Soft gluons are gluons with low energy or momentum, typically in the infrared region. Colinear gluons are gluons that are emitted in the same direction as a high-energy quark or gluon, but with a much lower energy or momentum.
Soft and colinear gluons play a crucial role in QCD calculations as they are responsible for the majority of the radiation and scattering processes in high-energy particle collisions. They also play a significant role in the development of parton shower algorithms used in simulations of particle collisions.
In QCD calculations, soft and colinear gluons are usually treated using factorization techniques. This involves separating the calculation into two parts: the hard process, which involves high-energy interactions, and the soft and colinear radiation, which is treated separately using effective theories such as soft-collinear effective theory (SCET) or parton distribution functions (PDFs).
Due to their low energy or momentum, soft and colinear gluons cannot be directly observed in experiments. However, their effects can be indirectly observed through their contributions to the final state particles in high-energy collisions.
The inclusion of soft and colinear gluons in QCD calculations is crucial for achieving accurate results. Neglecting their contributions can lead to large discrepancies between theoretical predictions and experimental data. Therefore, it is essential to accurately model and include these gluons in QCD calculations.