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Synthesis and Characterization of Nb, Mo-doped and Nb/Mo-codoped Monoclinic VO2 Nanoparticles and Their Thin Films by Hydrothermal/Post-Thermal Transformation and Wet-Coating Method

  • Received : 2019.01.14
  • Accepted : 2019.01.31
  • Published : 2019.04.20

Abstract

Nb, Mo-doped and Nb/Mo-codoped $VO_2(M)$ nanocrystallites with various doping levels were synthesized for the first time by a hydrothermal and post thermal transformation method. The reversible phase transition characteristics of those doped $VO_2(M)$ was comparatively investigated. Nb-doping of $VO_2(M)$ by this method resulted in a very efficient lowering of the transition temperature ($T_c$) with a rate of $-16.7^{\circ}C/at.%$ that is comparable to W-doping, while Mo-doping did not give a serious reduction of $T_c$ with only a rate of $-5.1^{\circ}C/at.%$. Nb/Mo-codoping gave a similar result to Nb-doping without a noticeable difference. The thin films of Nb-doped and Nb/Mo-codoped $VO_2(M)$ with a thickness of ca. 120 nm were prepared by a wet-coating of the nanoparticle-dispersed solutions. Those films showed a good thermochromic modulation of near infrared radiation with 30-35% for Nb-doped $VO_2(M)$ and 37-40% for Nb/Mo-codoped ones. Nb/Mo-codoped $VO_2(M)$ film showed slightly enhanced thermochromic performance compared with Nb-doped $VO_2(M)$ film.

Keywords

INTRODUCTION

Monoclinic VO2(M) has attracted extensive interests on its phase transition behavior since Morin showed the abrupt conductivity change from metallic to nonmetallic behavior with decreasing temperature in some metal oxides including VO2(M).1 The electrical transition from semiconductor to metal of VO2(M) is accompanied by the crystal phase transition from monoclinic to tetragonal rutile structure.2 This transition enables its optical property in infrared region to be changed depending on temperature and makes it useful for smart window applications as a thermochromic material.3 However, its transition temperature (Tc), that is about 68℃, is too high to be practical for a real life. Doping of VO2(M) with higher valent cations such as W6+, Mo6+, Nb5+ and Ta5+ than V4+ was known to lower Tc.4 The reduction of Tc by these cations were usually explained by the extra electrons introduced by the higher valent cations5 and the compressive strain introduced by larger ion size.6 But it is not clearly revealed so far. Among these cations W6+ was known to be the most effective dopant with a rate of -20 ~ -28 ℃ per atomic (at.) % vs V.4, W6+-doping could reduce Tc easily to a practical temperature but the transition sharpness also quickly decreased as the doping level increased and its thermochromic performance was reduced. Although there were so many studies of W-doped VO2(M),7 doping of Nb and Mo into VO2(M) has not been well investigated because the reduction of Twas known to be much less effective than W-doping. The early studies showed that both Nb- and Mo-dopings decreased Tc  at a rate of about -7~-10℃/ at.% that was less than a half of W-doped one.8

For the practical purpose to apply this thermochromic material to smart window, the preparation of its thin film is important as well as its transition property. Although there are some methods of fabricating VO2(M) thin film such as chemical vapor deposition (CVD), magnetron sputtering and sol-gel methods, the most cost-effective method of preparing thin films on any kind of substrate is wet-coating method without high-temperature thermal treatment using coating solution including well-dispersed functional materials. It is essential to prepare functional nanoparticles as smaller as possible for this coating method. Most of previously reported Nb or Mo doped VO2(M) films had been prepared by CVD9, magnetron sputtering10, and pulsed laser methods.11

In this study we report for the first time the preparation of Nb, Mo or Nb/Mo codoped VO2(M) nanoparticles by the thermal transformation of the doped VO2(B) that was first prepared by hydrothermal reaction and their thin films that were prepared by wet-coating method using these nanoparticles-dispersed solutions. Their phase transition characteristics were comparatively investigated.

EXPERIMENTAL

Materials and Preparation

Vanadium (V) oxide (V2O5, 99.2%), niobium (V) oxalate hydrate (Nb(HC2O4)5·xH2O), ammonium molybdate (para) tetrahydrate ((NH4)6Mo7O24·4H2O, 99%) were purchased from Alfa Aesar. Anhydrous oxalic acid (H2C2O4, 95%) were obtained from Kanto Chemical. The hydration number of niobium (V) oxalate was determined as 2.4 by thermal gravimetric analysis. Polyethylene terephthalate (PET) film with thickness of 40 μm and 0.7 % haze was purchased from Toray Chemical. All chemicals were used without further purification. Water was purified to 18.1 MΩ with Barnstead Nanopure water purification system. The syntheses of undoped and doped VO2(B) and VO2(M) were done by following the procedure previously described in detail.12 Briefly, for the synthesis of VO2(B), H2C2O4 and V2O5 with 2: 1 molar ratio were first reacted in water at about 60 ℃ for 24 h. The reacted solution mixture was transferred to an autoclave and kept at 200 ℃ for 24 hr. For doping, the appropriate amounts of niobium oxalate and ammonium molybdate were directly added to the reaction mixture and stirred for 2 h just before hydrothermal reaction. VO2(B), whether it was doped or not, was transformed to VO2(M) by being heated under argon gas flow at 600 ℃ for 2 h. VO2(M) thin film on PET substrate was prepared by bar- coating with VO2(M)-dispersed coating solution. The coating solutions were prepared by ball-milling the suspension of the sample powders in the mixed solution of ethanol and water (4:1 v/v) with zirconia bead for 5 days.

Characterization

The X-ray diffraction (XRD) patterns were obtained from Phillips X'Pert-MPD diffractometer using Cu Kα radiation source at a scan rate of 0.02o s-1 in the 2θ range of 5-80o. The instrumental line broadening of XRD was calibrated using Si 630c standard reference material by controlling slit width. Field-emission scanning electron microscopic (FE-SEM) and transmission electron microscopic images (FE-TEM) were taken with Jeol JEM-6700F, Jeol JEM- 2100F electron microscopes, respectively. Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) were carried out by Perkin-Elmer Pyris 1 with a heating rate of 5 ℃/min in nitrogen atmosphere. Temperature-dependent visible and near-infrared (NIR) spectra were measured by using JASCO V-670 UV-VIS-NIR spectro-photometer equipped with a Peltier thermostatted sample holder. Bar-coating for thin film was performed with BMS Tech VT-300D auto film applicator. The amounts of Nb and Mo in doped VO2(M) were analyzed with X-ray fluorescence spectrometer (Shimadzu XRF-1700). The film thickness was measured with Tencor AlphaStep 500 profilometer.

RESULTS AND DISCUSSION

The doped and codoped VO2(M)s with Nb and Mo were prepared by the thermal transformation of doped VO2(B) that was synthesized by hydrothermal reaction as previously described by us.12 Nb-doped, Mo-doped and Nb/ Mo-codoped VO2 will be denoted as Nb-VO2, Mo-VO2 and Nb/Mo-VO2 hereinafter. Fig. 1 and 2 show XRD patterns of Nb- and Mo-VO2, respectively with 0-4.0 at.% fed amounts of Nb and Mo dopants. Regardless of the fed amounts of dopants, all XRD patterns show the well-characterized peaks of VO2(B)13(a) and VO2(M).13(b) After the transformation to M phase, the small impurity level of B phase remained for Nb-doped VO2(M) as indicated with an arrow in Fig. 1(b) while it did not for the undoped one. This impurity B phase also appeared for W-doped VO2(M) that was prepared by this method.12 However, it is far less for Mo-VO2 as shown in Fig. 2(b). As the amounts of Nb dopant increase, the major peak intensities slightly decrease and the peaks become broader for both B and M phases of Nb-VO2. This means that the crystallites of both phases become systematically smaller with increased doping. For the case of Mo-VO2, however, M phase crystallite does not decrease while B phase does. Using the most intense peaks, (110) and (011) of B and M phases, respectively, the crystallite sizes are estimated by Scherrer equation14 and listed in Table 1. The actual doped level was analyzed semi-quantitatively with XRF and are also listed in Table 1. The actual doped amounts of both Nb and Mo decreased from about 80% to 60% of the fed amounts as the fed amounts increased from 1.0 at.% to 4.0 at.% vs vanadium atom. For comparison, our previous study showed that tungsten was doped in almost 100% if the fed amount was less than 1.5 at.% in the same synthetic method.12 While the crystallite sizes of both Nb- and Mo-VO2(B) are very similarly decreased with the increased doping level, those of Nb- and Mo-VO2(M) are quite different. The crystallinity of Mo-VO2(M) is barely affected by the dopants while the size of Nb-VO2(M) slightly decreases with the increased doping level. Anyhow, the crystallite sizes of these doped VO2(M) are in the range of ca. 30-57 nm for these doping levels. On the other hand, W-VO2(M) with 1.5 at.% doping was less than 30 nm.12

Figure 1. XRD patterns of (a) B and (b) M phases of Nb-VO2 samples with various fed amounts of Nb (The arrow indicates (110) peak of B phase).

Table 1. The estimated crystallite sizes of B and M phases of Nb- and Mo-VO2 with various doping levels

Figure 2. XRD patterns of (a) B and (b) M phases of Mo-VO2 samples with various fed amounts of Mo.​​​​​​​

The morphologies of the doped VO2(B) and VO2(M) are shown in Fig. 3 and 4, respectively as FE-SEM images. The B phase morphologies that were prepared by hydrothermal reaction are all similar and thin rod-like with aspect ratio of ca. 10-20 regardless of the type and amount of dopant. Both the B and M phases of VO2 that were prepared by direct hydrothermal reaction were reported to have usually rod-like or belt-type morphologies whether they were doped or not.15 When these VO2(B) were transformed to VO2(M) by thermal treatment, the morphologies were slightly changed to partly spherical shapes with fused forms each other. The fusion seemed to be more prominent for Mo-VO2(M) than Nb-VO2(M). The amounts of dopants barely affected the sizes of the fused forms.

Figure 3. FE-SEM images of Nb- and Mo-VO2(B) with two different fed amounts of dopants (Bar scale: 1 μm, Magnification: ×10,000).

Figure 4. FE-SEM images of Nb- and Mo-VO2(M) with two different fed amounts of dopants (Bar scale: 1 μm, Magnification: ×10,000).

The phase transition properties of Nb-VO2(M) and Mo- VO2(M) were characterized by DSC. Fig. 5 shows DSC data demonstrating the doping effect on Tc  and the hysteresis of the phase transition. The effect of two dopants on the transition characteristics is dramatically different. While Nb-VO2(M) shows large Tc shift depending on doping level, Mo-VO2(M) shows a small dependence on the dopant. And while the transition sharpness of Nb-VO2(M) decreases with increasing doping level, that of Mo-VO2(M) is not reduced at all. All Nb-VO2(M) samples show a small minor transition at the temperature higher than the major Tc. These minor transitions may be ascribed to the inhomogeneity of the spatial distribution of the dopant. Tc  and the temperature hysteresis (ΔTc) of these doped VO2(M) are listed in Table 2. In order to depict the doping level dependence of Tc, the plots of Tc vs doping level are shown in Fig. 6. For both the dopants, the dependence is almost linear with quite different slopes. The reducing rates of Tc from the slopes are -16.7 and -5.1 ℃/at.% for Nb and Mo, respectively. According to the previous studies of thin films of Nb-doped VO2(M) that were directly prepared by magnetron sputtering,9(c) CVD10(b) and laser deposition11 methods, the reducing rates were -7 ~ -8.5 ℃/at.%. Therefore, the reducing rate of our powder Nb-VO2(M) is about twice higher than that of the thin films and comparable to that of well-known W-doped VO2(M). Recently, Yuan et al. reported that Nb-VO2(M) that was prepared by the high temperature solid state synthesis with VO2(M) and Nb2O5 showed the reducing rate of -13 ℃/at.% that is slightly lower than ours.16 In the case of W-doping, there is no report, as far as we know, showing considerable difference between thin film and powder samples. However, Nb-doping seems to give a quite different result between thin film and powder samples. The reason is not clear at this point. On the other hand, our Mo- doped sample gives a slightly different rate than those of the thin films that were reported as -3 ℃/at.% from CVD10(b),17 and -7 ℃/at.% from sol-gel method.18 The powder sample of Mo-VO2(M) that were prepared by direct hydrothermal reaction was reported to give the reducing rate of -7.86 ℃/ at.%.19 Therefore, it seems that Mo-doping does not cause a serious difference between thin film and powder sample, unlike Nb-doping.

Figure 5. DSC curves of (a) Nb- and (b) Mo-VO2(M) with various fed amounts of dopants (The baseline was subtracted.).

Table 2. The estimated transition temperatures and hysteresis of Nb- and Mo-VO2(M) from DSC data according to doping level

Figure 6. Doping level dependence of transition temperatures of Nb- and Mo-VO2(M).

In our synthetic method of doped VO2(M), Nb-doping gives a pretty efficient lowered Tc close to W-doping and the hysteresis and the transition sharpness seems to be even better than W-doping.20 Meanwhile, Mo-doping does not give an efficient lowering of Tc but the transition sharpness becomes somehow better than the undoped one as shown in Fig. 5(b). The lowering of Tc by doping always requires the sacrifice of the transition sharpness as shown with W and Nb-doping. Our previous study showed that W/Mg- codoping helped the enhancement of transition sharpness while keeping the lowered Tc12  Therefore, we tried the codoping of Nb and Mo into VO2(M) with expecting a synergistic effect. The codoping was performed with the varied amounts of 1.0-3.0 at.% for Nb and the fixed amount of 1.0 at.% for Mo. The XRD data and the morphologies of Nb/Mo-codoped VO2 are very similar to those of Nb-doped one.21  The actual codoped levels of Nb and MO are also similar to those of separately doped Nb and Mo. The estimated crystallite sizes and the actual doped levels are listed in Table 3. While B phase sizes of the codoped VO2 are slightly smaller than those of Nb-doped ones, M phase sizes were slightly larger. Fig. 7 shows DSC curves of Nb/Mo-VO2(M) with various doping levels. The phase transition characteristics of Nb/Mo-VO2(M) depending on doping level also shows very similar tendency as that of Nb-VO2(M). The noticeable difference is that the second minor transition at higher temperature becomes slightly more recognizable at low doping level of Nb. The transition temperature and the hysteresis are listed in Table 3. Tc of Nb/Mo-VO2(M) is slightly lower than that of Nb-VO2(M) at the same feeding level of Nb. However, there is no considerable enhancement of transition sharpness.

Figure 7. DSC curves of Nb/Mo-VO2(M) with various fed amounts of dopants (The baseline was subtracted.).​​​​​​​

Table 3. The estimated crystallite sizes, transition temperatures and hysteresis of Nb/Mo-VO2(M) from XRD and DSC data according to doping levels

The thin films of Nb-doped and Nb/Mo-codoped VO2(M) was prepared on PET substrate by bar-coating method using the particle-dispersed solutions. The coating solutions were prepared by ball-milling of the sample powders in aqueous ethanol solution. In our previous study12 we had used a block copolymer as dispersing agent and binder in organic mixed solvent. But no dispersing agent was added in this coating solution. The well-dispersed solution gave a fairly transparent and very robust film on PET substrate. In order to check the particle sizes of the samples in the coating solution, TEM images of the ball-milled samples were taken and are shown in Fig. 8. The images of all samples with different doping levels are not considerably different as shown in the chosen two samples of Nb- and Nb/Mg-VO2(M). The particle sizes are distributed in the range of 20-80 nm. The average sizes are roughly similar to the estimated crystallite sizes that were about 40-50 nm. Therefore the fused particles after the thermal transformation were broken down to crystallite nanoparticles by the long-term ball-milling.

Figure 8. FE-TEM images of Nb- and Nb/Mo-VO2(M) after being ball-milled in aqueous ethanol solution (Bar scale: 100 nm, Magnification: ×25,000).

The thin films of Nb- and Nb/Mo-VO2(M) on PET also have all the similar morphologies regardless of doping levels as shown in FE-SEM images of Fig. 9. The films are all smooth without any crack and nanoporous as shown in the magnified images. The film thicknesses were controlled to give ca. 120 nm by the concentration of coating solution and Mayer rod number. The visible and near infrared (N-IR) transmission spectra of these thin films were measured at the wavelengths between 350-2,500 nm and temperatures between 20-90 ℃. Fig. 10 shows the transmission spectra of Nb-VO2(M) and Nb/Mo-VO2(M) at the selected doping levels for comparison. The N-IR transmittances of all the films decrease as the temperature increases and thus the thermochromic characteristics is clearly seen. The transmittance-vs-temperature curves are plotted for all the samples of Nb- and Nb/Mo-VO2(M) and shown in Fig. 11. The transition temperatures and the hysteresis that were estimated from these optical transmittance changes are listed in Table 4. The transition temperatures for all these doped VO2(M) films that were measured from transmittance data are about 15-25 ℃ higher and the hysteresis are wider than those of the corresponding powder samples that were measured from DSC data discussed above. This difference was also observed in our previous study for W- and W/Mg-VO2(M).12 We assumed that the difference came from the grain size difference that was caused by ball-milling. The reduced grain size after ball-milling gave the larger surface area and the increased surface property might have more effect, giving such a result. As the inhomogeneity of the dopant distribution was presumed from the DSC data that showed the second minor transition following the major one, the doping level of the surface may be higher than the interior and the deteriorated surface property by ball-milling may have affected on the transitions of the film samples.

Figure 9. FE-SEM images of the thin films of Nb- and Nb/MoVO2(M) (Bar scale:1 μm, 100 nm, Magnification: x20,000, ×80,000).​​​​​​​

Figure 10. Temperature dependence of transmission spectra of (a) Nb-VO2(M) and (b) Nb/Mo-VO2(M) films on PET substrate. (The temperature varied from 20 to 90 ℃ in an increment of 10 ℃).

Table 4. Optical transition properties of Nb- and Nb/Mo-VO2(M) films on PET substrate.

*The actual doped levels of Nb and Mo are listed in Table 2 and 3.

**ΔT denotes the transmittance difference between the values at 20 and 90℃ measured at 2,000 nm.

Figure 11. Temperature dependence of the transmittance at 2,000 nm for (a) Nb-VO2(M) and (b) Nb/Mo-VO2(M) films on PET substrate.

Nevertheless, Nb- and Nb/Mo-VO2(M) films are comparable to W-VO2(M) film although the doping level should be slightly higher. The N-IR transmittance changes at 2,000 nm by the phase transition, which are estimated from the difference between 20 and 90 ℃ data, are 30-35 % and 37- 40% for Nb-VO2(M) and Nb/Mo-VO2(M), respectively. These values are lower than that of the undoped VO2(M) film but higher than that of W-VO2(M) with the doping level of 1.5 at.%, which were reported by 47 and 29%, respectively in our previous study.12 Therefore, Nb-VO2(M) film that was prepared by our method is advantageous to W-VO2(M) film in terms of thermochromic effect, even though Tc is slightly higher at the same doping level. The codoping of a small amount of Mo with Nb into VO2(M) definitely helps the lowering of Tc and the increasing of the optical switching efficiency as shown in Table 4.

CONCLUSION

Nb-, Mo-doped and Nb/Mo-codoped VO2(M) nano-crystallites were, for the first time, synthesized by a hydrothermal and post thermal transformation method. Nb-VO2(M) showed the lowered Tc with a reducing rate of -16.7 ℃/ at.% that is comparable to W-VO2(M), while Mo-VO2(M) did not show the serious reduction of Tc with only the rate of -5.1 ℃/at.%. However, the doping of Mo did not cause the deterioration of transition sharpness that was observed in W- and Nb-doping. The transition property of Nb/Mo- VO2(M) is very similar to Nb-VO2(M) with a slightly lower Tc at the same doping level of Nb. The thin films of Nb- and Nb/Mo-VO2(M) that were prepared by a bar-coating of the particle-dispersed solutions shows a relatively good thermochromic modulation of N-IR with 30-35% and 37- 40%, respectively, although Tc became higher than those of the corresponding powder samples. Nb/Mo-VO2(M) film shows that the codoping have a synergistic effect on both the lowering of Tand the N-IR modulation efficiency.

Acknowledgments

This work was supported by the research fund of Pukyong National University (Year 2017-2018).

References

  1. Morin, F. J. Phys. Rev. Lett. 1959, 3, 34. https://doi.org/10.1103/PhysRevLett.3.34
  2. (a) Anderson, G. Acta Chem. Scand. 1954, 8, 1599. https://doi.org/10.3891/acta.chem.scand.08-1599
  3. (b) Westman, S. Acta Chem. Scand. 1961, 15, 217. https://doi.org/10.3891/acta.chem.scand.15-0217
  4. (a) Kamalisarvestani, M; Saidur, R.; Mekhilef, S.; Javadi, F. S. Ren. Sust. Ener. Rev. 2013, 26, 353. https://doi.org/10.1016/j.rser.2013.05.038
  5. (b) Gao, Y.; Luo, H.; Zhang, Z.; Kang, L.; Chen, Z.; Du, J.; Kanehira, M.; Cao, C. Nano Ener. 2012, 1, 221. https://doi.org/10.1016/j.nanoen.2011.12.002
  6. (c) Granqvist, C. G.; Lansaker, P. C.; Mlyuka, N. R.; Niklasson, G. A.; Avendano, E. Sol. Energy Mater. Sol. Cells 2009, 93, 2032. https://doi.org/10.1016/j.solmat.2009.02.026
  7. Goodenough, J. B. J. Solid State Chem. 1971, 3, 490. https://doi.org/10.1016/0022-4596(71)90091-0
  8. (a) Tang, C.; Georgopoulos, P.; Fine, M. E.; Cohen, J. B. Phys. Rev. B 1985, 31, 1000. https://doi.org/10.1103/PhysRevB.31.1000
  9. (b) Zhang, J.; He, H.; Xie, Y.; Pan, B. J. Chem. Phys. 2013, 138, 114705. https://doi.org/10.1063/1.4795431
  10. (a) Cao, J.; Ertekin, E.; Srinivasan, V.; Fan, W.; Huang, S.; Zheng, H.; Yim, J. W. L.; Khanal, D. R.; Ogletree, D. F.; Grossmanan, J. C.; Wu, J. Nat. Nanotechnol. 2009, 4, 732. https://doi.org/10.1038/nnano.2009.266
  11. (b) Zhang, J.; He, H.; Xie, Y.; Pan, B. Phys. Chem. Chem. Phys. 2013, 15, 4687. https://doi.org/10.1039/c3cp44476g
  12. (a) Horlin, T.; Nikelwski, T.; Nygren, M. Mat. Res. Bull. 1972, 7, 1515. https://doi.org/10.1016/0025-5408(72)90189-4
  13. (b) Tang, C; Georgopoulos, P.; Fine, M. E. Cohen, J. B. Phys. Rev. B 1985, 15, 31. https://doi.org/10.1103/PhysRevB.15.31
  14. (c) Sobhan, M. A.; Kivaisi, R. T.; Stjerna, B.; Granqvist, C. G. Sol. Energy Mater. Sol. Cells 1996, 44, 451. https://doi.org/10.1016/S0927-0248(95)00051-8
  15. (d) Li, G.; Chao, K.; Peng, H.; Chen, K.; Zhang, Z. Inorg. Chem. 2007, 46, 5787. https://doi.org/10.1021/ic070339n
  16. (a) Savborg, O.; Nygren, M. Phys. Status Solidi A 1977, 43, 645. https://doi.org/10.1002/pssa.2210430236
  17. (b) Kleinschmidt, P. Phys. Lett. 1974, 47A, 205. https://doi.org/10.1016/0375-9601(74)90009-7
  18. (c) Febritchnyi, P. B.; Bayard, M.; Pouchard, M.; Hagenmuller, P. Solid State Commun. 1974, 14, 603. https://doi.org/10.1016/0038-1098(74)91021-7
  19. (a) Greenberg, C. B. Thin Solid Films 1983, 110, 73. https://doi.org/10.1016/0040-6090(83)90175-X
  20. (b) Piccirillo, C.; Binions, R.; Parkin, I. P. Eur. J. Inorg. Chem. 2007, 4050.
  21. (c) Manning, T. D.; Parkin, I. P.; Blackman, C.; Qureshi, U. J. Mater. Chem. 2005, 15, 4560. https://doi.org/10.1039/b510552h
  22. (a) Batista, C.; Carneiro, J.; Ribeiro, R.; Teixeira, V. J. Nanosci. Nanotech. 2011, 11, 9042. https://doi.org/10.1166/jnn.2011.3486
  23. (b) Batista, C.; Ribeiro, R.; Teixeira, V. Nanoscale Res. Lett. 2011, 6, 301. https://doi.org/10.1186/1556-276X-6-301
  24. Nishikawa, M.; Nakajima, T.; Kumagai, T.; Okutani, T.; Tsuchiya, T. J. Cerm. Soc. Japan 2011, 119, 577. https://doi.org/10.2109/jcersj2.119.577
  25. Park, H.; Kim, J.; Jung, Y. H.; Kim, Y. I. J. Korean Chem. Soc. 2017, 61, 57. https://doi.org/10.5012/jkcs.2017.61.2.57
  26. (a) JCPDS 81-2392.
  27. (b) JCPDS 43-1051.
  28. Patterson, A. Phys. Rev. 1939, 56, 978. https://doi.org/10.1103/PhysRev.56.978
  29. (a) Liu, X.; Xie, G.; Huang, C.; Xu, Q.; Zhang, Y.; Luo, Y. Mater. Lett. 2008, 62, 1878. https://doi.org/10.1016/j.matlet.2007.10.022
  30. (b) Liu, J.; Li, Q.; Wang, T.; Yu, D.; Li, Y. Angew. Chem. Int. Ed. 2004, 43, 5048. https://doi.org/10.1002/anie.200460104
  31. (c)Zhang, Y.; Zhang, J.; Zhang, X.; Deng, Y.; Zhong, Y.; Huang, C.; Liu, X.; Mo, S. Ceram. Int. 2013, 39, 8363. https://doi.org/10.1016/j.ceramint.2013.04.016
  32. Zhang, R.; Yin, C.; Fu, Q.; Li, C.; Qian, G.; Chen, X.; Lu, C.; Yuan, S.; Zhao, X.; Tao, H. Cerm. Int. 2018, 44, 2809. https://doi.org/10.1016/j.ceramint.2017.11.024
  33. Bastista, C; Teixeira, V.; Ribeiro, R. M. J. Nanosci. Nanotechnol. 2010, 10, 1393. https://doi.org/10.1166/jnn.2010.1873
  34. Hanlon, T. J.; Coath, J. A. Richardson, M. A. Thin Solid Films 2003, 436, 269. https://doi.org/10.1016/S0040-6090(03)00602-3
  35. Li, D.; Li, M.; Pan, J.; Luo, Y.; Wu, H.; Zhang, Y.; Li, G. App. Mater. Interfaces 2014, 6, 6555. https://doi.org/10.1021/am500135d