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Energy Calibration of the SPS with Proton and Lead Ion Beams J. Wenninger, G. Arduini, C. Arimatea, T. Bohl, P. Collier, K. Cornelis (CERN, Geneva) Introduction Since the shutdown of LEP at the end of 2000, the SPS machine is modified and adapted to its role as injector for the LHC collider. n beam to Gran Sasso SPS As LHC injector, the SPS must deliver very bright beams with high efficiency and without emittance degradation to both LHC rings. The machine model is re-measured in details and as part of this effort, the beam momentum at the extraction energy of 450 GeV/c was calibrated in order to obtain the best possible initial energy setting when the LHC will be commissioned. Calibration principle The speed of the particles c, where c is the speed of light, can be related to the revolution frequency frev and the corresponding RF frequency fRF through The speed pc of the proton beam is related to its momentum P, the main parameter of interest, and its rest mass mp by 2 P ( p c) 2 P ( m p c) 2 2 Cf Cf rev RF h where h is the harmonic number of the RF system, h = 4620 for the SPS. C is the machine circumference. To determine the speed b and therefore the momentum, both C and frev must be known. An ion beam of charge Z, injected into the same magnetic machine and on the same orbit than the proton beam has a momentum Pi= Z P. We define the proton equivalent momentum of the ion as P = Pi/Z. The speed ic of the ions is given by 2 P ( i c) 2 2 P (mi c / Z ) 2 To determine momentum and machine circumference at the same time, frev is measured for two particles with different masses (or charge over mass ratio) that are injected into exactly the same magnetic machine and on the same orbits. In our case the measurements are performed for a proton and an lead ion beam. The two equations can be solved for the proton beam momentum P: mi Zmp p f 2 1) RF P m pc ( p i ) 2( f RF f RF (p = proton, i = ion) Central RF frequency measurement technique Horizontal chromaticity scans The goal of the energy calibration is the determination of the beam momentum on the central orbit, where the beam is centered on average in the machine quadrupoles. On this orbit the momentum is entirely determined by the dipole field and the measurement of the beam momentum under such conditions provides a calibration of the integrated field of the main dipoles. In practice the central RF frequency is determined by centering the beams in the machine sextupoles. For that RF frequency value, the transverse tune no longer depends on the setting of the chromaticity. For a sufficiently large number of sextupoles and a correct alignment of the sextupoles with respect to the quadrupoles, the beam should be centered in the sextupoles and quadrupoles at the same time. Systematic alignment effects can be probed by performing the measurement for the horizontal plane and for the vertical plane independently. Hor. tune Vertical chromaticity scans Ver. tune In this example the central frequencies obtained by changing the horizontal and vertical chromaticity differ !! Energy Calibration of the SPS with Proton and Lead Ion Beams J. Wenninger, G. Arduini, C. Arimatea, T. Bohl, P. Collier, K. Cornelis (CERN, Geneva) Tidal distortions Central frequency for protons and lead ions (Pb53+) Hor. tune The effect of local gravity changes due to Earth tides on the circumference is well known from the LEP machine. Hor. tune Vert. tune Vert. tune The change of circumference / central RF frequency is proportional to the change in gravity, for the SPS : Df [Hz] (3.1 0.2) Dg[m / s2 ] Horizontal and vertical chromaticity scans for proton and lead ion beams Tidal corrections must be applied because the measurements were spread over a 48 hours period Measurements Gravity change Central RF frequency difference Pb53+-p : Df = 6194.3 1.6 Hz Df = 6200.4 2.7 Hz Horizontal chrom. scan Vertical chrom. scan Pb53+ was used instead of Pb82+ to increase Df Local gravity change due to Earth tides between October 17th and 24th 2002 The difference between H and V scans is 6.1 3.1 Hz (corrected for tidal effects) October 2002 Proton beam momentum Momentum for proton beam : p = 449.18 0.16 GeV (error dominated by H/V difference) Machine circumference : C = 6’911.566 0.002 m C = 6’911.504 m R = 1100.0099 0.0004 m R = 1100.0000 m The momentum is –0.18% lower than the nominal value of 450 GeV/c. measured model Systematic studies The difference in central frequency between H and V corresponds to a difference in radial position between the two SPS sextupole families of: DR = 0.8 mm at 450 GeV/c !! This unexpected difference was studied, and was found to depend on the momentum, vanishing at injection energy. A mechanical movement has been excluded, a possible source may be shifts of the magnetic center of the sextupole magnets. Corresponds to a radial offset of 0.8 mm between sextupole families