is a color index in the adjoint representation of SU which take values 1, 2,..., 8 for the eight generators of the group, namely the Gell-Mann matrices;
is a spacetime index, 0 for timelike components and 1, 2, 3 for spacelike components;
are its four components, that in a fixed gauge are traceless Hermitian matrix-valued functions, while are 32 real-valued functions, the four components for each of the eight four-vector fields.
Different authors choose different signs. Expanding the commutator gives; Substituting and using the commutation relation for the Gell-Mann matrices, in which are the structure constants of SU, each of the gluon field strength components can be expressed as a linear combination of the Gell-Mann matrices as follows: so that: where again are color indices. As with the gluon field, in a specific coordinate system and fixed gauge are traceless Hermitian matrix-valued functions, while are real-valued functions, the components of eight four-dimensional second order tensor fields.
Differential forms
The gluon color field can be described using the language of differential forms, specifically as an adjoint bundle-valued curvature 2-form ; where is the gluon field, a vector potential 1-form corresponding to and is the wedge product of this algebra, producing the structure constants. The Cartan-derivative of the field form would be zero in the absence of the "gluon terms", i.e. those which represent the non-abelian character of the SU. A more mathematically formal derivation of these same ideas can be found in the article on metric connections.
Characteristic of field theories, the dynamics of the field strength are summarized by a suitable Lagrangian density and substitution into the Euler–Lagrange equation obtains the equation of motion for the field. The Lagrangian density for massless quarks, bound by gluons, is: where "tr" denotes trace of the matrix, and are the gamma matrices. In the fermionic term, both color and spinor indices are suppressed. With indices explicit, where are color indices and are Dirac spinor indices.
Gauge transformations
In contrast to QED, the gluon field strength tensor is not gauge invariant by itself. Only the product of two contracted over all indices is gauge invariant.
Equations of motion
Treated as a classical field theory, the equations of motion for the quark fields are: which is like the Dirac equation, and the equations of motion for the gluon fields are: which are similar to the Maxwell equations. More specifically, these are the Yang–Mills equations for quark and gluon fields. The color charge four-current is the source of the gluon field strength tensor, analogous to the electromagnetic four-current as the source of the electromagnetic tensor. It is given by which is a conserved current since color charge is conserved. In other words, the color four-current must satisfy the continuity equation:
