1. Prospecting for Gold: Particle Detectors
What does a particle detector need to do?
The first particle detectors
The unique challenges of modern detectors
Rising to the challenge - let’s design a detector!
The LHC detectors and components
What might physicists get excited about in a few years from now?
BA Festival of Science, York, 14th September 2007
David Barney, CERN

2. What does a particle detector need to do?
Need to determine:
What particles do we see?
Where did they come from and where do they go?
What were their energies and momenta?
In order to understand:
What happened in a collision between particles?
Has something interesting been created?
Sometimes the “interesting” things decay to lighter (stable) particles
Need to focus on the stable particles and be “detectives” – work out what happened from the evidence left behind
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

3. The first particle detectors
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
Liquid hydrogen “bubble chamber”
The hydrogen acts as a target (for incoming particles) and a detector
BA Festival of Science, York, 14th September 2007
David Barney, CERN

4. The first particle detectors
Aircraft leaving “contrails” in the sky
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

5. The first particle detectors
Particle colliding with a proton in liquid hydrogen
- A “Bubble Chamber”
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

6. The challenges of modern detectors
We don’t really know what we are looking for!
The “interesting” things we are looking for are very rare
Need to make millions of collisions every second!
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

7. The challenges of modern detectors
Each collision produces many hundreds of particles
The energies/momenta of the particles involved are huge
The detectors are very complex and have many layers
They also need to be big!
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
VERY BIG!!
BA Festival of Science, York, 14th September 2007
David Barney, CERN

8. A “simple” collision at LHC (simulation)
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
Higgs  4 muons
Where are the muons?
Red lines show the muons (cheating!)
BA Festival of Science, York, 14th September 2007
David Barney, CERN

9. Let’s add a magnetic field!
Charged particles bend in the magnetic field
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
The lower the particle momentum (~speed) the more they bend.
Now the muons are clear!
BA Festival of Science, York, 14th September 2007
David Barney, CERN

10. A typical detector for the LHC #1
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
The “CMS” detector for LHC
Each colour shows a different layer
This is the view along the beam direction
BA Festival of Science, York, 14th September 2007
David Barney, CERN

11. Let’s design a detector #1
Start with a BIG and powerful magnet!
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

12. The “Gothic Cathedrals of the 21st Century”
ATLAS
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

13. A basic “Tracker”
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
Multiple thin layers of, for example, silicon sensors
BA Festival of Science, York, 14th September 2007
David Barney, CERN

14. CMS Tracker Many layers of silicon sensors
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
Many layers of silicon sensors
BA Festival of Science, York, 14th September 2007
David Barney, CERN

15. Let’s design a detector #2
Calorimeters – to measure the energies of different types of particle
Electromagnetic – sensitive to photons, electrons, positrons
Hadronic – sensitive to “hadrons” (particles containing quarks) such as protons, neutrons, pions etc.
The calorimeters “stop” the incoming particles so must go outside of the “tracker”
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

16. A basic calorimeter
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
Total # of particles is proportional to energy of incoming particle
Light materials (green) produce a signal proportional to the number of charged particles traversing
BA Festival of Science, York, 14th September 2007
David Barney, CERN

17. ATLAS tile calorimeter
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

18. CMS Electromagnetic Calorimeter Crystals
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
Lead tungstate (PbWO4) crystals nearly as dense as lead!
BA Festival of Science, York, 14th September 2007
David Barney, CERN

19. Let’s design a detector #3
Need to identify the different types of particle
Combination of signals in the tracker and calorimeters can identify many particles
Also have dedicated sensors for muons
These are the only particles that travel all the way through the calorimeters without stopping
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

20. A typical detector for the LHC #2
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

21. A typical detector for the LHC #3
Cylindrical detector: “capture” as many produced particles as possible
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
3-D view of CMS
BA Festival of Science, York, 14th September 2007
David Barney, CERN

22. The two giant detectors for the LHC
ATLAS
CMS
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

23. The “Gothic Cathedrals of the 21st Century”
CMS
2000 tonnes 15m diameter
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

24. The “Gothic Cathedrals of the 21st Century”
CMS detector 100m underground
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

25. The “Gothic Cathedrals of the 21st Century”
The ATLAS detector 100m underground
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

26. In the CMS cavern #1 (VR panorama by Peter McReady)
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

27. In the CMS Cavern #2 BA Festival of Science, York, 14th September 2007
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

28. What might a real Higgs event look like?
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
2 muons
2 electrons
BA Festival of Science, York, 14th September 2007
David Barney, CERN

29. The physicist’s gold!
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
IF the Higgs particle exists & IF it has a mass around 130 GeV
This is the signal we will see after about a year of running!
BA Festival of Science, York, 14th September 2007
David Barney, CERN

30. Some final thoughts on the technology
The LHC detectors are the most complex scientific instruments ever made
A typical LHC detector has about 100 million individual sensors (c.f. a typical digital camera with ~6 Mpixels)
But it takes a “digital photo” 40 million times every second!
The detectors have to operate for at least ten years with little or no intervention
Technology – sensors and electronics – are cutting-edge
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

31. They come from all over the world - about 80 countries
People
CMS and ATLAS have about 2500 collaborators each, including more than 1000 students!
They come from all over the world - about 80 countries
We have been working on these detectors for the past ~15 years – and they haven’t even started operation yet!
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

32. A mini black-hole produced in ATLAS
Basics
The past
Challenges
Where to start?
Detector Design
Tracker
Calorimetry
Particle ID
LHC detectors
“Events”
Final thoughts
BA Festival of Science, York, 14th September 2007
David Barney, CERN

33. From “EVO” magazine Oct 07
“It’s rather like the Large Hadron Collider, the new giant particle accelerator about to be fired up in Switzerland. Size really does matter. The bigger the bang, the more exciting the result.”
BA Festival of Science, York, 14th September 2007
David Barney, CERN