Jun‑Kai Yang · Ping‑Quan Wang · Zhong‑Guo Ren · Ren‑Sheng Wang · Hui Zhang · Jian Zhang
Abstract The neutron energy spectrum was measured using a Bonner sphere spectrometer at six locations inside the containment vessel of a nuclear reactor at the Qinshan nuclear power plant. The structures of the neutron spectra obtained by the maximum entropy, iteration, and genetic algorithm methods were consistent with one another and could be interpreted as the spectral superposition of different energy regions. The characteristic parameters of the neutron spectrum, including the fluence rate,average energy, and neutron ambient dose equivalent rate ̇H∗(10), were in good agreement among the three methods. In addition, an LB6411 neutron ambient dose equivalent meter was employed to obtain the ̇H∗(10) directly for comparison.These findings indicate that neutron spectrum unfolding methods can be used to overcome the problems associated with the response functions of dosimeters to provide more accurate ̇H∗(10) values. In this study, the following three evaluation criteria were systematically addressed to ensure the accuracy of the unfolded spectra: count rates of the inverse solutions,neutron spectrum structures, and comparison of key parameters.
Keywords Neutron spectrum · ̇H∗(10) · Nuclear power plant · Evaluation criteria
The neutron spectrum, which is the neutron fluence rate or neutron density versus neutron energy, is one of the most critical parameters for describing the neutron irradiation field of a radiation source [1]. Obtaining the on-site energy spectrum of a neutron field is a relatively complicated issue in neutron measurements [2, 3], which has motivated studies to not only determine more exact measurement methods,unfolding algorithms, and simulation methods [4] but also the application of rational criteria to ensure the accurate unfolding of the neutron spectrum. Furthermore, although the neutron ambient dose equivalent ratėH∗(10) can be conveniently obtained using an ambient dose equivalent meter,owing to the diversity and complexity of the neutron spectrum, the response function and fluence-dose equivalent conversion coefficients are rarely consistent over a wide energy range [5]. Most neutron ambient dose equivalent meters are calibrated in a reference neutron irradiation field with a specific spectrum structure, such as241Am—Be,252Cf, or252Cf moderated by D2O, as recommended by the International Organization for Standardization (ISO) ISO 8529-2:2000[6]. These requirements are difficult to satisfy with the calibration results of on-site measurements in complex environments. According to the International Commission on Radiological Protection (ICRP) 74 report, accuratėH∗(10)values can be derived from the fluence—dose equivalent conversion coefficient and neutron spectrum [7, 8]. Therefore,the neutron spectrum tends to be an important part of the neutron protection dosimetry.
To obtain the neutron spectra anḋH∗(10) at six locations in three plant areas of the Qinshan Nuclear Power Plant, the Neutron Laboratory of the National Institute of Metrology,China (NIM) performed energy spectrum measurements using a set of Bonner sphere spectrometer (BSS), which is widely used for the on-site measurement of the neutron spectrum [9], and unfolded the neutron spectra using the maximum entropy, iteration, and genetic algorithm (GA) methods[10, 11]. A neutron ambient dose equivalent meter (LB6411)was employed to compare with thėH∗(10) values given by the energy spectrum methods. The response functions of the BSS containing a3He core detector and the calibration factor of the LB6411 were calibrated at Physikalisch-Technische Bundesanstalt (PTB) and NIM, respectively. Moreover, an analysis was conducted to further validate the rationality and effectiveness of the three following evaluation criteria applied during the unfolding of the spectra: count rates of the inverse solutions, neutron spectrum structures, and comparison of key parameters.
As shown in Fig. 1, the neutron spectrum measurement includes the following four main parts: (1) calculation of the BSS response function, (2) on-site measurement, (3)unfolding of the spectrum based on the response function and measurement data, and (4) rationality evaluation of the neutron spectrum using various criteria.
The BSS, manufactured by Centronic Ltd., UK, consists of an SP93He thermal neutron detector and a set of highdensity polyethylene spheres (0.938 ± 0.009 g/m3) with the following 12 different diameters: 3, 3.5, 4, 4.5, 5, 6, 7, 8,9, 9.5, 10, and 12 inches (1 inch = 2.54 cm). The internal diameter of SP9 was 3.2 cm, the stainless-steel shell was 1 mm thick, and the nominal pressures were 230 kPa3He and 120 kPa Kr at 20 °C. The incident neutrons moderated by polyethylene spheres were detected by SP9 at the center of each sphere and a coupled series of suitable electronic equipment [12, 13].
The neutron spectrum unfolding method of the BSS is based on the theory of the development of few channel data,which is an underdetermined system of equations [2, 14] that has infinite solutions. When the response functionRi(E) and each detector count rateCiare known, the neutron fluence rateφ(E) can be determined using Eq. (1):whereRijis the response of theith sphere in thejth energy interval, which can be calculated by a simulation and validated by a sufficient monoenergetic neutron field, andφjis the fluence rate in thejth energy interval.
Fig. 1 (Color online) Flowchart of neutron spectrum measurements
The maximum entropy, iteration, and GA methods were used to unfold the neutron energy spectra and provide mutual verification. The maximum entropy and iteration methods achieved by FORTRAN integrated into UMG,called MAXED and GRAVEL, respectively, were employed to obtain the neutron energy spectrum. A priori default spectrum for the preliminary determination of the structure of the neutron energy spectrum was required when using the maximum entropy and iteration methods. The two methods aim to change the default spectrum into one that fits the data but remains “as close as possible” to the default spectrum.Therefore, the a priori default spectrum significantly affects the final results of the spectral unfolding process. Detailed descriptions and analyses of these two methods are available in previous studies [15, 16]. For MAXED, the chi-squared per degree of freedom was 1.8, and the highest energy, temperature, andtempreductions were set to 20, 1, and 0.85,respectively. For GRAVEL, the chi-square per degree of freedom was 1.8, and the highest energy and maximum number of iterations were set to 20 and 2000, respectively.The selection of the default spectrum used in this study is described in Sect. 2.3.
The GA, which imitates the Darwinian evolution paradigm, also known as the “survival of the fittest” strategy,was applied to solve the problem of unfolding the neutron energy spectrum [17]. It is a new type of unfolding method that has recently emerged and can eliminate the limitation of requiring a default energy spectrum during calculations.In this study, the GA code was achieved using C++ within
the ROOT framework. The main parameters used in the code were as follows: the upper and lower boundaries of the spectral unfolding zone were 20 MeV and 0, respectively,genetic algebra was 500, population size was 30,000, crossover probability was 0.3, mutation probability was 0.001, and genetic probability was 0.2.
The response functions, which are the key parameters of a BSS, were calculated using Geant4, a Monte Carlo code library used for simulating particle transport, coupled with ENDF/B-VII [18]. Figure 2 shows the geometry of a 4.5 inches polyethylene sphere with SP9. The incident neutrons were assumed to be a monoenergetic parallel beam emitted from a circular plane with a diameter equal to that of the simulated sphere, and the circular plane was placed at a distance of 20 cm from the SP9 center. The structure,dimensions, material, and material density of the SP9 and polyethylene spheres were the same as the actual parameters described above.S(α, β) was applied to the neutron transport calculation in polyethylene to solve the problem of neutron thermalization [19]. Excluding the polyethylene sphere and SP9, all the spaces were set to a vacuum. A neutron was considered to escape, and the trace was stopped once it occurred in the vacuum zone during the simulation. The calculated response energy ranged from 10—9eV to 20 MeV, considering 20 energy blocks per order of magnitude from 10—9eV to 10 MeV, and five energy blocks from 10 to 20 MeV. In addition, the responses of six experimental energies, 144 keV,250 keV, 565 keV, 1.2 MeV, 2.5 MeV, and 14.8 MeV, which were determined from an accelerator-driven neutron source were also calculated.
Fig. 2 (Color online) Sketch of a Bonner sphere with incident neutrons
To validate the simulated BSS energy response values,the six aforementioned energy responses were calibrated in a monoenergetic neutron field using the shadow cone method,and the thermal neutron response of SP9 was calibrated in a thermal neutron reference irradiation field formed by a neutron source and graphite moderator [20] at PTB. We should also consider that the air gap between the SP9 holder and sphere is a key factor for BSS [21].
Neutron energy spectra have different structures for incident neutrons with various energies because the absorption cross section of the moderator varies with the neutron energy.Neutrons above 20 MeV are produced by a proton-induced reaction on a lithium target in the laboratory; its characteristics can be described by a quantum molecular dynamics model [22]. However, in fission reactors or other common neutron fields, the neutron energy is lower than 20 MeV and the energy spectra can be expressed by the following three equations:
In the thermal region (< 0.5 eV), the energy spectrum follows the Maxwellian distribution as follows (Eq. (3)) [23]:
whereφ1is the thermal neutron fluence rate in cm—2·s—1,Eis the neutron energy in eV,kis Boltzmann’s constant(8.617 × 10−5eV/K),Tis the temperature, andmis the neutron mass.
In the intermediate energy region (0.5 eV—0.1 MeV), the classical 1/Edistribution was abandoned because the function diverges forE→ 0 and decreases very slowly for an energy of ~ 1 keV; the distribution was replaced by Eq. (4)as follows [24]:whereφ3is the fission neutron fluence rate andα2(0 <α2< 1)andβ2(1 <β2< 2) are the parameters of the fast component of the spectrum.
Normally, fission neutrons emitted from U-235 are moderated by both the coolant and moderator, such as light water and heavy water, and then become thermal neutrons and a small number of intermediate energy neutrons, epithermal neutrons, and fission neutrons [27].
According to the physical process, a hypothesis indicating that the spectrum of a reactor building can be explained as a superposition of these energy spectra with different parameters and weight factors can be proposed as follows (Eq. (6)):
whereC1,C2, andC3are different weight factors that are positive or null.
Neutrons in the thermal energy region account for a high proportion of the final spectra, and the most probable energy of a fast neutron may move to a lower energy (< 1 MeV)owing to the surrounding moderators. In addition, the neutron-absorbing material also affects the final superposition energy spectrum around the measurement locations. In addition, moderators with a high resonance absorption crosssectional distort the energy spectrum in the intermediate energy region, although this effect can be neglected owing to the low energy resolution of the BSS in the intermediate energy region.
According to the analysis of the neutron energy spectrum of reactor buildings, a previously published [28] neutron spectrum at the workplace of a nuclear power plant(Fig. 3), with a covering thermal, intermediate energy, and fast neutrons, was chosen as the default spectrum for the MAXED and GRAVEL methods.
Fig. 3 Default neutron energy spectrum of reactor buildings
The neutron energy spectra were measured at the following six locations: F1-A (305), F1-B (access route), F2-C(1R326), F2-D (1R511), F3-E (position between pumps 1 and 3 in 501), and F3-F (501 ladder). F1-A and F1-B are located in factory 1, F2-C and F2-D in factory 2, and F3-E and F3-F in factory 3. Table 1 summarizes the measurement devices used. Extra polyethylene holders should fill the holes of the Bonner spheres as much as possible(Fig. 4a) because the air gap between the holder and sphere has a significant influence on the response function. The direction of SP9 was parallel to the floor during the measurement (Fig. 4b). The height of each sphere support varied to make the geometric center of SP9 with different moderators 35 cm above the ground. According to the uncertainty formula of the linear model (Eq. 7), the time and total count of a single measurement should begreater than 200 s and 13,000, respectively, to ensure that the relative uncertainty of the count rate is less than 1%.
Table 1 Measurement devices
Hereucandutare the relative uncertainties of the count rate and measurement time, respectively, andNis statistical fluctuation.
In addition, a neutron dose equivalent ratemeter,LB6411, a3He detector located at the center of a 25 cm diameter polyethylene moderator, was employed to directly measure the neutron dose equivalent ratėH∗(10). The LB6411 is one of the best-known neutron dose equivalent ratemeters, and its measurement results were representative [29]. The calibration factor was 0.998, which was calibrated in a neutron reference radiation field based on a neutron reference with a241Am—Be source. The final results are the average of 10 measurement values.
The on-site process of measurement relied on the following three assumptions: (1) The fluence rate of the neutron radiation field is homogeneous in the local area of measurement, and the minor positional changes when replacing different spheres are negligible. (2) The fluence rate of the neutron radiation field was stable and unchanged during the measurement. (3) The disturbance induced by BSS can be ignored in the measurement area of the neutron radiation field.
Fig. 4 (Color online) a Photograph of an 8 inches polyethylene sphere and one holder of SP9. b Photograph of the on-site measurement setup
Fig. 5 (Color online) Response functions of the Bonner sphere spectrophotometer simulated by Geant4
The response functions that were simulated using Geant4 are shown in Fig. 5. The thermal neutron response of SP9 was 3.2 cm2based on the calibration results in PTB, and the real gas pressure of3He in SP9 was 248.7 kPa, which is 7.5%higher than the nominal value. Therefore, in subsequent simulations, the actual value of the gas pressure was used. Figure 6 shows the deviation of the simulation compared to the experiment, which indicates theD-values between the ratio of the simulation to the experimental value and 1; excluding the 3 inches and 3.5 inches spheres at a neutron energy of 14.8 MeV, all the results were within 0.9—1.1 at each energy point, indicating that they sufficiently coincided with one another. The largest relative deviation was observed at a high neutron energy (14.8 MeV) for the smallest sphere (3 inches), and the maximum was 14%. Table 2 lists the combined uncertainty (k= 1) and components, including the3He pressure, density of the polyethylene sphere, air gap, isotropy of the sphere, statistic of uncertainty by simulation, maximum deviation, and experimental uncertainty. The uncertainty of the3He pressure was fixed at 1% for all the spheres and was mainly due to the absorption of the thermal energy by stainless steel. The uncertainty of the density of polyethylene caused by the polyethylene nonuniformity and measurement error ranged from 5 to 13%, which increased as the diameter of the sphere increased. A constant air gap between the SP9 holder and the sphere of 0.4 mm was used in the response function simulations, and the estimations of the deduced uncertainties caused by this factor were based on a 0.4 mm variation. The largest uncertainty (approximately 12%) occurred for the 3 inches sphere responses. The isotropy of the sphere uncertainty and statistical uncertainty of the simulation changed monotonically, decreasing from 3 to 1% and increasing from 1 to 4%, respectively, when the sphere diameter varied from 3 to 12 inches. The largest experimental uncertainty of each sphere was relatively stable, which was approximately 4—5% during the calibration based on a monoenergetic neutron field. For each sphere, the maximum deviation between the experimental and simulation results was also selected among the six energy points as an uncertainty component of the response function, which are representative because they cover the thermal neutrons,intermediate energy neutrons, and fast neutrons. Finally, the maximum combined uncertainty, namely 20% (k= 1), was considered as the final response function uncertainty owing to the inability to obtain the experimental values of all the energy points.
Fig. 6 (Color online) Plot of the deviation of the simulation from the experimental results versus sphere diameter at different neutron energies (the two red dashed lines represent the region with a deviation of less than 10%)
Figure 7 displays the normalized measurement results of the BSS relative to the average count rate with polyethylene spheres and a bare detector at the six locations. The normalization constants at the six locations were 3616,729, 979, 343, 1354, and 1871 cps, respectively, which were the average count rates of each location. The peak package of F1-A was approximately 3 inches, which was lower than the other locations, indicating that F1-A would have the lowest neutron energy among these positions according to the response function shown in Fig. 5. The peak locations of F1-B and F3-E corresponded to a largersphere, approximately 4—5 in, thus the neutron energy could be higher than that of the other locations. The peak locations were essentially the same and were located at 3.5 inches or 4 inches for F2-C, F2-D, and F3-F. Therefore, a preliminary conclusion indicates that the neutron energy at each location would be in the following order:F1-B and F3-E > F2-C, F2-D, and F3-F > F1-A.
Table 2 Uncertainty list and combined uncertainty of response function (k = 1)
Fig. 7 (Color online) Normalization of count rate versus sphere diameter at different measurement locations
Figure 8 shows the neutron energy spectra at six positions obtained by MAXED and GRAVEL; the two methods had nearly the same distribution. The thermal and fast neutron peak positions occurred at approximately 0.01 eV and 100 keV, respectively. Although the peak height of the GA unfolded spectrum was different from that of the other methods at certain locations, their corresponding peak positions were essentially in unity in the entire energy region,and the most probable energies of the fast neutrons were also near 10—100 keV. We also observed that the spectrum given by GA at F1-B and F3-E did not have a small thermal neutron peak compared to MAXED and GRAVEL at the same position. This may be caused by the constraint of the default spectrum required when using MAXED and GRAVEL, which presents an apparent peak for thermal neutrons. In addition, Fig. 9 shows the proportion of neutrons with different energy regions over the total neutrons at the six locations. Compared to MAXED and GRAVEL, there were larger proportions of intermediate-energy neutrons and smaller proportions of thermal neutrons and fast neutrons given by GA. This may be due to the influence of the default spectrum when using MAXED and GRAVEL.
Fig. 8 (Color online) Comparison of spectra given by the MAXED, GRAVEL, and GA unfolding methods at a F1-A, b F1-B, c F2-C, d F2-D, e F3-E, and f F3-F
Fig. 9 (Color online) Bar plot of the proportion of fast,intermediate, and thermal neutrons over the total neutrons at six measurement positions(MX, GV, and GA represent MAXED, GRAVEL, and the genetic algorithm, respectively,and the red arrows indicate the borderlines of the measurement positions)
According to the shapes and structures of the unfolded energy spectra (Figs. 8, 9), three groups were identified;this grouping was consistent with the pre-analysis by the count rate. For group 1, including the spectra obtained at F2-C, F2-D, and F3-F, which was in good agreement with the aforementioned analysis in Sect. 2.3, most of the neutrons were concentrated in the thermal region, and there was an apparent spike in the fast neutron energy region. For F2-D, the energy of the thermal neutron peak given by GA (1 eV) was higher than that of MAXED and GRAVEL (0.1 eV). Thermal, intermediate energy,and fast neutrons accounted for approximately 40%, 50%,and 10% of the total, respectively. For group 2, including the spectra obtained at F1-A, nearly all the neutrons were located in the thermal (approximately 50%) and intermediate energy (approximately 50%) regions, and the proportion of fast neutrons was near 0%, as shown in Fig. 9. The mean energy given by the three methods was 0.3 eV, indicating that a thicker material with a higher neutron moderation efficiency may be present in the environment. For group 3, including the neutron spectra obtained at F1-B and F3-E, the intermediate energy and fast neutrons were the vast majority (> 80%), whereas the thermal neutron proportions were only 10—20%.Their corresponding average energies were 49.8 keV and 91.6 keV, respectively, which was significantly higher than those of the other locations in the same buildings,0.3 keV of F1-A (Fig. 8a) and 42.9 keV of F3-F (Fig. 8f).However, considering the high mean fluence rates at F1-A(3167 cm—2·s—1) and F3-F (1474 cm—2·s—1), the mean fluence rates at F1-B and F3-E were relatively low at 513 and 967 cm—2·s—1, respectively, as shown in Fig. 10. A higher neutron energy and lower fluence rate indicates that there should be an extra absorption material of thermal neutrons nearby; intermediate and fast neutrons that were not totally moderated were detected by the BSS.
It is easy to derive the neutron ambient dose equivalent ratėH∗(10) based on the neutron energy spectra and conversion coefficients that relate the neutron fluence rate to the dose equivalent rate. Considering that the results obtained by the three unfolding spectrum methods provide only an approximate value, the average value per location was considered as the reference value for a better comparison (Fig. 11).The maximum appeared at F3-E, which was approximately 209.3 μSv/h, owing to a higher average energy and fluence rate. Moreover, F1-A only had 1.7 times thėH∗(10) of the access route, although the total fluence rate of F1-A was far higher than that of F1-B in Factory 1. Neutrons above the keV range are prone to the reaction of recoil protons. The human body contains a large amount of water, thus the conversion coefficients rapidly rise when the neutron energy is above ~ 1 keV. Therefore, neutrons with a higher energy have a greater influence oṅH∗(10) and the human body.
Fig. 10 (Color online) Bar plot of the a total fluence rate, and b the average energy comparison given by MAXED, GRAVEL, and the genetic algorithm at different locations
ThėH∗(10) ratios of the direct measurement results(LB6411) to the energy spectrum methods exhibit large variations at different positions (Fig. 11, red point-andline curve). ThėH∗(10) measured by LB6411 was significantly greater than that derived from the spectrum methods at F1-A (more than 60%), whereas at F3-F, thėH∗(10)measured by LB6411 was lower than that derived from the spectrum methods. At F1-B and F3-E, the values obtained by the direct measurement and spectrum methods were not significantly different. These disparities resulted from the differences in the survey instrument responses in the various energy regions; the neutron spectra structure of the calibration laboratory was not the same as in practice. ThėH∗(10) of the direct measurement was significantly higher than that of the spectrum methods, which may be due to the over-response of LB6411 for the thermal neutrons at F1-A. For F1-B and F3-E, the survey instrument responded properly with more intermediate-energy neutrons. However, for the neutron spectrum structures at F2-C, F2-D,and F3-F, the direct measurement results demonstrated a significant fluctuation, overresponse in certain locations, and under-response in others. In addition, according to the relative deviation, the calibration factors were 0.62, 0.94, 0.87,0.78, 1.07, and 1.12, respectively, at the six locations and were different from 0.998 based on the241Am—Be neutron source. Considering a practical protection, these factors are more promising. Therefore, energy spectrum methods can effectively avoid the problems of over- or under-responses and help obtain a more accuratėH∗(10) in a complex field environment.
Fig. 11 (Color online) Bar plot of ̇H∗(10) given by the energy spectrum methods and LB6411 at different measurement locations
There is no determined and unique spectrum; owing to the few-channel data of the BSS, certain criteria and conditions are required to verify the results of the unfolding spectra and ensure that they approximate the true values. However,all criteria are necessary and insufficient for the true spectrum. Three criteria, including the count rates of the inverse solutions, neutron spectrum structures, and key parameter comparison among the three methods, were used to evaluate the quality of the spectrum unfolding results.
3.5.1 Count rates of the inverse solutions and experiment
Fig. 12 (Color online) Plot of measurement and inverse solution neutron count rate against the sphere diameter at a F1-A, b F1-B, c F2-C,d F2-D, e F3-E, and f F3-F. The count rate ratio of the experimental results to the results derived by each of the three methods is plotted on the second y axis. The two red lines represent the region of deviation of the ratio that is less than 20%
Table 3 Normalization relative deviations of the total fluence rate, average energy, and ̇H∗(10)using three unfolding methods
The count rate of the inverse solution of the neutron spectrum is one of the most important constraints. Although the spectra may not indicate the correct results despite the inverse solution values sufficiently matching the experimental results, poor results of the unfolding spectra can be excluded if they are inconsistent with one another. Figure 12 shows the absolute experimental count rate, inverse solution count rate, and their ratios for the three unfolding methods applied in this study. The inverse count rate of the GA approximated the measurement results more closely than MAXED and GRAVEL at most locations, and the maximum relative deviation was 18% for the 9 inches sphere at F1-A. It is difficult to quantify the uncertainty of the neutron spectrum involving a response function, measurement,experiment (temperature, scattering, etc.), unfolding spectrum, and other unknown factors, especially in an on-site complex environment. Therefore, a ± 20% relative deviation between the measurement and inverse solution values may be considered satisfactory owing to the 20% response function uncertainty and 1% measurement uncertainty.
3.5.2 Neutron spectrum structures
Generally, an approximation of the spectrum can be obtained for the measurement spot. First, according to the peak package of the measurement count rate and the response function of the BSS, we qualitatively evaluated the neutron energy.In particular, this can provide a comparison of the neutron energy for the measurement of multiple locations. In this study, the grouping based on neutron spectrum structures was consistent with the grouping based on the count rate analysis. The order of the spectra average energy in the three groups was as follows: group 3 > group 1 > group 2. Second,according to the hypothesis of the energy spectrum superposition of reactor buildings, the spectra of group 1 were in good agreement with the hypothesis. The neutron energy spectra in groups 2 and 3 can also be expressed by Eq. (7)with different weight factors. In group 3,C3of the spectra had the greatest value compared toC1andC2, whereas in group 2,C3was close to 0. Therefore, the six spectra met the theoretical hypothesis considering that they had different parameters and weight factors, indicating that the unfolding spectrum results were credible.
3.5.3 Key parameter comparisons of three methods
The key parameters of a neutron spectrum include the total fluence rate, average energy, anḋH∗(10), as well as the neutron proportion of different energy regions, which provides a better representation of the energy spectrum characteristics and structures. The two parameters, the ambient dose equivalent average energyEHand the average fluence to the ambient dose equivalent conversion factorh∗φ, were not applied in this third criterion because they were only the derived parameters in terms of the neutron energy, neutron fluence rate, and fluence-dose equivalent conversion coefficient.Comparing the aforementioned parameters from various methods is helpful in improving the accuracy of the unfolding results, given the unavailability of the true neutron spectrum. Table 3 and Fig. 9 demonstrate that the normalization relative deviations of the parameters above were 0—2.5%,0—33%, 0.8%—7.2%, and 0—9%, respectively, which were normalized by the parameter average of the three methods.Excluding the average energy deviation of MAXED (33%)and GRAVEL (33%) at F1-A, the parameters derived from the different methods were within the uncertainty of the BSS response function. Although 33% appeared to be relatively high, the absolute average energies were within 0.2—0.4 keV in F1-A, which was significantly lower than that of other locations. Moreover, most of the neutrons were concentrated in the thermal and intermediate energy regions; the 33%deviation may be caused by the poor resolution of the BSS in the intermediate energy region. Therefore, the average energy calculated by each method was acceptable for F1-A.
Neutron spectra measurements were conducted by NIM using a BSS at six on-site locations in the complex environment of the Qinshan Nuclear Power Plant, and the maximum entropy, iteration, and GA unfolding methods were applied to obtain more precise spectra and parameters. The following three conclusions were drawn from the analysis.
1. The neutron spectrum shape, total fluence ratėH∗(10),and average energy obtained by unfolding using the three methods were consistent. These neutron spectra can be described by the linear superposition of the Maxwellian, intermediate energy, and fast neutron spectrum functions with different parameters and weight factors.The spectral superposition idea can be applied to generate a large number of random energy spectra containing the real or close-to-real neutron spectrum of a workplace, and can be used for other unfolding methods, such as training spectra in a generalized regression neural network (GRNN).
2. For the measurement of the neutron ambient dose equivalent ratėH∗(10), the neutron spectrum of a realistic calibration field, compared to a conventional calibration field based on a radionuclide neutron source, more closely matched the actual workplace fields, and the calibration factors at the six locations were 0.62, 0.94, 0.87,0.78, 1.07, and 1.12, respectively. Therefore, neutron spectrum methods can overcome the problems associated with neutron structures and response functions of dosimeters and provide a more accuratėH∗(10). The BSS is unable to identify the neutron direction; therefore, further research including the measurement of the neutron angular distribution, personal dose equivalent ratėHp(10), and the calibration of personal dosimeters in the relative workplace fields is needed.3. The results of the unfolding energy spectra obtained by the three methods were relatively reliable based on the following three criteria: count rates of the inverse solutions, neutron spectrum structures, and comparison of the key parameters derived from the spectra. More criteria need to be identified for a better evaluation of the neutron spectra and unfolding methods in the future.
AcknowledgementsWe thank the other members of the neutron measurement group for their assistance with this work. We also appreciate the researchers of the MAXED and GRAVEL codes.
Author contributionsAll authors contributed to the study conception and design. Material preparation, data collection and analysis were performed by Jun-Kai Yang, Ping-Quan Wang, Zhong-Guo Ren, Ren-Sheng Wang, Hui Zhang. The first draft of the manuscript was written by Jun-Kai Yang, Ping-Quan Wang, Hui Zhang, and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
Nuclear Science and Techniques2022年12期