Detector Research & Development RECFA, NIKHEF, Amsterdam. Sept 23, 2005 Harry van der Graaf, NIKHEF, Amsterdam
MediPix General Purpose CMOS Pixel chip GridPix Micropattern/pixel readout of gas-filled detectors TPC for ILC Vertex detecor for ILC & (S)LHC New semiconductors: diamond, SiC IC technology X-ray imaging XFEL ESRF 100 m RASNIK alignment ILC CLIC
Medipix2: Hybrid Pixels Schematic of a hybrid pixel detector MediPix chip 14 x 14 mm 2 sensitive area periphery approved Eureka proposal
Some Images mm 28 mm 10 keV 5.9 keV Tungsten source 55 Fe source mm
Tiling High-bandwidth communication X-ray imaging (100 x 100 mm2) XFEL in Hamburg Industrial collaboration
MediPix General Purpose CMOS Pixel chip GridPix Micropattern/pixel readout of gas-filled detectors TPC for ILC Vertex detecor for ILC & (S)LHC New semiconductors: diamond, SiC IC technology X-ray imaging XFEL ESRF 100 m RASNIK alignment ILC CLIC
CVD diamond properties produced by Chemical Vapour Deposition in an organic plasma discharge polycrystalline wafer, generally mm thick detector substrates up to 2 x 4 cm 2 typical value of bias field: 1 V/µm leakage current 50 pA/cm 2 columnar structure
Application as a detector
Radiation damage of CVD Diamond Example: pion irradiation until cm -2 General decrease of the mean charge signal caused by the formation of additional traps (interstitials and vacancies)
CVD diamond: results CVD diamond suffers from a certain degree of radiation damage but narrowing of the distribution curve makes the decrease of the 98% threshold less severe. At cluster threshold of 1500 e- efficiencies >98% can be obtained, even after charged hadrons The charge signal distribution curve of a CVD diamond sample is accurately described by only two parameters: mean charge signal and width of the distribution Radiation hardness of CVD diamond as a tracker is sufficient for 10 year of operation at R = 7 cm at the LHC.
New detector material: Si C Charge collection with particles: neutron irradiated samples CREE 5 n/cm 2
MediPix General Purpose CMOS Pixel chip GridPix Micropattern/pixel readout of gas-filled detectors TPC for ILC Vertex detecor for ILC & (S)LHC New semiconductors: diamond, SiC IC technology X-ray imaging XFEL ESRF 100 m RASNIK alignment ILC CLIC
1906: Geiger tube gaseous detector ionisation: primary electrons (central) anode wire electron multiplication
Geiger-Müller tube Proportional tube Multi Wire Proportional Chamber Drift Chamber Time Projection Chamber 1988: Micro Strip Gas Counter (MSGC): Oed 1995 Micromegas (Charpak & Giomataris) 1996 GEM (F. Sauli)
Micro Patterned Gaseous Detectors High field created by Gas Gain Grids Most popular: GEM & Micromegas improved granularity : wire chambers react on COG of many electron clouds/clusters GEM Micromegas
Time Projection Chamber (TPC): 2D/3D Drift Chamber The Ultimate Wire (drift) Chamber E-field (and B-field) Wire Plane + Readout Pads track of charged particle Wire plane Pad plane
Problem With wires: measure charge distribution over cathode pads: c.o.g. is a good measure for track position; With GEMs or Micromegas: narrow charge distribution (only electron movement) wire avalanche Cathode pads GEM Micromegas Solutions:- cover pads with resisitive layer - ‘Chevron’ pads - many small pads: pixels!
MediPix2 pixel sensor Brass spacer block Printed circuit board Aluminum base plate Micromegas Cathode (drift) plane 55 Fe Baseplate Drift space: 15 mm Very strong E-field above (CMOS) MediPix! MediPix2 & Micromegas: apply the ‘naked’ MediPix2 chip without X-ray convertor!
He/Isobutane 80/20 Modified MediPix δ-ray! Efficiency for detecting single electrons: < 95 % 14 mm GridPix: the electronic bubble chamber
Integrate GEM/Micromegas and pixel sensor: InGrid ‘GEM’ ‘Micromegas’ ‘wafer post processing’ by Univ. of Twente, MESA+ approved VICI proposal ‘there is plenty of room at the top’
Processing InGrids Strips Litho. 50 µm SU8UV Exposure 0.8 µm Al Holes Litho. Development Suspended membrane 50 µm above the wafer
Prototypes 19 different fields of 15 mm Ø 2 bonding pads / fields Square / Walls Square / Pillars Hex / Pillars
Energy resolution in Argon IsoC 4 H 10 80/20 Observation of two lines: K 5.9 keV K 6.4 keV FWHM of the K α distribution 16.7 % Gain fluctuations < 5% Very good energy resolution: Very precise dimensions d < 0.1 μm
Gains in Argon Argon / CO2 mixtures offers good ageing properties (GOSSIP gas) Gain of 10 4 reachable in Argon CO 2 80/20 Ageing studies in a reasonable amount of time (intense X-rays source)
Other applications of GridPix: - μ-TPC - Transition Radiation Detectors - GOSSIP: tracker for intense radiation environment
GOSSIP: Gas On Slimmed SIlicon Pixels new vertex detector! CMOS pixel array MIP InGrid Drift gap: 1 mm Max drift time: 16 ns MIP CMOS chip ‘slimmed’ to 30 μm Cathode foil
Essentials of GOSSIP: Generate charge signal in gas instead of Si (e-/ions versus e-/holes) Amplify # electrons in gas (electron avalanche versus FET preamps) Then: No radiation damage in depletion layer or pixel preamp FETs No power dissipation of preamps No detector bias current Ultralight detection layer (Si foil)
Aging test (remember MSGCs….!) ratio of anode surface: thin wire surface versus anode plane (~20x) low gas gain due to fast signal and low source capacity (~20x) At X-ray source (PANalytical) With standard Ar/Methane 90/10 mixture: Equivalent of 3 years Super 2 cm from beam pipe
Next GridPix (TPC for ILC) TimePix: modify MediPix 2 chip: TDC clock over pixel matrix EUDET (Nikhef-Saclay-Freiburg et al) approved $$$ ! InGrid Study the geometry influence on Resolution, Gain, Ion back flow: optimise detector geometry Protect the chip from discharges High resistive grid, or separated grid segments Apply InGrid on MediPix2, (TimePix!), PSI 46 pixel chips GOSSIP repeat aging test with Ar/CO2 Gossipo: MPW submit for low-noise preamp (C s = 30 fF) Test with PSI 46 FE pixel chip equipped with InGrid
MediPix General Purpose CMOS Pixel chip GridPix Micropattern/pixel readout of gas-filled detectors TPC for ILC Vertex detecor for ILC & (S)LHC New semiconductors: diamond, SiC IC technology X-ray imaging XFEL ESRF 100 m RASNIK alignment ILC CLIC
Momentum Measurement of muons in the L3 experiment: Chamber Position Monitoring
Principle of CCD-RASNIK Coded Mask Light SourceLens CCD
100 m RASNIK for CLIC CLIC Accelerator length:2 x 15 km Number of elements: Number of ‘4 m’ RASNIKs:15.000/ Number of ‘100 m’ RASNIKs: 600 Laser zone lens hole dia. 50 mm RasCam 100 m (vacuum tube!)
Pixels for LHC Super LHC ILC!