The missing energy is just one "dimension" to the problem. In practice, you need many more (generalized) "coordinates". Different physics will show different behaviors in the interplay (correlations) between those coordinates, which has to be studied by simulation but is not necessarily model-dependent(*). In the literature, this us called "signature" for dark-matter for instance.kashiark said:It is my understanding that physicists hope to use conservation of energy in the LHC to determine if there are multiple dimensions AND if there is dark matter
Depending on which reaction exactly, it may or may not be done on an event-by-event basis. But given the entire sample, using statistical analysis, yes. You may want to read about "Dalitz plots" for instance. Note that, otherwise (if they could not determine the mass of the missing particle), they would simply not understand anything !kashiark said:So with all of that other information they can determine how much of the missing energy is actually the mass of the particle?
Extra dimensions refer to theoretical dimensions beyond the three spatial dimensions (length, width, and height) that we experience in our everyday lives. They are a key concept in many theories that attempt to unify the fundamental forces of nature. In the context of the Large Hadron Collider (LHC), extra dimensions are being investigated as a possible explanation for the existence and properties of dark matter.
The LHC is the world's largest and most powerful particle accelerator, capable of producing high-energy collisions between particles. By analyzing the particles and energy produced in these collisions, scientists can search for evidence of extra dimensions and dark matter. The LHC's detectors are specifically designed to capture and measure the properties of these particles, providing valuable data for researchers.
So far, the LHC has not found direct evidence of extra dimensions or dark matter. However, the data collected by the LHC has allowed scientists to rule out certain theories and parameters related to these concepts. This has helped to narrow down the search and guide future experiments and studies.
Extra dimensions and dark matter are both important concepts in our quest to understand the fundamental laws of the universe. If extra dimensions exist, it could help to explain why gravity is so much weaker than the other fundamental forces. Dark matter, on the other hand, is thought to make up about 85% of the total matter in the universe and its existence is crucial to our understanding of the dynamics of galaxies and the large-scale structure of the universe.
The LHC is currently undergoing a major upgrade, known as the High-Luminosity LHC, which will significantly increase its collision rate and sensitivity to rare processes. This will allow scientists to search for signals of extra dimensions and dark matter with even greater precision. In addition, other experiments and theoretical studies are also being conducted to further explore these concepts and their potential implications for our understanding of the universe.