Detecting Neutral Super-Partner Particles

In summary, the conversation discusses the possibility of detecting neutral super-partner particles, their stability and potential decay into other particles. It also mentions the concept of WIMP as a candidate for dark matter and the difficulty in directly detecting the particles themselves, instead relying on their decay products and collision processes. There is also mention of using invariant mass measurements to confirm the existence of the particles.
  • #1
indigojoker
246
0
If SUSY particles existed, is it possible for detectors to pick up on neutral super-partner particles? or would they pass the detector like neutrinos?
 
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  • #2
All neutral particles are harder to detect than charged particles. There is no general rule - each particle is detectable by its specific collision possibilities.
 
  • #3
If they are stable, they would not be detectable and would appear as missing energy in a collision. If not, they would decay into other particles which could be detectable.
 
  • #4
There is a related concept: WIMP, a Weakly Interacting Massive Particle. Not sure if it is the same than the stable, not decaying, superparticle. Candidates for dark matter.
 
  • #5
Indeed, the lightest neutral super-symmetric particles particles would appear as large missing transverse energy in the case where they are stable (when R parity is conserved).

Adrian Buzatu, Clubul Fizica Particulelor, http://fizicaparticulelor.ro
 
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  • #6
We do not expect to detect the particle but its disintegration products and/or the cross-sectiond of the colision process.
 
  • #7
Indeed, we can detected experimentally the charged decay products and reconstruct an invariant mass for different decay products, for many experiments and if in many cases we obtain more or less the same value, we could guess there is a particle with a distribution of invariant mass that is decaying into the daughter particles that we detect.

Adrian Buzatu, Clubul Fizica Particulelor http://fizicaparticulelor.ro
 
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What are neutral super-partner particles?

Neutral super-partner particles are hypothetical particles that are predicted by supersymmetry, a theory that suggests every known particle has a super-partner particle with a different spin. These super-partner particles are expected to have the same mass as their corresponding known particles, but they have different properties such as electric charge and spin.

How can we detect neutral super-partner particles?

Currently, there is no direct experimental evidence for the existence of neutral super-partner particles. However, scientists are working on various experiments and theories to detect these particles. Some proposed methods include using the Large Hadron Collider (LHC) to produce and detect these particles, as well as indirect methods such as studying the decay patterns of known particles.

What is the importance of detecting neutral super-partner particles?

Detecting neutral super-partner particles would provide evidence for the validity of supersymmetry and help us understand the fundamental forces and interactions of the universe. It could also potentially solve some of the unanswered questions in physics, such as the hierarchy problem and the nature of dark matter.

What are some challenges in detecting neutral super-partner particles?

One of the main challenges in detecting neutral super-partner particles is their high mass, which makes them difficult to produce and detect. Additionally, the super-partner particles may have a short lifetime, making it challenging to observe them before they decay into other particles. The lack of direct evidence for these particles also makes it challenging to design experiments and theories to detect them.

What are some other implications of detecting neutral super-partner particles?

If neutral super-partner particles are detected, it would have significant implications for our understanding of the universe. It could provide evidence for theories beyond the Standard Model of particle physics and potentially open up new avenues for technological advancements. Additionally, it could help us understand the origin of mass and potentially lead to new discoveries in the field of cosmology.

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