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LC TPC R&D Results May 2003 1
Selected LC TPC R&D Resultsfor the DESY RPC Meeting 2003 May 07
The LC TPC R&D Groups of the PRC R&D-01/03 Proposal
Carleton, Montreal, Victoria,Orsay, Saclay,
Aachen, DESY, Hamburg, Karlsruhe, MPI-Munich, Rostock, NIKHEF, Cracow,
Novosibirsk, St. Petersburg,Berkeley, MIT
AbstractExamples of the results from TPC R&D studies are collected here. They were part of the full PRC
presentation (alephwww.mppmu.mpg.de/~settles/tpc/tpcstatus070503.ppt). In the following a more detailed description of the results has been added to selected foils showing results to
supplement the note submitted to the PRC (alephwww.mppmu.mpg.de/~settles/tpc/tpcprcstatus070503.ps). Recent tests in high magnetic field also have been emphasized since this was encouraged the original PRC recommendations
of 2001 October 26
EXAMPLE OF A LARGE TPC SET-UP
2
DESY/Hamburg large Gem prototype (B=0)
Several TPC prototypes, large and small, are now in operation. Shown here is the large one in DESY/Hamburg which uses cosmic rays to study the tracking characteristics using GEM gas-amplification. Obviously these studies are with no magnetic field. The size of the chamber is suitable for studies of gas properties and of the impact of readout geometry on the coordinate resolution.
RESULTS ON RESOLUTION AT LARGE DRIFT DISTANCE
3
DESY/Hamburg
An example of the results from the DESY/Hamburg test chamber (p.1). In the early version of the set-up, the first GEM foil was at ground potential for the drift volume, which meant that the pads were at ca. 2 kV. This turned out to be somewhat delicate and was changed in order to run the pads at ground which enabled more sensitive measurements.
SET-UP FOR DIFFERENT PAD GEOMETRIES
4
Double GEM TPC Cosmic Ray Tests Carleton/Victoria/Montreal
•Aleph TPC preamps + Montreal 200 MHz FADCs•15 cm drift (no B field)•Pads can share track charge due to transverse diffusion
•Ar CO2(90:10), small T ~ 200 m / cm•P10 Ar CH4(90:10), large T ~ 500 m / cm
•Compute pad centroids, measure resolution for different width padsHere is the Carleton test chamber using GEMs. Again there is no magnetic field, and the pad layout is with 3x multiplexed readout (thus the mirrored hits in right diagram). Drift distances up to 15cm, two different gases (Argon with CO2 or CH4) and resolution with different pad widths (2mm and 3mm) have been studied; the pads were rectangular and charge sharing took place via transverse diffusion in the induction gap (between GEM and anode). The track was defined by outer rows (3 on each side) and the resolution measured on the middle rows (see p.5).
FURTHER RESULTS VS DRIFT DISTANCE
5
3 mm x 5 mm pads2 mm x 6 mm pads
Ar CO2P10
Resolution vs Drift Distance for Different Pad Widths |φ| < 0.1
Carleton/Victoria/Montreal
3 mm x 5 mm pads2 mm x 6 mm pads
cm cm
Single pad row resolution measurements from the Carleton TPC (p.4). Tracks are formed from the outer 6 rows, and residuals calculated for each of the two inner rows with 2mm x 6mm and 3mm x 5mm pads. The residuals are fit to Gaussians, and the standard deviations (in microns) is shown here for different drift distances.
TEST MEASUREMENT USING STAR ELECTRONICS
6
TPC cosmic tests at Karlsruhe
Cosmic ray setup using STAR electronicsMeasured resolution 124 m, S/N = 18:1
The Karlsruhe test chamber with GEMs (left) has recorded cosmics. It was also exposed to a test beam in CERN (on the right is a track). The readout took place using the STAR electronics test-stand supplied by LBNL. The tests were with no magnetic field, but the chamber can fit into the 5T magnet at DESY.
GEM DEVELOPMENT IN RUSSIA
7
Novosibirsk
Russian GEM manufacturing company in Nijni Novgorod
(80 m holes at a 140 m pitch)
Gating the 1st GEM by pulsingUsing a test chamber at Novosibirsk, GEM manufacturing and gating are under study, among other things.
Left: Gain-voltage characteristics of the triple-GEM structures, produced by a local company at Nijni Novgorod with active areas of 28mm x 28mm and 100mm x 100mm. Gains as high as few tens of thousands can be reached. Right: Electron transparency of a GEM as a function of the GEM voltage, at the induction field of 100 and 1000 V/cm. At zero GEM voltage the GEM transparency to electrons and ions can be as low as 0.01, and the voltage needed to "open" the GEM, in a gating mode, is about 300 V.
NEW READOUT CONCEPT USING PIXELS
8
NIKHEF
MediPix2 Si-pixel detector
Cathode foil
GEM foils
base plate
MediPix 2
Drift Space
Medical application TPC test
At NIKHEF a new idea is being tried out, namely to read out a TPC using a Si detector with pixels matching the GEM-hole pitch. Left: the MediPix2 chip has 256 x 256 pixels of 55 x 55 µm², low noise and a minimum threshold of about 1000 electrons. Right: schematic view of the one liter test TPC with a triple-GEM foils and an insert in the base plate for the MediPix2 chip.
GEM ELECTRON DRIFT STUDIES
9
Aachen
Three test chambers have been built in Aachen (see also below) and detailed simulations on GEM properties is also being carried out. On the left are the simulated electron-drift trajectories in a GEM using the programs MAXWELL and GARFIELD, and on the right is the calculated extraction efficiency compared with measurements. The black curve is a parameterization of results from simulation with MAXWELL only, which is adequate for gases with small diffusion. The data points labeled “MC simulation” are due to the combination of MAXWELL+GARFIELD so that diffusion is included. That simulation and results agree well will be important for the final optimization of a GEM TPC readout.
HIGH-FIELD MAGNETS 10
Right: The 2T superconducting solenoid magnet inoperation in Saclay has a 53 cm bore diameterand a length of 150 cm. It has been used for testing two Micromegas TPCs and a wire TPC built by Saclay/Orsay using current measurements. It is nowbeing equipped with a 1000-channel cosmic ray Micromegas prototype with a 50 cm drift length.
Left: The 5T superconducting solenoid at DESY which started operation at the end of last year. First tests (see below, p.11) were made using a small GEM device built at Aachen to allow measurement of all currents in order to derive the charge-transfer characteristics. Similar measurements had previously been carried out in a 2T magnet at Jülich.
SACLAY
DESY
GEM CURRENTS VS B-FIELD 11
Here are the results mentioned above (p.10) from the Aachen test chamber in the DESY magnet. The variouscurrents arise from an Fe55 source. The anode current (electrons arriving at pads) rises significantly with B-field. In order to understand this, the triple-GEM structure was run symmetrically with GEM voltages at 330V and transfer fields at 1kV/cm, so that the anode current was the primary current times C³G³X³. The collection times gain drops slightly while the extraction improves, meaning only few primary electrons are lost during collection at 5Twhile the net gain of the overall structure increases at higher B-fields.
ION-FEEDBACK in B-FIELD for MICROMEGAS, GEMs
12
Left: the ion-feedback improves at high magnetic field in GEMs, as seen from the Aachen/DESY measurements described on pp.10-11.
Right: Positive ion feedback fraction as a function of magnetic field, as measured in the 15cm Orsay/Saclay Micromegas TPC. No dependence on the magnetic field is observed, consistent with expectations, and it is about 3 times the optimal feedback due to the use of a relatively coarse micromesh (500 lines per inch). A finer mesh (1000 lpi) should allow reaching the optimal feedback with this gas (Ar10%CH4). Orsay/Saclay
LC TPC R&D Results May 2003 13
Summary ↔ Outlook
• Measurements in high B-field have started, with encouraging results for the charge-transfer coefficients for GEM and Micromegas
• Better understanding of amplification and resolution achieved
• Test-stand infrastructure now functioning for systematic optimization
• Resolution in high B-fields must be measured for all three technologies, GEM, Micromegas and wires
• Design and testing of large prototypes should follow promptly
• Mechanics, electronics and field cage design studies should start now
LC TPC R&D Results May 2003 14
Milestone exercise TPCThe TPC group went through the exercise of seeing
what steps are involved in producing a final detector and came up with the following realistic milestones (the first two are rather ambitious).
• 2005 - “Large” TPC prototype design/testing • 2007 - Final design all components • 2011 - Four years for construction • 2012 - Commission TPC alone• 2014 - Install and integrate