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LHC experiments are back in business at a new record energy

Geneva, 3 June 2015. Today, CERN1's Large Hadron Collider (LHC) started delivering physics data for the first time in 27 months. After an almost two year shutdown and several months re-commissioning, the LHC is now providing collisions to all of its experiments at the unprecedented energy of 13 TeV, almost double the collision energy of its first run. This marks the start of season 2 at the LHC, opening the way to new discoveries. The LHC will now run round the clock for the next three years.


* For photos, videos and the webcast, please see here *

Geneva, 3 June 2015. Today, CERN1's Large Hadron Collider (LHC) started delivering physics data for the first time in 27 months. After an almost two year shutdown and several months re-commissioning, the LHC is now providing collisions to all of its experiments at the unprecedented energy of 13 TeV, almost double the collision energy of its first run. This marks the start of season 2 at the LHC, opening the way to new discoveries. The LHC will now run round the clock for the next three years.

With the LHC back in the collision-production mode, we celebrate the end of two months of beam commissioning,” said CERN Director of Accelerators and Technology Frédérick Bordry. “It is a great accomplishment and a rewarding moment for all of the teams involved in the work performed during the long shutdown of the LHC, in the powering tests and in the beam commissioning process. All these people have dedicated so much of their time to making this happen.

Today at 10.40am, the LHC operators declared “stable beams”, the signal for the LHC experiments that they can start taking data. Beams are made of “trains” of proton bunches moving at almost the speed of light around the 27 kilometre ring of the LHC. These so-called bunch trains circulate in opposite directions, guided by powerful superconducting magnets. Today the LHC was filled with 6 bunches each containing around 100 billion protons. This rate will be progressively increased as the run goes on to 2808 bunches per beam, allowing the LHC to produce up to 1 billion collisions per second2.

During the first run of the LHC, the ATLAS and CMS experiments announced the discovery of the so-called Higgs boson, which was the last piece of the puzzle known as the Standard Model, a theory that describes the fundamental particles from which everything visible in the universe is made, along with interactions at work between them.

The first 3-year run of the LHC, which culminated with a major discovery in July 2012, was only the start of our journey. It is time for new physics!” said CERN Director General Rolf Heuer. “We have seen the first data beginning to flow. Let’s see what they will reveal to us about how our universe works.

With run 2 starting today, physicists have the ambition to further explore the Standard Model and even to find evidence of new physics phenomena beyond its boundaries, which could explain remaining mysteries such as dark matter, believed to make up about a quarter of the universe, or nature’s apparent preference for matter over antimatter, without which we would not exist3.

Over the two-year shutdown, the four large experiments ALICE, ATLAS, CMS and LHCb also went through an important programme of maintenance and improvements in preparation for the new energy frontier4.

The collisions we are seeing today indicate that the work we have done in the past two years to prepare and improve our detector has been successful and marks the beginning of a new era of exploration of the secrets of nature,” said CMS spokesperson Tiziano Camporesi. “We can hardly express our excitement within the collaboration: this is especially true for the youngest colleagues.”

The successful restart of physics data-taking, with all systems in great shape to collect, process and analyse the new data quickly, is a testament to the commitment and immense hard work of very many people from across ATLAS during the long shutdown,” said ATLAS spokesperson Dave Charlton. “We are now starting to delve into the new data to see what nature has in store for us at these new unexplored energies.

“All within the collaboration are tremendously excited that the new run has now begun,” said LHCb spokesperson Guy Wilkinson. “It will allow us to follow up on puzzles from our run-1 studies, and to probe with higher sensitivity the difference in behaviour between matter and antimatter.”

"Proton-proton collisions will provide essential reference data for the run with heavy-ion beams foreseen for the end of the year, in which the LHC will provide both higher energy and luminosity as compared to run 1,” said ALICE spokesperson Paolo Giubellino. “In addition, we plan to extend the exploration of the intriguing signals that have emerged from Run 1.”

In addition to these large collaborations, three smaller experiments – TOTEM, LHCf and MoEDAL – will be among those searching for new physics at the LHC's new energy frontier of 13 TeV5.

1. CERN, the European Organization for Nuclear Research, is the world's leading laboratory for particle physics. It has its headquarters in Geneva. At present, its member states are Austria, Belgium, Bulgaria, the Czech Republic, Denmark, Finland, France, Germany, Greece, Hungary, Israel, Italy, the Netherlands, Norway, Poland, Portugal, Slovakia, Spain, Sweden, Switzerland and the United Kingdom. Romania is a Candidate for Accession. Serbia is an Associate Member in the pre-stage to Membership. Turkey is an Associate Member. India, Japan, the Russian Federation, the United States of America, the European Union, JINR and UNESCO have observer status.
2. See ‘LHC Season 2: facts & figures’ : http://test-press-everis.web.cern.ch/backgrounders/lhc-season-2-facts-figures
3. See LHC Season 2: New frontiers in physics : http://test-press-everis.web.cern.ch/backgrounders/lhc-season-2-new-frontiers-physics
4. See LHC Season 2: Major work at the experiments for Run 2 : http://test-press-everis.web.cern.ch/backgrounders/lhc-season-2-major-work-experiments-run-2
5. Smaller LHC collaborations to analyse collisions at 13 TeV : http://home.web.cern.ch/about/updates/2015/06/smaller-lhc-collaborations-analyse-collisions-13-tev