Thermal Conductivities and Thermal Expansion Coefficients of (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ Ceramics

The XRD patterns of all the products in (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ were recorded in Fig. 1 and analyzed. Detailed analysis indicates that all XRD patterns match well with the standard cubic defect fluorite phase of CeO₂. The diffraction peaks of (Sm_0.5Gd_0.5)₂(Ce_0.7Zr_0.3)₂O₇ located at 28.33°, 32.85°, 47.28°, and 56.21° can be well indexed to the (111), (200), (220), and (311) planes of a cubic fluorite structure, respectively (Ref 27). In XRD patterns of other oxides, the defect fluorite structure can be identified by the scarce of super-lattice peaks at 2θ values between 32.85° and 47.28°. These two peaks could help us to distinguish the fluorite and pyrochlore structures (Ref 28). Furthermore, no peaks corresponding to the individual oxides are observed. This disparate feature can be attributed to the formation of (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics.

In the A₂B₂O₇ system, the crystal structure is mainly determined by the ionic radius ratio \( r(A^{3 + } )/r(B^{3 + } ) \) of A and B cations. The stable pyrochlore structure is limited to the range of \( 1.46 \le r(A^{3 + } )/r(B^{3 + } ) \le 1.78 \), and the fluorite oxide will form if the \( r(A^{3 + } )/r(B^{3 + } ) \) is lower than 1.40 (Ref 29). For the complex rare-earth cerium oxides, the ionic radius can be estimated from the ionic radius of the component ions and the chemical composition using the following equation.where 0.5, 1 − x, and x are the composition of each atom. The ionic radii of Sm³⁺ and Gd³⁺ are 1.079 and 1.053 Å, while the Zr⁴⁺ and Ce⁴⁺ are 0.72 and 0.97 Å, respectively. The values of \( {{r(A_{\text{av}}^{3 + } )} \mathord{\left/ {\vphantom {{r(A_{\text{av}}^{3 + } )} {r(B_{\text{av}}^{4 + } )}}} \right. \kern-0pt} {r(B_{\text{av}}^{4 + } )}} \) for (Sm_0.5Gd_0.5)₂ (Ce_1−x Zr _x )₂O₇ oxides can be calculated by the Eq 3 with above mentioned ionic radiuses, and the values are equal to 1.11, 1.13, 1.156, and 1.189 with x increasing from zero to 0.3. The ionic ratios of (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ are smaller than 1.40 due to the co-doping in the Sm and Ce sites, which reveals that the co-doping in Sm₂Ce₂O₇ cannot change the crystal structure.

The typical microstructure of (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics is shown in Fig. 2. The average grain size of (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics is several micrometers. The interfaces between grains are very clean, the gap is very small, and no other inter-phases and unreacted oxides existed in boundaries between grains. The chemical compositions and relative density of the synthesized (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics are listed in Table 1. As can be seen from Table 1, the mole ratios of different elements in (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics are very close to their stoichiometries, and each specimen has a high relative density due to the high-temperature sintering.

The dilatometric measurement results of (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics with calibration are plotted in Fig. 3. The typical linear expansions can be observed for (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics in the temperature range of 20-1000 °C. Clearly, there is no phase transformation for (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics in the temperature range. The technical thermal expansion coefficient is defined aswhere L ₀ is the length of the specimen at T ₀ (20 °C), ΔL ₀ is the change in length at T ₀, and ΔL _k is the corresponding length change at temperature T _k.

Their calculated technical thermal expansion coefficients against temperature are plotted in Fig. 4, together with the data of YSZ. Fig 4 shows that their thermal expansion coefficients increase smoothly with temperature up to 1000 °C, which is attributed to the increasing atomic spacing at elevated temperatures. As also can be seen in Fig. 4, the thermal expansion coefficient decreases gradually with increasing x from 0 to 0.3 at identical temperature levels. It is well known that the thermal expansion coefficient is inverse the crystal energy (U). The crystal (U) of an ionic compound can be expressed as (Ref 30).where N ₀, A, z, r ₀, e, and n represent Avogadro^’s number, the Madelung constant, the ionic charge, the inter-ionic distance, the charge of an electron, and Born exponent, respectively. From the lattice parameters listed in Table 1, it can be known that the substitution of Zr⁴⁺ for Ce⁴⁺ results in a slight contraction in the unit cell, indicating a decrease in the average inter-ionic distance, \( r_{0} \). This would lead to an increase in the crystal energy of the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics, which represents the decrease of thermal expansion coefficient. Alternatively, there are some structure defects, such as substitutional or interstitial cations and other imperfections in the lattice or varying properties in thermal expansion along with different orientations that have significant effect on the overall thermal expansion coefficient of A₂B₂O₇ oxides (Ref 31, 32). In the fluorite-type A₂Ce₂O₇ system, oxygen vacancies are randomly distributed in disordered fluorite structure; therefore, it facilitates formation of the ionic vacancy clustering, which represents to some extent the decrease in thermal expansion. The structure disorder degree of fluorite-type A₂Ce₂O₇ is inverse to value of \( {{r(A_{\text{av}}^{3 + } )} \mathord{\left/ {\vphantom {{r(A_{\text{av}}^{3 + } )} {r(B_{\text{av}}^{4 + } )}}} \right. \kern-0pt} {r(B_{\text{av}}^{4 + } )}} \) (Ref 29), and the increasing value of \( {{r(A_{\text{av}}^{3 + } )} \mathord{\left/ {\vphantom {{r(A_{\text{av}}^{3 + } )} {r(B_{\text{av}}^{4 + } )}}} \right. \kern-0pt} {r(B_{\text{av}}^{4 + } )}} \) in (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics represents the increase of thermal expansion coefficient. Hence, the decrease of thermal expansion coefficients with increasing ZrO₂ content in (Sm_0.5Gd_0.5) ₂(Ce_1−x Zr _x )₂O₇ ceramics reveals that the influence of crystal energy is greater than oxygen vacancy (Ref 29, 33). These thermal expansion coefficients are obviously higher than 7 wt.% yttria-stabilized zirconia [10.7 × 10⁻⁶/K at 1000 °C (Ref 10)] and are good enough to be used as thermal barrier coating materials in the industry condition.

The specific heat capacities of the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics at different temperatures were calculated according to the Neumann-Kopp rule based on the reference specific heat values of Sm₂O₃, Gd₂O₃, CeO₂ and ZrO₂. As can be seen in Fig. 5, the specific heat capacity of the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics increases with increasing temperature from room temperature to 1000 °C, and the calculated specific heat capacity of the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics slightly increases from x = 0 to 0.3 at identical temperature levels.

Fig 6 shows the composition-dependent thermal diffusivities of the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics measured by laser flash method. The values of thermal diffusivity are the arithmetic mean of three measurements. Since the error derived from the mean standard deviation of the three measurements for each specimen is <1.5%, the error bars in Fig. 6 are omitted for all thermal diffusivity date because they are smaller than symbols. As can be seen in Fig. 6, the thermal diffusivity of the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics exhibits inverse temperature dependence, which suggests a dominant phonon conduction behavior in most polycrystalline materials (Ref 32, 33). Furthermore, the thermal diffusivity remarkably decreases with increasing Zr⁴⁺ fraction, and (Sm_0.5Gd_0.5)₂ (Ce_0.7Zr_0.3)₂O₇ exhibits the lowest thermal diffusivity among all the ceramics investigated.

The thermal conductivities were calculated using Eq 1 and calibrated with Eq 2 to represent fully dense samples, as plotted in Fig. 7. The error bars are omitted because they are smaller than the symbols. The thermal conductivity of the synthesized samples also decreases with increasing ZrO₂ content. It decreases from 1.69 W/m K for Sm₂Ce₂O₇ to 1.22 W/m K for (Sm_0.5Gd_0.5)₂(Ce_0.7Zr_0.3)₂O₇ at 1000°C. The composition with x = 0.3 exhibits the lowest at all temperatures, and the thermal conductivities of (Sm_0.5Gd_0.5)₂ (Ce_1−x Zr _x )₂O₇ ceramics are obviously lower than those of fully dense 7 wt.%YSZ [3.0 at room temperature to 2.3 W/m K at 700 °C reported by Wu et al (Ref 31)]. In electronic insulator crystalline solids, heat is transferred by lattice vibrations. The quanta of lattice vibrations are defined as phonons, and the thermal conductivity is proportional to the phonon mean free path \( l(\upomega ,t) \), which can be approximately described as reported in (Ref 33).where \( l_{\text{i}} (\upomega ,t) \), \( l_{\text{p}} (\upomega ,t) \), \( l_{\text{v}} (\upomega ,t), \) and \( l_{\text{gb}} \) are the phonon mean free path due to interstitials scattering, point defect scattering, vacancies scattering, and grain boundary scattering, respectively. Since the phonon mean free path is several orders of magnitude smaller than the grain size for the (Sm_0.5Gd_0.5)₂(Ce_1−x Zr _x )₂O₇ ceramics, the grain boundary scattering can be omitted (Ref 34). The small phonon mean free path contributes to strong phonon scattering in the crystal cell. First, the special and complex crystal structure of fluorite-type (Sm_0.5Gd_0.5)₂ (Ce_1−x Zr _x )₂O₇ ceramics can reduce the phonon mean free path. The second factor is the intrinsic oxygen vacancies existed in the crystal lattice. The (Sm_0.5Gd_0.5)₂ (Ce_1−x Zr _x )₂O₇ ceramics could be regarded as the solid solution of Zr⁴⁺ taking the site of Ce⁴⁺ in (Sm_0.5Gd_0.5)₂Ce₂O₇ ceramics. Thus, the last factor is the substitutional atoms existing in the lattice of (Sm_0.5Gd_0.5)₂Ce₂O₇, which can also reduce the mean free path of phonon. Atomic substitution causes lattice distortion, increases phonon scattering, and decreases phonon mean free path, according to Eq 7 (Ref 35). On the other hand, the phonon mean free path is proportional to the square of atomic weight difference between the solute and host cations, according to Eq 8 (Ref 35): where a ³ is the volume per atom, \( v \) the transverse wave speed, \( \upomega \) the phonon frequency, \( c \) the concentration per atom, \( J \) the constant, \( \upgamma \) the Grüneisen parameter, \( M \) and \( R \) the average mass and ionic radius of the host atom, respectively, and \( \Delta M \) and \( \Delta R \) are the differences of masses and ionic radius between the substituted and substituting atoms, respectively. Because the atomic weights of Zr and Ce are 91.22 and 140.1, respectively. The effective ionic radii of Zr⁴⁺ and Ce⁴⁺ are 0.72 and 0.97 Å, and the effective phonon scattering of the substitutional atoms contributes to the lower thermal conductivity. Thus, thermal conductivity of (Sm_0.5Gd_0.5)₂ (Ce_1−x Zr _x )₂O₇ ceramics decreases with increasing ZrO₂ content at identical temperature levels. The low thermal conductivity indicates that the (Sm_0.5Gd_0.5)₂ (Ce_1−x Zr _x )₂O₇ ceramics can be explored as potential candidates for thermal barrier coating applications.