When 2 particle beams meet head on

In summary, when two particle beams collide head on, there is more energy available compared to when the particles are directed at a fixed target. This is due to the Lorentz transformation, which converts energy from the center of mass system to the fixed target system. This is because the particles in accelerators are travelling close to the speed of light, causing an increase in energy through the addition of mass. This can be seen through equations such as Eq 38.3 in the provided source.
  • #1
Masafi
65
0
When 2 particle beams meet head on, more energy is avaliable than when the particle beam is directed at a fixed target. Why is this?

My textbook gives an explanation which I don't understand, involving rest mass energy. Any alternate explanation or explaining the one given will be great.

Thank you
 
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  • #2
To understand it, first look at the low speed case. When two things going at speed x, the relative speed is 2x, so the energy involved is larger than an object hitting a fixed target at speed x.
In particle accelerators, the particles are going close to the speed of light, so the relationship between the particles involves adding energy by adding mass using the Lorentz transformation.
 
  • #3
Look at Eq 38.3 in
http://pdg.lbl.gov/2009/reviews/rpp2009-rev-kinematics.pdf
This equation converts energy in the center of mass system (colliding beams) to fixed target beams. This equation can be derived from either Eq 38.1 or 38.2.

Bob S
 

1. What happens when 2 particle beams meet head on?

When 2 particle beams meet head on, the particles collide and interact with each other. This can result in the creation of new particles or the annihilation of existing particles.

2. How do particle beams collide in experiments?

Particle beams are accelerated and directed towards each other using powerful magnets and electric fields. When the beams are aimed precisely, they collide at high speeds in a designated collision point.

3. What is the purpose of colliding particle beams in experiments?

The purpose of colliding particle beams in experiments is to study the fundamental building blocks of matter and the interactions between them. This can help us understand the laws of physics and the origins of the universe.

4. What types of particles are commonly used in colliding beam experiments?

Protons and electrons are commonly used in colliding beam experiments. However, other types of particles such as antiprotons, positrons, and heavy ions can also be used.

5. How is data collected and analyzed from colliding beam experiments?

Data from colliding beam experiments is collected through detectors that record the particles produced from the collisions. This data is then analyzed using sophisticated software and algorithms to understand the properties and behavior of the particles involved in the collisions.

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