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Detectors and electronics for Super-LHC: IRRADIATION RESULTS Andrea Candelori INFN Sezione di Padova.

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Presentation on theme: "Detectors and electronics for Super-LHC: IRRADIATION RESULTS Andrea Candelori INFN Sezione di Padova."— Presentation transcript:

1 Detectors and electronics for Super-LHC: IRRADIATION RESULTS Andrea Candelori INFN Sezione di Padova

2 OUTLINE 1) Nuclear reactor irradiation in Lubiana: -MCZ n-type detectors(SMART) -Epitaxial n-type detectors(SMART) 2) 24 GeV proton irradiation at CERN: -Epitaxial n-type detectors(SMART) -FZ thinned n-type detectors(SMART) - 0.13  m CMOS technology(DEI) The presented results are from experiments performed by: -SMART Collaboration (Bari, Firenze, Pisa, Padova, Perugia, Trieste, Trento) -Department of Information Engineering (DEI), University of Padova Measurements are in progress …

3 DETECTORS -MCZ detectors Substrate: MCZ, n-type, 300  m thick,  = 0.6 k  ×cm, from Okmetic Detector processing: IRST -Epitaxial detectors Epitaxial layer: n-type, 50  m thick,  = 50  cm, grown by ITME on CZ substrate Detector processing: IRST -FZ thinned detectors Substrate: FZ, n-type, 300  m thick,  = 6 k  ·cm Thinning: down to 50-100  m by Tetra Methyl Ammonium Hydroxide (TMAH) etching from backside: IRST Detector processing: IRST

4 MCZ n-type 300  m thick detectors: neutron irradiation  The minimum of V dep is reached at 1-1.5×10 14 n/cm 2.  V dep is  650 at 10 15 n/cm 2. Measurements after irradiation and before annealing

5 Epitaxial n-type 50  m thick detectors: neutron irradiation Measurements after irradiation and before annealing  The minimum of V dep  40-50 V is reached at 2-4×10 15 n/cm 2.  V dep < V dep,0 at 8×10 15 n/cm 2.

6 Epitaxial n-type 50  m thick detectors: neutron irradiation  V dep decreases for annealing times at 80  C higher than 8 minutes.  If this effect is due to deep acceptor generation, devices are not type inverted.

7 Epitaxial n-type 50  m thick detectors: neutron irradiation  J D increases linearly with fluence.  J D decreases with annealing time at 80  C.

8 Epitaxial n-type 50  m thick detectors: neutron irradiation  J D decreases with annealing time at 80  C. 0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 110100 Annealing time at 80  C (min) J D scaled to 20  C (A/cm 3 ) 8×10 15 6 ×10 15 4 ×10 15 3 ×10 15 2 ×10 15 1 ×10 15  n/cm  

9 Epitaxial n-type 50  m thick detectors: proton irradiation Measurements after irradiation and before annealing  The minimum of V dep for protons (90-100 V) is higher than for neutrons (40-50 V).  V dep > V dep,0 at 10 16 p/cm 2.  The radiation effects induced by neutrons and protons are different. neutrons

10 Epitaxial n-type 50  m thick detectors: proton irradiation  V dep decreases for annealing times at 80  C higher than 8 minutes.  If this effect is due to deep acceptor generation, devices are before SCSI after irradiation: for devices irradiated at low fluences V dep ↑, ↓: no SCSI during long-term annealing; for devices irradiated at high fluences V dep ↑, ↓, ↑: SCSI during long-term annealing.

11 FZ thinned n-type detectors: proton irradiation Device thinning limits the V dep increase after irradiation: -V dep  290 V for 100  m thick detectors at 8×10 15 p/cm 2 -V dep  70 V for 50  m thick detectors at 10 16 p/cm 2 Measurements after irradiation and before annealing 0 100 200 300 024681012 Fluence (10 15 24 GeV protons/cm 2 ) V dep (V) 50  m 100  m

12 FZ thinned n-type detectors: proton irradiation 0.00 0.05 0.10 0.15 0.20 0.25 0.30 024681012 Fluence (10 15 24 GeV protons/cm 2 ) J D scaled to 20  C (A/cm 3 ) 50  m 100  m Measurements after irradiation and before annealing  J D linearly increases with fluence, independently on the thickness. (some data dispersion is present)

13 DETECTORS: future activity CERN, 24 GeV protons, May 2004 (n-type materials) Lubiana, nuclear reactor neutrons, December 2004 (n- and p-type materials)

14 ELECTRONICS -Electronics for LHC (10 Mrad(Si) and 10 15 fast hadrons/cm 2 ):  0.25  m CMOS technology from IBM;  5.5 nm oxide thickness;  radiation hardened by design: enclosed geometry transistors. The 0.25  m CMOS technology will not be any more available for Super-LHC -Electronics for Super-LHC (100 Mrad(Si) and 10 16 fast hadrons/cm 2 ): following the scaling down of the commercial CMOS technologies?  0.13  m minimum channel length;  2.5 nm oxide thickness;  no radiation hardened by process;  no radiation hardened by design (i.e., no enclosed geometry).

15 0.13  m CMOS technology: proton irradiation n-channel MOSFET p-channel MOSFET  g M peak decrease 15%  g M peak shift negligible  g M peak decrease higher than in n-MOSFET  g M peak shift of 200 mV

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