Why was Higgs not discovered at Tevatron?

In summary, the Tevatron was able to identify an excess in decay processes in a certain energy range, but it did not have enough events or luminosity to produce statistically significant results to confirm the Higgs. This was due to either the low cross-section at their energy or the low luminosity. The results were at a 2.9 sigma level, which is below the standard 5 sigma required for a discovery.
  • #1
Silversonic
130
1
As far as I can tell Tevatron was able to identify relative to background an excess in decay processes in the range from 105 to 145 GeV. But what was different with Tevatron that didn't allow it to discover the Higgs before the LHC? The LHC had double the CM-energy but the Higgs could've still been produced at Tevatron. Was the Higgs cross section at Tevatron's 2TeV too low to produce statistically significant results to confirm the Higgs? I have looked around but haven't come across a straight up answer.
 
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  • #2
The Tevatron results for the Higgs were at only the 2.9 sigma (= 2.9 standard deviations) level of statistical significance. A long-standing convention in experimental HEP is that you need at least 5 sigma in order to claim a discovery.

They didn't have enough events either because the cross-section was too low at their energy, as you suggest, or the luminosity (basically the number of collisions per second that could lead to Higgs production) was too low. I don't know which factor was more important.
 
  • #4
jtbell said:
The Tevatron results for the Higgs were at only the 2.9 sigma (= 2.9 standard deviations) level of statistical significance. A long-standing convention in experimental HEP is that you need at least 5 sigma in order to claim a discovery.
5 sigma ("there is something unless we made a measurement error") is usually called an observation, 3 sigma ("there could be something but we are not sure") is often called discovery.
 

1. Why was Higgs not discovered at Tevatron?

The Tevatron was a particle accelerator located at Fermilab in the United States. It operated from 1983 to 2011 and was designed to reach energies of up to 1 TeV. However, the energy required to produce a Higgs boson was higher than what the Tevatron could provide. The Higgs boson was eventually discovered at the Large Hadron Collider (LHC) at CERN, which has a much higher energy reach of 13 TeV.

2. What is the significance of the Higgs boson?

The Higgs boson is a fundamental particle in the Standard Model of particle physics. It is responsible for giving other particles mass through the Higgs mechanism. Its discovery confirmed the existence of the Higgs field, which is believed to permeate the entire universe and give particles their mass. This discovery was a major milestone in our understanding of the fundamental building blocks of the universe.

3. Could the Tevatron have discovered the Higgs if it had operated for longer?

It is unlikely that the Tevatron would have been able to discover the Higgs even if it had operated for longer. The energy reach of the Tevatron was simply not high enough to produce a Higgs boson. In addition, the LHC was able to collect much more data in a shorter amount of time, making it more likely to find rare particles like the Higgs.

4. Did the Tevatron contribute to the discovery of the Higgs in any way?

Although the Tevatron did not directly discover the Higgs boson, it did contribute to the overall understanding of the particle and its properties. Scientists at the Tevatron were able to exclude certain energy ranges where the Higgs could potentially exist, which helped guide the search at the LHC. The Tevatron also provided valuable data for other research projects and experiments, contributing to our overall knowledge of particle physics.

5. Are there any other reasons why the Tevatron did not discover the Higgs?

Aside from its energy limitations, the Tevatron also did not have the same level of precision as the LHC in detecting particle collisions. The LHC is a newer and more advanced accelerator, with better detectors and technology. Additionally, the Tevatron was decommissioned in 2011, while the LHC continues to operate and make groundbreaking discoveries in particle physics.

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