High Granularity Timing Detector (HGTD) Didier Lacour (LPNHE Paris) Dirk Zerwas (LAL Orsay) members of the ATLAS and Calice collaborations

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High Granularity Timing Detector (HGTD) Didier Lacour (LPNHE Paris) Dirk Zerwas (LAL Orsay) members of the ATLAS and Calice collaborations In the framework of the Large Eta Task Force of the ATLAS collaboration Extensions or improved instrumentation in the forward region at eta > 2.5 Improvement of the phase-ii ATLAS detector with much better pile-up rejection at HL-LHC A benefit for number of physics channels for signatures with forward jets or multiple objects and more efficient background suppression Standard Model, Higgs boson VBF processes, H-> 4 leptons, ttbar background rejection for H->WW (improved missing energy transverse resolution, extended b or c tagging) SM physics with VBF processes, same sign WW WZ final states Reference: ATL-UPGRADE-INT-2015-001 31 st May 2015 Didier Lacour LPNHE Munich, September 2015 1

Upgrade scenarios Timing preshower detector Multi-Channels Plate (MCP) Mini-FCAL Si-W calorimeter Reference: ATL-UPGRADE-INT-2015-001 31 st May 2015 A Silicon HGTD detector inspired in Calice 2

HGTD in the gap between the LAr barrel and end-cap cryostats Gap occupied by ITk services, ITk end-plate and MBTS Reconfiguration is possible Envelope of Delta z =70 mm available 3

Calorimeter cell noise Degradation of the performances because of the pile-up conditions at the HL-LHC Increase of the total noise in individual readout channels Expected total noise energy (electronic + pile-up) of the cells at different eta for an average number of interactions mu=30 and mu = 200 From lower to higher pile-up scenarios, significant increases High level of noise in the EMEC and FCAL 4

High Granularity Timing Detector Capability to identify the vertex origin of forward jets Pile-up vertices produced at different z positions: Particles from different vertices arrive at different times (interactions occur at different times) Crab-kissing: a novel colliding scheme to extend the spatial pile-up density profile and to reduce the spread of the time density of hard scatter interactions Run1: very small separation for signal and pile-up due to the large time spread of collisions relative to the z spread of the bunch Crab-kissing: significant sharpening of the time distribution for hard scatter particles, maintaining a large spread for pile-up particles Reference: S. Fartoukh, Pile up management at the high-luminosity LHC and introduction to the crab-kissing concept, Phys. Rev. ST Accel. Beams 17,111001 (2014). 5

HGTD ATLAS based on CALICE ATLAS measurement: t and E 4 layers in depth (z) Granularity: 5mm x 5mm option: mix with 1cm x 1cm Same basic structure No absorber option: absorber Weaker constraints: 4 layers in 6cm ~1.5cm per layer: Chip+PCB+Glue+Wafer=3.225mm, leaves 1cm for cooling and absorber (eg tungsten 3mm 1X0) ILD Measurement: E (and t) 30 layers Absorber: tungsten 30 layers in 18cm ~0.6cm per layer includes tungsten absorber Harsher constraints: Cooling of sensors -20deg RadHardness of FE electronics RadHardness of Glue (measurements foreseen in 2015-2016) 40MHz Time measurement Cooling of electronics (passive) Zero suppression/power pulsing 5Hz 1ms bunchtrain 6

Signal: Large MIP signal (roughly 10-15 for CALICE) Occupancy (rough estimate): ¼ (at η=4) Intrinsic timing resolution ~150ps per RO for S/N=25-30 4 measurements per track? Per jet/area? Add absorber to increase signal? Which material? Impact on energy resolution? LGAD sensors? Granularity variation from 5mm to 10mm? Readout: 5mm x 5mm pads: 38x4x2 ASUs 304k channels (=1.5*LArg) Digital flux: 3ASUs=3072channels : 4Tb/s Zero suppression: ¼ (not sufficient) Reduction to Gb/s: More than 1 link per ASU Lvl1 reduction of 500-1000 (buffering?) Local clustering? 7

Preserve basic CALICE structure Sketch of an implementation in ATLAS R=110mm, η=4.1 R=600mm, η =2.4 Slabs CALICE-like: 2ASUs 3ASUs Alternative: Single PCB Pro: less interconnections Con: planarity Support structure (attached to cryostat) Material? Alveola? Direct mounting? 8

Time-line and milestones for the implementation of the HGTD 9

Expressions of interest Text for IN2P3 circulation Expression of interest for ATLAS September 4 th ATLAS meeting on High Granularity Timing Detector Didier Lacour (LPNHE): assembly of ASUs characterization of wafers and ASUs: geometry and electric I(U) Daniel Fournier, Laurent Serin, Dirk Zerwas (LAL), Dominique Breton (SERDI-LAL): FE electronics digital readout electronics assembly of Slabs Christophe de la Taille (Omega): FE electronics in charge of the architecture of the CMS HGCAL readout similarities with HGTD 10

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