‘Q-DAY’ could be a calamity to mankind: BTQ product head
2 Days Ago
Another Zuckerfuck Actor.
"Google leading the Way"
Misinformation, fear, panic, Bad Actors attempting to Hijack "Q".
Fuckery at the Front Line.
https://www.youtube.com/watch?v=SZh9fHPqqKw
"Up to…"
Meaning, barely any at some Camp Snoopy day Spa.
5 Years is not enough for TREASON.
Musk is a Rat
Highest paid Pickle Contractor
Pulled into the front lines, working for "Deal."
But, we see, we know, and are fucking tired of the bullshit show.
He had no problem being the one, fucking the entire world over for the "Billionaire" status. Not one ounce of remorse.
571
Jan 21, 2018 2:25:40 PM EST
Q !UW.yye1fxo ID: 000000 No. 48
@Jack, MZ, ES, JB, EM, SH, MSM, etc.
Do you know that we know?
Do you know that we see all?
Do you know that we hear all?
FEAR the STORM.
NOBODY PLAYING THE GAME GETS A FREE PASS.
NOBODY.
Q
>She is a whore this bitch
Wouldn't know who you're referring to, since anon filtered the spamshill
Not Wasting Energy on Shills
Just Curious if Homan is Investigating City Mayors, who allow their cities to be overrun with Drugs and Homeless Zombies, and appear to be working in conjunction with Cartels and Dirty Cops in Gangs.
Cause, there are MANY.
4532
Jun 26, 2020 8:20:15 PM EDT
Q !!Hs1Jq13jV6 ID: 1ed764 No. 9760164
As the darkness falls so does our enemies.
Q
“We Waited 5,000 Years for This”: CERN Detects Two Ultra-Rare God Particle Decays That Could Rewrite Particle Physics
In a groundbreaking achievement, CERN's ATLAS collaboration has detected two of the rarest Higgs boson decays, potentially unlocking new pathways to explore the universe's fundamental structure.
In the fascinating world of particle physics, the Higgs boson, often called the God particle, remains one of the most enigmatic elements. Its detection and study can reveal fundamental truths about the universe, yet its behaviors are frustratingly elusive. Recently, the ATLAS collaboration at CERN has made significant strides in understanding some of the rarest decays of the Higgs boson. These discoveries not only enhance our grasp of the particle itself but also open new pathways to explore the fabric of the universe. The results of these experiments are not just scientific milestones; they are keys to unlocking mysteries that have perplexed physicists for decades.
Catching the Rare Decays with High Confidence
The journey to uncover the rare decays of the Higgs boson, such as its transformation into a pair of muons (H→μμ) or into a Z boson and a photon (H→Zγ), has been an arduous one. These events occur so infrequently, in merely one out of every 5,000 Higgs decays, that identifying them required extraordinary precision. The ATLAS collaboration, comprised of dedicated scientists from around the globe, has been at the forefront of this research. Utilizing the immense capabilities of the Large Hadron Collider (LHC) at CERN, they meticulously gathered data across multiple experimental runs.
Their task was daunting: to detect a faint signal amid the overwhelming background noise of other particle interactions. By combining datasets from LHC Runs 2 and 3, the team managed to refine their search parameters. This fusion of data allowed them to isolate the events that hinted at the rare Higgs decays. For the H→μμ decay, the scientists searched for a distinct bump in the muon pair’s mass at 125 GeV, the known mass of the Higgs boson. Meanwhile, the H→Zγ decay presented an even more formidable challenge, demanding innovative solutions.
New Methods to Improve Sensitivity of Search
To tackle the complexities of identifying the H→Zγ decay, the ATLAS team had to develop new analytical techniques. The Z boson in this decay only breaks down into electron or muon pairs a minuscule six percent of the time. Compounding the difficulty, photons are challenging to distinguish from particle jets generated in other processes. The team categorized events based on the Higgs production method and refined their selection criteria to sharpen their detection capabilities.
These efforts bore fruit: the team achieved a 3.4 standard deviation significance for the H→μμ decay, indicating that the result is unlikely (with a probability of one in 3,000) to be a mere statistical anomaly. This was a substantial improvement over past results, which only hinted at the decay with a lower significance level. For the H→Zγ decay, they observed an excess signal with 2.5 standard deviations, marking a crucial advancement from previous findings. These achievements underscore the importance of innovation and adaptability in scientific research.
Moar
Go Ask Alice
WE Own Switzerland.
https://www.energy-reporters.com/news/we-waited-5000-years-for-this-cern-detects-two-ultra-rare-god-particle-decays-that-could-rewrite-particle-physics/
Unsure of that Resolve at this point.
Hopium ran out in 2016
I've No More F***s To Give (With Tom Carradine)