Radiation hardness of the Avalanche Photodiodes for ECAL CMS detector at CERN

RESMDD02 July 10-12 2002, Florence, A.Singovski, University of Minnesota 1

Radiation hardness of the Avalanche Photodiodes for ECAL CMS detector

at CERN

A. Singovski The University of Minnesota


APD’s in the CMS detector

PbWO4 crystal


Radiation level after 10 years

Radiation doses are in red, 104 Gy. Neutron fluence in green 1013 neutrons/cm 2 with E > 100 keV.

Levels outside of the detector are down by a factor of 100 or more.

Crystal calorimeter

100


APD’s for CMS

Manufacturer:•Hamamatsu Photonics, Japan.

Quantity:•Two APD’s per crystal– 124,000 APD’s with spares.

Accessibility during operation:•None.

Radiation levels:•Maximum expected dose 200 kGy and 2 1013 neutrons/cm2.


Basic APD Structure:

APD is grown epitaxially on an n++ wafer.

Junction

Si2N4 AR coating

Groove to minimize

surface leakage current.

5 5 mm2

active area


APD radiation damage

Radiation damage of APD can influence ECAL performance by essentially two effects:

-rise of the bulk current increase APD noise contribution to the energy resolution

-early breakdown breakdown happens before APD can reach operation point at Gain=50


APD contribution to the ECAL resolution

Resolution:

where, a : due to intrinsic shower fluctuations & photo statistics

b : related to stability and reproducibility c : noise contributions CMS design goal : a ~3%, b~0.5%, c~200 MeV APD contributions: a - photo statistics (area, QE) & excess noise factor b - gain variation with bias voltage and temperature c - capacitance as series noise and dark current as parallel noise

E

cb

GeVE

a

E

E⊕⊕=

)(σ

σ σ σtotal parallel series= +2 2

( ) τσ qFMII dbdsparallel ⋅+= 2

⎟⎟⎠

⎞⎜⎜⎝

⎛+⋅

⋅= R

gCkT

series

7.02

4 2

τσ

M = APD gain F = excess noise factor τ=shapingtimeconstantq=electronchargeIds=darksurfacecurrentIdb=darkbulkcurrentR=seriesresistanceC=capacitanceofAPDandamplifierk=BoltzmannconstantT=absolutetemperatureg=transconductanceofamplifierfirststage


Irradiation Tests.

Irradiation with protons:•70 MeV protons beam at PSI – Switzerland.

•11013 hadrons/cm2 in ~ 2 hours.

Irradiation with gammas.•All irradiation with 60C0 source.

Irradiation with neutrons.•Californium source (252Cf) for irradiation at the University of Minnesota.

•2 1013 neutrons/cm2 in ~ 2 days.


Device failure

0

5

10

15

20

25

30

35

0 1000 2000 3000 4000 5000 6000 7000 8000Time (s)

Dark Current (

μ)A

Irradiation in a 70 MeV proton beam.


Neutron irradiation facility

Draws for irradiation

Use old tandem laboratory facility in Minneapolis to store and operate two 7 mg sources for irradiation samples.

•High and low flux areas 1013 and 1011

n/cm2 in 2 – 4 days.

•Must provide biases to components during irradiation.

•Return sources after 4 years of operation.


Neutron irradiation results

705 APD's Irradiated - Includes Source Decay

y = 1.3954E-11x

R2 = 8.6333E-01

0

50

100

150

200

250

300

0.0E+00 5.0E+12 1.0E+13 1.5E+13 2.0E+13

Integrated Neutron Flux (neutrons cm-2)

Id/M (nA) at Gain 50


Durk current

Total Current (dark current + ionisation current)

02468

101214161820

0.00E+00 5.00E+12 1.00E+13 1.50E+13 2.00E+13

total Neutron Flux / cm2

Current [

μ]A

Current vs Flux

0

5

10

15

20

25

0 2E+12 4E+12 6E+12 8E+12 1E+13 1.2E+13 1.4E+13

Total neutron flux

Current at M=50, mkA

3003006176

2802004514

70 MeV protons

1 MeV neutrons from 252Cf


Neutron irradiation summary

1.All APD tested so far survived -> no significant shift in breakdown voltage.

2.The mean bulk current after 2x1013 neutrons/cm2 is Id280nA (non-amplified value).

3.It corresponds to 14μA at Gain=50 and ~ 80MeV noise contribution (no-recovery case, CMS TDR).

Acceptable for CMS ECAL detector


Gamma irradiation

APDs

32 wires containing 60Co surround the probe and give a very uniform irradiation field.

Present activity is 2.5 kGy/h

60Co irradiation facility at PSI


Gamma irradiation results

Lot 34 Breakdown Voltage Comparison

-30

-25

-20

-15

-10

-5

0

5

8900 9000 9100 9200 9300 9400 9500 9600

APD #

VB(irradiated)-V

B(Hamamatsu) [V]

Rejected


Gamma irradiation results 2

APD with a significant shift of Vb after 60Co

irradiation

(vs. good one)

Id/Gain

Noise


Screening

Method:

- irradiate 100% of APD`s (0.5 Mrad) with Co-60 gamma source (at PSI);

- measure VB and Id(V) of all irradiated APD`s 1 day after irradiation (at PSI);

- measure noise at M=1, 50, 150, 300 before annealing (at CERN APD Lab)

- anneal all APD`s in the oven (for 4 weeks at T=80C, at CERN APD Lab);

- measure VB, Id(V) after annealing/ageing (at CERN APD Lab);

-reject potentially non-reliable APD`s: ones showing

-Shift of Vb more than 5V

-high Id

-high noise


APD rejection

High dark current High noise


Screening efficiency

Double irradiation (225 APDs from lot##33,34)

-5

-4

-3

-2

-1

0

1

2

3

0 50 100 150 200 250

APD #

Change of VB [V]dVB(after first Co-irr.)

dVB(after annealing)

dVB(after second Co-irr.)

225 APD`s which passed 1st irradiation and annealing were irradiated the 2nd time. No change of VB>2V was

found for all APD`s !!!


Gamma irradiation summary

1.APDs are sensitive to the gamma irradiation.

2.Several percents “die” after irradiation -> get a breakdown close to the operation point.

3.Screening, applied to 100% of APDs make them 99.9% rad. Hard.

Radiation hardness of the Avalanche Photodiodes for ECAL CMS detector at CERN

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