The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.

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The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme.
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Presentation transcript:

The HiLumi LHC Design Study is included in the High Luminosity LHC project and is partly funded by the European Commission within the Framework Programme 7 Capacities Specific Programme, Grant Agreement Vibration studies for civil engineering work in Point 1/5 Miriam Fitterer, Gianluigi Arduini, S. Fartoukh Acknowledgments: W. Bialowons, X. Buffat, R. De Maria, W. Herr, W. Höfle, B. Holzer, M. Giovannozzi, M. Guinchard, S. Redaelli, F. Schmidt, D. Schulte, F. Zimmermann

2 Outline 1.Effect of vibrations on the beam 2.Ground motion and vibrations at DESY (HERA and PETRAIII) 3.Amplification of vibrations 4.Orbit deviation estimates Run III 5.Emittance growth estimates Run III 6.Summary and next steps

3 Effect of vibrations on the beam main effects of vibrations (tunneling/construction work) on beam: -> causes displacement of magnets, which can in turn cause:  slow movement of the ground (week/months) during and after the construction (detector and magnets) -> correction of orbit necessary, so that beam is guided through the center of the magnets -> more frequent alignment campaigns to avoid reaching the corrector strength limit  orbit deviations (several hours = 1 fill), which are particularly critical at the IP and at the collimators. Note: at the moment the orbit feedback is off when in stable beams  effects of vibrations on the beam (< 1 hour): emittance growth (see later estimates): in general two regimes are distinguished: - “high frequency” [5], f > 3 kHz : overlap with betatron sidebands at (ν x/y -n)∙f rev,LHC - “low frequency” [4], 0<f< 3 kHz : ν x/y ∙f 0,LHC = 3485 Hz, less harmful stronger population of tails due to interplay of orbit jitter and beam-beam (non-linearities) -> tail generation, higher losses (very difficult to estimate, would require more thorough/long term study) reduction of lifetime

4 Tunnel excavations close to DESY several construction works close to HERA and PETRA:  excavation of the XFEL tunnel (about 500 m? distance) with a “Schildvortriebmaschine” (road heading machine with shield tunneling) during operation of PETRA-III -> no effect but: during construction of the injector Hall, the operation of PETRA-III was disturbed whenever the “Schlitzwandbagger” (bagger shovel for making slits for reinforced concrete walls) encountered some hard obstacles  construction of the football stadium right above the HERA tunnel (50 m) -> considerable disturbances of HERA, e.g. increase of tail population, correction of orbit to compensate the raise of the ground of the HERA tunnel (kink), …  excavation of the “Elbtunnel” (about 2 km distance) -> no effect Note: PETRA is in general less sensitive than the LHC due to its higher revolution frequency, the strong synchrotron radiation damping, its smaller tune spread and smaller beta functions Courtesy to B. Holzer, W. Bialowons

Amplification of Vibrations by structure 2. Oktober Wilhelm Bialowons (DESY), Konstruktionsbesprechung, nm vibration amplitude amplification by structure

6 Amplification of Vibrations by structure low frequency range (10 Hz – 100 Hz) is a superposition of ground motion and excitation of the cryostat and the cold mass => as cryostat ( ~ 30 t, “stiff” metal) and cold mass ( ~ 3 t, “flexible”) have different mass and the frequency spectrum of the cold mass can differ considerably from the one of the cryostat [*] K. Artoos et al., “Mechanical Dynamic Analysis of the LHC Arc Cryo-magnets”, PAC2003 [*]

7 Parameters For tunneling work in Point 1/5 we assume that: 1) only the elements in the straight section at Point 1/5 are effected 2) main effect is displacement of magnets - neglect effect from dipoles D1/D2 - distortion of the beam by quadrupole displacement - no sextupoles in this area => consider only effects due to quadrupole misalignment in Point 1/5 Run III parameters: N bunch =1.25x10 11, ε N =2.0 μm, N tot =2740, β*(IP1/5)=0.4 m (option med RunII), E=6.5 TeV

8 Closed orbit effects closed orbit distortion due to quadrupole misalignment: => stronger effect from quadrupoles with high k*l and high beta-function => main effect expected from inner triplet during collision (closest to tunneling works!!!) Note: - the orbit distortion scales linearly with the misalignment error - the corrector strength scales linearly with the misalignment error

9 Correction of week/months orbit drifts assuming 1mm alignment error on the IT magnets with dx(Q1L)=dx(Q3L)=-1mm, dx(Q2L)=1mm: => in the most unfortunate case, already misalignment larger than 0.8 mm could be right at the limit of the corrector strength (-> more frequent alignment campaigns?) preliminary!!!

10 Correction during one fill (hours) misalignment of one triplet magnet by 1 μm leads to:  μm at the IP (= σ)  μm at the primary collimators, μm at the secondary collimators, μm at the tertiary collimators and μm at the TCLs -> in Run I already about 40 μm orbit deviation caused high losses. For Run III this will be even more critical due to the higher energy => need to have movements well below 1 μm over timescales of ∼ 30 mins/1 hour (at present no orbit feedback is used in collision) (see G. Arduini, M. Lamont, LHC Commissioning 2012, Summary of week 19)

11 Emittance growth (high frequencies, <1hour) emittance growth from misalignment of one quadrupole is given by [5]: 1) only components equal to the betatron sidebands contribute to emittance growth. The betatron sidebands are given by with and lowest frequency for LHC= ν x/y f 0 = 3485 Hz 2) random dipole kicks drive coherent oscillations -> phase mixing of beam particles due to beam-beam tune spread a) decoherence time: b) resonance width: LHC Run III: τ decoh = s ≙ 50 turns Δf res = 36 Hz => narrow sidebands

emittance growth with feedback system [5]: g= feedback gain (g>>Δν), X noise =precision of feedback pickup, β 1 =β at location of pickup feedback parameters LHC: X noise =1 μm, β 1 = 180 m, g=0.01 Run III bb tune shift: assume 1% emittance growth per hour: 12 Emittance growth (high frequencies, <1hour) 1)emittance growth dominated by noise from feedback pickup for x noise > 0.12 μm 2)high feedback gain desired

13 Emittance growth (High frequencies, <1hour) => more ambitious feedback parameters necessary: assumed feedback parameters: X noise =0.02 μm, β 1 = 180 m, g=0.3 Run III optics: option med, β*(IP1/5)=0.4 m, β*(IP2)= 10 m, β*(IP8)= 3 m assume 1% emittance growth per hour: => Note: models always assume a contribution from the high frequency part of the spectrum, in particular the betaron sidebands. The emittance growth due to a low frequency excitations should be studied further but information about the expected spectrum is required (amplitude and frequency distribution).

14 Summary 1)according to the time scale tunneling work can lead to different effects. 2)some estimates have been provided based on simplified models and extrapolations from existing experience 3)Acceptable amplitude will vary according to the time scale: Long time scale (weeks/months): few 10th of mm Time scale < hours (based on present mode of operation of the machine without orbit feedback in stable beams): well below 1 μm (at the triplet) up to a few hundred Hz: 1 μm (at the triplet) in order to avoid visible effects on luminosity and losses (emittance blow-up effect to be studied) kHz range: <1 nm (at the triplet) likely pessimistic, but dependent on exact frequency range and spectrum (frequency spectrum could overlap with betaron sidebands) => emittance growth

15 Next steps To proceed further we need to know: expected long term (week/months) movement of the ground (detector/inner triplet) amplitude of movements and extension of the area where the movements occur. Are they coherent/what is their wavelength? Spectrum of the vibrations (amplitude vs frequency) up to several kHz with resolutions compatible with the above transfer functions floor to cold masses

16 BACKUP SLIDES

Crosscorrelation K und Coherence C Vertikale Kohärenz zwischen HERA WL350 und 745 (3. Juli :00 h). 2. Oktober Wilhelm Bialowons (DESY), Konstruktionsbesprechung, correlation only for low frequencies

18 Theoretical Background - Literature Ground motion LEP/LHC: in general not much available (measurements in view of a linear collider study and in ATLAS/CMS experimental hall) [1] L. Vos, “Ground motion in LEP and LHC”, CERN-LHC-NOTE-299 [2] M.P. Zorzano, T. Sen, “Emittance Growth for the LHC Beams Due to Head-On Beam-Beam Interaction and Ground Motion”, FERMILAB-TM-2106 [3] V.E. Balakin, W. Coosemans et al., “Measurments of Seismic Vibrations in the CERN TT2A Tunnel for Linear Collider Studies”, CLIC-Note 191 Ground motion HERA: all publications can be found at Detailed studies for SSC (theoretical background): low frequency (f < f rev ν): [4] K.Y. Ng, “Emittance Growth due to a Small Low-frequency Perturbations”, FERMILAB-FN-575 high frequency (f ≥ f rev ν): [5] V. Lebedev, V. Parkhomchuk, V. Shiltsev, G. Stupakov, “Emittance Growth due to Noise and its Suppression with the Feedback System in Large Hadron Colliders”, SSCL-Preprint-188 [6] Y.I. Alexahin, “On the emittance growth due to noise in hadron colliders and methods of its suppresion”, NIM A 391, p , 1996 Ground motion CLIC:

19 High frequencies (no feedback) estimate of emittance growth for Run III (spectral density): emittance growth from misalignment of quadrupoles in IR1/5 is given by [5]: Spectral density S Δx : where K Δx is the correlation function given by: Run III optics: option med, β*(IP1/5)=0.4 m, β*(IP2)= 10 m, β*(IP8)= 3 m note: β(kl) 2 (triplet IR1+IR5) = /m, β(kl) 2 (Q4-Q7 IR1+IR5) = 1.7 1/m => triplet clearly dominates and is the closest element to the tunneling works!!! assume 1% emittance growth per hour: => IR1+IR5

estimate of emittance growth for Run III (“white noise”): - assume white noise = correlation time is much less than one revolution period - all frequencies contribute => emittance growth from misalignment of quadrupoles in IR1/5 is given by [5]: assume 1% emittance growth per hour => 20 High frequencies (no feedback) IR1+IR5

21 Orbit deviation at collimators and IP

22 Orbit deviation at collimators and IP