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Gamma and X-Ray Detection -
Detector Overview
The kinds of detectors commonly used can be categorized as:
- Gas-filled Detectors
- Scintillation Detectors
- Semiconductor Detectors
The choice of a particular detector type for an application
depends upon the X-ray or gamma energy range of interest and the
application’s resolution and efficiency requirements. Additional
considerations include count rate performance, the suitability of
the detector for timing experiments, and of course, price.
Detector Efficiency
The efficiency of a detector is a measure of how many pulses
occur for a given number of gamma rays. Various kinds of efficiency
definitions are in common use for gamma ray detectors:
Absolute Efficiency
The ratio of the number of counts produced by the
detector to the number of gamma rays emitted by the source (in all
directions).
Intrinsic Efficiency
The ratio of
the number of pulses produced by the detector to the number of gamma
rays striking the detector.
Relative Efficiency
Efficiency of
one detector relative to another; commonly that of a germanium
detector relative to a 3 in. diameter by 3 in. long NaI crystal,
each at 25 cm from a point source, and specified at 1.33 MeV
only.
Full-Energy Peak (or Photopeak)
Efficiency
The efficiency for producing full-energy
peak pulses only, rather than a pulse of any size for the gamma
ray.
Clearly, to be useful, the detector must be capable of absorbing
a large fraction of the gamma ray energy. This is accomplished by
using a detector of suitable size, or by choosing a detector
material of suitable high Z. An example of a full-energy peak
efficiency curve for a germanium detector is shown in Figure 1.1
below.
Figure 1.1 Efficiency
Calibration
Detector Resolution
Resolution is a measure of the width (full width half max) of a
single energy peak at a specific energy, either expressed in
absolute keV (as with Germanium Detectors), or as a percentage of
the energy at that point (Sodium Iodide Detectors). Better (lower)
resolution enables the system to more clearly separate the peaks
within a spectrum. Figure 1.2 shows two spectra collected from the
same source, one using a sodium iodide detector and one using
germanium.
Even though this is a rather simple spectrum, the peaks presented
by the sodium iodide detector are overlapping to some degree, while
those from the germanium detector are clearly separated. In a
complex spectrum, with peaks numbering in the hundreds, the use of a
Germanium detector becomes mandatory for analysis
Gas-Filled Detectors
A gas-filled detector is basically a metal chamber filled with
gas and containing a positively biased anode wire. A photon passing
through the gas produces free electrons and positive ions. The
electrons are attracted to the anode wire and collected to produce
an electric pulse.
At low anode voltages, the electrons may recombine with the ions.
Recombination may also occur for a high density of ions. At a
sufficiently high voltage nearly all electrons are collected, and
the detector is known as an ionization chamber. At higher voltages
the electrons are accelerated toward the anode at energies high
enough to ionize other atoms, thus creating a larger number of
electrons. This detector is known as a proportional counter. At
higher voltages the electron multiplication is even greater, and the
number of electrons collected is independent of the initial
ionization. This detector is the Geiger-Müller counter, in which the
large output pulse is the same for all photons. At still higher
voltages continuous discharge occurs.
The different voltage regions are indicated schematically in
Figure 1.3. The actual voltages can vary widely from one detector to
the next, depending upon the detector geometry and the gas type and
pressure.
Figure 1.3: Gas Detector Output vs. Anode
Voltage
Ionization Chamber
The very low signal output for the ionization chamber makes this
detector difficult to use for detecting individual gamma rays. It
finds use in high radiation fluxes in which the total current
produced can be very large. Many radiation monitoring instruments
use ionization chambers. Absolute ionization measurements can be
made, using an electrometer for recording the
output.1
1A.C. Melissinos,
Experiments in Modern Physics, Academic Press, New York (1966), p.
178.]
Proportional Counter
Proportional counters are frequently used for X-ray measurements
where moderate energy resolution is required. A spectrum of
57Co is shown in Figure 1.4 in which 14.4 keV gamma rays
are well-separated from the 6.4 keV x rays from iron.
Proportional counters can be purchased in different sizes and
shapes, ranging from cylindrical with end or side windows to
"pancake" flat cylinders. They may be sealed detectors or operate
with gas flow, and may have thin beryllium windows or be windowless.
A detector is typically specified in terms of its physical size,
effective window size and gas path length, operating voltage range
and resolution for the 5.9 keV x ray from a 55Fe source
(Mn x ray). Typical resolutions are about 16 to 20% full-width at
half maximum (FWHM).
Operating voltages depend upon the fill gas as well as the
geometry. For x rays, noble gases are often used, with xenon,
krypton, neon and argon common choices. Xenon and krypton are
selected for higher energy x rays or to get higher efficiencies,
while Neon is selected when it is desired to detect low energy x
rays in the presence of unwanted higher energy x rays. Sometimes gas
mixtures are used, such as P-10 gas, which is a mixture of 90% argon
and 10% methane. Gas pressures are typically one atmosphere. The
preamplifiers available for proportional counters are shown in
Figure 1.5
Figure 1.5: Proportional Counter and
Preamplifier
Geiger-Müller Counter
The Geiger-Müller counter produces a large voltage pulse that is
easily counted without further amplification. No energy measurements
are possible since the output pulse height is independent of initial
ionization. Geiger-Müller counters are available in a wide variety
of sizes, generally with a thin mica window. The operating voltage
is in the plateau region (see Figure 1.3), which can be relatively
flat over a range of bias voltage. The plateau is determined by
measuring the counting rate as a function of the anode voltage.
The discharge produced by an ionization must be quenched in order
for the detector to be returned to a neutral ionization state for
the next pulse. This is accomplished by using a fill gas that
contains a small amount of halogen in addition to a noble gas. The
voltage drop across a large resistor between the anode and bias
supply will also serve to quench the discharge since the operating
voltage will be reduced below the plateau.
The Geiger-Müller counter is inactive or "dead" after each pulse
until the quenching is complete. This dead time can be hundreds of
microseconds long, which limits the counter to low count rate
applications.
Scintillation Detectors
A gamma ray interacting with a scintillator produces a pulse of
light, which is converted to an electric pulse by a photomultiplier
tube. The photomultiplier consists of a photocathode, a focusing
electrode and 10 or more dynodes that multiply the number of
electrons striking them several times each. The anode and dynodes
are biased by a chain of resistors typically located in a plug-on
tube base assembly. Complete assemblies including scintillator and
photomultiplier tube are commercially available from Canberra.
The properties of scintillation material required for good
detectors are transparency, availability in large size, and large
light output proportional to gamma ray energy. Relatively few
materials have good properties for detectors. Thallium activated NaI
and CsI crystals are commonly used, as well as a wide variety of
plastics. NaI is the dominant material for gamma detection because
it provides good gamma ray resolution and is economical. However,
plastics have much faster pulse light decay and find use in timing
applications, even though they often offer little or no energy
resolution.
NaI(Tl) Scintillation Detectors
The high Z of iodine in NaI gives good efficiency for gamma ray
detection. A small amount of Tl is added in order to activate the
crystal, so that the designation is usually NaI(Tl) for the crystal.
The best resolution achievable ranges from 7.5%-8.5% for the 662 keV
gamma ray from 137Cs for 3 in. diameter by 3 in. long
crystal, and is slightly worse for smaller and larger sizes. Figure
1.6 shows, respectively, the absorption efficiencies of
various thicknesses of NaI crystals, and the transmission
coefficient through the most commonly used entrance windows.
The family of curves are derived from NBS
circular 583 (1956), Table 37, mass attenuation coefficients for
NaI(Tl). Each curve represents the percent absorption
(l-attenuation) of a parallel beam of gamma rays normally incident
on that thickness NaI(Tl) crystal.
Compiled from NBS Circular 583 and
supplement to NBS Circular 583. (Estimated Max. Error
±2%)
Many configurations of NaI detectors are commercially available,
ranging from crystals for x-ray measurements in which the detector
is relatively thin (to optimize resolution at the expense of
efficiency at higher energies), to large crystals with multiple
phototubes. Crystals built with a well to allow nearly spherical 4p
geometry counting of weak samples are also a widely-used
configuration. A typical preamplifier and amplifier combination is
shown in Figure 1.7.
Figure 1.7: NaI(Tl) Detector
Electronics
The light decay time constant in NaI is about 0.25
microseconds, and typical charge sensitive preamplifiers translate
this into an output pulse rise time of about 0.5 microseconds. For
this reason, NaI detectors are not as well-suited as plastic
detectors for fast coincidence measurements, where very short
resolving times are required.
Plastic Scintillators
Many types of plastic scintillators are commercially available
and find applications in fast timing, charged particle or neutron
detection, as well as in cases where the rugged nature of the
plastic (compared to NaI), or very large detector sizes, are
appropriate. Subnanosecond rise times are achieved with plastic
detectors coupled to fast photomultiplier tubes, and these
assemblies are ideal for fast timing work.
Separate outputs are usually used for timing, with the positive
dynode output to a preamplifier and amplifier for energy analysis,
and the larger negative anode output to a fast discriminator, as
shown in Figure 1.8.
Figure 1.8: Plastic Scintillation
Detector Electronics
Semiconductor Detectors
A semiconductor is a material that can act as an insulator or as
a conductor. In electronics the term "solid state" is often used
interchangeably with semiconductor, but in the detector field the
term can obviously be applied to solid scintillators. Therefore,
semiconductor is the preferred term for those detectors which are
fabricated from either elemental or compound single crystal
materials having a band gap in the range of approximately 1 to 5 eV.
The group IV elements Silicon and Germanium are by far the most
widely-used semiconductors, although some compound semiconductor
materials are finding use in special applications as development
work on them continues.
Table 1.1 shows some of the key characteristics of various
semiconductors as detector materials:
| Material |
Z |
Band Gap(eV) |
Energy/e-h
pair (eV) |
| Si |
14 |
1.12 |
3.61 |
| Ge |
32 |
0.74 |
2.98 |
| CdTe |
48-52 |
1.47 |
4.43 |
| Hgl2 |
80-53 |
2.13 |
6.5 |
| GaAs |
31-33 |
1.43 |
5.2 |
Table 1.1: Element vs. Band Gap
Semiconductor detectors have a P-I-N diode structure in which the
intrinsic (I) region is created by depletion of charge carriers when
a reverse bias is applied across the diode. When photons interact
within the depletion region, charge carriers (holes and electrons)
are freed and are swept to their respective collecting electrode by
the electric field. The resultant charge is integrated by a charge
sensitive preamplifier and converted to a voltage pulse with an
amplitude proportional to the original photon energy.
Since the depletion depth is inversely proportional to net
electrical impurity concentration, and since counting efficiency is
also dependent on the purity of the material, large volumes of very
pure material are needed to ensure high counting efficiency for high
energy photons.
Prior to the mid-1970’s the required purity levels of Si and Ge
could be achieved only by counter-doping P-type crystals with the
N-type impurity, lithium, in a process known as lithium-ion
drifting. Although this process is still widely used in the
production of Si(Li) X-ray detectors, it is no longer required for
germanium detectors since sufficiently pure crystals have been
available since 1976.
The band gap figures in Table 1.1 signify the temperature
sensitivity of the materials and the practical ways in which these
materials can be used as detectors. Just as Ge transistors have much
lower maximum operating temperatures than Si devices, so do Ge
detectors. As a practical matter both Ge and Si photon detectors
must be cooled in order to reduce the thermal charge carrier
generation (noise) to an acceptable level. This requirement is quite
aside from the lithium precipitation problem which made the old
Ge(Li), and to some degree Si(Li) detectors, perishable at room
temperature.
The most common medium for detector cooling is liquid nitrogen,
however, recent advances in electrical cooling systems have made
electrically refrigerated cryostats a viable alternative for many
detector applications.
In liquid nitrogen (LN2) cooled detectors, the
detector element (and in some cases preamplifier components), are
housed in a clean vacuum chamber which is attached to or inserted in
a LN2 Dewar. The detector is in thermal contact with the
liquid nitrogen which cools it to around 77 °K or –200 °C. At these
temperatures, reverse leakage currents are in the range of 10-9
to 10-12 amperes.
In electrically refrigerated detectors, both closed-cycle Freon
and helium refrigeration systems have been developed to eliminate
the need for liquid nitrogen. Besides the obvious advantage of being
able to operate where liquid nitrogen is unavailable or supply is
uncertain, refrigerated detectors are ideal for applications
requiring long-term unattended operation, or applications such as
undersea operation, where it is impractical to vent LN2
gas from a conventional cryostat to its surroundings.
A cross-sectional view of a typical liquid nitrogen cryostat is
shown in Figure 1.9.
Figure 1.9: Model 7500SL Vertical
Dipstick Cryostat
Detector Structure
The first semiconductor photon detectors had a simple planar
structure similar to their predecessor, the Silicon Surface Barrier
(SSB) detector. Soon the grooved planar Si(Li) detector evolved from
attempts to reduce leakage currents and thus improve resolution.
The coaxial Ge(Li) detector was developed in order to increase
overall detector volume, and thus detection efficiency, while
keeping depletion (drift) depths reasonable and minimizing
capacitance. Other variations on these structures have come, and
some have gone away, but there are several currently in use. These
are illustrated in Figure 1.10 with their salient features and
approximate energy ranges.
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For more information on specific detector types refer to the Detector Products
Section
Detector Performance
Semiconductor detectors provide greatly improved energy
resolution over other types of radiation detectors for many reasons.
Fundamentally, the resolution advantage can be attributed to the
small amount of energy required to produce a charge carrier and the
consequent large "output signal" relative to other detector types
for the same incident photon energy. At 3 eV/e-h pair (see Table
1.1) the number of charge carriers produced in Ge is about one and
two orders of magnitude higher than in gas and scintillation
detectors respectively. The charge multiplication that takes place
in proportional counters and in the electron multipliers associated
with scintillation detectors, resulting in large output signals,
does nothing to improve the fundamental statistics of charge
production.
The resultant energy reduction in keV (FWHM) vs. energy for
various detector types is illustrated in Table 1.2.
| Energy (keV) |
5.9 |
1.22 |
1.332 |
| Proportional Counter |
1.2 |
---- |
---- |
| X-ray NaI(Tl) |
3.0 |
12.0 |
---- |
| 3 x 3 NaI(Tl) |
---- |
12.0 |
60 |
| Si(Li) |
0.16 |
---- |
---- |
| Planar Ge |
0.18 |
0.5 |
---- |
| Coaxial Ge |
---- |
0.8 |
1.8 |
Table 1.2 Energy Resolution (keV FWHM)
vs. Detector Type
At low energies, detector efficiency is a function of
cross-sectional area and window thickness while at high energies
total active detector volume more or less determines counting
efficiency. Detectors having thin contacts, e.g. Si(Li), Low-Energy
Ge and Reverse Electrode Ge detectors, are usually equipped with a
Be cryostat window to take full advantage of their intrinsic energy
response.
Coaxial Ge detectors are specified in terms of their relative
full-energy peak efficiency compared to that of a 3 in. x 3 in.
NaI(Tl) Scintillation detector at a detector to source distance of
25 cm. Detectors of greater than 100% relative efficiency have been
fabricated from germanium crystals ranging up to about 75 mm in
diameter. About two kg of germanium is required for such a
detector.
Curves of detector efficiency vs. energy for various types of Ge
detectors can be found in the Detector
Products Section.
