Buildup factor is an important parameter in the design of a radiation shielding system. As a manufacturing material commonly used for nuclear equipment, type 316 stainless steel is selected as the research object of this article. Exposure geometric progression fitting parameters and the corresponding exposure buildup factor (EBF) are calculated for type 316 stainless steel in the photon energy range of 0.015 MeV - 15 MeV, as well as penetration depth up to 40 mean-free-paths (mfp), and studied as a function of the photon energy and penetration depth. It can be observed that EBF changes significantly with the photon energy and penetration depth. These changes are attributed to the dominant interaction process in different photon energy regions. Besides, EBFs of 1.17 MeV and 1.33 MeV are interpolated using the obtained data and compared with those from the MCNP5 simulation by introducing a co-concentric multi-layer model, respectively. The results obtained from the Geometric Progression method are consistent with those calculated by the MCNP5 code. Buildup factors for type 316 stainless steel obtained in this article can be used as a reference for shielding performance assessment of the equipment made of type 316 stainless steel.
In order to reduce personnel exposure to ionizing radiation and protect the environment, it is essential to evaluate the radiation shielding performance of different materials used to manufacture the nuclear component. There are three commonly used methods to evaluate the radiation shielding performance of a material, i.e., the Monte Carlo method, the analytical method and the point-kernel method. Because of its simplicity and convenience, the point-kernel method is often used to deal with the complex shielding problems [
Buildup factor, defined as the ratio of the total detector response to that of un-collided photons, may refer to different quantities of interest, e.g., exposure to the interacting material [
In this article, the exposure geometric progression (G-P) fitting parameter and the corresponding EBF are calculated for type 316 stainless steel in the photon energy range of 0.015 MeV - 15 MeV and penetration depth up to 40 mfp. Besides, EBFs of 1.17 and 1.33 MeV are calculated based on the data obtained in this article and validated with the MCNP5 simulation, respectively. The results obtained in this article are useful for the shielding performance assessment of the component made of type 316 stainless steel.
Type 316 stainless steel is an austenitic chromium-nickel stainless steel containing 2% - 3% molybdenum. Due to the addition of molybdenum, type 316 stainless steel not only improves the chloride corrosion-resistance compared with the type 304 stainless steel, but also increases its strength at high temperatures. In China, type 316 stainless steel has been used in the manufacture of different components of the pressurized water reactor and fast neutron reactor [
Generally, the calculation of EBFs using the G-P method can be done in three steps as followed.
The interaction of photon and matter depends on the equivalent number of the matter (Zeq) which is energy-dependent and can be estimated by the ratio (R) of the Compton partial interaction coefficient (μc) and mass attenuation coefficients (μt) at specific energy. To evaluate Zeq of type 316 stainless steel at specific energy, μc and μt are obtained using WinXCom code and the interpolation of Zeq is done using the following formula [
Z e q = Z 1 ( log ( R 2 ) − log ( R 316 ) ) + Z 2 ( log ( R 316 ) − log ( R 1 ) ) log ( R 2 ) − log ( R 1 ) (1)
where R1 and R2 are the (μc/μt) ratios of the two successive elements of atomic numbers corresponding to Z1 and Z2, respectively. R316, lying between R1 and R2, is the (μc/μt) ratio of type 316 stainless steel at specific energy.
To calculate Zeq of type 316 stainless steel, the values of μc and μt in the photon energy range of 0.015 MeV - 15 MeV are obtained for type 316 stainless steel and elements from Z = 1 to Z = 60 using WinXCOM program at first [
The calculation of EBF using the G-P method requires five fitting parameters, i.e., b, c, a, Xk and d. ANSI/ANS-6.4.3 has given these parameters for 23 elements, 1 compound, 2 mixtures and 25 photon energies. However, Zeq of type 316 stainless steel does not match that of any matter given in ANSI/ANS-6.4.3. G-P fitting parameters of type 316 stainless steel at specific energy can be calculated in a similar procedure as Zeq, i.e., interpolated from Zeq using the following formula [
p 316 = p 1 ( log Z 2 − log Z e q ) + p 2 ( log Z e q − log Z 1 ) log Z 2 − log Z 1 (2)
where p1 and p2 are the G-P fitting parameters taken from ANSI/ANS-6.4.3, corresponding to the elements with atomic numbers Z1 and Z2, respectively.
| Element | C | Si | Mn | P | S | Ni | Cr | Mo | Fe |
|---|---|---|---|---|---|---|---|---|---|
| wt (%) | 0.08 | 1.0 | 2.0 | 0.045 | 0.03 | 12.0 | 17.0 | 2.5 | 65.345 |
| Energy (MeV) | Zeq | Energy (MeV) | Zeq |
|---|---|---|---|
| 0.015 | 25.751 | 0.600 | 26.514 |
| 0.020 | 26.312 | 0.800 | 26.489 |
| 0.030 | 26.379 | 1.000 | 26.538 |
| 0.040 | 26.415 | 1.500 | 26.376 |
| 0.050 | 26.439 | 2.000 | 26.251 |
| 0.060 | 26.448 | 3.000 | 26.166 |
| 0.080 | 26.473 | 4.000 | 26.115 |
| 0.100 | 26.476 | 5.000 | 26.116 |
| 0.150 | 26.500 | 6.000 | 26.129 |
| 0.200 | 26.515 | 8.000 | 26.087 |
| 0.300 | 26.498 | 10.00 | 26.087 |
| 0.400 | 26.492 | 15.00 | 26.119 |
| 0.500 | 26.508 |
p316 is the G-P fitting parameter (i.e. b, c, a, Xk and d) of type 316 stainless steel corresponding to Zeq. The calculated exposure G-P fitting parameters for type 316 stainless steel are given in
EBFs of type 316 stainless steel (B(E, x)) in the photon energy range of 0.015 MeV - 15 MeV and penetration depth up to 40 mfp are estimated with the calculated G-P fitting parameters using the G-P method [
B ( E , x ) = 1 + ( b − 1 ) × ( K x − 1 ) / ( K − 1 ) when K ≠ 1 (3)
B ( E , x ) = 1 + ( b − 1 ) × x when K = 1 (4)
K ( E , x ) = c x a + d × [ tanh ( x X k − 2 ) − tanh ( − 2 ) ] / [ 1 − tanh ( − 2 ) ] (5)
where E is a specific photon energy in MeV; x is the source-detector distance in the material in mfp; K(E, x) is a parameter, the variation of which represents the photon dose multiplication and changes in the shape of the energy spectrum.
For specific photon energy (E) in the photon energy range of 0.015 MeV - 15 MeV not given in ANSI/ANS-6.4.3, EBF corresponding to E (B) can be interpolated from E using the following formula:
B = B 1 ( log E 2 − log E ) + B 2 ( log E − log E 1 ) log E 2 − log E 1 (6)
| Energy (MeV) | b | c | a | Xk | d |
|---|---|---|---|---|---|
| 0.015 | 1.004 | 1.526 | −0.533 | 5.652 | 0.344 |
| 0.020 | 1.012 | 0.127 | 0.636 | 11.323 | −0.665 |
| 0.030 | 1.027 | 0.372 | 0.192 | 27.042 | −0.282 |
| 0.040 | 1.056 | 0.335 | 0.247 | 12.056 | −0.116 |
| 0.050 | 1.095 | 0.364 | 0.234 | 13.838 | −0.136 |
| 0.060 | 1.142 | 0.399 | 0.213 | 14.071 | −0.117 |
| 0.080 | 1.254 | 0.466 | 0.182 | 14.396 | −0.099 |
| 0.100 | 1.372 | 0.549 | 0.147 | 14.073 | −0.081 |
| 0.150 | 1.635 | 0.731 | 0.083 | 14.097 | −0.049 |
| 0.200 | 1.813 | 0.897 | 0.037 | 13.300 | −0.034 |
| 0.300 | 1.954 | 1.082 | −0.007 | 11.973 | −0.019 |
| 0.400 | 1.978 | 1.178 | −0.025 | 10.847 | −0.014 |
| 0.500 | 1.957 | 1.231 | −0.037 | 8.620 | −0.008 |
| 0.600 | 1.937 | 1.241 | −0.039 | 8.259 | −0.010 |
| 0.800 | 1.896 | 1.232 | −0.038 | 7.777 | −0.011 |
| 1.000 | 1.836 | 1.241 | −0.045 | 17.236 | 0.009 |
| 1.500 | 1.748 | 1.195 | −0.040 | 16.224 | 0.011 |
| 2.000 | 1.711 | 1.123 | −0.021 | 8.052 | −0.006 |
| 3.000 | 1.626 | 1.059 | −0.005 | 12.003 | −0.013 |
| 4.000 | 1.553 | 1.026 | 0.005 | 12.930 | −0.019 |
| 5.000 | 1.483 | 1.009 | 0.012 | 13.126 | −0.026 |
| 6.000 | 1.441 | 0.981 | 0.023 | 13.364 | −0.036 |
| 8.000 | 1.354 | 0.974 | 0.029 | 13.645 | −0.043 |
| 10.000 | 1.297 | 0.949 | 0.042 | 13.968 | −0.056 |
| 15.000 | 1.199 | 0.958 | 0.049 | 14.375 | −0.060 |
where B1 and B2 are EBFs corresponding to the photon energy E1 and E2 given in ANSI/ANS-6.4.3, respectively. E just lies between E1 and E2.
In order to calculate EBF for type 316 stainless steel, an MCNP5 model is setup. As illustrated in
the thickness of each layer is 1 mfp. To reduce statistical error, the importance of each layer doubles from inside to outside. The photon and electron (MODE P E) is considered to transport primary photons and all secondary electrons and photons. Surface-crossing flux estimator (F2 card) is set to the surface of the sphere to record the total average flux on the surface of the spherical shield and works with the dose energy card (DEn) and dose function card (DFn) to obtain the total exposure ( X ˙ total ). The mass energy absorption coefficient (μen/ρ) of dry air used to calculate the dose function value is given in
For a gamma-ray point isotropic source of specific energy, exposure rate caused by the un-collided flux on the surface of a spherical shield ( X ˙ un-collided ) can be calculated analytically using the following expression:
X ˙ un-collided = E × A 4 π r 2 × ( μ e n / ρ ) air × ( e / W air ) × e − μ l × r (7)
where E is the photon energy in MeV; μl is the linear attenuation coefficient for the photon energy of intereste in the shield material, μl of 1.17 MeV and 1.33 MeV are 2.701 × 10−2 cm−1 and 2.623 × 10−2 cm−1, respectively [
B = X ˙ total X ˙ un-collided (8)
| Energy (MeV) | μen/ρ (cm2/g) | Energy (MeV) | μen/ρ (cm2/g) |
|---|---|---|---|
| 0.010 | 4.640E+0 | 0.600 | 2.953E−2 |
| 0.015 | 1.300E+0 | 0.800 | 2.882E−2 |
| 0.020 | 5.255E−1 | 1.000 | 1.000E−2 |
| 0.030 | 1.501E−1 | 1.500 | 2.545E−2 |
| 0.040 | 6.694E−2 | 2.000 | 2.342E−2 |
| 0.050 | 4.031E−2 | 3.000 | 2.054E−2 |
| 0.060 | 3.004E−2 | 4.000 | 1.866E−2 |
| 0.080 | 2.393E−2 | 5.000 | 1.737E−2 |
| 0.100 | 2.318E−2 | 6.000 | 1.644E−2 |
| 0.150 | 2.494E−2 | 8.000 | 1.521E−2 |
| 0.200 | 2.672E−2 | 10.00 | 1.446E−2 |
| 0.300 | 2.872E−2 | 15.00 | 1.349E−2 |
| 0.400 | 2.949E−2 | 20.00 | 1.308E−2 |
| 0.500 | 2.966E−2 |
Based on the data listed in
It is noted that the EBF values of type 316 stainless steel are lower in the low-energy and high-energy range while higher in the intermediate-energy range. In the low energy range, photo-electric effect is the dominant process, resulting in a complete removal of the incident photons and a little buildup of photons, e.g., EBFs for 0.015 MeV photon are slightly greater than 1.0 for all penetration depths. In the intermediate energy range, due to the dominance of Compton scattering that only degrades the photon energy and fails to remove photons completely, the scattered photons exist for a longer time, resulting in a large value of EBF. In the high energy range, pair production starts dominating which results in a strong absorption of photons. However, secondary photons generated by electron-positron annihilation pile up and result in a small increase in EBF.
As for the variation of EBF with the penetration depth, it can be clearly observed that EBFs increase with the penetration depth and the increasing rate of EBF in the intermediate energy range (e.g., 1 MeV) is higher than those of other energy ranges. This is attributed to the increase of penetration depth prevents photons from escaping but producing more scattering, especially for the 1 MeV photon, and leads to the increase of EBF.
Since the energy of gamma rays emitted by 60Co is often used as a benchmark to evaluate the shielding performance of a material, EBFs at 1.17 MeV and 1.33 MeV are calculated based on the data obtained above. EBFs calculated here (BG) are validated with those obtained using the MCNP5 (BM). Variations of (BM − BG)/BM for 1.17 MeV and 1.33 MeV are given in
It can be seen from 5(a) and 5(b), for the penetration depth up to 40 mfp, BMs are consistent with BGs for 1.17 MeV and 1.33 MeV, respectively. The maximum values of (BM − BG)/BM are 8.10% and 15.10% for 1.17 MeV and 1.33 MeV, respectively. Therefore, the bi-linear interpolation is applicable to calculate EBF at specific energy for type 316 stainless steel using the results obtained in this article. Besides, (BM − BG)/BM for 1.17 MeV and 1.33 MeV can be found to increase with the penetration depth for both 1.17 MeV and 1.33 MeV. The reason for the deviation between BM and BG lies in the following aspects:
1) The Monte Carlo model used here is a concentric multilayer model. Being different from the infinite slab model used by ANSI/ANS-6.4.3, the tally surface in the concentric multilayer model can record not only the photons originating from the source point but also the secondary scattered photons in the opposite direction of the emergence of photon. With the increase of the radius, more scattered photons move towards the opposite direction of the emergent photon and are recorded by the tally.
2) Compared with ANSI/ANS-6.4.3, the reaction cross-sections used by MCNP5 are new and the results based on these cross-sections may be more accurate if the simulation model is correct. Besides, it cannot be denied that there
are certain errors in the results obtained using the G-P method, bi-interpolation and MCNP5 simulation.
In this article, the G-P method is used to calculate EBF of type 316 stainless steel produced in China in the photon energy range of 0.015 MeV - 15 MeV and penetration depth up to 40 mfp. It can be observed that EBFs change significantly with the photon energy and penetration depth. Values of EBF are minimum in the low and high photon energy range whereas they are higher in the intermediate photon energy range. Besides, EBFs at 1.17 MeV and 1.33 MeV are calculated based on the obtained data using the bi-linear interpolation and compared with those using MCNP5 by introducing a concentric model. The interpolated results are consistent with the MCNP5 simulation results. The maxima of (BM − BG)/BM are 8.10% and 15.10% for 1.17 MeV and 1.33 MeV, respectively. The results of the present work are helpful for practical calculations in the manufacture of nuclear equipment.
The authors declare no conflicts of interest.
Li, D., Guo, Y.L., Wang, G.X. and Ge, L.Q. (2022) Calculation and Study on the Exposure Buildup Factor of Type 316 Stainless Steel. Open Access Library Journal, 9: e8679. https://doi.org/10.4236/oalib.1108679