is called a quantum (or quantized) field.

Aside from some models referring to the two-dimensional or three-dimensional world (see [2], [4]), one has constructed only (1983) simple examples of so-called free quantum fields [3].

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