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The LHCb Vertex Locator Lars Eklund LHCb VELO Group of the LHCb Collaboration CERN (Geneva), EPFL (Lausanne), NIKHEF (Amsterdam), University of Glasgow,

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Presentation on theme: "The LHCb Vertex Locator Lars Eklund LHCb VELO Group of the LHCb Collaboration CERN (Geneva), EPFL (Lausanne), NIKHEF (Amsterdam), University of Glasgow,"— Presentation transcript:

1 The LHCb Vertex Locator Lars Eklund LHCb VELO Group of the LHCb Collaboration CERN (Geneva), EPFL (Lausanne), NIKHEF (Amsterdam), University of Glasgow, University of Heidelberg, University of Liverpool

2 IWORID (July 28, 2004)Lars Eklund, CERN2 Outline LHCb and its Vertex Locator Radiation Environment Technology Choices Current Status Upgrade Possibilities

3 IWORID (July 28, 2004)Lars Eklund, CERN3 The LHCb Experiment – High Energy Physics Introduction One of four experiments at LHC: @ CERN, Geneva Commissioned April 2007 14 TeV p-p collisions at 40 MHz → 25 ns read-out time Study the physics of b-flavoured hadrons (CP-violation) Secondary vertex Single spectrometer arm → 15-300 mrad acceptance Primary and secondary vertex resolution → Characteristic of b-hadrons Flight path in the order of mm Measured with precision of 100 μm Primary vertex pp B0B0 π+π+ π-π- θbθb Kinematical constraints → majority of b-hadrons produced in the direction close to the beam-line Angular distribution of b-hadrons Forward direction L

4 IWORID (July 28, 2004)Lars Eklund, CERN4 The LHCb Experiment - VELO p 20 m p Underground cavern 21 pairs of silicon micro-strip detector modules Two retracting detector halves The Vertex Locator (VELO) beam-line First sensitive element: 8.2 mm from beam-line Operated in vacuum: separated from LHC vacuum by a 250 μm Aluminum foil. High spatial resolution (>4 μm) Minimal material Radiation hardness Secondary vertex identification used in the trigger → Fast track reconstruction (1 MHz rate)

5 IWORID (July 28, 2004)Lars Eklund, CERN5 Radiation Environment Non-uniform radiation environment: Peak value: 1.3 * 10 14 n eq cm -2 NIEL per year Particle flux for one year of operation tracking station 7 (1 MeV neutron/cm 2 NIEL equivalent) Middle station Far station Fluence as a function of tracking station Fluence as a function of radius Goal: To operate two - three years with sufficient resolution and S/N Depends on z (tracking station) Decreases with increasing radius

6 IWORID (July 28, 2004)Lars Eklund, CERN6 The Detector module 2 silicon types of sensors: R and Ф micro-strips 2 x 16 Read-out chips (“Beetle”): → IBM rad-hard deep sub-micron process TPG substrate with carbon fibre frame → Kapton flex circuit laminated on each side Contact for CO 2 cooling Low-mass, high rigidity carbon fibre paddle Precision aluminium base plate Silicon micro-strip sensor: R and Ф strips: for computational efficiency and occupancy Pitch: 40-102 μm for R and 36-97 μm for Ф Read-out chips out of acceptance Double metal for routing lines Silicon operating temperature: -5 °C

7 IWORID (July 28, 2004)Lars Eklund, CERN7 Technology choices (1) Diffusion Oxygenated Float Zone Silicon (DOFZ) is shown to be more resistant to charged particle radiation. VELO will use thin (200-300 μm) DOFZ sensors produced by MICRON Depletion voltage vs. particle fluence, 1 MeV NIEL equivalent. From ROSE collaboration (NIM A 466 pp 308-326) Beetle 1.3 front-end chip IBM 0.25 μm CMOS process Rad-hard design rules Qualified > 30 MRad

8 IWORID (July 28, 2004)Lars Eklund, CERN8 p-on-n silicon: Pre-irradiation Fully depleted p-on-n silicon: After type inversion, under depleted Crosstalk to routing lines: Loss in CCE Degraded resolution n-on-n silicon: After type inversion, under depleted Limited loss in CCE Depletion fraction resolution Technology choices (2)

9 IWORID (July 28, 2004)Lars Eklund, CERN9 Current Status Final stage of R/D Evaluation of a final prototype in beam-test (June 04) Irradiation and sub-sequent measurements in the fall Verify sensor design Confirm radiation hardness Finalise the detector system Sampling time [ns] S/N Example: Optimisation of front-end chip settings

10 IWORID (July 28, 2004)Lars Eklund, CERN10 VELO upgrade scenarios (1) One option: Magnetic Czochralski (Cz) silicon Alternative to float-zone silicon - widely available in industry Naturally high oxygen levels: ~10 18 cm -3 (Cf. DOFZ ~10 17 cm -3 ) Expected to be radiation hard First beam-test of a large micro-strip Cz sensor with 40 MHz read-out 380 μm sensor, parallel 50 μm strips p-on-n Measured before and after irradiation Cz detector in the beam-line VELO Silicon foreseen to last ~ 3 years → LHC will operate ~ 10 years → Performance upgrade Many different upgrade scenarios under discussion → n-on-p, 3D, Cz silicon, strixels, pixels …

11 IWORID (July 28, 2004)Lars Eklund, CERN11 VELO upgrade scenarios (2) Results: S/N before irradiation: 23.5 ± 2.5 for 380 μm S/N after irradiation: 11 for 380 μm → Corresponding to two years of VELO operation → Under-depleted → Low statistics We aim to continue investigating this track as a possibility for a VELO upgrade

12 IWORID (July 28, 2004)Lars Eklund, CERN12 Summary LHCb Vertex Locator Exciting application of rad-hard silicon sensors Technology choices (DOFZ and n-on-n) Final R/D phase – commissioned April 2007 Vision of one upgrade track

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