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Beam on Target Diagnostics Beam on Target Meeting 2013 March Tom Shea
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Goals Support commissioning/studies of beam expansion section and target/dumps Support rapid production setup (maximize neutron production) Assure operations within approved envelope Minimize beam-induced damage to target and dump system components Support neutronics studies Record accelerator performance
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(Old) Requirements Measurement accuracy based on the preliminary Accelerator to Target Interface table Requirements are similar for beam measurement at Target, Proton Beam Window, and Dump Also: interface to MPS, buffering of data, event-driven data acquisition, beam accounting Normal Condition Off-normalRatio Allocation for instrumentation error Beam power within 160 mm by 60 mm >90 % > 50% power outside spot 40% (referred to full power) 20% Peak time- average beam current density ≤0.47 A/m^ 2 >0.47 and ≤0.64A/m^ 2 36% (referred to nominal) 20% Peak single pulse density ≤2.09 x 10^17 protons/m^ 2 >2.87 x 10^17 prot/m^ 2 37% (referred to nominal) 20% Tolerance on beam centroid relative to global coordinates ±6 mm> +/- 6 mm Horizontal: 4% of beam size Vertical: 10% of beam size +/- 3 mm or 10% of vertical beam size Preliminary interface: McManamy Old estimates – will be revised
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Accelerator to Target Line 25 mm 200 mm Simulation with 500,000 particles Simulation data: Aarhus
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Tom Shea, ESS, Beam Shaping Workshop, Aarhus, 2012-03-27 Beam-on-Target Based on preliminary interface definition: Measure beam density with 20% accuracy, centroid with 3 mm accuracy Upstream wire scanners to measure emittance (not shown here) BCM shown above: – Used to normalize beam density measurements, also used by neutron instruments – Beam accounting (power on target, total energy delivered, etc) Redundant measurements at proton beam window and target: – Halo: Halo monitoring via thermocouple assemblies – Img: Imaging (luminescent coatings on Proton Beam Window and Target) – NPM: Non-Invasive Profile monitor (He gas luminescence) – Grid: SEM in vacuum and ionization in Helium He at ~1 atmvacuum
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Space is Allocated in Target Monolith Target shaft Target diagnostics (no details yet) Target wheel Beam Instrumentation Plug Optics (upstream, downstream, H and V) H and V grid halo PBW: Coating (<100 C) H and V grid halo PBW plug He-valve plug Access to water cooled shielding blocks (if necessary) Coating on target (<200 C) 4.4 meters Optical and signal path Drawing: Jülich
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Images vs. Wavelength ESS imaging: Use spectral filtering to separate coating emission from Helium gas luminescence Data from SNS
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Tom Shea, ESS, Beam Shaping Workshop, Aarhus, 2012-03-27 Proton Beam Window Panpipe proton beam window helium cooled Drawing: Jülich Locate halo thermocouples on window frame Integrate wire grid into assembly Develop coating for window
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Proton Beam Window halo thermocouples Thermocouples for Halo monitoring & Beam Centering SNS example
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Multi-wire Grid: Ionization monitor in Helium 10 6 protons in the simulation, flat beam 1 cm * 1 cm 2.5 GeV, no energy spread no divergence Proton beam widow, 1 mm Al Detector, 3 cathode separate by 1 cm thickness = 0.1 mm Al target 50 cm390 cm Helium atmosphere after the window Profile measurement with multi wire proportional chamber used in ionization mode Simulation: Benjamin
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At Grid Location Protons neutron γ Electron neutron γ π + π - assuming a cell size of 1mm(trans) * 1 cm (long.) with full power the current on the wire is 3.5 mA. the ratio between the proton and the particle in the shower ( mainly pions and electrons) is around 10^-4, the particles have a high energy and we can assume that the signal given by the shower has the same ratio as the proton. Full power allowed
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Tom Shea, ESS, Beam Shaping Workshop, Aarhus, 2012-03-27 Raw SEM Signals at SNS Wire position (mm) Amplitude (a.u.) SEM signals: How fast can we acquire with reasonable S/N?
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Tom Shea, ESS, Beam Shaping Workshop, Aarhus, 2012-03-27 Slow Scan observed by SNS Imaging System
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Tom Shea, ESS, Beam Shaping Workshop, Aarhus, 2012-03-27 Effect of Beam Position on Neutron Production – pencil beam Iverson, Shea Goal: support neutronics studies
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Machine protection and interlocks Risk assessment – Worst case: Analyze impact of static beamlet. Can we survive single pulse? Time to mitigate? – Analyze other failure modes (with Scandpower – Annika leads?) Redundant MPS inputs – Direct detection of power converter/kicker problems – Measurement of beam position vs. time. Position electrodes at proton beam window and upstream. – Profile measurements (imaging and wire grid, possibly He luminescence) – Ionization monitor: measure position even in case of saturation? – Loss monitors, halo montors? – Target instrumentation??
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Conclusion and Next Steps Requirements have been developed based on preliminary Accelerator to Target Interface. These can be refined as target, beam window, and, dump designs proceed; and as rastering option is considered. Techniques identified for all required measurements and preliminary locations identified for components Technical challenges of baseline system will be addressed with focused R&D program – Luminescent coating for window low-mass window and higher temperature target – Development of broadband, radiation-tolerant optical systems – Development of ionization monitor As we refine beam to target strategy and evaluate rastering, what additional activities are required in instrumentation and interlocks?
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