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Lepton Collider Increased interest in high energy e + e - collider (Japan, CERN, China) STFC funded us for £75k/year travel money in 2015 and 2016 to re-

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Presentation on theme: "Lepton Collider Increased interest in high energy e + e - collider (Japan, CERN, China) STFC funded us for £75k/year travel money in 2015 and 2016 to re-"— Presentation transcript:

1 Lepton Collider Increased interest in high energy e + e - collider (Japan, CERN, China) STFC funded us for £75k/year travel money in 2015 and 2016 to re- engage with international LC community Outlined three aspects Silicon tracking (ex. LCFI, etc.) DAQ (ex. Calice, EUDET, AIDA) Calorimetry (ex. Calice) Birmingham Nigel Watson / Birmingham 30-Sep-2015

2 Lepton Collider R&D - DECAL Concept, CALICE Concept, swap ~0.5x0.5 cm 2 Si pads with small pixels (“Small” := at most one particle/pixel,1-bit ADC/pixel) How small to avoid saturation/non-linearity? EM shower core density at 500GeV is ~100/mm 2 Pixels must be<100  100  m 2 Used baseline 50  50  m 2 Gives ~10 12 pixels for ECAL – “Tera-pixel APS” Mandatory to integrate electronics on sensor Concept, swap ~0.5x0.5 cm 2 Si pads with small pixels (“Small” := at most one particle/pixel,1-bit ADC/pixel) How small to avoid saturation/non-linearity? EM shower core density at 500GeV is ~100/mm 2 Pixels must be<100  100  m 2 Used baseline 50  50  m 2 Gives ~10 12 pixels for ECAL – “Tera-pixel APS” Mandatory to integrate electronics on sensor AECALDECAL N pixels =N particles DECAL N pixels <N particles 30-Sep-2015 Nigel Watson / Birmingham

3 MAPS, MIP Efficiency Project tracks to individual test sensors Check for sensor hits as function of track (x,y) position relative to pixel centre Determine efficiency by fitting distribution scintillators 2 TPAC test sensors 4 TPAC track sensors Efficiency for 4 sensor variants, from CERN (Aug.’09, 120 GeV  ) and DESY (Mar.’10, 1-5 GeV e - ) testbeams Standard CMOS sensors have low efficiency due to signal absorption by circuit elements Deep p-well (INMAPS) reduces signal absorption, raises efficiency by factor ~5 (12  m) high-resistivity epitaxial layer raises efficiency by further factor ~x2 30-Sep-2015 Nigel Watson / Birmingham 12  m

4 MAPS, MIP Efficiency Project tracks to individual test sensors Check for sensor hits as function of track (x,y) position relative to pixel centre Determine efficiency by fitting distribution scintillators 2 TPAC test sensors 4 TPAC track sensors Efficiency for 4 sensor variants, from CERN (Aug.’09, 120 GeV  ) and DESY (Mar.’10, 1-5 GeV e - ) testbeams Standard CMOS sensors have low efficiency due to signal absorption by circuit elements Deep p-well (INMAPS) reduces signal absorption, raises efficiency by factor ~5 (12  m) high-resistivity epitaxial layer raises efficiency by further factor ~x2 Single particle efficiency Pixel threshold (arbitrary units) 30-Sep-2015 Nigel Watson / Birmingham 12  m

5 MAPS, MIP Efficiency Project tracks to individual test sensors Check for sensor hits as function of track (x,y) position relative to pixel centre Determine efficiency by fitting distribution scintillators 2 TPAC test sensors 4 TPAC track sensors Efficiency for 4 sensor variants, from CERN (Aug.’09, 120 GeV  ) and DESY (Mar.’10, 1-5 GeV e - ) testbeams Standard CMOS sensors have low efficiency due to signal absorption by circuit elements Deep p-well (INMAPS) reduces signal absorption, raises efficiency by factor ~5 (12  m) high-resistivity epitaxial layer raises efficiency by further factor ~x2 Single particle efficiency Pixel threshold (arbitrary units) Preliminary 2009/10 testbeam data 30-Sep-2015 Nigel Watson / Birmingham

6 MAPS for DECAL, (~)Shower Profile Project tracks to individual test sensors Vary depth of absorber thickness, study downstream hit multiplicity Purely to cut cost – not ideal 30-Sep-2015 Nigel Watson / Birmingham scintillators 2 TPAC test sensors 4 TPAC track sensors # clusters/# tracks Absorber thickness (X 0 ) Study TPAC sensors as “calorimeter” layer Peak of sensor activity vs. depth of material Single sensor study of EM shower response Electron beam shows expected log behaviour (NB: single sensor transverse size)

7 MAPS for DECAL, (~)Shower Profile Project tracks to individual test sensors Vary depth of absorber thickness, study downstream hit multiplicity Purely to cut cost – not ideal 30-Sep-2015 Nigel Watson / Birmingham scintillators 2 TPAC test sensors 4 TPAC track sensors Absorber thickness (X 0 ) Shower max. depth (X 0 ) Now (Bham, PPD, Sussex) using CHERWELL sensor to find show stoppers for DECAL Power consumption (  1% duty cycle “no harm” tests) Pixel ganging (exploit tracker technology) Future (-- “ --), investigating rad hard MAPS for DECAL and tracking (higher intensity hadron colliders + LC) Incident e - energy (GeV)

8 Cherwell tests Sensor on daughter board Firmware adaptation required for power cycling Nigel Watson / Birmingham 30-Sep-2015

9 PRD Bid… Let’s hope… Nigel Watson / Birmingham 30-Sep-2015

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