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Optimizing gamma radiation shielding with cobalt

Jun 07, 2023Jun 07, 2023

Scientific Reports volume 13, Article number: 8936 (2023) Cite this article

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Cobalt-doped titania nanocomposites were fabricated to be utilized for radiation shielding aims. The chemical composition of the composites was measured using the energy-dispersive X-ray spectrometer. Moreover, the structure of the composites was evaluated using the X-ray diffractometer, and the morphology of the fabricated composites was presented using the scanning electron microscope. Furthermore, the γ-ray shielding properties were estimated using the Monte Carlo simulation between 0.059 and 2.506 MeV. The linear attenuation coefficient of the fabricated composites decreased by factors of 93% for all samples by raising the incident γ-energy between 0.059 and 2.506 MeV. Moreover, the partial replacement of the Ti4+ by Co3+ slightly enhanced the linear attenuation coefficient from 0.607 to 0.630 cm−1 when the Co3+ increased from 0 to 3.7 wt%. The improvement in the linear attenuation coefficient causes an enhancement in other radiation shielding properties.

High-energy ionizing radiations such as X-rays are used in applications such as radiation therapy to eliminate cancerous cells and for imaging of the body. This form of electromagnetic radiation is also used in the field of energy production, agriculture, and many others, with new uses for this technology created every year1,2,3. Because ionizing radiation has such high energy, these photons can also induce negative side effects on the human body such as acute radiation poisoning, cancer, and death. A common technique to reduce these effects is to use a radiation shield that absorbs incoming photons and lowers the amount of radiation to a safe level4,5,6. Nanomaterials outperform conventional radiation shields due to their small particle size, which results in more even dispersion of the filler heavy metal oxides (HMOs) that are introduced into the shield. Greater dispersion means that the incoming radiation has a higher probability to get absorbed or deflected by the atoms within the material, leading to greater attenuation. Nanoparticles are becoming widely used in the construction of cement building materials such as cement paste, mortars, and concretes, which enhance the properties of the materials when introduced with nano HMOs7,8,9,10,11,12.

Titanium oxide nanostructures are often used as an antimicrobial agent for the food packaging industry or as photocatalysts for the degradation of organic compounds because these nanostructures are simple to process, have a low cost, and their ability to induce these reactions can easily be tuned without sacrificing the thermal or chemical stability of the material. Nano-TiO2 is chemically stable, which allows it to be used in cement materials as a filler to improve the chemical characteristics of the material. Ti also has a greater total neutron reaction cross section than Ca and Si at most energy regions, which are used to make conventional cement. This characteristic leads to cement paste containing nano-TiO2 having a better neutron shielding capability than plain cement paste13,14,15,16,17.

Additionally, TiO2 itself has a low cost, can abundantly be found, is not toxic, and is chemically inert. It has extensively been used in the coating industry, in waste-water purification, and energy storage devices. TiO2 as a typical n-type semiconductor has a carrier concentration of only 1017–1018 cm−3 and has a high refractive index at visible wavelengths. Pure TiO2 has three different polymorphs, each with its bandgap energy. More specifically, these are rutile (for 3.0 eV), anatase (for 3.2 eV), and brookite (for ~ 3.2 eV). The bandgap of TiO2 can be tuned by doping it with various ions or defects, which activates the TiO2 compound in the visible light spectrum; pure TiO2 is active in the ultraviolet region. By introducing transition metal oxides and noble metal compounds into TiO2, visible light TiO2 photocatalysts are created, which can be used to remove water pollutants. Cobalt oxides are one of these dopants that are drawing attention because of their god speed in the photocatalytic-reduction of Carbon dioxide (CO2) in visible and ultravilot light and dye-sensitized solar cells for energy production18,19.

To understand the shielding abilities of certain materials, radiation shielding parameters need to be calculated and analyzed across a wide range of energies. Monte Carlo simulations are used to determine these values such as linear attenuation coefficients using a specific set of conditions. These simulations can be used to understand the properties of material before experimentally determining these parameters, to save time and resources, or alongside theoretical calculations such as XCOM to ensure the two methods agree with each other. After the initial values are obtained, further parameters can be determined to gain a full understanding of the radiation shielding abilities of the material20,21,22,23,24,25.

The concept presented in present study is estsblished on the exact planning of a two dimintion (2D) nanoparticular structure of cobalt oxides and titanium oxides linked by carbon sheets. The inclusion of cobalt contributes to thermal stability, corrosion resistance, and wear, which makes it, along with titanium, useful in many industries. Additionally, cobalt oxides stand out due to their capacity for coloring. The two-dimensional carbon sheets increase the surface area of the prepared nanomaterial. The newly synthesized compounds' characterization and γ-ray protection particulares has been inspected.

(I) A known size and concentration (0.4 mL–0.1 M) of hydrous potassium chloride, 98 mL solution of ethanol, and 1.6 mL of (Ti4O28H12C) titanium isopropoxide have been mixed together and agitated for 5 h. All the contents were then moved to a Teflon-lined stainless steel autoclave with a 100 mL capacity.Then the temperature was raised to 170 °C for 35 h. After that, the autoclave has been brought to cooling naturally at room temperature. The finished product was gathered thoroughly and soaked in ethanol and has been dried in the oven at 70 °C after filtering. Finally, the solids were transferred to the furnace to be calcined at a temperature of 500 °C for 4 h to produce TiO2 NPs. (II) to produce a Cobalt-doped TiO2 nanocomposite (Co-TiO2), 0.9 gm of cobalt acetate is added to the mixed solution before transferring it to the autoclave and then following the same previous steps. (III) The method for preparing cobalt-doped TiO2 loaded on carbon sheets (Co-TiO2/C) involves mixing 0.5 g of Co-TiO2 nanocomposites produced in step (ii) with 80 mL of an aqueous solution containing 0.02 g glucose. The mixture has been stirred for 4 h, then placed in the autoclave used in the previous steps then heated for 30 h at 170 °C. After that, leave the autoclave to cool naturally in the air. The solids were gathered thoroughly and stirred well in water for washing and have been arid in the furnace at 70 °C. Finally, the solids powder have been calcined for 4 h at 500 °C.

Utilizing a (PANalytical X'Pert Pro diffractometer, Netherlands), XRD patterns have been obtained. To comprehend the crystallographic phase, a monochromatic CuKa radiation source with a wavelength of (0.15406 nm) was set to (45 kV) and (40 mA) at 25 °C. The diffractograms were captured with a step size of (0.013) over a scan range of 20°–80°. To predestine the morphology of the fabricated solid powders materials and appreciation the element analysis, scanning electron (SEM) microscope and an energy-dispersive X-ray spectrometer (EDX) havebeen used (JEOL JSM-6400—Jeol Ltd., Tokyo, Japan). The TEM analysis, which was performed using a (Philips CM200, America) transmission electron microscope with a 200 kV accelerating voltage, provided information about the morphological structure of the composite. The crystallinity of various components in the produced composite was determined using Raman spectroscopy with a 532 nm laser excitation (GL Gem Raman™ PL532, Canada).

Utilizing the MCNP5 code, the ability for γ-ray shielding for the newly synthesized cobalt-doped titania nanocomposites was simulated in the γ-ray energy ambit of (0.059–2.506 MeV). The MCNP code utilized the nuclear database ENDF/B.VI.8 and the tally F4 to estimate the median flux per unit cell and average track length (ATL) of gamma photons in the chosen composites. To estimate the ATL of gamma photons in the manufactured materials an input file contains all information about the fabricated nanocomposites, radioactive source, detector, and tally, as illustrated in Fig. 1. The required information was introduced to the MCNP's input file through some definite cards such as cell, surface, materials, source, and tally cards. After runout the simulation process, a new output file was created and has a txt format. The created output file contains all required information about the ATL, the number of collisions in the material cell as well as the relative error in the simulation process. The relative error recorded for all samples ranged from ± 3%. Detailed information about created geometry and the dimensions of the geometry components collimators, sample, detector, and source was discussed in some previous works26,27.

The MCNP's geometry as illustrated in the input file.

Using some mathematical equations, the simulated MCNP's ATL for the fabricated composites was transferred to the linear (µ) and mass (µm, cm2/g) attenuation coefficients. Then, based on the estimated µ, the half-value thickness (Δ0.5), lead equivalent thickness (Δeq), transmission factor (TF), and radiation protection efficiency (RPE) were evaluated as illustrated in the following equations28.

\(N_{0}\), \(N_{t}\), and x are the number of emitted photons from the radioactive source, the transmitted photon number through the fabricated composite with a definite thickness (x, cm).

The fabricated composite's thickness that can attenuate 50% of the emitted γ- photons define the Δ0.5 and it is can be predicted through Eq. (3).

The XRD diffraction pattern (Fig. 2) was utilized to illustrate the synthesized composites’ phase compositions. TiO2 XRD pattern shows all of the tetragonal anatase characteristic peaks (JCPDS 9015929) which the main diffraction peaks of crystalline phase at 2θ values of 25.77°, 37.72°, 47.92°, 53.9°, 55.02°, 62.57°, 68.4°, 70.3°, and 74.9° are corresponding to the (101), (004), (200), (105), (211), (204), (116), (220) and (215)29. The XRD results of TiO2 doped by Co and C nanocomposites demonstrate the lack of any free cobalt phases, which implies that all the cobalt is a fuse in anatase crystallites. XRD results show that there is a lack of obvious carbon peaks, indicating that the carbon in the composite has a low degree of crystallinity. Surprisingly, the two samples’ Co-TiO2 and Co-TiO2/C diffraction patterns resembled those of virgin TiO2, with a minor change in the position of the peak. The slight shift in peak position in the XRD pattern is the result of the modification in structure at the local level around Ti4+ resulting from the substitution of Co3+ and Co2+. This suggests that Cobalt dissolved within the lattice. Another notable change with the inclusion of cobalt is the change in the color of TiO2. All of the XRD patterns revealing that the average size of the nanocrystalline particles of pure TiO2 changed when cobalt or cobalt/carbon is added. According to Scherrer's equation (Fig. 3)29, the average crystallite size of prepared samples: pure TiO2 (TiO2 nanoparticles), single doped TiO2 (Co-TiO2 nanocomposite), and double doped TiO2 (Co-TiO2/C nanocomposite) were 11.7, 12.4, and 13.24 nm, respectively. The samples' increased crystal size emphasizes that cobalt is replacing Titanium in the lattice of TiO2 (anatase phase). An examination of the main peak in XRD diffraction (101) in Fig. 2 (inset) when magnified, shows a significant shift towards higher 1 theta values when cobalt and carbon are introduced as dopants. Additionally, the average crystallite size of double-doped TiO2 by C and Co (Co-TiO2/C) material is found to be greater in comparison to that of the single-doped TiO2 by Co only (Co-TiO2). These findings suggest that there is a synergistic effect between carbon and cobalt when they are combined together. The XRD results reveal that the average crystallite size of the two manufactured materials doped by (Co) and (Co, C) are almost identical. Furthermore, their positions of diffraction peaks are similar, which implies that carbon doping has a minor impact on the crystal structure30,31.

XRD diffraction pattern for the fabricated nanocomposites samples.

The crystal size of the fabricated nanocomposites samples.

Figure 4 shows the Raman spectrum of three fabricated samples in the 50–2000 cm−1 range. The Peaks which apperant at 151.5, 391.5, 513, and 631.5 cm−1 were assigned to TiO2 (anatase crystalline phase) modes Eg, B1g, A1g, and Eg, respectively32. All peaks show a significant decrease in intensity after cobalt doping, along with some shift in peak position. Although these findings imply that the anatase phase was not entirely altered by the Co, they also reveal a significant long-order crystallite distortion, which agrees with the XRD findings. The substitution of Ti4+ by Co3+ and the disparity in their cationic charges could explain this distortion. Furthermore, doping by Co and C also correlated to the formation of vacancies in the oxygen chain, which significantly affects the vibration of the bond between Ti and O (Ti–O). It is substantial to point out while the size of the nanoscale crystalline phase, which influences the frequency of shifting brought on by phonon confinement, limits the peak position shift. The A1g peak shows a clear shift in location and an obvious rise in intensity. Modification in the A1g peak indicates the formation of more vacancies in the oxygen chain, mainly likely as a consequence of the reaction with carbon in the hydrothermal reaction. According to the strong Raman peak at 689 cm−1, the anatase Eg modes shifted as a result of being doped by carbon and cobalt33. Even after the calcination of the material containing carbon in the air, the existence of carbon can be established by seeing peaks at 1300 cm−1 and 1850 cm−1 which refer to D and G bands, respectively. Given that the ratio of the intensity of two peaks D and G (ID/IG) = 1.3, the carbon is most likely amorphous in form34.

Raman spectrum of the fabricated nanocomposites samples.

Figure 5a–c shows SEM of TiO2 nanoparticles, TiO2 doped by Co (Co-TiO2), and when adding carbon (Co-TiO2/C) after 500 °C calcination. The results show that nanoparticle clusters form in all samples. Surprisingly, the two samples of TiO2 which were doped by (Co) and (Co, C) form 2D sheets. Undoped TiO2 nanoparticles, on the other hand, tend to form more irregular shapes when clustered. After the addition of cobalt and carbon, the appearance of distinct nanosheets indicates a predilection for development in particular directions. After the addition of cobalt, there is most likely a rise in state density perpendicular to the C-axes; in addition, partial oxygen removal occurs due to the presence of carbon. The 2D sheets are only weakly attached to one another to create a zigzag pattern with pores, which is seen in Fig. 5b,c. The TEM images (Fig. 5d–f) provide additional information concerning fabricated materials' morphology. According to the findings, each of the three types of material put to the test is made up of nanoparticles that have parallel sides and measure approximately 23 nm in size on average. At the edges, the particles start fusing together after adding Co which forms 2D nanolayer sheets. Then, when glucose has been added as a carbon source, the clusters and average particle size were increased without any distortion in the anatase phase. The EDX spectra and element mapping (Fig. 6) show pure TiO2, Fig. 7 indicates the existence of (Co) element in the single doped prepared sample (Co-TiO2), and Fig. 8 indicates the existence of (Co, C) elements in the double doped prepared sample (Co-TiO2/C). There were no peaks associated with Co or C in the XRD patterns. As a result, the Co ions in the single-doped case (Co-TiO2) and (Co, C) ions in the double-doped case (Co-TiO2/C) are distributed among the titanium dioxide crystallites (anatase phase) in a uniform form. In Table 1, the elemental analysis composition of TiO2 nanoparticles after doping by Co and C can be determined.

(a–c) SEM image for TiO2 nanoparticles, single doped TiO2 (Co-TiO2), and double doped TiO2 (Co-TiO2/C), respectively. (d–f) TEM image for TiO2 nanoparticles, single doped TiO2 (Co-TiO2), and double doped TiO2 (Co-TiO2/C), respectively.

Elemental analysis and mapping (EDX) of the fabricated TiO2 nanoparticles.

Elemental analysis and mapping (EDX) of the fabricated Co-TiO2 nanocomposite.

Elemental analysis and mapping (EDX) of the fabricated Co-TiO2/C nanocomposite.

The µm and µ are the main important parameters that describe the capacity of newly synthesized cobalt-doped titania nanosheets on resisting the transport of photons. Both µm and µ were evaluated for the fabricated nanocomposites (pure TiO2 nanoparticles, single doped TiO2 (Co-TiO2) nanocomposite, and douple doped TiO2 (Co-TiO2/C) nanocomposite) using the MCNP code as well as the XCOM software program over a wide γ-ray spectrum (Eγ, MeV) ranging from 0.059 to 2.506 MeV. The µm behavior is depicted in Fig. 9 at various γ-ray interactions regions [a] photoelectric interaction, [b] Compton scattering, and [c] pair production interactions. According to Fig. 9a, the µm values decreased by 68% for both manufactured composites (pure TiO2 nanoparticles, single doped TiO2 (Co-TiO2) nanocomposite, and douple doped TiO2 (Co-TiO2/C) nanocomposite) with increasing Eγ values. The simulated µm values decreased between 0.567 and 0.183 cm2/g for the TiO2 NPs, between 0.576–0.184 cm2/g for the Co-TiO2 composite, and between 0.569 and 0.183 cm2/g for the Co-TiO2/C composite. The photoelectric cross section varied inversely with the third power of Eγ, explaining the large decrease in the µm values. Figure 9b shows a decrease in the µm values between 0.0989–0.0618 cm2/g for the TiO2 NPs, between 0.0991 and 0.0619 cm2/g for the Co-TiO2 composite, and between 0.0991 and 0.0619 cm2/g for Co-TiO2/C with raising the Eγ values between 0.344 and 0.964 MeV. The presented reduction behavior was studied using the cross-section of the Compton scattering, which varies inversely with Eγ. Figure 9c depicts a slight reduce in the µm values associated with any increase in the Eγ values within the energy interval 1.173–2.506 MeV. The illustrated slight reduction is due to the fact that the CS interaction is still the predominant interaction also between 1.173 and 2.506 MeV. Therefore, the PE, and CS interactions only appeared during the result analyses while the pair production interaction (PP) was not observed in the studied energy range. The delayed appearance of PP interaction in the current work is attributed to the relatively small density of the manufactured composites. The PP interaction in the current work starts at gamma-ray energy higher than 3 MeV where the high variation in the gamma energy (in the PP interval) causes a very slight increase in the µm values. This behavior is attributed to the proportionality of the PP cross-section with Log E.

The mass attenuation coefficient for the fabricated composites.

The simulated results using the MCNP were confirmed using the theoretical free program XCOM as illustrated in Fig. 9. The obtained results showed an agreement with the simulated data with a range between ± 2%.

Also, the modification of the titanium dioxide (TiO2 NPs) with Co and C nanoparticles has a slightly enhancing effect on the µm values. Figure 10 describes the variation of the µm values versus the Ti nanoparticle concentrations in the fabricated composites. In the low energy interval (i.e., Eγ of 0.103 MeV) the µm values increased slightly with decreasing Ti nanoparticles in the fabricated composites while in the high photon energies, the µm values increased with raising the Ti nanoparticle. This behavior is attributed to the Co nanoparticles where the decrease in the Ti nanoparticles concentrations was accompanied by an increase in the Co nanoparticles concentration. Hence, the Co nanoparticles have a µm value higher than that recorded for the Ti nanoparticles at low Eγ values while the µm values for the Co nanoparticles are comparable to the µm values of Ti at high Eγ values. For instance, the µm for Co is 1.343cm2/g at a low Eγ of 0.059 MeV while it is 0.782cm2/g for Ti element at the same Eγ value. Moreover, the Co's µm value is 0.496 cm2/g at Eγ of 1.408 MeV, which is comparable to the Ti's µm value of 0.495 cm2/g35. Then decreasing the concentration of Ti nanoparticles in the manufactured nanocomposites was associated with an increase in the µm values at low γ-photon energies while the mentioned trend was reversed for the high γ-photon energy. Because of the low concentrations of Co and C nanoparticles added to the TiO2 nanoparticles, the variation in simulated µm values is relatively small.

Variation of the mass attenuation coefficient (µm, cm2/g) versus the Ti concentrations at 0.103, 0.662, and 1.250 MeV.

The Δeq describes the synthesized composites’ thickness which is able to attenuate the same photon number as a 1 cm thickness of the pure lead (Pb). Figure 11 depicts the change in the µ, Δ0.5, and Δeq values versus Eγ values for the fabricated composites [a] TiO2 nanoparticles, [b] single doped TiO2 (Co-TiO2), and [c] double doped TiO2 (Co-TiO2/C) versus. Figures 11 a, b, and c show a decrease in µ and Δeq values and increase the Δ0.5 values. The evaluated µ values decreased shapely between 1.884 and 0.127 cm−1 (for TiO2 NPs), between 1.970–0.131 cm−1 (For Co-TiO2/C nanocomposite), and between 1.955 and 0.132 cm−1 (for Co-TiO2/C nanocomposite) with raising the Eγ. The reduction of the µ was caused by the effect of PE, CS, and PP interactions. The highest calculated Δeq values are 83.978, 80.772, and 80.977 cm for the fabricated pure TiO2 nanoparticles, single doped TiO2 Co-TiO2 composite, and double doped TiO2 Co-TiO2/C composite, respectively. The calculated Δeq decrease rapidly as the Eγ values increase due to the large decrease in the Pb's µ values compared to the decrease achieved in the fabricated composites’ µ value. Between 0.059 and 0.122 MeV, the Δeq increased by a factor of ≈ 103% for the fabricated composites. The mentioned increase in the Δeq is attributed to the low drop in Pb's µ compared to the reported drop in the fabricated composites µ values. The Pb's µ droped by a factor of ≈ 34%, whereas the tested composites’ µ values decreased by a factor of ≈ 67% when the Eγ was raised between 0.059 and 0.122 MeV. After that, in the intermediate energy interval between 0.344 and 0.964 MeV, the Δeq values were reduced by factors of ≈ 62%. This reduction is due to a large reduction in Pb's µ values compared to the moderate µ values reduction for the fabricated composites. In the CS interaction interval, the Pb's µ value droped by 76% and the µ for the synthesized composites decreased by 37.57, 37.60, and 37.57% for TiO2 nanoparticles, single doped TiO2 (Co-TiO2), and double doped TiO2 (Co-TiO2/C). Because the µ values for Pb and the fabricated composites are independent of the γ-photon energy, there is no significant variation in the Δeq values with variation in the Eγ values in the high Eγ interval between 1.173–2.506 MeV. The Δ0.5 values show an increase with raising the Eγ values due to the reduction recorded for the µ values, where the Δ0.5 values are inversely proportional to the µ (see Eq. 3).

The linear attenuation coefficient, half-value thickness, and lead equivalent thickness for the prepared composites.

The change in µ, Δ0.5, and Δeq values vs. the amounts of Ti4+ and Co3+ nanoparticles at Eγ of 0.662 MeV was given in Fig. 12. The µ values decreased with raising the Ti concentrations while they increased with raising the Co concentration. While, the Δ0.5, and Δeq increased with raising the Ti concentrations while they decreased with raising the Co concentrations at Eγ of 0.662 MeV. The Δ0.5 values increased slightly from 2.730 to 2.827 cm with raising the Ti4+ concentration from 55.4 to 61.9 wt% while it decreased with raising the Co concentration from 0 to 3.7%. Furthermore, the Δeq values at the same Eγ of 0.662 increase from 4.896 to 5.069 cm with raising the Ti nanoparticle concentration from 55.4 to 61.9 wt% while it decreases from 5.069 to 4.896 with raising the Co3+ nanoparticle concentration from 0 to 3.7 wt%. The illustrated behaviors for µ, Δ0.5, and Δeq were attributed to the partial replacement of Ti4+ nanoparticles with Co3+ nanoparticles where the partial replacement of the Ti by Co nanoparticles causes an increase in the electron density of the composites which creates more resistance for passing the incident photons.

Variation of the linear attenuation coefficient, half-value thickness, and lead equivalent thickness versus Ti and Co concentrations.

Figure 13 illustrates a comparison between the fabricated composites µ values and the µ values for some previously reported composites and common commercial shielding glasses at Eγ of 0.662 MeV. The fabricated composites TiO2, Co-TiO2 and Co-TiO2/C have µ values of 0.245 cm−1, 0.253 cm−1, and 0.254 cm−1. These values are higher than reported for AlB12 (0.186 cm−1), B4C (0.189 cm−1), MgB2 (0.192 cm−1), Al (SO4) (0.203 cm−1), KAl (SO4) (0.132 cm−1), Mg(OH)2 (190 cm−1), and Na2SO4 (0.197 cm−1) compounds36,37. Additionally, the fabricated composites µ values are higher than the common commercial glasses’ RS-253, RS-253 G18, and RS-323 G19 with µ values of 0.16 cm−1, 0.16 cm−1, and 0.24 cm−1, respectively38. In contrast, the fabricated compounds have µ values less than that reported for BaSO4, Fe2O336, and RS-36038 with µ values of 0.347 cm−1, 0.388 cm−1, and 0.27 cm−1, respectively. The high amount of heavy metals Ba, Fe, and Pb is responsible for the high linear values for Ba2SO4, Fe2O3, and RS-360, with the last containing almost 45 wt% PbO.

Comparison of the linear attenuation coefficient for the fabricated composites to the linear attenuation of previously reported compounds and commercial shielding glasses.

The TF and RPE for the selected composites were exhibited in Fig. 14. A decrease in the TF values between 15.2 and 88.0% (for composite TiO2), between 13.9 and 87.7% (for Co-TiO2 composite), and between 14.2 and 87.8% (for Co-TiO2/C composite) when the Eγ increased from 0.059 to 2.506 MeV. On the other hand, the RPE decreases from 84.8 to 12.0% (for composite TiO2), from 86.1 to 12.3% (for composite Co-TiO2), and from 85.8 to 12.3% (for composite Co-TiO2/C) when the Eγ varied between 0.059 and 2.506 MeV. The previously discussed behaviors for both parameters are attributed to the penetration ability of the incident γ-photons, where raising the energy causes an increase in the penetration power of the photons due to the decrease of the photon wavelength. Therefore, the emitted photons (No) pass the tested composites with a low number of collisions with the surrounding electrons. Thus, the Nt increase is associated with a decrease in the number of photons absorbed in the fabricated composites (Na). The mentioned increase in the Nt as well as the decrease in the Na photons give rise to the increase in the TF and decrease in the RPE with raising the γ-photon energies.

Dependence of the transmission factor and the radiation protection efficiency on the γ-photon energy for the fabricated composites.

The dependence of TF and RPE values on the composites’ thickness was illustrated in Fig. 15. The TF values decreased and the RPE increases for all fabricated composites when the composite thickness grew between 0.025 and 2 cm. When the thickness ranged between 0.25 and 2 cm, the TF values decreased linearly from 93.3 to 57.6% (for TiO2 composite), between 86.7 and 56.6% (for Co-TiO2 composite), and between 86.7 to 56.5% (for Co-TiO2/C composite). But, the RPE increased linearly from 6.7 to 42.4% (for TiO2 composite), from 6.9 and 43.4% (for Co-TiO2 composite), and from 6.9 to 43.5% (for Co-TiO2/C composite) when the thickness of the composite raised from 0.25 to 2 cm at a gamma photon energy of 0.511 MeV. Raising the composite thickness causes an increase in the path length of incident γ-photons inside the fabricated composites. Therefore, the possibility of the incident photons interacting with the surrounding electrons increases. Thus, the consumed energy by incident photons increased inside the material with higher thicknesses than the lower one, resulting in a significant increase in RPE values accompanied by a corresponding decrease in TF values39.

Dependence of the transmission factor and the radiation protection efficiency on the composite thickness.

A Cobalt-doped TiO2 nanocomposite with more vacancies in the oxygen chain was synthesized based on a hydrothermal method in one step and the formation and crystallinity of the synthesized composite were confirmed using XRD in 2D sheets with an average crystal size of less than 13 nm. Moreover, the µm of the cobalt-doped titania nanocomposites was estimated using MCNP5 between 0.059 and 2.506 MeV. The simulated values of the mass attenuation coefficient were confirmed using the XCOM program, where the difference between the XCOM and MCNP results ranged between ≈ ± 2%. The mass attenuation coefficient decreased from 0.567 to 0.038 cm2/g (TiO2 composite), 0.567 to 0.038 cm2/g (Co-TiO2 composite), and from 0.570 to 0.038 cm2/g (Co-TiO2/C composite) in the studied energy region. The mass attenuation coefficient values increase with decreasing the Ti4+ ions in the fabricated composites at low γ-photo energy while it has no considerable changes with substitution of Ti4+ by Co3+ ions at intermediate and high γ-photon energy. Furthermore, the µ is slightly increased by raising the Co3+ ions between 0 and 3.7 wt% in the fabricated composites. The mentioned increase in the µ values was associated with a slight decrease in Δ0.5 and Δeq values. Based on the concluded results, the fabricated composites-based TiO2 nanocomposites can be used as fillers to improve the gamma-ray shielding capacity of polymers, ceramics, and paint materials. The fabricated composites have a good shielding capacity in low and intermediate gamma-ray energy intervals but it is not suitable for high gamma-ray energy applications.

The data that support the findings of this study are available from the corresponding author upon reasonable request.

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The authors express their gratitude to Princess Nourah bint Abdulrahman University Researchers Supporting Project number (PNURSP2023R2), Princess Nourah bint Abdulrahman University, Riyadh, Saudi Arabia.

Nuclear Materials Authority, P.O. Box 530, El-Maadi, Cairo, Egypt

Islam G. Alhindawy & Karem A. Mahmoud

Department of Physics, Faculty of Science, Isra University, Amman, Jordan

M. I. Sayyed

Department of Nuclear Medicine Research, Institute for Research and Medical Consultations (IRMC), Imam Abdulrahman Bin Faisal University (IAU), P.O. Box 1982, 31441, Dammam, Saudi Arabia

M. I. Sayyed

Department of Physics, College of Science, Princess Nourah Bint Abdulrahman University, P.O.Box 84428, 11671, Riyadh, Saudi Arabia

Aljawhara H. Almuqrin

Ural Federal University, 19 Mira St, Yekaterinburg, Russia, 620002

Karem A. Mahmoud

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Category 1: Conception and design of study—I.G.A.; K.A.M.; M.I.S. Acquisition of data: I.G.A.; K.A.M.; A.H.A. Analysis and/or interpretation of data: I.G.A.; K.A.M. Category 2: Drafting the manuscript— I.G.A.; K.A.M.; M.I.S. Revising the manuscript critically for important intellectual content: I.G.A.; K.A.M.; A.H.A.; M.I.S. Category 3: Approval of the version of the manuscript to be published—I.G.A.; M.I.S.; A.H.A.; K.A.M.

Correspondence to Islam G. Alhindawy or Karem A. Mahmoud.

The authors declare no competing interests.

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Alhindawy, I.G., Sayyed, M.I., Almuqrin, A.H. et al. Optimizing gamma radiation shielding with cobalt-titania hybrid nanomaterials. Sci Rep 13, 8936 (2023). https://doi.org/10.1038/s41598-023-33864-y

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Received: 17 February 2023

Accepted: 20 April 2023

Published: 01 June 2023

DOI: https://doi.org/10.1038/s41598-023-33864-y

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