Targets

3.2 Targets

There are two ways to make the necessary collisions with the accelerated beam: Fixed target and colliding beams.

In ﬁxed target mode the accelerated beam hits a target which is ﬁxed in the laboratory. Relativistic kinematics tells us that if a particle in the beam collides with a particle in the target, their centre-of-mass (four) momentum is conserved. The only energy remaining for the reaction is the relative energy (or energy within the cm frame). This can be expressed as

E_{C M} = {[m_{b}^{2} c^{4} + m_{t}^{2} c^{4} + 2 m_{t} c^{2} E_{L}]}^{1 ∕ 2}

(3.14)

where $m_{b}$ is the mass of a beam particle, $m_{t}$ is the mass of a target particle and $E_{L}$ is the beam energy as measured in the laboratory. as we increase $E_{L}$ we can ignore the ﬁrst tow terms in the square root and we ﬁnd that

E_{C M} \approx \sqrt{2 m_{t} c^{2} E_{L}},

(3.15)

and thus the centre-of-mass energy only increases as the square root of the lab energy!

In the case of colliding beams we use the fact that we have (say) an electron beam moving one way, and a positron beam going in the opposite direction. Since the centre of mass is at rest, we have the full energy of both beams available,

E_{C M} = 2 E_{L} .

(3.16)

This grows linearly with lab energy, so that a factor two increase in the beam energy also gives a factor two increase in the available energy to produce new particles! We would only have gained a factor $\sqrt{2}$ for the case of a ﬁxed target. This is the reason that almost all modern facilities are colliding beams.

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