Pseudorapidity

In experimental particle physics, pseudorapidity, η {displaystyle eta } , is a commonly used spatial coordinate describing the angle of a particle relative to the beam axis. It is defined as In experimental particle physics, pseudorapidity, η {displaystyle eta } , is a commonly used spatial coordinate describing the angle of a particle relative to the beam axis. It is defined as where θ {displaystyle heta } is the angle between the particle three-momentum p {displaystyle mathbf {p} } and the positive direction of the beam axis. Inversely, As a function of three-momentum p {displaystyle mathbf {p} } , pseudorapidity can be written as where p L {displaystyle p_{ ext{L}}} is the component of the momentum along the beam axis (i.e. the longitudinal momentum – using the conventional system of coordinates for hadron collider physics, this is also commonly denoted p z {displaystyle p_{z}} ). In the limit where the particle is travelling close to the speed of light, or equivalently in the approximation that the mass of the particle is negligible, one can make the substitution m ≪ | p | ⇒ E ≈ | p | ⇒ η ≈ y {displaystyle mll |mathbf {p} |Rightarrow Eapprox |mathbf {p} |Rightarrow eta approx y} (i.e. in this limit, the particle's only energy is its momentum-energy, similar to the case of the photon), and hence the pseudorapidity converges to the definition of rapidity used in experimental particle physics: This differs slightly from the definition of rapidity in special relativity, which uses | p | {displaystyle left|mathbf {p} ight|} instead of p L {displaystyle p_{ ext{L}}} . However, pseudorapidity depends only on the polar angle of the particle's trajectory, and not on the energy of the particle. One speaks of the 'forward' direction in a hadron collider experiment, which refers to regions of the detector that are close to the beam axis, at high | η | {displaystyle |eta |} ; in contexts where the distinction between 'forward' and 'backward' is relevant, the former refers to the positive z-direction and the latter to the negative z-direction. In hadron collider physics, the rapidity (or pseudorapidity) is preferred over the polar angle θ {displaystyle heta } because, loosely speaking, particle production is constant as a function of rapidity, and because differences in rapidity are Lorentz invariant under boosts along the longitudinal axis: they transform additively, similar to velocities in Galilean relativity. A measurement of a rapidity difference Δ y {displaystyle Delta y} between particles (or Δ η {displaystyle Delta eta } if the particles involved are massless) is hence not dependent on the longitudinal boost of the reference frame (such as the laboratory frame). This is an important feature for hadron collider physics, where the colliding partons carry different longitudinal momentum fractions x, which means that the rest frames of the parton-parton collisions will have different longitudinal boosts.