gamma-ray spectroscopy

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Gamma-Ray Spectroscopy

Dr.Ir. Peter Bode Associate Professor Nuclear Science &

Engineering

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

INAA:Semiconductor detectors

RNAA:Semiconductor detectorsScintillation detectors

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Principle of a semiconductor detector

Solid-state ionisation detectors

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detectors

N-type Ge:

Impurities such as P and As as electron donors

P-type Ge:

Impurities as B, Al, Ga as positive charge donors

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detectors

Semiconductor detector:

Junction diode with P and N type impurities on either side

Applying a reverse bias:

A P-I-N structure is formed

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

n-type silicon

e

h

-V 0

qe dV1

qh dV2

dq = (qedV1 + qhdV2 )/V

i = dq/dt

n+ contact

p+n junction

reverse bias, fully depleted

• silicon diode

• germanium detector

Solid-state ionisation detectors

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Atomic

number Operating

temperature (K)

Band Gap, eV

Electron mobility,

(cm2V-1s-1)

Hole mobility

(cm2V-1s-1)

Energy to produce an electron-hole pair, eV

Si 14 77 300

1.16 1.12

2.1 .104

1500 1.1.104

500 3.76 3.61

Ge 32 77 0.67 3.6 . 104 4.2.104 2.96

GaAs 21 33 130

300

1.43

8500

400 4.51 4.2

CdTe 48 52 300 1.47 1100 100 4.43

Cd1-x Znx Te 48 30

52 300 1.44 (x=0)

- 2.26

(x=1); typically

1.5-2.2 for x=0.1 -0.2

1350 120 4.43 (x=0) –

(x=1); typically 5.0-5.5 for

x=0.1-0.2

HgI2 80 53 300 2.13 100 100 4.22 Some properties of semiconductor materials

Solid-state ionisation detectors

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Schematic representation of a Ge-semiconductor detector,

Solid-state ionisation detector

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detector

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detectors

Contacts:

n+: diffusion of Li-atoms 700 – 1000 m (dead layer)

p+: implantation of B-atoms 0.3 m

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

•Different types of Ge semiconductor detectors

Solid-state ionisation detector

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detector

Channel number pulse height

No.o

f p

uls

es

(*

10

00

)

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detector

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Solid-state ionisation detector

Pulse height spectra obtained with Si(Li) detectors.Left: X-ray spectrum of 241AmRight: - spectrum of 241Am

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Different types of cryostats for use with Ge-semiconductor detectors

Solid-state ionisation detector

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Energy resolution

Usually:

Full Width on Half Maximum @ 1332 keV of 60Co

@ 122 keV of 57Co

@ 6 keV of 55Fe

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Energy resolution

State-of-the-art:

1332 keV: 1.58 – 2.0 keV, depending on crystal size

122 keV: 0.6 – 1 keV

5.9 keV: 0.2 – 0.5 keV

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Peak Shape

Ratio of :

FWHM/Full Width 0.1 M

FWHM/Full Width (1/50) M

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Gamma-ray peak shape and tail parameters

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Peak Shape

Ratio of :

FWHM/Full Width 0.1 M theoretically: 1.83

FWHM/Full Width (1/50) M theoretically: 2.38

Importance: symmetry !!!

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

High energy (top) and low energy tail parameters

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

High energy tail of pulser peak

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

High energy tail of pulser peak

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Calibration source activity

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Peak-to-Compton ratio

Defined as:

Ratio of peak height at 1332 keV and average peak height in energy range between 1040 and 1096 keV

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Peak-to-Compton ratio

State-of-the-art:

p/C ~ 50-100, depending on size of crystal:

pC = 34.75 + 1.068 (εCo-60) - 4.96.10-3 (εCo-60)2

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Efficiency

Absolute efficiency defined as:

Relative to the efficiency of a 3” x 3 ” NaI(Tl) detector,

defined as 1.2.10-3 counts/1332 keV photon,measured at a source-detector distance of 25 cm

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Determination of photopeak efficiency curve

Absolute: Using calibrated sources with known gamma-ray emission rates and activity values, traceable to Bq

Single gamma-ray emitting radionuclidesPoint sourcesExtended sources

Problem:Many sources contain 60Co and 88Y; corrections for coincidence effects require also the p/T curve

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Determination of photopeak efficiency curve

Relative:

Using mix of sources with well-established gamma-ray intensity ratios

1 source for entire energy range, e.g. 152Eu

2-5 sources, e.g. 182Ta + 133Ba + 75Se + 24Na + … Problem:Intensity ratios not always well established

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Determination of photopeak efficiency curve

Relative:

1 source:advantage: simpledisadvantage: do not always fully cover entire energy range; inter/extra-polation disputable in 80-150 keV range

3-5 sources:advantage: better coverage all energy rangesdisadvantage: more cumbersome, problems with non-matching parts

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Determination of efficiency curves

Relative:

Using mix of sources with well-established gamma-ray intensity ratios

1 source for entire energy range, e.g. 152Eu

2-5 sources, e.g. 182Ta + 133Ba + 75Se + 24Na + …

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

New Tools for Nuclear Spectroscopy

Better and bigger Ge detectors High count rate electronics

High-resolution scintillation detectors (LaBr3(Ce))

Position-sensitive (strip) detectorsMonte Carlo modelingImage processing

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Bigger Ge- Detectors

100 10000.1 %

1 %

10 %

100 %

3000

Absolute photopeak efficiency

75 cm3 (17 %) 4 cm

560 cm3 well

Photon energy, keV

0.3 % 20 %

3 % 90 %

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Typical improvement in detection limits

20 %

100 %

well125 cm3

Arbitrary units

0,01 0,1 1

0,01 0,1 0,25-0,3 1

0,01 0,1 0,15-0,25 1

Bigger Ge-Detectors

well560 cm3

0,01 0,1 1

0,07 - 0,1

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

New Tools for Nuclear Spectroscopy

LaBr3(Ce) scintillation spectra

P.Doorenbos et.al., IEEE Transactions 51 (2004) 1289Developed and Patented by T.U.Delft: produced by Saint Gobain, France

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Preamplifiers

- Resistor feedback- Pulse optical feedback

high resolutions (planar detectors)

- Transistor feedbackhigh count rates

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

NIM bin and power supply

- Adequate capacity

- standard: +/- 24 V +/- 12 V +/- 6 V

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

High Voltage supply

Typically (+/-) 3-5 kV

Different power supplies for Ge and NaI(Tl) detectors

dV/dt networks

LN2 switchoff option

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Spectroscopy Amplifiers

Analogue systems

Digital systems

- Gaussian shaping- Triangular shaping- Gated-integrated shaping

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Baseline retoration and Pole-zero setting

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Spectroscopy Amplifiers

Essential:

- Amplifier and HV at opposite outermost places in NIM-BIN- Match amplifier’s output DC level to ADC’s input DC level

- High time (shaping) constant: better resolution, lower

throughput Often typically set at 3 s for most (coaxial) detectors 6 s for planar detectors

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

ADC

- Linear Approximation or Wilkinson ADC- Successive Approximation ADC

Wilkinson ADC’s : best linearity

Wilkinson ADC: dead time depends on channel no.

Succ. Appr. ADC: fixed dead time per channel.

Settings: zero level, lower level, upper level, conversion gain

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Pulse generators

- Used for dead time/pile-up correction

- Fed into the test input of the preamplifier

- Essential: input peak shape must match detector signal (rise time and fall time (1000-2000 s )

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Dead-time stabilizer

Loss free counting

Digital dead-time stabilizer

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Signals

Use oscilloscope

Track:

- Output signal preamplifier

- Output signal spectroscopy amplifier

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Bad signals

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Low energy tailing:

- wrong baseline restoration- incomplete charge collection

High energy tailing:- wrong baseline restoration

Peak broadening:- increased noise- incomplete charge collection

Shifts/instability:- proportional: gain- constant: DC problems

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Spectral shape

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Photoelectric effect (1)

The photon energy is transferred to an atomic electron

KL

e-

h

3

4

, h

Ze Cross section

Energy photo-electron: be EhE

Photo-electron

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Compton effect (1)h

h’

Ee-

Energy conservation:

Energy Compton electron:

Angular correlation:

)cos1(1

)cos1()(

2

2

2

cmhcmh

E

e

ee

'hvEhv e

Partial energy transferto a ‘free’ electron

2tan1)cot( 2

cm

h

e

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

h

h’

Ee-

Angular distribution of the scattered photons

0

90

180

270

0 1 2

10 MeV

1 MeV0.1 MeV

0.01 MeV

richting invallend

foton

Compton effect (3)

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Only if

• E > 1022 keV

Mainly if• high Z

Pair production

Annihilation

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Interactions of photons

10 -2 10 -1 10 0 10 1 10 2

Photon energy (MeV)

0

20

40

60

80

100A

tom

ic n

um

ber

Z

Photo-Electric Effect

dominantPair Production

dominant

Compton Effect

dominant C =

= C

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Photon interacts with crystal:

• Absorption of all energy by photoelectric effect

• Absorption of all energy by multiple scatteringand subsequent absorption by photoelectric effect

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Photon interacts with crystal:

3. Absorption of part of the energy of the photon due to scattering effects and escape of scattered photon from the crystal

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Photon interacts with crystal:

3. If energy of photon > 1022 keV: pair production effects:

-All energy absorbed- One of the electrons escapes from the crystal: only E- 511 keV deposited- both scattered electrons escape from the crystal:E-1022 keV deposited

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Photon interacts with crystal:

4. Al low energies:

All energy transferred to Ge electrons, but scattered Ge electrons escape from crystal:

E-(Ge-k) keV deposited in crystal

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Coincidence effects

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Coincidence effects

Coincidence count rate: Rc = D.1.2

Random coincidence count rate: Rr = 2..R1.R2

Rr = 2..D2. 1.2

1, 2 : total counting efficiency

(= full energy photopeak efficiency x peak/Total ratio)

Relevant:True coincidence effects: Absolute efficienciesRandom coincidence effects: Count rate + absolute efficiencies

In all cases needed: peak-to-Total ratio

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Measuring the p/T curve

Simple: using e.g. 65Zn or 137Cs

Complex: modeling using MCNP

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Coincidence effects

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Coincidence effects

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Coincidence effects

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Compton suppression systems

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Compton suppression spectometerTiming Electronics

Anti-coincidence

Spectroscopy electronics

Analogue to Digital

converter

Multi-channel pulse-height

analyzer

Annular scintillation detector shield with

plug detector

Sample

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Gamma-ray spectrum of 137Cs, recorded with and without Compton suppression.

Compton suppression spectrometer

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Compton suppression spectrometer

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Compton suppression spectrometer

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Selecting a detector

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

P.Bode, J.Radioanal.Nucl.Chem. 222 (1997) 117-125 + 127-132

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Errors in gamma-ray spectroscopy

- Source-to-detector distance

- Filling height and source-self attenuation effects

- Coincidence summing effects

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Steps to be taken for an NAA laboratory

Vial with comparator

Vial with comparator

Vial with sample

Neutron fluence rate

Estimation neutron fluence rate at sample position

Not necessarily the arithmetic mean of the comparator values !

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Source-detector distance

Source-end-cap distance e.g. R cm

End-cap thickness + end-cap-crystal distance e.g 0.6 cmDistance to average point of complete absorption of photon energy e.g. 2.5 cm

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Steps to be taken for an NAA laboratory

Don’t correct just for difference in distance to end-cap! Include distance to average interaction point inside the Ge crystal (typically at ~ 1.5-2.5 cm (depends on size of detector; add 0.5 cm crystal-end cap distance)

sample standard

10 cm

0.5 cm

0.2 cm

0.5 cm2.5

cm

Correction for count rates: {10+ (0.5/2)+0.5 + 2.5}2/{10+(0.2/2)+0.5 + 2.5}2 = 1.023

Assuming uncertainty in interaction depth 1 cm: correction is then 1.025

Uncertainty of correction is difference between these corrections, viz. 0.2 %

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Source-detector distance

0 5 10 15 201.0

1.5

2.0

2.5

3.0

3.5

Co

rre

ctio

n f

act

or

Source-to-endcap distance (cm)

Source height 0.1 cm 0.2 cm 0.3 cm 0.5 cm 1 cm 2 cm 5 cm

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008

The mot optimal choice

Summer CourseInstrumental Neutron Activation

Analysis

July 7-18, 2008