Polarized Gas Target for LHCb Erhard Steffens (Erlangen) for the target study group Paolo Lenisa (Ferrara), Alexander Nass (FZ Jülich), Pasquale Di Nezza (Frascati), Frank Rathmann (FZ Jülich), E. St. Introduction Storage cell principle and development Storage cell targets at HERA-e and COSY Polarized gas target for LHC Conclusions
Motivation for internal targets Study of spin dependent observables: Polarized beam - extracted from accelerator, or secondary beams on a polarized target – by dynamical nucl. polarization = microwaves in high B at low T (SLAC experiments E…, European Muon Collaboration EMC/CERN, Spin Muon Collaboration SMC, COMPASS….) New idea (1980‘s): Stored beam - multi-mA plus polarized gas target: HOW?? Atomic polarized H and D beams as target: Studied at Stanford Tandem with mA beams Experiment at VEPP-3 (Novosibirsk) t ~ 2·1011 /cm2 Polarized atomic beams: produced by an ABS 2017-01-10-CERN Polarized gas target for LHC
Atomic Beam Source (ABS) Collimated cold atomic beams produced by dissociator with cold nozzle (100K) and differential pumping system (Stotal ~104 l/s) Spin-dependent focussing of H and D atomic beams by 6-pole magnets: mJ= +1/2 Nuclear polarization Pz, Pzz produced by means of rf transitions with ~100% effi-cieny + rapid switching Bc = 50.7 mT 2017-01-10-CERN Polarized gas target for LHC
Free Atomic Beam as a Target? Best example: the polarized H-Jet at RHIC used as absolute Polarimeter for the proton beam(s): A beam from an ABS is focused on a bright spot shortly after the last Sextu- pole magnet and employed as target, surrounded by detectors. The ABS intensity is 12.4·1016 H↑ /s (about 2× intensity of HERMES-ABS) and the areal density seen by the proton beam is t 1.3 1012/cm2 . With the LHC proton beam – Ip = 3.6 1018/s – the luminosity would only be 4.7 1030/cm2 s*. This is the maximum available density for a free polarized ‚jet‘ with present technology – despite all the effort of many decades! *) note: the gas load of a jet for a given target thickness would be high compared with a storage cell target. 2017-01-10-CERN Polarized gas target for LHC
Compression Tube (CT) for intensity measurements AAbggbkA ABS Gas conductance C (molecular flow) of tube – length L and i.d. D: C = 3.81 l/s √(T/M) × D3/(L+4/3 D) Example: T=100K, M=1, L=10cm, D=1cm → C = 3.36 liter/sec I (part./s into given phase space) r = I / C CT e.g. r = 6.5∙1016 / 3.36∙103 cm3 = 1.93∙1013/cm3 The pressure p0 at the tube end is related to the intensity I by I = r ∙ C = p0 C / kT From the measured p0 and T, and the calculated Ctube, the intensity I (part./s) can be deduced. 2017-01-10-CERN Polarized gas target for LHC
History of Storage Cells Storage Cell to enhance the target density? Storage Bulb of Hydrogen MASER (Ramsey 1960) with Teflon coating Storage Cell for ion beams (proposed by Haeberli 1965, demonstrated 1980 by Madison group with Tandem beam) FILTEX proposal to use Storage Cell targets as Spin Filter for stored antiproton beam (Heidelberg group 1985). The cell is a thin-walled T-shaped tube with straight beam tube and feed tube from the side. Polarized gas is injected by an ABS ballistically via feed tube into the cell center and diffuses outwards through the three openings, performing in average about 300 wall collisions. Estimates based on molecular flow: Factor ≥ 100 expected! Storage cell has one big advantage - density - and many disadvantages – wall depolarization and recombination, extended target, material close to beam, …. But no alternative! 2017-01-10-CERN Polarized gas target for LHC
Storage Cell for density enhancement AAbggbkA Central density r0 with T-shaped cell (C2 = conductance of feed tube): Conductance C1 of beam tube ABS L1 = 25cm, D2 = 1cm, T = 100K, M = 1 (H): C1 = 1.45 l/s r0 = I/ (C2 + 2 C1) = 6.5 1016/ 6.26 1013cm3 = 1.04 1013/cm3 I I = 6.5∙1016 H/s HERMES feed tube D1 beam tube ion beam L1 L1 Target (areal) density t = ½ Lbt ∙ r0 = L1 r0 = 2.60 1014/cm2 at 100K and Lbt = 50cm Volume density r0 -L1 L1 z Note: this areal density t is for a 50cm long beam tube with i.d. of 1cm, at T=100K and fed by a HERMES-like ABS. Other dimensions and assumptions result in different numbers. Guidance needed for a reasonable lay-out. 2017-01-10-CERN Polarized gas target for LHC
1992: Target test in the Heidelberg Test Storage Ring TSR experiments Ring designed for Heavy Ions – no shielding. Four straight sections: Injection (foreground), Electron Cooling (left), Experiments (background), Cavity and Diagnostics (right) Polarized gas target for LHC 2017-01-10-CERN
FILTEX target Target installed in the TSR (1992) beam 2017-01-10-CERN Polarized gas target for LHC
FILTEX target: view into target chamber Picture taken through Kapton detector window (chamber under vacuum) Last 6-pole magnet focusing H atoms into storage cell T-shaped storage cell with straight beam tube 10 mm i.d. Cooled cell support and Cryo pump 2017-01-10-CERN Polarized gas target for LHC
FILTEX target First results (1992) Asymmetry with stored a beam Target polarization P = 0.8 (single substate) at 100 K The FILTEX target was employed for the HERMES experiment at the electron ring of the HERA ep Collider (DESY) 1996 - 2005 2017-01-10-CERN Polarized gas target for LHC
HERMES H&D Target- Overview ABS: Dissociator with cooled nozzle and differential pumping; permanent 6-poles and RF transitions Target chamber with cell, holding field coils, beam and sample tubes TGA (Target Gas Analyzer): Measurement of dissociation degree a BRP (Polarimeter for atoms): Measurement of substate population of atoms → electron pol. Pe and nuclear pol. Pn ! Sampling corrections applied to calculate polarization seen by the beam Target chamber 2017-01-10-CERN Polarized gas target for LHC
HERMES Detector with H&D Target (1996-2005) 1996/97: successful run with ‚longitudinal‘ hydrogen! Running and analysis procedures had to be developed. 1998/2000 longitudinal deuterium running (Pz and Pzz) 2002/05 transverse hydrogen; important for possible measurement of Single-Spin asymmetries at the LHC. Machine conditions in Run 2 difficult (more spin rotators, comp.-solenoids removed): P┴ = 0.80±0.03 Side view. blue: spectrometer magnet with back chambers, Cerenkov, TRD and lead glass wall. The H&D target and front detectors are shown on the right. 2017-01-10-CERN Polarized gas target for LHC
Polarized gas target for LHC Storage Cell Design Liverpool-Madison-Ferrara Cell optimized for operation in an electron storage ring (wake fields, SR in the kW range) Conducting surface with smooth variation of cross section to avoid excitation of wake fields! System of W collimators for protection against beam and SR Cooled via cooling rails with cold He gas to 60-100K 75mm Al walls with Drifilm coating - Radiation damage visible! But: Very effective wall coating due to ice layer maintained by small fraction of water in the atomic beam ! 2017-01-10-CERN Polarized gas target for LHC
Diagnostics: Target Gas Analyzer Target gas analyzer (TGA) - measures degree of dissociation a to 1% in few minutes Temperature scan on used cell (deuterium 2000) after formation of water layer no T-dependence visible: no recombination in the (perfect) cell! 2017-01-10-CERN Polarized gas target for LHC
Diagnostics: Sampling Polarimeter BRP * measures substate population ni of sample beam to Dn/n = 1% in few minutes n Hydrogen hfs-population as function of holding field Detector Sample Beam From the ni and a, and by applying ‘sampling corrections’, the target polarization as seen by the beam is calculated. The relative error achieved is about 4%. 2017-01-10-CERN Polarized gas target for LHC
Polarized gas target for LHC PAX target at COSY Former HERMES target re- configured and improved (A. Nass et al., FZJ, and G. Ciullo et al, INFN Ferrara). Employed for the PAX experiment: Spin Filtering of stored protons in COSY by a polarized H target (2011/12), in preparation for Spin Filtering of anti-protons at FAIR. Shown: Target installed in the COSY tunnel at the PAX place in between four low-b quads (blue). ABS (top), target chamber with openable storage cell (center) and support for the target polarimeter (left). 2017-01-10-CERN Polarized gas target for LHC
Openable storage cell development in Ferrara Storage Cell for 2 GeV p/d beam at COSY (FZ-Juelich) Length: 400 mm Free diameter in open/closed position: 10 / 40 mm closed open 2017-01-10-CERN Polarized gas target for LHC
Polarized Gas Target for LHCb nnn A storage cell gas target is the most efficient method in terms of (areal) density t vs. gas load. The density t depends on input rate I of the ABS (or unpol. gas feed system), and the geometry and temperature T of the cell, and can be varied in a wide range. The HERMES electron scattering experiment was limited by the available target density. Therefore, a huge effort went into improving the ABS intensity. The range of densities for a polarized gas target for LHCb have to be specified in order to come up with reliable performance figures. As a guess, we may assume the following: * A storage cell with L = 50cm (i.e. L1 = 25cm) and i.d. of D1 = 1.4cm at T = 100K, and the standard feed tube 10cm long and 1cm i.d. With the HERMES ABS intensity of I = 6.5 1016/s, we get t = 1.44∙1014/cm2 ≈ t HERMES With Ip LHC = 3.63∙1018 p/s @ 7 TeV, the maximum luminosity is Lmax = 5∙1032/cm2 s Relative loss rate of the 7TeV beam: < 10-7/s, i.e. no effect of the target on the proton beam life time! Conclusion: a HERMES/PAX type gas target with conservative assumptions on cell geometry (D1 > DSMOG) enables to produce target densities of the order 1014/cm2. The value can be adjusted according to the data taking strategy of LHCb. 2017-01-10-CERN Polarized gas target for LHC
Further considerations A gas flow of about 1017 atoms/s corresponding to Q∙(H2) = 1.9∙10-3 mbar l/ s into the target section must be accommodated which requires a powerful differential pumping system. In case of a failure of the target source and/or the polarimeter, the valves to the target section will be closed by the Interlock. In this case, the option to feed the cell with unpolarized gas for a different physics program is possible. Access to the target area for fixing the polarized target should be enabled in due time. The SMOG system has paved the way towards Fixed Target data at the LHC. The proposed storage cell target with differential pumping could add new options also with unpolarized (heavy) target gas. Different combinations of masses could be studied, e.g. Pb on Xe or on Kr. For the Pb beam, the nucleon-nucleon CM energy is √s = 71.9 GeV, above the values of the CERN SPS Heavy Ion program (about 20 GeV) and the FAIR CBM program (4 – 9 GeV). 2017-01-10-CERN Polarized gas target for LHC
Polarized gas target for LHC Conclusions A Storage cell target gives highest areal density at minimum gas input. Good performance over many months experienced at the HERA 27.6 GeV electron storage ring in ten years of operation (1996 – 2005) at e± currents up to 40 mA. A cell of 50cm in length and 1.4cm i.d. has been assumed, in accordance with the aperture requirements at the SMOG/VELO detector of LHCb. Polarized H and D gas target by ballistic injection of polarized gas from an ABS: (i) luminosities of the order 1032/cm2 s seem accessible; (ii) practically no back- ground i.e. better systematics compared with a solid polarized target; (iii) sign of P switchable at 1/min or faster. The density can be adjusted to eventually allow for data taking in parallel to the pp collider programme. Cell filled with unpolarized gas: p-A and Pb-A collisions could be studied with gases like H2, He, Ne, Ar, Kr and Xe at √sNN = 72 GeV at the optimum luminosity. Next: (i) simulations to study and optimize the layout, and (ii) a conceptual design. This may finally lead to measurements of Single-Spin Azimuthal Asymmetries of various processes at the LHC. Thank you ! 2017-01-10-CERN Polarized gas target for LHC