Studies on the Drift Properties and Spatial Resolution Using a Micromegas-equipped TPC Philippines Japan Germany Canada France Asia High Energy Accelerator.

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Presentation transcript:

Studies on the Drift Properties and Spatial Resolution Using a Micromegas-equipped TPC Philippines Japan Germany Canada France Asia High Energy Accelerator Research Organization (KEK),, TUAT, Kinki Univ., Hiroshima Univ, Saga Univ, Kogakuin Univ., Tsukuba Univ. (Japan) & Mindanao State University-IIT (Phil.) Europe: MPI-Munich, DESY (Germany), DAPNIA/CEA/Saclay & LAL & IPN/Orsay (France) Canada : Carleton University Collaborating Institutions:: Rosario L. Reserva, Bangalore, India March 9-13, 2006

1. Overview/Motivation 2. Experimental Set – up Beam test 3. Some Preliminary Results Electron drift velocity Pad response studies Transverse spatial resolution 4. Summary Outline ILC-TPC Motivation Why Micromegas a possible option to TPC sensor ?  Small E×B effect  Fast signals  Self-suppression of positive ion feedback & the ions return to the grid  Better spatial resolution  No wire angular effect Rosario L. Reserva, Bangalore, India March 9-13, 2006

Overview: KEK Complex Conditions: Conditions: beam : 4GeV/c,π- Gas Mixture: Ar+5% Isobutane Maximum Drift Length =26 cm Maximum Drift Length =26 cm E=220V/cm, B = & 1Tesla Gain = 10,000 Gain = 10,000 Pad Pitch width = 2.3 mm Pad Pitch width = 2.3 mm Readout plane: Readout plane: Effective area: 100 mm×100 mm Field Cage: cathode H.V.: = - 6 kV Beam Test on the Prototype Micromegas-based TPC June 2005 PS Experimental Hall TPC Field Cage

Rosario L. Reserva, Bangalore, India March 9-13, 2006 TPC inside the Jaycee Magnet JECCEE (or PCMAG) Inner diameter : 850 mm Effective length: 1 m Readout-ALEPH TPC electronics: 24 amplifiers with 16 channels each digitized by 6 TPDs FASTBUS FADC: 80ns time slice Pre-amplifier : 500 ns shaping time Jacee Magnet Inner diameter : 850 mm Effective length: 1 m Experimental set -up

Rosario L. Reserva, Bangalore, India March 9-13, 2006 Event Display at B= 1Tesla Some Preliminary Results

Drift Velocity Measurement Method:  determined from the maximum drift time bucket distribution on one pad Average time Resolution for 4 central Padrows = ± 30ns Add: Trigger cable delay = 311±5ns Trigger logic & TPD = 20ns Total Time = ±0.050 cm/µs Total drift length=26.08 cm Ref: Paul Colas Drift time (80 ns clock ticks scintillator counter beam at 45 0 TPC Drift Velocity (Ar+5% Iso) = ±0.034cm/µs ( 220V/cm,P=1002 hPa & Temp=27 o C) Time Distribution Rosario L. Reserva, Bangalore, India March 9-13, 2006

scintillator counter normal beam incidence TPC Time B= 0.5Tesla Padrow ns Padrow ns Padrow ns Padrow ns Total Ave Time = ±0.050cm/µs Total drift length=26.08 cm  Measured Drift velocity(Ar+5%Iso ) Magboltz Simulation: V d = ± cm/µs Measured Drift Velocity (Ar+5% Iso) Beam at normal incidence V d = ±0.036cm/µs in excellent agreement with Time Distribution Rosario L. Reserva, Bangalore, India March 9-13, 2006

Most Tracks are found out to cross in the middle padrows Charge distribution becomes wider at longer drift distance due to diffusion Charge Width Measurement for different drift regions X tract -X center - pad z=0 z=26 B = 0.5 Tesla Rosario L. Reserva, Bangalore, India March 9-13, 2006

Rosario L. Reserva, Bangalore, India March 9-13, 2006 Charge Width Measurement from Pad Response Method: Plotted Qi/Q tot against X tract - X pad-center for different drift regions (N zbins = 15) Reject single & double pad hits Divide the plot into different X-slices Fit each slice with Gaussian function Plotted sigma vs drift length. The slope of the fitted track spread is used to measure the transverse diffusion. B = 0.5 Tesla

Rosario L. Reserva, Bangalore, India March 9-13, 2006 Diffusion Constant Measurements C D measured T T T C D Magboltz B Data Theory Data B = 0 Tesla B = 1.0 Tesla Data Theory with Track segment width as function of Z B = 0.5 Tesla Data Theory Data Theory

Rosario L. Reserva, Bangalore, India, March 9-13, 2006 The fit of the slope for large z gives a good measurement of C D B= 0.5T B= 0T B= 1. 0T Analytical calculation for Ar+5%isobutane with Magboltz diffusion coeff. for B=0, 0.5 and 1 T, =1/46 and Polya fluctuations with  =0.5, pad pitch = 2.3 mm (Program coded by Keisuke Fujii) Theory

Rosario L. Reserva, Bangalore, India March 9-13, 2006 Track Segment Width vs Z –Simulation Studies B=0 B=0.5 T B=1T T T T C D fitC D input B The fit of the slope for large z gives a good measurement of C D by K. Boudjemline

Rosario L. Reserva, Bangalore, India March 9-13, 2006 The Z-dependence of Spatial Resolution At lower z, the spread due to diffusion is small com- pared to pad-pitch. B = 0 Tesla B = 0.5 Tesla Spatial Point Resolution- Two Padrow Measurement pad-pitch dominant region C Data Theory Diffusion dominant region Method: The residual is calculated The residual is calculated & fitted by gaussian func Sigma is plotted for different Sigma is plotted for different drift regions Cd /sqrt(Neff) = 50.7 ± 4.04 x (  0) = 199 ± 15.2(um) B = 0 Tesla Cd /sqrt(Neff)=69.5 ± 4.12 x ( 0) = 154 ± 22.3 (um) Data

Rosario L. Reserva, Bangalore, India March 9-13, 2006 Analytical Calculation for spatial resolution ( adapted from K. Fujii) Pad : 2.3 mm Diffusion Constant : 469, 285 and 193 (um/sqrt cm) for B = 0, 0.5 and 1.0 T Neff = 27.5 B=1.0 Tesla Cd /sqrt(Neff)=40.7 ± 3.64 x (0) = 134 ±76.2 (um) At low drift distances, the resolution tends to pitch/√12 Data B = 0T B = 0.5T B = 1.0T Theory Detailed talks on analytical formulation of resolution limit to be given by K. Makoto

Rosario L. Reserva, Bangalore, India March 9-13, T 0.5T 0T B B= 0 B=1 T Simulation..by Khalil Boudjemline (Carleton Univ) Spatial Resolution  x (z) - Simulation Studies Good agreement with analytical calculation  0 =2.3 mm / √(12x28) = 126  m σ x (0) fit σ x (0) measured 154 ± ± ± ± ± ± 2

Spatial Resolution σ x (0) B=0 T B=0.5 T Cd/ sqrt {N eff } Sigma PR (0) (µm) Cd (µm/  cm) B=1.0 T 134 ± ± ± ± 14.0 B=1.0 T 199 ± ± ± ± 5.93 B=0.5 T 154 ± ± ± ± 5.93 B=0 T Summary of Preliminary Results T572 Beam Test : Micromegas TPC Beam KEK June 22-July 1, 2005 (With 3-Pad Cluster in PR Analysis and & with Pedestal Correction ) Magboltz Prediction Diffusion Constant (Cd) Montecarlo Simulation Diffusion Constant (Cd) ± ±0 186 ± 1 Rosario L. Reserva, Bangalore, India March 9-13, 2006

Prototype Micromegas - TPC had been successfully operated at KEK, Japan. Measured drift velocity is in excellent agreement with Magboltz prediction. At large Z, track segment can be approximated by gaussian fit. C d is calculated from the asymptotic slope of the sqrt(Z) dependence. Measured spatial resolution as a function of drift distance, i.e, σ x (0)  ơ (100)μm to few 100 μm with variation in Z due to diffusion and pad pitch contribution. SUMMARY Rosario L. Reserva, Bangalore, India March 9-13, 2006

ILC- ASIA/ EUROPE/ CANADA TPC Collaboration KEK, Tsukuba, Japan ACFA LCWS06 Organizers MSU-IIT, Phil Rosario L. Reserva, Bangalore, India March 9-13, 2006 Acknowlegment