The Large Hadron Collider (LHC) has been fired up again after a three year break for maintenance and upgrades – with the first beam sent around the tunnel just before 10am BST this morning.
The LHC works by smashing atoms together to break them apart and discover the subatomic particles that exist inside them, and how they interact.
CERN, the European Organization for Nuclear Research, shut down the collider in 2019, so that it could carry out work to make the instruments more sensitive.
This will give researchers a higher resolution view inside atoms – capturing data 30 million times per second – and allow more runs.
Firing up the nearly 17 mile-long LHC is a complex process, requiring everything to ‘work like an orchestra’, especially after the extended shut down due to Covid-19.
‘It’s not flipping a button,’ explained Rende Steerenberg, in charge of control room operations at CERN in Switzerland, where the collider control room is based.
‘This comes with a certain sense of tension, nervousness,’ he explained, adding that a lot can go wrong, including obstructions in the tunnel and issues with magnets.
Particle physicists hope the upgrades will help them discover a new fundamental force of nature, to add to the four basic forces – gravitational, electromagnetic, strong, and weak – and help explain the underpinnings of the universe.
Another hope is that the resumption of collisions will help in the quest for so-called ‘dark matter’ that lies beyond the visible universe and makes up most of the matter in the known universe, according to researchers.
CERN operates the Large Hadron Collider, the world’s largest and most powerful particle accelerator (pictured) famous for its 2012 discovery of the Higgs Boson
THE LARGE HADRON COLLIDER
The Large Hadron Collider (LHC) is the world’s largest and most powerful particle accelerator.
It is located in a 27-kilometer (16.8-mile) tunnel beneath the Swiss-French border.
The LHC started colliding particles in 2010. Inside the 27-km LHC ring, bunches of protons travel at almost the speed of light and collide at four interaction points.
Inside the accelerator, two high-energy particle beams travel at close to the speed of light before they are made to collide. The beams travel in opposite directions in separate beam pipes.
They are guided around the accelerator ring by a strong magnetic field maintained by superconducting electromagnets.
The electromagnets are built from coils of special electric cable that operates in a superconducting state, efficiently conducting electricity without resistance or loss of energy.
These collisions generate new particles, which are measured by detectors surrounding the interaction points.
By analysing these collisions, physicists from all over the world are deepening our understanding of the laws of nature.
Potential pitfalls facing the startup team included the discovery of an obstruction, and the shrinking of materials due to a nearly 300 degree temperature swing.
They also faced the chance of developing difficulties with thousands of magnets that help keep billions of particles in a tight beam as they circle the collider tunnel beneath the Swiss-French border.
Steerenberg said the system had to work ‘like an orchestra,’ explaining that ‘in order for the beam to go around all these magnets have to play the right functions and the right things at the right time.’
On Friday, particles were pushed through the collider’s almost 17-mile ring for the first time since December 2018.
However, it will take six to eight weeks for the LHC to get up to full speed, at which point proton collisions can take place again.
Head of Cern’s Beams department, Rhodri Jones, said: ‘These beams circulated at injection energy and contained a relatively small number of protons.
‘High-intensity, high-energy collisions are a couple of months away.
‘But first beams represent the successful restart of the accelerator after all the hard work of the long shutdown.’
The batch of LHC collisions observed at CERN between 2010-2013 brought proof of the existence of the long-sought Higgs boson particle.
Along with its linked energy field, this particle is thought to be vital to the formation of the universe after the Big Bang 13.7 billion years ago.
But plenty remains to be discovered by particle physicists, and the upgrades will allow them to peer deeper into the hidden quantum realm than ever before.
It will also potentially help in the discovery of the underpinnings of the larger universe, by allowing for an understanding of dark matter.
Dark matter is thought to be five times more prevalent than ordinary matter but does not absorb, reflect or emit light. Searches have so-far come up empty-handed.
‘We are going to increase the number of collisions drastically and therefore the probability of new discoveries also,’ said Steerenberg, who added that the collider was due to operate until another shutdown from 2025-2027.
The LHC first went live on 10 September 2008, and despite a few glitches taking it offline, everything it has discovered has fallen in line with the standard model.
This is the primary, guiding theory of particle physics, developed in the 1970s – but there are issues with it, as it fails to explain some aspects of physics.
A general view of the Large Hadron Collider (LHC) experiment during a media visit at the Organization for Nuclear Research (CERN) in 2014
Data collected during one LHC experiment appeared to show that particles can behave in a way not explained by the standard model, which also doesn’t explain dark matter.
This experiment, into the decay of particles known as beauty quarks, found they turned into muons 15 per cent less often than predicted.
This suggests there is an unknown factor at play in the universe, and many suspect it is a new type of force tipping the scales. The team plan to run the experiment again using the more sensitive equipment on the revamped LHC.
‘The stakes are extremely high,’ Dr Mitesh Patel, a particle physicist at Imperial College London in charge of the original experiment, told the Guardian.
This 2018 photo made available by CERN shows the LHCb Muon system at the European Organization for Nuclear Research Large Hadron Collider facility outside of Geneva
EXPLAINED: THE STANDARD MODEL OF PHYSICS
The theories and discoveries of thousands of physicists since the 1930s have resulted in a remarkable insight into the structure of matter.
Everything in the universe is found to be made from a few basic building blocks called fundamental particles, governed by four fundamental forces.
Our best understanding of how these particles and three of the forces are related to each other is encapsulated in the Standard Model.
All matter around us is made of elementary particles, the building blocks of matter.
These particles occur in two basic types called quarks and leptons. Each consists of six particles, which are related in pairs, or ‘generations’.
All stable matter in the universe is made from particles that belong to the first generation. Any heavier particles decay to the next most stable level.
There are also four fundamental forces at work in the universe: the strong force, the weak force, the electromagnetic force, and the gravitational force.
The Standard Model includes the electromagnetic, strong and weak forces and all their carrier particles, and explains well how these forces act on all of the matter particles.
However, the most familiar force in our everyday lives, gravity, is not part of the Standard Model, and fitting gravity comfortably into this framework has proved to be a difficult challenge.
‘If we confirm this, it will be a revolution of the kind we’ve not seen – certainly in my lifetime. You don’t want to mess it up.’
In 2018 the team suggested the odds of the discovery they made happening by chance was one in a thousand, but for a new force of nature to be declared, the gold standard is one in 3.5 million.
So they need more data to prove it wasn’t just a glitch in the equipment or the experiment design.
This latest upgrade marks the start of the third run of the LHC, and included the installation of more powerful magnets that squeeze protons inside the collider into denser beams – increasing the collision rate of particles.
Scientists will be able to use this to observe more events, rarer events and do so with much more precision than would previously have been possible.
Mike Lamont, CERN’s Director for Accelerators and Technology, said the LHC will operate at an even higher energy and, thanks to major improvements in the injector complex, it will deliver significantly more data to the upgraded LHC experiments.
Teams across the world have helped the Large Hadron Collider reach record-breaking energy levels for its third physics run.
UK teams have led a series of vital work packages to improve the performance of each of the LHC’s four main instruments.
The UK’s contributions to the upgrade are worth more than £25 million, funded by the Science and Technology Facilities Council (STFC).
Executive Chair of STFC and particle physicist Professor Mark Thomson said this continues a ‘strong and fruitful’ relationship between the UK and CERN.
‘It will never cease to impress me how our scientists and engineers, with their incredible skill and expertise, can continue to improve these cutting-edge facilities using ever-more innovative technologies.
‘The global science community will now eagerly await the results from the new run, which will probe some of the recent hints of new physics seen at the LHC and elsewhere.’
Science Minister George Freeman said: ‘Through our leading role in global projects of this scale the UK is building on a role as a global science superpower and helping retain the highest calibre of talented scientists in the UK.’
UK-LED ACTIVITIES AT THE LARGE HADRON COLLIDER
LHCb (Large Hadron Collider beauty)
The LHCb experiment studies the differences between matter and antimatter by investigating the decay of a type of particle called the ‘b quark’.
The collaboration has undergone a major technology upgrade to allow an increased collision rate of the LHC.
When the LHC restarts, the proton–proton collision rate at LHCb will be increased by a factor of five.
Vertex Locator (VELO) detector upgrade (UK universities of Glasgow, Liverpool, Manchester, Oxford and Warwick)
The UK leads development of the new VELO, which is designed to act like a camera taking ‘pictures’ 40 million times per second to image particles produced in the LHCb experiment.
The beauty particles, that give the experiment its name, travel only a few millimetres before decaying. The detector is located only 5 mm from the proton-proton collisions in order to identify these beauty particles.
RICH (Ring Imaging Cherenkov) particle identification (PID) system (UK universities Birmingham, Bristol, Cambridge, Edinburgh, Imperial College London, and STFC Rutherford Appleton Laboratory)
The ring-imaging Cherenkov (RICH) detectors, which determine particles’ identities, are equipped with new photon detectors, mechanics and mirrors.
Cones of light are emitted by travelling particles and are deflected and focussed onto an array of detectors. The new system will perform in an environment of much larger particle densities.
ALICE (A Large Ion Collider Experiment)
ALICE is a heavy-ion detector used to characterise a specific state of matter created under extreme temperature and energy density – quark-gluon plasma.
The ALICE-UK Collaboration plays a leading role in the ALICE Upgrade at the LHC. ALICE-UK has developed and built upgrades for the Central Trigger Processor (CTP) and the Inner Tracking System (ITS).
ATLAS (A Toroidal LHC Apparatus)
ATLAS is a general-purpose detector designed to record high-energy particle collisions of the LHC.
· Upgraded Level 1 Calorimeter Trigger
The calorimeter upgrade aim is to keep a low trigger rate, thanks to the background rejection, and to keep low thresholds, thanks to the higher geometrical resolution. UK groups have led these activities.
· Upgraded High Level Trigger
The UK group leads the placement of new data read-out boards along with new multi-threaded software to maximise the efficiency and flexibility of current data-taking.
· Analysis upgrades
The UK group leads the creation of innovative new data-taking streams which will allow novel analyses to take place.
· Phase II upgrades
Construction of pixel and strip detectors is currently underway. In addition, the High Level Trigger and Data Acquisition will also undergo many upgrades for Phase II, aiming at trigger granularity that will enable the management of a much higher rate of data with finer grained information.
CMS (Compact Muon Solenoid)
The CMS detector is a general-purpose detector built around a huge solenoid magnet used to bend the paths of particles from collisions in the LHC.
· Upgrade of CMS tracker (Brunel University London, Imperial College London, University of Bristol, STFC Rutherford Appleton Laboratory)
Upgrades are required to cope with the anticipated increase in the beam luminosity of the LHC.
Large parts of the detector will be replaced including areas that the UK is strongly engaged in namely the trackers, the electromagnetic calorimeter and entire endcap calorimeter and the fast electronics used for triggering.
The new systems are all designed to cope with the harsh environment of the High Luminosity LHC.