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textbook:nrctextbook:chapter9 [2025-04-16 15:06] Merja Herzig |
textbook:nrctextbook:chapter9 [2025-05-07 13:23] (current) Merja Herzig |
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| - | NaI is an effective material for gamma ray measurement since it can be manufactured in large crystals that can absorb readily penetrating gamma rays. The larger the crystal the higher is the [[textbook: | + | NaI is an effective material for [[textbook: |
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| - | * gamma radiation primarily results in the formation of electrons (e< | + | * [[textbook: |
| * the electrons interact with tallium ions to form tallium atoms $e^- + \text{Tl}^+ \rightarrow \text{Tl}^0$ while the holes interact with tallium ions to form divalent tallium ions $h^+ + \text{Tl}^+ \rightarrow \text{Tl}^{2+}$ | * the electrons interact with tallium ions to form tallium atoms $e^- + \text{Tl}^+ \rightarrow \text{Tl}^0$ while the holes interact with tallium ions to form divalent tallium ions $h^+ + \text{Tl}^+ \rightarrow \text{Tl}^{2+}$ | ||
| * then tallium atoms interact with holes to form excited tallium ions $h^+ + \text{Tl}^0 \rightarrow (\text{Tl}^+)^*$ and divalent tallium ions interact with electrons also forming excited tallium ions $e^- + \text{Tl}^{2+} \rightarrow (\text{Tl}^+)^*$ | * then tallium atoms interact with holes to form excited tallium ions $h^+ + \text{Tl}^0 \rightarrow (\text{Tl}^+)^*$ and divalent tallium ions interact with electrons also forming excited tallium ions $e^- + \text{Tl}^{2+} \rightarrow (\text{Tl}^+)^*$ | ||
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| - | Since the excitation energy level of (Tl< | + | Since the [[textbook: |
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| - | The light photons, more than 10000 for each MeV energy absorbed in the NaI(Tl) crystal, are transformed into electric pulses with a photomultiplier tube (PMT) (Figure IX.1). The number of light photons is directly proportional to the energy of gamma rays absorbed in the crystal. The light photons first hit the photocathode at the PMT end facing the NaI(Tl) crystal. Photocathode material is typically made of Cs< | + | The light photons, more than 10000 for each MeV energy absorbed in the NaI(Tl) crystal, are transformed into electric pulses with a [[textbook: |
| - | released electrons is directly proportional to the number of photons hitting the photocathode. PMT multiplies the number of electrons to a countable electric pulse with the aid of successive dynodes, also made of Cs< | + | |
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| - | Since NaI(Tl) can be produced as large crystals they have good gamma ray detection efficiency, much better than what is obtained with semiconductor detectors. They can also be produced as well-type crystals in which a cylindrical whole is drilled in the middle of crystal. The sample to be counted is placed in the hole, which considerably increases counting efficiency compared to planar crystals. The drawback of solid scintillators in comparison with semiconductor detectors is their poor energy resolution. The energy resolution of NaI(Tl) detector is approximately 50-100 keV for | + | Since NaI(Tl) can be produced as large crystals they have good gamma ray [[textbook: |
| - | gamma rays of energy between 2 - 0.5 MeV while with semiconductor detectors the resolution is about 50-times better (Figure IX.2). Therefore, due to overlapping peaks solid scintillators cannot be used for identification of radionuclides from samples having a large number of radionuclides. Solid scintillators are used in gamma spectrometry only when high detection efficiency is needed and when the sample does not have a large number of radionuclides. More usually, solid scintillators are used in counting of single radionuclides in a single channel mode. In this, only the | + | |
| - | pulses of the photopeak, representing the energy of the most intensive gamma transition, are counted. This is accomplished by use of voltage discriminators: | + | |
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| - | In addition to NaI(Tl) detectors there are other types of solid scintillators, | + | In addition to NaI(Tl) detectors there are other types of solid scintillators, |
| - | LaBr< | + | LaBr< |
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| - | Figure IX.2. Gamma spectra collected from the same source by a semiconductor detector (left) and by a scintillation detector (right) (http:// | + | Figure IX.2. Gamma spectra collected from the same source by a [[textbook: |
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| - | Semiconductor detectors are diodes produced either of silicon or germanium, the former being used for alpha and X-ray detection and the latter for gamma detection. Germanium is more suitable to gamma detection than silicon due to its higher atomic number Z=32, and thus density, which increase the stopping power compared to silicon, the atomic number of which is only Z=14. The formation of photoelectric effect is proportional to the atomic number of the element absorbing gamma rays. Thus, for example, 0.1 MeV gamma rays are absorbed 40-times more efficiently in germanium than in silicon. The detector consists of two parts (Figure IX.3). The other part is pure Si/Ge, having four electrons in the outer shell, doped with atoms having five electrons in the outer | + | Semiconductor detectors are diodes produced either of silicon or germanium, the former being used for [[textbook: |
| - | shell, such as phosphorus. This type of semiconductor is called n-type and it acts as an electron donor. The other part, p-type, is also pure Si/Ge but now doped with atoms with three electrons in the outer shell, such as boron. This part acts as an electron acceptor with electron holes surrounding boron atoms. When these two parts are attached to each other electrons from n-type move to p-type and a narrow layer at interface, junction, becomes free of electrons and holes. This layer is called | + | |
| - | depletion layer. When now electrodes are attached to the other sides of n-type and p-type semiconductors, | + | |
| - | formation time of an electric pulse is much shorter than in the gas ionization detectors. In addition, semiconductor detectors produce about ten times higher number of electrons (and holes) per unit energy absorbed in the detector. To be efficient for gamma ray detection the germanium detector has to be large and the depletion layer should be several centimeters wide. To observe thick depletion layer the germanium used has to be very pure, the fraction of foreign atoms being one atom per 10< | + | |
| - | destroy them due to high mobility of lithium ions at higher temperatures. In the case of alpha detection the n-type facing to the source need to be very thin in order to enable penetration of alpha particles into depletion layer, which is also very thin, less than one micrometer. Alpha detectors and spectrometry are described in more detail in [[textbook: | + | |
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| - | As already mentioned, the energy resolution of germanium detector is 50-times better than that of NaI(Tl) detector and absolute resolution is about 2 keV (0.1%) for gamma rays with energies of 2 MeV, about 1.5 keV (0.15%) at 1 MeV, about 1 keV (0.2%) at 0.5 MeV and about 0.5 keV (0.5%) at 0.1 MeV. Thus germanium detectors can be used to identify gamma-emitting radionuclides from a mixture of a number of radionuclides, | + | As already mentioned, the [[textbook: |
| of net areas of the representative peaks and using pre-determined [[# | of net areas of the representative peaks and using pre-determined [[# | ||
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| Figure IX.3. Structure and function of a semiconductor detector. | Figure IX.3. Structure and function of a semiconductor detector. | ||
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| - | The detection efficiency of germanium detectors is dependent on the size of the detector: the larger the detector the higher the efficiency. Efficiency depends also on the gamma energy (Figure IX.4). At higher gamma energies the efficiency decreases due to penetration of gamma rays without interactions with the detector. At energies higher than about 150 keV the efficiency decreases more or less linearly when both energy and efficiency are presented on logarithmic scales. Ordinary germanium detectors are covered with an aluminum shield, which effectively absorbs low energy | + | The detection efficiency of germanium detectors is dependent on the size of the detector: the larger the detector the higher the efficiency. Efficiency depends also on the gamma energy ([[textbook: |
| - | gamma rays. This can be seen in Figure IX.4 as a dramatic drop in efficiency of gamma ray energies below 100 keV. To overcome this and to enable also measurement of low energy gamma rays broad energy (BEGe) and low energy (LEGe) germanium detectors have been developed. These have, instead of aluminum, very thin window, made of either beryllium or carbon composite, between the source and the detector. This allows efficient detection of low energy gamma emitters, such as < | + | |
| - | down to 3 keV can be measured with BEGe/LEGe detectors and even below 1 keV with ultra-low energy detectors. | + | |
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| - | When used the germanium detectors need to be cooled to about -200°C with liquid nitrogen cryostat (Fig. IX.5) or electrically to reduce electric noice which would considerably increase the background. Modern high purity germanium detectors (HPGE) can be let to warm when not in use but the earlier generation Li-drifted germanium detectors would destroy when letting them to warm up. | + | When used the germanium detectors need to be cooled to about -200°C with liquid nitrogen cryostat ([[textbook: |
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| Figure IX.5. Liquid nitrogen cryostat for cooling germanium detectors (http:// | Figure IX.5. Liquid nitrogen cryostat for cooling germanium detectors (http:// | ||
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| - | Germanium detectors have three types of shapes: planar, coaxial and well (Figure IX.6). Low-energy (LRGe) and broad energy-detectors (BEGe) are planar. The detector size in this construction mode is small and therefore these detectors are not able to efficiently detect high-energy gamma rays. In the coaxial mode the depletion layer is much thicker and therefore they are suitable in the detection of high-energy gamma rays. In the well-type the sample in placed inside the hole bored in the detector which considerably improves the counting efficiency. | + | Germanium detectors have three types of shapes: planar, coaxial and well ([[textbook: |
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| - | The counting efficiency of the detectors is the fraction of gamma rays resulting in the formation of electric pulse of the total gamma ray number hitting the detector. The efficiency varies with detector type and the gamma ray energy as was shown in Figure IX.4. To compare efficiencies of various detectors this absolute efficiency is, however, not typically used but instead the efficiency is expressed in a relative manner by comparing the detector efficiency at 1332 keV photo-peak | + | The [[textbook: |
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| - | Multichannel analyzer sorts the pulses according to their heights, which are proportional to the energy of the gamma rays. To know what channel represents what energy the system needs to be calibrated. This is done by measuring standards of known energies depicted in Figure IX.7. In the figure the channel number are on the x-axis and the energies of the radionuclides on the y-axis. Here, three radionuclides with the following gamma energies are used: | + | [[textbook: |
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| - | By plotting a curve of the peak energy versus the channel where the mid point of the peak appears a calibration curve is obtained. | + | By plotting a curve of the peak energy versus the channel where the mid-point of the peak appears a calibration curve is obtained. |
| - | be in the channel 175 (=950×122/ | + | be in the channel 175 (=950×122/ |
| spectrum library and do the identification analysis automatically. They utilize not only gamma energies of each radionuclides but also relative intensities in case the nuclide has several gamma transitions. | spectrum library and do the identification analysis automatically. They utilize not only gamma energies of each radionuclides but also relative intensities in case the nuclide has several gamma transitions. | ||
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| One needs to bear in mind that the channels where each peaks go to depends on the settings of the amplifier: the higher the amplification the higher is the channel where peaks go. For example, when amplifier gain is doubled, the 662 keV peak of < | One needs to bear in mind that the channels where each peaks go to depends on the settings of the amplifier: the higher the amplification the higher is the channel where peaks go. For example, when amplifier gain is doubled, the 662 keV peak of < | ||
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| Figure IX.7. Energy calibration in gamma spectrometry. | Figure IX.7. Energy calibration in gamma spectrometry. | ||
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| ===== 9.4. Efficiency calibration ===== | ===== 9.4. Efficiency calibration ===== | ||
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| - | As is seen from Figure IX.4 the detector efficiency as a function of gamma ray energy is not constant but varies considerably. This must be taken into account by carrying out an efficiency calibration. The system is calibrated by measuring a mixture of radionuclides with a wide range of gamma photopeak energies. The activities of radionuclides should naturally be known and their values should be certified. Such radionuclide mixtures with certified activities are commercially available for efficiency calibration. At least seven radionuclides with varying energy should be used in the mixture. More radionuclides are needed for energy range below about 200 keV since the efficiency here varies in a more complex manner than at higher energies where an approximately linear relationship is obtained between energy and efficiency when presented in logarithmic scales. An example of composition of such standards with energy range from 60 keV to 1836 keV is presented in Table IX.I. This standard is meant for high accuracy calibration and consists of twelve nuclides. The standard is measured sufficiently long time to get at least 10000 counts to every photopeak and their net count rates are calculated by subtracting the background. Net count rates | + | As is seen from [[textbook: |
| - | are then compared with activities to calculate the efficiencies and curve is fitted for the efficiencies as a function of gamma energy, i.e. efficiency calibration curve is plotted (Figure IX.8). This calibration curve can then be used to calculate the counting efficiency of photopeaks in actual sample measurements. Software of modern gamma spectrometers do this automatically based on the calibration curve stored in their memory. | + | |
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| Table IX.I. Composition of a standard for efficiency calibration of gamma spectrometer (NIST). | Table IX.I. Composition of a standard for efficiency calibration of gamma spectrometer (NIST). | ||
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| - | Efficiency calibrations are typically done in pure water solutions with the density of approximately 1 g/mL. Calibration curves are determined for all geometries used in actual sample measurements, | + | Efficiency calibrations are typically done in pure water solutions with the density of approximately 1 g/mL. Calibration curves are determined for all geometries used in actual sample measurements, |
| - | by using Monte Carlo computer models. In these, the self-absorption is calculated by taking into account the density and elemental composition of the sample. | + | |
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| ===== 9.5. Interpretation of gamma spectra ===== | ===== 9.5. Interpretation of gamma spectra ===== | ||
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| - | In the interpretation of gamma spectra all three major atomic scale interaction processes of gamma rays with detector material need to be taken into account. These are [[textbook: | + | In the interpretation of gamma spectra all three major atomic scale interaction processes of gamma rays with detector material need to be taken into account. These are [[textbook: |
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| - | In the photoelectric effect a gamma ray loses its energy to a shell electron | + | In the [[textbook: |
| - | photopeak area. Varying proportion of the gamma energy is lost to Compton electrons and therefore a continuum is seen. Compton electrons do not, however, have continuous energy between zero and the photopeak energy (Eγ) but their spectrum ends at about 200 keV less than the Eγ. This is due to fact that the maximum energy that the gamma ray can lose is when it is scattered to opposite direction to its initial path and the maximum energy of the scattered gamma ray in this case is about 200 keV less than its initial energy, more or less irrespective of the initial energy. Thus a valley is | + | |
| - | created between the Compton continuum and the photopeak. As seen from the right side of the Figure IX.10 there are, however, pulses in this valley. These are due to simultaneously occurring multiple Compton events and summation of the ensuing electric peaks. At part of such summation pulses go to the photopeak area and they need to be subtracted in the way later described. | + | |
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| Figure IX.10. Photopeak, Compton continuum and their combination in a gamma spectra. | Figure IX.10. Photopeak, Compton continuum and their combination in a gamma spectra. | ||
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| - | Gamma rays with energies higher than 1.022 MeV may undergo pair formation, i.e. turn into an electron and a positron. If they both lose their energy in the detector an electric pulse goes to the photopeak area. However, since the positron is not stable but annihilates after losing its kinetic energy with an electron to form two gamma rays of 0.511 MeV energy. In the case where one of these escapes the detector, a peak at Eγ - 0.511 MeV is created and correspondingly a peak at Eγ -1.022 MeV when both annihilation gamma rays escape (Figure IX.11). | + | Gamma rays with energies higher than 1.022 MeV may undergo |
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| - | Still there may be additional peaks in gamma spectra. If two gamma rays simultaneously lose their energy in the detector a sum peak will be formed which is called coincidence summing. Furthermore, | + | Still there may be additional peaks in gamma spectra. If two gamma rays simultaneously lose their energy in the detector a sum peak will be formed which is called coincidence summing. Furthermore, |
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| ===== 9.6. Subtraction of background ===== | ===== 9.6. Subtraction of background ===== | ||
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| - | From gamma spectra radioactivities are determined from net peak areas of the photopeaks. In total peaks there are background counts created by external radiation, electric noise, Compton background of the radionuclides, | + | From gamma spectra radioactivities are determined from net peak areas of the [[textbook: |
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| Figure IX.12. Subtraction of Compton background from gross photopeak area. | Figure IX.12. Subtraction of Compton background from gross photopeak area. | ||
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| ===== 9.7. Sample preparation for gamma spectrometric measurement ===== | ===== 9.7. Sample preparation for gamma spectrometric measurement ===== | ||
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| - | Typically gamma spectrum is measured from samples without pretreatment by packing the sample into vial used in efficiency calibration. Also, the sample volume needs to correspond to a calibrated volume. Sometimes, however, pretreatment of samples is necessary. In cases where the activity concentration is so low that the activity of the target nuclide cannot be determined in a reasonable time, preconcentration is needed. For example, < | + | Typically gamma spectrum is measured from samples without pretreatment by packing the sample into vial used in [[textbook: |
| - | low that even measuring one-liter samples does not allow its detection in a reasonable time. Thus < | + | |
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textbook/nrctextbook/chapter9.1744808797.txt.gz · Last modified: 2025-04-16 15:06 by Merja Herzig