LHCb's new analysis confirms old puzzle

LHCb's new analysis confirms old puzzle
The LHCb analysis presented at the Moriond Electroweak conference; the black points show the measurements released today. The LHCb analysis presented at the Moriond Electroweak conference; the black points show the measurements released today.

Today, at the 50th Moriond Electroweak conference (link) (La Thuile, Italy), LHCb physicists presented their latest analysis of the rare B → K*μμ decay. The new results show deviations from Standard Model calculations.

The LHCb experiment searches for new physics by looking for the effects of new in rare decays. These "indirect searches" allow them to probe mass scales inaccessible by other techniques. "This is quantum mechanics magic," said LHCb spokesperson Guy Wilkinson. "Like in the well-known - n → peν - that is now understood to be caused by the exchange of the W boson, 100 times heavier than the proton itself, we look at this B decay to explore interactions involving particles even 10 times heavier or more than the W boson."

In this search, LHCb physicists have been studying the angular distribution of the particles coming from the B → K*μμ decay. These angular observables are highly sensitive to the effects of new particles on the decay. "The decay B → K*μμ is a laboratory on its own," said Patrick Koppenburg, LHCb Physics Coordinator. "Many of the particles that CERN experiments search for in their data can be studied in this decay."

In their analysis of the full LHC Run 1 data set, LHCb physicists found the angular observable P5' to have a local deviation from Standard Model calculations. As seen in the graph above, the measurements (in black) in the muon pair mass (q2) region between 4 and 8 GeV2/c4 both show a 2.9 sigma deviation from the Standard Model calculations. The results confirm a previously published analysis using 2011 LHCb data (in blue).

"The new analysis agrees with the previous result, and tells us that there are very important questions to be answered associated with this decay. But it does not yet tell us what is the cause," said Christoph Langenbruch, LHCb physicist who presented the results today.

The new B → K*μμ results are certain to draw the attention of worldwide, as theorists consider the many possible implications. Theoretical predictions of the Standard Model values (in orange on the graph) are also expected to be further improved.


Explore further

LHCb experiment squeezes the space for expected new physics

More information: Read more about the new result on the LHCb public page: lhcb-public.web.cern.ch/lhcb-p … lic/Welcome.html#P5p
Provided by CERN
Citation: LHCb's new analysis confirms old puzzle (2015, March 23) retrieved 21 August 2019 from https://phys.org/news/2015-03-lhcb-analysis-puzzle.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.
58 shares

Feedback to editors

User comments

Mar 26, 2015
The article concludes: "The new B → K*μμ results are certain to draw the attention of physicists worldwide, as theorists consider the many possible implications." The major implication is that, once gain, unwarranted assumption of continuous space-time has produced distorted predictions at this level of fineness, compared to the precision possible with quantized space, time and energy in binary mechanics.

And "Theoretical predictions of the Standard Model values (in orange on the graph) are also expected to be further improved." ...which cannot be done without adding new fudge-factors to the discredited mathematical treatment in the SM (ref: "If you want to keep your Higgs boson..." J Binary Mech).


Please sign in to add a comment. Registration is free, and takes less than a minute. Read more