3.1. The Impact of Increasing Entropy on the Irradiation Resistance of PdTi Alloys
During the incidence of a PKA atom, the cascade collision process can be observed.
Figure 2 illustrates the evolution of irradiation damage in PdTi alloys at a temperature of 300 K with an incident particle energy of 10 keV. The figure shows that the PKA atom collides with atoms along its trajectory, transferring energy to these atoms. When the collision energy exceeds the displacement energy threshold, the atoms are displaced, creating displaced atoms. At the initial stage of the cascade collision, at 0.01 ps, a small number of point defects are generated. As the PKA atom continues to move and reaches 0.42 ps, the cascade collision peaks and the number of point defects reaches its maximum, although they are highly unstable. As the cascade collision progresses, these defects begin to recombine. By 1.07 ps, the number of point defects has significantly reduced. Over the following time, the point defects continue to recombine, eventually reaching a stable state around 5.24 ps. This process is consistent with the general behavior of irradiation damage in other alloys, but the irradiation damage in alloys is not entirely the same as that in other materials, such as metal oxides, with some exhibiting significant differences.
By comparing the irradiation evolution of CuO and ODS steels, it is evident that the irradiation evolution of PdTi alloys, CuO [
54], and ODS steels [
55] is different. Their distinct irradiation evolution also reflects the different mechanisms by which they respond to radiation. PdTi alloys show exceptional resistance to irradiation through a reduction in defect formation and enhanced defect recombination. During irradiation, primary knock-on atoms (PKAs) create point defects, but the unique composition of PdTi alloys limits the depth and extent of cascade collisions, preventing secondary defect clusters. CuO, on the other hand, exhibits a suppression of CuO formation in favor of Cu
2O under irradiation, a process driven by radiation-induced defects that modify ion diffusion and oxidation behavior. ODS steels utilize dispersed nano-sized oxides to absorb radiation-induced defects, thereby enhancing their strength and stability in extreme environments such as nuclear reactors. However, maintaining the stability of these nano-oxides at high temperatures remains a challenge due to coarsening effects. These three materials emphasize the crucial role that defect formation and evolution play in determining their structural integrity and irradiation resistance.
Figure 3 presents the distribution of the point defects at the peak of the cascade collisions and the stabilized distribution of the point defects after 10 ps of recombination under a system temperature of 600 K and with a PKA atom incident energy of 20 keV for Pd, PdTi
1.5, PdTi, and Pd
1.5Ti.
Figure 3a depicts the scenario at the peak of the cascade collisions, and the bottom row (b) illustrates the scenario after 10 ps of irradiation. At the peak of the cascade collisions under 20 keV irradiation (
Figure 3a), significant point defects can be observed. For the pure Pd, the point defects are widespread, with the cascade collisions penetrating the entire model and creating multiple secondary cascade clusters, indicating minimal obstruction. In the PdTi
1.5 alloy, the depth and size of point-defect distribution are reduced, but secondary cascade clusters still exist, indicating some degree of obstruction. In the PdTi alloy, the depth and size of the point defects are further reduced, and no secondary cascade clusters are observed, suggesting significant obstruction of the cascade collision.
The definition of high-entropy alloys stems from their high mixing entropy. In thermodynamic processes, entropy measures the degree of disorder in a system. The increase in system entropy (
S) is synchronous with the increase in the mixing degree (Ω), meaning the greater the mixing, the larger the entropy value. According to the statistical thermodynamic hypothesis by Boltzmann, the system entropy is related to the system mixing degree by the following formula:
S =
klnΩ. In this equation,
k is the Boltzmann constant, 1.38054 × 10
23 J/K. For a pure alloy system, the total entropy includes the mixing entropy (also called configurational entropy,
Sconf), magnetic entropy (
Smag), vibrational entropy (
Sv), and electronic entropy (
Se). In the changes in different combined entropies, the mixing entropy contributes the most compared to the others. Therefore, changes in the entropy of the alloy system are often represented by the mixing entropy Δ
Sconf in solid-solution or liquid-solution alloys.
where
R is the molar gas constant,
R = 8.314 J/(K⋅mol), and
Xi is the atomic fraction of element
i in the alloy. The first term in the formula represents the number of atoms; when the atomic fractions of the components in the alloy are equal, the system achieves the maximum mixing entropy. It is known that as the number of components in the alloy system continues to increase, the corresponding system’s mixing entropy also increases. The components of the alloy can be any metallic elements. When
n = 2 and 5, Δ
Sconf is 0.69 R and 1.61 R, respectively. When the number of components increases beyond five, the growth rate of the system’s mixing entropy gradually decreases. The most direct manifestation is that the slope gradually flattens. When
n exceeds 10, the rate of increase in the mixing entropy of the system slows down significantly. This suggests that when
n reaches a certain value, the influence of increasing
n on the mixing entropy becomes quite limited. Enhancing the mixing entropy cannot be achieved merely by increasing the number of main components.
The calculated entropy values for pure Pd, PdTi1.5, PdTi, and Pd1.5Ti are 0, 0.673 R, 0.693 R, and 0.673 R, respectively. From the irradiation damage graphs of the first three alloys (Pd, PdTi1.5, and PdTi), it is evident that as the entropy increases and the Pd content rises, the alloys’ irradiation resistance significantly improves, with PdTi showing a marked enhancement in performance. However, the Pd1.5Ti alloy displays a similar depth and size of point-defect distribution compared to PdTi, indicating that the irradiation resistance does not improve further with increased Pd content, potentially due to the reduction in entropy.
Figure 4 presents the distribution of the point defects at the peak of the cascade collisions and the stabilized distribution of the point defects after 10 ps of recombination under a system temperature of 600 K and with a PKA atom incident energy of 30 keV for Pd, PdTi
1.5, PdTi, and Pd
1.5Ti.
Figure 3a depicts the scenario at the peak of the cascade collisions, and the bottom row (b) illustrates the scenario after 10 ps of irradiation. At the peak of the cascade collisions under 30 keV irradiation (
Figure 4a), the point defects increase significantly across all alloys compared to the 20 keV scenario. For pure Pd, the point defects are even more widespread, with deeper penetration and multiple secondary cascade clusters, indicating continued minimal obstruction, which is similar to the trend observed in the results for Ni in the referenced literature [
56,
57]. In the PdTi
1.5 alloy, the depth and size of the point-defect distribution are still reduced, but secondary cascade clusters persist. In the PdTi alloy, the point defects are further reduced, with no secondary cascade clusters, indicating significant obstruction of the cascade collision. The Pd
1.5Ti alloy shows a similar pattern to PdTi, suggesting that increasing Pd content does not improve irradiation resistance further, likely due to the reduced entropy.
After 10 ps of irradiation under 30 keV (
Figure 4b), the distribution of the point defects stabilizes but remains more pronounced than in the 20 keV scenario [
57]. In pure Pd, the defects remain extensive. The PdTi
1.5 alloy continues to exhibit some secondary cascade clusters, but when the incident PKA atom energy is increased from 20 keV to 30 keV, the PdTi
1.5 alloy does not show reduced defect depth and size compared to pure Pd, nor does it demonstrate an advantage in defect recovery capability. The PdTi alloy maintains significantly reduced defects, with no secondary clusters, indicating strong obstruction. The defect distribution of Pd
1.5Ti appears to be smaller than that of PdTi. This improvement might be due to the increased Pd content, whose advantage becomes more significant than the entropy increase when the incident PKA atom energy is raised from 20 keV to 30 keV.
Although this study focuses on a binary PdTi alloy, which differs from high-entropy alloys, medium-entropy alloys (MEAs) still exhibit significant effects that can help explain the enhanced irradiation resistance observed in PdTi. The medium-entropy effect refers to the relatively high mixing entropy of medium-entropy alloys, which helps form a stable solid solution, thereby enhancing the thermal stability of the alloy under irradiation. Additionally, the difference in atomic radii between Pd and Ti leads to a lattice distortion, increasing the resistance to dislocation motion and defect formation, which helps mitigate the expansion of radiation-induced defects. In PdTi alloys, these effects collectively explain the alloy’s superior irradiation resistance. First, the medium-entropy effect contributes to the formation of a stable solid-solution structure, and compared to pure Pd, the addition of Ti enhances the thermodynamic stability of the alloy under irradiation, thereby reducing structural damage caused by phase transformations. Second, the lattice distortion effect increases lattice strain in PdTi alloys, further strengthening the resistance to dislocation motion and point-defect formation, ultimately reducing the expansion of radiation-induced defects. The synergy of these effects makes PdTi alloys highly effective in resisting irradiation damage.
3.2. The Impact of the Pd Element Ratio on the Irradiation Resistance of PdTi Alloys
Figure 5 shows the trajectories of primary knock-on atoms (PKAs) in different PdTi alloys at 600 K under a PKA atom incident energy of 20 keV. The images depict the movement of the PKA atoms in the four different alloy compositions: (a) PdTi, (b) PdTi
1.5, (c) PdTi, and (d) Pd
1.5Ti. In the PdTi alloy (a), the trajectory of the PKA atom appears relatively straight and covers a considerable distance. This indicates that the PKA atom moves through the lattice with minimal deflection, suggesting that the lattice provides less resistance to the PKA atom’s motion. This could imply relatively fewer interactions with surrounding atoms, leading to fewer collisions and, thus, less energy dissipation. In the PdTi
1.5 alloy (b), the PKA atom’s trajectory is also relatively straight and similar to that in pure Pd. This suggests that the PKA atom encounters a similar level of resistance in PdTi
1.5 as in pure Pd, resulting in comparable energy dissipation. The trajectory shown for PdTi (c) indicates more deflection and the shortest path among the alloys. This suggests a higher degree of interaction between the PKA atom and the surrounding lattice atoms, leading to more collisions and energy dissipation. The increased deflection implies that the PKA atom loses energy more quickly, resulting in a shorter overall trajectory. The PKA atom in Pd
1.5Ti (d) exhibits a curved trajectory with a short path. This indicates a high level of interaction with the lattice atoms, leading to multiple collisions and substantial energy dissipation. Although the path is slightly longer than that in PdTi (c), it still shows significant energy dissipation. Overall, the trajectories of the PKA atoms in pure Pd and PdTi
1.5 alloys are similar, indicating comparable levels of energy dissipation and obstruction. The PdTi alloy shows the shortest and most deflected trajectory, indicating the highest energy dissipation and strongest interaction with the lattice [
56,
58]. The Pd
1.5Ti alloy’s trajectory is similar to PdTi, showing high interaction and significant energy dissipation.
Regarding energy dissipation quantification, we used molecular dynamics (MD) simulations to track the energy loss of primary knock-on atoms (PKAs) as they interacted with the lattice. The dissipation was monitored by measuring the decrease in kinetic energy over time and its conversion into lattice vibrations and atomic displacements. To assess the trajectory deviations, key parameters included the PKA’s initial and final positions, the deflection angle, and the number of collisions with lattice atoms. We visualized the trajectory using tools such as OVITO to observe the PKA’s motion. The rate of energy dissipation was calculated by monitoring the PKA’s kinetic energy at each time step and summing the energy transferred to surrounding atoms. This allowed us to correlate the energy loss with the trajectory deviations and collision frequency.
Since point defects such as interstitial atoms and vacancies invariably form Frenkel defects, a detailed analysis of the temporal evolution in point defect numbers was conducted by statistically tracking the Frenkel pair count over time. For successful recombination, the standard was based on observing a reduction in interstitial and vacancy atoms from the data. Specifically, the Wigner–Seitz defect analysis in OVITO was used to track how displaced atoms rejoined their original lattice positions. When a displaced atom returned within a cutoff distance (√2 times the lattice constant) of its original position, we considered this a successful recombination. Regarding long-term migration effects, the driving forces for long-term migration are primarily atomic vibrations and the presence of local stress fields within the lattice, while temperature could also play a possible role. Although recombination can still occur during long-term migration, the likelihood decreases as defects become more widely dispersed and the potential for mutual interaction diminishes. In our simulations, we observed some degree of recombination during these extended timescales, but it was significantly less than during the initial collision stages.
As depicted in
Figure 6, the curves represent the Frenkel pair count as a function of time, averaged across 10 datasets. To enable a clear and unambiguous observation of the temporal evolution of the Frenkel pairs, error bars are omitted. Despite this, each calculation inherently exhibits minor fluctuations, which remain within 5% of the nominal value. A comprehensive analysis reveals that the trend in the Frenkel pair count closely mirrors the trends observed in irradiation simulation results for other alloys [
59]. This congruence likely arises from the irradiation-induced alterations in crystal structure and atomic interactions. Irradiation triggers processes such as atomic displacement, defect formation, and migration, which are ubiquitous across various alloy systems. Consequently, the observed trends in the Frenkel pair count from irradiation simulations may possess universal applicability to diverse alloy systems. Initially, the Frenkel pair count in the three metals reaches a zenith within an exceedingly brief period. The temporal evolution of the Frenkel pair count can be delineated into four distinct stages: During the primary knock-on stage (0–0.1 ps), the Frenkel pair count escalates rapidly, attaining the thermal spike stage (0.1–3 ps) for a remarkably short duration, where the Frenkel pair count peaks. Subsequently, the cascade collision transitions into the ballistic collision residual stage, wherein the Frenkel pairs further evolve and recombine. The duration of the ballistic collision residual stage varies substantially depending on the alloy. Finally, in the defect migration stage, the remaining Frenkel pairs from the preceding stage undergo further recombination and annihilation, resulting in a continued diminution in defect numbers. The termination time of the defect migration stage also varies significantly based on the alloy. The evolution of the Frenkel pair count in these metals traverses through the primary knock-on stage, thermal spike stage, ballistic collision residual stage, and defect migration stage. These stages encapsulate the processes of defect formation, accumulation, recombination, and migration at the atomic scale.
In
Figure 6a, corresponding to an initial energy of 20 keV, the red curve represents the PdTi alloy, the black curve represents the PdTi
1.5 alloy, and the blue curve represents the Pd
1.5Ti alloy. It is evident that the number of Frenkel pairs increases rapidly at the onset, reaching a peak and subsequently decreasing gradually over time. In
Figure 6b, where the initial energy is 30 keV, the red curve corresponds to the PdTi alloy, the black curve to the PdTi
1.5 alloy, and the blue curve to the Pd
1.5Ti alloy. The behavior is similar to the 20 keV case, with the number of Frenkel pairs initially rising sharply, peaking, and then diminishing over time. However, both the peak number of Frenkel pairs and the overall scale are notably higher in the 30 keV case compared to the 20 keV scenario.
In both panels, the evolution of Frenkel pairs indicates that the PdTi
1.5 alloy consistently exhibits the highest number of defects, followed by the Pd
1.5Ti alloy, with the PdTi alloy showing the lowest number of defects. Additionally, a noticeable shift in the peak position is observed, suggesting that the peak time varies with the alloy composition and initial energy, thereby underscoring the significant influence of both factors on the defect dynamics in these alloys [
59].
The defect recombination rate is a crucial metric for assessing irradiation resistance. It is defined as the percentage of interstitial atoms returning to lattice positions relative to the total number of defects. According to the Kinchin–Pease (K–P) theoretical model, the number of defects in the steady state can be calculated.
Figure 7a shows the recombination rate curves for pure Pd and three PdTi alloys after 10 ps of irradiation at 600 K. From the figure, it can be observed that at a PKA energy of 20 keV, the recombination rates of Pd and PdTi
1.5 are below 90%, while those of PdTi and Pd
1.5Ti exceed 90%. As the incident energy increases to 30 keV, the defect recombination rates of the four metals slightly decrease. When the incident energy is 20 keV, the recombination rates of Pd, PdTi
1.5, and PdTi increase sequentially, with PdTi and Pd
1.5Ti showing the highest recombination rates, which are almost identical. At an incident energy of 30 keV, the recombination rates of Pd and PdTi
1.5 are similar. The recombination rate of PdTi is higher than that of Pd and PdTi
1.5 but slightly lower than that of Pd
1.5Ti. This suggests that as the incident PKA energy increases to 30 keV, the Pd content in the alloys enhances their irradiation resistance, and this factor outweighs the advantage of the higher entropy in PdTi.
From
Figure 7b, it is evident that as the incident PKA energy increases, the destructive impact on the alloy structure intensifies, resulting in a higher proportion of defect atoms in the system. Regardless of whether the incident PKA energy is 20 keV or 30 keV, the proportion of defect atoms in the Pd, PdTi
1.5, and PdTi alloys decreases sequentially. This indicates that the increase in entropy positively contributes to the irradiation resistance of the materials. At 20 keV, the PdTi alloy exhibits the smallest proportion of defect atoms. When the incident PKA energy increases to 30 keV, the proportion of defect atoms in Pd, PdTi
1.5, PdTi, and Pd
1.5Ti alloys decreases with the increasing Pd content, with Pd
1.5Ti showing a lower proportion of defect atoms than PdTi. This suggests that at an incident PKA energy of 30 keV, increasing the Pd content in the alloy plays a more significant role in enhancing irradiation resistance.
During irradiation, defects migrate and coalesce to form stable clusters, including interstitial atom clusters and vacancy clusters. The size and quantity of these defect clusters are critical indicators of a material’s irradiation resistance. Larger defect clusters can induce local stress concentrations and lattice distortions, rendering the material more prone to fracture, crack propagation, and other failure mechanisms, thereby accelerating its degradation. Specifically, the aggregation of large vacancy clusters results in voids that occupy the crystal lattice, reducing material density and causing macroscopic swelling behavior [
60,
61].
In this study, the cluster analysis method in OVITO was utilized to assess the size of defect clusters by setting an appropriate cutoff distance. The cutoff distance was chosen as
a (where a represents the lattice constant), thus being set to 5.5 Å. This implies that during the cluster analysis, OVITO identifies particles within a distance of 5.5 Å as connected, thereby classifying them into clusters accordingly. The size of the defect clusters in this study is determined by the number of interstitial atoms and vacancies within each cluster. The aggregation of two or more interstitial atoms or vacancy defects is defined as a cluster [
62].
Figure 8 shows the defect cluster size distribution for Pd, PdTi
1.5, PdTi, and Pd
1.5Ti alloys at 600 K with incident PKA energies of (a) 20 keV and (b) 30 keV. At an incident energy of 20 keV, Pd and PdTi
1.5 alloys, in particular, exhibit a higher number of clusters across different size ranges, indicating significant defect aggregation. The cluster quantities for PdTi and Pd
1.5Ti are similar, suggesting comparable defect clustering behavior at this energy level. When the incident energy increases to 30 keV, Pd and PdTi
1.5 show an increase in both defect cluster size and quantity. Notably, PdTi has the smallest cluster sizes among all alloys. Although Pd
1.5Ti has a higher number of atoms not equal to 1 compared to PdTi at 30 keV, its overall cluster size is larger than that of PdTi, which is an interesting phenomenon. As the incident PKA energy increases from 20 keV to 30 keV, the overall number of clusters with sizes of 1, 2, greater than 2 but less than 500, and greater than 500 increases. After 10 ps of irradiation, neither PdTi nor Pd
1.5Ti shows clusters larger than 500 at 20 keV or 30 keV. As the PKA energy increases from 20 keV to 30 keV, PdTi forms smaller defect clusters, demonstrating the best irradiation resistance.
Figure 9 presents a comparison of the number of interstitial atoms (occupancy = 2) and vacancy atoms (occupancy = 0) in different cluster sizes for Pd, PdTi
1.5, PdTi, and Pd
1.5Ti alloys at 600 K with incident PKA energies of (a) 20 keV and (b) 30 keV. It is observed that the defect clusters in these alloys predominantly exist in the form of single defects, with only a small number of clusters forming with sizes of 2, 3–500, and greater than 500. The number of clusters with sizes of 2, 3–500, and greater than 500 increases with the incident energy. PdTi exhibits the least formation of larger clusters. Furthermore, interstitial atoms are more likely to aggregate and form clusters in the size range of 3–10, whereas vacancy defects are less likely to form clusters. Studies indicate that vacancies are less mobile than interstitials because the atoms around a vacancy in a crystal form a binding effect that restricts the movement of the vacancy. As the number of defects increases, their mobility decreases, making vacancy clusters more prone to being confined by surrounding atoms and thus forming smaller clusters. In contrast, the atoms around interstitial defects are more loosely arranged, allowing interstitials to move more easily. Therefore, individual vacancies are more likely to form smaller clusters.
Figure 10 describes the variation in the number of defect cluster atoms with PKA energy for (a) PdTi, (b) PdTi
1.5, and (c) Pd
1.5Ti alloys after 10 ps of irradiation. According to
Figure 10, as the PKA energy increases from 20 keV to 30 keV, the number of interstitial atoms and vacancies in the defects also increases. The interstitial atoms increase the fastest and constitute the main part of the defect clusters, which is consistent with the conclusions in
Figure 9. Therefore, we explored the elemental composition of interstitial atoms in these clusters. From the pie charts in
Figure 10, it is evident that as the PKA energy increases from 20 keV to 30 keV, the Ti atom content in the interstitial atoms of defect clusters in (a) PdTi and (c) Pd
1.5Ti alloys increases to some extent. During this process, the Ti atom content in the PdTi
1.5 alloy does not increase; however, from the pie chart in
Figure 10b, it can be observed that the Ti atom content in the PdTi
1.5 alloy is already as high as 57.4%. This further indicates that as the PKA energy increases, Ti atoms, compared to Pd atoms, can increase the number of interstitial atoms in defect clusters in PdTi alloys, making them an important factor in increasing the number of atoms.
Therefore, we found that when irradiating the PdTi alloy at PKA energies of 20 keV and below, the irradiation resistance of the alloy gradually enhances with the increase in entropy. As the PKA energy increases to 30 keV, the Pd component in the PdTi alloy demonstrates its stability, while the Ti atoms in the PdTi alloy are more likely to be irradiated into interstitial atoms.
3.3. The Impact of Temperature on the Irradiation Resistance of PdTi Alloys
Figure 11 illustrates the distribution of the point defects in PdTi at different temperatures (300 K, 600 K, 900 K, and 1200 K) with an incident PKA energy of 20 keV, both at the peak of the cascade collisions and after 10 ps of recombination. At 300 K, the depth and size of the point-defect distribution generated by cascade collisions are relatively small, with defects clustered near the PKA atom and no secondary cascade clusters observed. After 10 ps of recombination, the stable point-defect distribution significantly decreases in depth and size, leaving only a few atoms that did not return to their original positions. As the temperature increases to 600 K, the distribution of the point defects generated by cascade collisions shows little change compared to 300 K. However, after 10 ps of recombination, the number of stable point defect atoms significantly decreases, indicating an effective recombination process. At 900 K, the number of displaced atoms due to cascade collisions increases compared to 600 K, but after 10 ps of recombination, the number of atoms occupying non-regular lattice sites greatly reduces, with no large clusters observed. When the temperature rises to 1200 K, the depth and size of the point-defect distribution generated by cascade collisions are similar to those at 900 K. However, after 10 ps of recombination, despite a large number of atoms recombining, two relatively distinct clusters are still observed.
Figure 12 shows the number of Frenkel pairs as a function of cascade time in Pd and PdTi at different temperatures with a PKA energy of 20 keV. The main plot illustrates the evolution of Frenkel pairs over a period of 10 ps, with each curve representing a different temperature: 300 K, 600 K, 900 K, and 1200 K for PdTi, and 300 K and 600 K for Pd. The inset zooms in on the peak of Frenkel pairs within the initial stage of the cascade. The green and purple lines represent the evolution of Frenkel pairs in Pd at 300 K and 600 K, respectively. From the graph, it is evident that the cascade collision peak and the number of Frenkel pairs after 10 ps of recombination in Pd at 600 K are significantly higher than those in PdTi. This indicates that an increase in temperature has a significantly detrimental effect on the irradiation resistance of Pd. In contrast, PdTi shows lower numbers of Frenkel pairs both at the cascade collision peak and after 10 ps of recombination at 300 K, 600 K, and 900 K. However, when the temperature increases to 1200 K, there is a significant increase in the cascade collision peak and the number of Frenkel pairs after 10 ps of recombination in PdTi [
32].
After understanding the images of alloy irradiation at different temperatures, both at the peak of the cascade collisions and after 10 ps of recombination, we proceed to further calculate the defect recombination rate.
Figure 13 shows the defect recombination fraction curves for PdTi and Pd at different temperatures (300 K, 600 K, 900 K, and 1200 K) with an incident PKA energy of 20 keV. From the figure, it can be observed that as the temperature increases, the recombination rate for PdTi (a) initially remains high but starts to decrease slightly when the temperature reaches 900 K and continues to decline at 1200 K. In contrast, the recombination rate for Pd (b) shows a significant decline as the temperature rises from 300 K to 1200 K. This indicates that before reaching a certain temperature threshold, the temperature has little effect on the recombination rate of PdTi. However, beyond this threshold, the recombination rate decreases significantly. Compared to pure Pd, PdTi exhibits a significantly higher recombination rate, likely due to the higher entropy of the medium-entropy alloy PdTi compared to pure Pd.
Figure 14 shows the number of shift atoms in PdTi after irradiation at different temperatures (300 K, 600 K, 900 K, and 1200 K) with an incident PKA energy of 20 keV. These shift atoms refer to atoms occupying non-regular lattice sites. The graph distinguishes between interstitial atoms (black squares) and vacancy atoms (red squares) in the clusters. From the figure, it is evident that both the numbers of interstitial atoms and vacancy atoms increase with temperature. At 300 K, the numbers of interstitial and vacancy atoms are relatively low. As the temperature increases to 600 K, the numbers of both types of shift atoms increase slightly. At 900 K, the number of vacancy atoms increases significantly compared to interstitial atoms, indicating that higher temperatures favor the formation of vacancies. At 1200 K, there is a sharp increase in the numbers of both interstitial and vacancy atoms, with the increase in vacancies being particularly pronounced. Overall, the data suggest that the effect of temperature on PdTi’s resistance to irradiation damage is primarily due to the increased number of vacancy atoms. While PdTi maintains a relatively stable defect structure at temperatures up to 900 K, at 1200 K, the number of defects, especially vacancies, increases significantly, which could lead to a considerable weakening of PdTi’s irradiation resistance. The data indicate that PdTi may retain good irradiation resistance at temperatures up to 900 K.
Figure 15 illustrates the number of defect clusters in PdTi at various temperatures (300 K, 600 K, 900 K, and 1200 K) with an incident PKA energy of 20 keV, categorized by cluster size. From this figure, it is evident that an increase in temperature has no significant impact on the size of the clusters. At all temperatures, the defect clusters remain relatively small. Even at the highest temperature of 1200 K, there is no notable increase in cluster size, with the most abundant clusters being those of size 2, totaling 13 clusters. The distribution of cluster sizes remains fairly consistent across the different temperatures, indicating that temperature is not a primary factor affecting the size of defect clusters in PdTi. The formation and size of defect clusters in PdTi may be more significantly influenced by the increase in vacancy atoms resulting from the rise in temperature.
Figure 16 shows the proportion of Pd and Ti elements in PdTi after 10 ps of recombination at different temperatures (300 K, 600 K, 900 K, and 1200 K), where (a) shows the proportion of Pd and Ti in clusters composed of all atoms, (b) shows the proportion of Pd and Ti in clusters composed of interstitial atoms, and (c) shows the proportion of Pd and Ti in clusters composed of vacancy atoms. Observing
Figure 16a, it is evident that as the temperature increases from 300 K to 600 K and then to 900 K, the proportion of Ti in the clusters gradually rises. However, as the temperature increases from 900 K to 1200 K, the proportion of Pd becomes dominant. The overall trend in
Figure 13b, showing the proportion of Pd and Ti in clusters composed of interstitial atoms, is similar to that in
Figure 16a for clusters composed of all atoms. From
Figure 14, we conclude that the effect of temperature on PdTi’s resistance to irradiation damage is primarily due to the increased number of vacancy atoms. By observing
Figure 16c, it is clear that as the temperature rises, the proportion of Pd in the clusters composed of vacancy atoms consistently increases, indicating that higher temperatures may promote the formation of more Pd vacancies.