Dope sheet for Video News Release "LHC run2-14 Feb"
https://cds.cern.ch/record/1987384?ln=en
TIME
/FOOTAGE
00:00 – 00:12
/CERN logo, opening credits
00:13 - 00:18
/CERN signage, Entrance "B" on the CERN site
00:19 – 00:34
/Slow panning shots of the Large Hadron Collider (LHC) in its tunnel
00:35 – 00:51
/Workers in green overalls open an interconnection between to superconducting dipole magnets on the LHC
00:52 – 01:09
/Close-ups of opening the interconnection
01:10
/The interconnection from below
01:31
/Close-up of the niobium-tin wires that carry the 11,000 amp current between magnets when the LHC is switched on
01:42
/Sawing open the protective sheath around the interconnection
01:46
/A custom tool designed at CERN closes the protective sheath around the interconnection
02:00
/Welding the sheath back together
02:14
/Shot from above of worker adding a splice to the interconnection to carry the current in case of a fault
02:26
/Closeup – Screwing the splice into place
02:33
/Closing the radiation-protection doors to the LHC tunnel
02:53
/ Studio interview with Frederick Bordry, CERN’s Director for Accelerators and Technology.TRANSCRIPT:
"This work finished in June 2014, and since we have been testing the LHC, to be able to add current in a secure way, and to be able to run the machine at 13 teraelectronvolts (TeV)"
03:03
/"This test work will finish in March, and then afterwards, we will inject beams. That way we have time to prepare the beams to have the first collisions at 13 TeV towards the end of May or the beginning of June."
03:19
/"This is what we expect – we will collide beams together even stronger. Before we collided them at 8 TeV, now we're adding even more energy -imagine nuts that we will be smashing even harder – and this will allow us to look at what is in the structure of these particles."
03:30
/"Physicists are very interested to move into this new era of physics – 13 TeV, nearly double what there was at 8 TeV. We really expect many more collisions at this energy, and we can hope maybe to have new physics. Of course we will better study the Higgs boson – its properties – we have just met this particle, we don't know it well yet. But also, maybe we will find new, supersymmetric particles – new physics, which would explain part of dark matter."
04:03
/Shots of a crowded CERN Control Centre at the LHC restart on 20 November 2009.
04: 17
/Control screens show the status of the LHC's various sectors
04:24
/Close up of a screen with diagnostics of the beams in the LHC
04:27
/High shot of physicists in the CERN Control Centre on 20 November 2009
04:31
/Physicists in the CERN Control Centre cheer, then applaud, as the beam travels around the LHC once again.
04:44
/Physicists in the CERN Control Centre throw their hats in the air and cheer for the beam in the LHC on 20 November 2009
04:48
/Animation showing a circulating beams of protons as they travel through CERN's accelerator chain to full velocity in the LHC
05:00
/Animated cross section of a dipole magnet in the LHC. Zoom into the beampipe showing how magnets focus bunches of protons (shown in red)
05:18
/Animated cross section of an LHC dipole, showing how proton bunches are separated in time
05:25
/Magnetic field of a dipole magnet (field shown in green)
05:30
/How the beams are made to travel around the curve of the LHC
05:39
/B-Roll
05:40
/The ATLAS detector
05:46
/The CMS detector
05:57
/The ALICE detector
06:03
/The LHCb detector
06:08
/Animated simulation of beams colliding in the ATLAS detector, producing a Z boson which decays into a muon and an antimuon
06:38
/Researchers applaud in the CERN auditorium on 4 July 2012, when the CMS and ATLAS experiments report they have found the Higgs boson with a mass of 126 GeV
06:44
/A teary Peter Higgs removes his glasses
06: 48
/Further applause from the crowd