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Journal articles on the topic 'CALCIUM COBALTITE'

Author: Grafiati
Published: 27 June 2021
Last updated: 20 July 2024

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1

Yu, Jincheng, and Robert Freer. "Calcium cobaltite, a promising oxide for energy harvesting: effective strategies toward enhanced thermoelectric performance." Journal of Physics: Energy 4, no. 2 (2022): 022001. http://dx.doi.org/10.1088/2515-7655/ac5172.

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Abstract Thermoelectric (TE) materials are able to generate power from waste heat and thereby provide an alternative source of sustainable energy. Calcium cobaltite is a promising p-type TE oxide because of its intrinsically low thermal conductivity arising from the misfit-layered structure. Its structural framework contains two sub-layers with different incommensurate periodicities, offering different sites for substituting elements; the plate-like grain structure contributes to texture development, thereby providing opportunities to modulate the TE response. In this topical review, we briefly introduce the misfit crystal structure of calcium cobaltite and summarize three efficient strategies to enhance the TE performance, namely (a) elemental doping, (b) optimization of fabrication route, and (c) composite design. For each strategy, examples are presented and enhancing mechanisms are discussed. The roles of dopants, processing routes and phase composition are identified to provide insights into processing-microstructure-property relationships for calcium cobaltite based materials. We outline some of the challenges that still need to be addressed and hope that the proposed strategies can be exploited in other TE systems.
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2

Kim, Dong-Wan, Young-Dae Ko, Jong-Sung Park, Hae-June Je, Ji-Won Son, and Joosun Kim. "Electrochemical Performance of Calcium Cobaltite Nano-Plates." Journal of Nanoscience and Nanotechnology 9, no. 7 (2009): 4056–60. http://dx.doi.org/10.1166/jnn.2009.m10.

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3

Romo-De-La-Cruz, C., L. Liang, S. A. Paredes Navia, Y. Chen, J. Prucz, and X. Song. "Role of oversized dopant potassium on the nanostructure and thermoelectric performance of calcium cobaltite ceramics." Sustainable Energy & Fuels 2, no. 4 (2018): 876–81. http://dx.doi.org/10.1039/c7se00612h.

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The impact of the non-stoichiometric addition of potassium (K) on the nanostructure and thermoelectric performance of misfit layered calcium cobaltite (Ca<sub>3</sub>Co<sub>4</sub>O<sub>9</sub>) ceramics is reported.
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4

Baily, S. A., and M. B. Salamon. "Anomalous Hall effect of calcium-doped lanthanum cobaltite films." Journal of Applied Physics 93, no. 10 (2003): 8316–18. http://dx.doi.org/10.1063/1.1540183.

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5

Lee, Hwasoo, Felipe Caliari, and Sanjay Sampath. "Thermoelectric properties of plasma sprayed of calcium cobaltite (Ca2Co2O5)." Journal of the European Ceramic Society 39, no. 13 (2019): 3749–55. http://dx.doi.org/10.1016/j.jeurceramsoc.2019.05.008.

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6

Sopicka-Lizer, Małgorzata, Paweł Smaczyński, Karolina Kozłowska, Ewa Bobrowska-Grzesik, Julian Plewa, and Horst Altenburg. "Preparation and characterization of calcium cobaltite for thermoelectric application." Journal of the European Ceramic Society 25, no. 12 (2005): 1997–2001. http://dx.doi.org/10.1016/j.jeurceramsoc.2005.03.222.

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7

Srepusharawoot, Pornjuk, Supree Pinitsoontorn, and Santi Maensiri. "Electronic structure of iron-doped misfit-layered calcium cobaltite." Computational Materials Science 114 (March 2016): 64–71. http://dx.doi.org/10.1016/j.commatsci.2015.12.006.

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8

Tang, G. D., H. H. Guo, T. Yang, et al. "Anisotropic thermopower and magnetothermopower in a misfit-layered calcium cobaltite." Applied Physics Letters 98, no. 20 (2011): 202109. http://dx.doi.org/10.1063/1.3592831.

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9

Sekak, Khairunnadim Ahmad, and Adrian Lowe. "Structural and Thermal Characterization of Calcium Cobaltite Electrospun Nanostructured Fibers." Journal of the American Ceramic Society 94, no. 2 (2010): 611–19. http://dx.doi.org/10.1111/j.1551-2916.2010.04106.x.

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10

Klyndyuk, A. I., and I. V. Matsukevich. "Synthesis and properties of disubstituted derivatives of layered calcium cobaltite." Glass Physics and Chemistry 41, no. 5 (2015): 545–50. http://dx.doi.org/10.1134/s1087659615050077.

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11

Faaland, Sonia, Mari-Ann Einarsrud, and Tor Grande. "Reactions between Calcium- and Strontium-Substituted Lanthanum Cobaltite Ceramic Membranes and Calcium Silicate Sealing Materials." Chemistry of Materials 13, no. 3 (2001): 723–32. http://dx.doi.org/10.1021/cm991184n.

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12

Carvillo, Paulo, Yun Chen, Cullen Boyle, Paul N. Barnes, and Xueyan Song. "Thermoelectric Performance Enhancement of Calcium Cobaltite through Barium Grain Boundary Segregation." Inorganic Chemistry 54, no. 18 (2015): 9027–32. http://dx.doi.org/10.1021/acs.inorgchem.5b01296.

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13

Murai, Kei-Ichiro, Shuhei Kori, Shun Nakai, and Toshihiro Moriga. "Effect of thermoelectric material of Ca or Fe-doped LaCoO3." International Journal of Modern Physics B 32, no. 19 (2018): 1840037. http://dx.doi.org/10.1142/s0217979218400374.

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As the Perovskite-type Lanthanum Cobalt Oxide of LaCoO3 is nontoxic and thermally stable even at high temperature, this material is expected as a candidate for thermoelectric applications. The thermoelectric performance of a material is often evaluated by the dimensionless figure-of-merit, ZT (=S[Formula: see text]T/[Formula: see text]), or S[Formula: see text] in the ZT equation. S[Formula: see text] shows the electrical characteristic as a Power factor (PF). It has been reported Seebeck coefficient of LaCoO3 is higher than other oxide materials at room temperature even though electrical conductivity and ZT are lower values. In this study, calcium-doped lanthanum cobaltite La[Formula: see text]Ca[Formula: see text]CoO3 (x = 0.00, 0.05, 0.10 and 0.15) and iron-doped lanthanum cobaltite LaCo[Formula: see text]Fe[Formula: see text]O3 (y = 0.05, 0.10 and 0.15) have been prepared by solid-phase process. The X-ray diffraction patterns of the calcium-doped samples and iron-doped samples show cubic perovskite structure. Electric conductivities were improved by Ca or Fe substitution and showed a tendency to increase with increasing the temperature. The sample substituted with Fe 5 mol.% showed the maximum PF, 0.510 ([Formula: see text] W/K2m) at 548 K, and the sample substituted with Ca 15 mol.% showed the maximum PF, 0.152 ([Formula: see text] W/K2m) at 498 K.
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14

Machado, R. A. M., M. V. Gelfuso, and D. Thomazini. "Thermoelectric properties of barium doped calcium cobaltite obtained by simplified chemical route." Cerâmica 67, no. 381 (2021): 90–97. http://dx.doi.org/10.1590/0366-69132021673813034.

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15

Ermakova, E. A., S. S. Strel’nikova, A. S. Anokhin, A. N. Rogova, and D. N. Sovyk. "Sol-Gel Synthesis of Lanthanum Cobaltite Powders with Added Strontium and Calcium." Glass and Ceramics 77, no. 11-12 (2021): 438–41. http://dx.doi.org/10.1007/s10717-021-00327-7.

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16

Abbas, Yasir, Muhammad Kamran, Tanveer Akhtar, and Muhammad Anis-ur-Rehman. "Study of Temperature Dependent Dielectric Spectroscopy of Cerium Doped Bismuth Calcium Cobaltite." Materials Science Forum 1067 (August 10, 2022): 197–203. http://dx.doi.org/10.4028/p-292841.

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Bulk specimens of Bi2Ca2-xCexCoO6 (x = 0.00, 0.20) were prepared in pure phase form using co-precipitation method. The monoclinic structure of all samples is revealed via X-Ray Diffraction (XRD) analysis. The crystallite size, lattice constant, lattice strain, and volume of the unit cell were all determined using XRD analysis. On sintered at 750°C for 2 hours, the average crystallite size was 32-38nm. The precision analyzer was used to determine the loss tangent tan (δ), dielectric constant (ε'), AC conductivity (σac) in the 20Hz-3MHz range. The conduction process of electrical conductivity was also investigated utilizing the Jonscher Power Law.
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17

Klyndyuk, A. I., N. S. Krasutskaya, and A. A. Khort. "Synthesis and Properties of Ceramics Based on a Layered Bismuth Calcium Cobaltite." Inorganic Materials 54, no. 5 (2018): 509–14. http://dx.doi.org/10.1134/s0020168518050059.

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18

Shi, Zongmo, Can Zhang, Taichao Su, et al. "Boosting the Thermoelectric Performance of Calcium Cobaltite Composites through Structural Defect Engineering." ACS Applied Materials & Interfaces 12, no. 19 (2020): 21623–32. http://dx.doi.org/10.1021/acsami.0c03297.

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19

Boyle, Cullen, Paulo Carvillo, Yun Chen, Ever J. Barbero, Dustin Mcintyre, and Xueyan Song. "Grain boundary segregation and thermoelectric performance enhancement of bismuth doped calcium cobaltite." Journal of the European Ceramic Society 36, no. 3 (2016): 601–7. http://dx.doi.org/10.1016/j.jeurceramsoc.2015.10.042.

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20

Song, Xueyan, Dustin McIntyre, Xueqin Chen, Ever J. Barbero, and Yun Chen. "Phase evolution and thermoelectric performance of calcium cobaltite upon high temperature aging." Ceramics International 41, no. 9 (2015): 11069–74. http://dx.doi.org/10.1016/j.ceramint.2015.05.052.

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21

Bresch, Sophie, Björn Mieller, Daniela Schönauer‐Kamin, et al. "Influence of pressure and dwell time on pressure‐assisted sintering of calcium cobaltite." Journal of the American Ceramic Society 104, no. 2 (2020): 917–27. http://dx.doi.org/10.1111/jace.17541.

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22

Yu, Jincheng, Kan Chen, Feridoon Azough, Diana T. Alvarez-Ruiz, Michael J. Reece, and Robert Freer. "Enhancing the Thermoelectric Performance of Calcium Cobaltite Ceramics by Tuning Composition and Processing." ACS Applied Materials & Interfaces 12, no. 42 (2020): 47634–46. http://dx.doi.org/10.1021/acsami.0c14916.

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23

Yu, Shancheng, Guiping Zhang, Han Chen, and Lucun Guo. "A novel post-treatment to calcium cobaltite cathode for solid oxide fuel cells." International Journal of Hydrogen Energy 43, no. 4 (2018): 2436–42. http://dx.doi.org/10.1016/j.ijhydene.2017.12.040.

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24

Bresch, Sophie, Björn Mieller, Christian Selleng, Thomas Stöcker, Ralf Moos, and Torsten Rabe. "Influence of the calcination procedure on the thermoelectric properties of calcium cobaltite Ca3Co4O9." Journal of Electroceramics 40, no. 3 (2018): 225–34. http://dx.doi.org/10.1007/s10832-018-0124-3.

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25

Silva, Thayse, Vinícius Silva, Jakeline Santos, Thiago Simões, and Daniel Macedo. "Effect of Cu-doping on the activity of calcium cobaltite for oxygen evolution reaction." Materials Letters 298 (September 2021): 130026. http://dx.doi.org/10.1016/j.matlet.2021.130026.

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26

Klyndyuk, A. I., E. A. Chizhova, E. A. Tugova, R. S. Latypov, O. N. Karpov, and M. V. Tomkovich. "Thermoelectric Multiphase Ceramics Based on Layered Calcium Cobaltite, as Synthesized Using Two-Stage Sintering." Glass Physics and Chemistry 46, no. 6 (2020): 562–69. http://dx.doi.org/10.1134/s1087659620060127.

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27

Aswathy, P. K., R. Ganga, and Deepthi N Rajendran. "Impact of A-site calcium on structural and electrical properties of samarium cobaltite perovskites." Solid State Communications 350 (July 2022): 114748. http://dx.doi.org/10.1016/j.ssc.2022.114748.

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28

Yu, Jincheng, Mikko Nelo, Xiaodong Liu, et al. "Enhancing the thermoelectric performance of cold sintered calcium cobaltite ceramics through optimised heat-treatment." Journal of the European Ceramic Society 42, no. 9 (2022): 3920–28. http://dx.doi.org/10.1016/j.jeurceramsoc.2022.03.017.

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29

Ko, Young-Dae, Jin-Gu Kang, Kyung Jin Choi, et al. "High rate capabilities induced by multi-phasic nanodomains in iron-substituted calcium cobaltite electrodes." Journal of Materials Chemistry 19, no. 13 (2009): 1829. http://dx.doi.org/10.1039/b817120c.

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30

Zhang, Cuijuan, Xinyue Zhang, Katelynn Daly, Curtis P. Berlinguette, and Simon Trudel. "Water Oxidation Catalysis: Tuning the Electrocatalytic Properties of Amorphous Lanthanum Cobaltite through Calcium Doping." ACS Catalysis 7, no. 9 (2017): 6385–91. http://dx.doi.org/10.1021/acscatal.7b02145.

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31

Tani, Toshihiko, Hiroshi Itahara, Hiroaki Kadoura, and Ryoji Asahi. "Crystallographic Orientation Analysis on Calcium Cobaltite Ceramic Grains Textured by Reactive-Templated Grain Growth." International Journal of Applied Ceramic Technology 4, no. 4 (2007): 318–25. http://dx.doi.org/10.1111/j.1744-7402.2007.02146.x.

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32

Yang, Wenchao, Huicheng Zhang, Jiaqing Tao, et al. "Optimization of the spin entropy by incorporating magnetic ion in a misfit-layered calcium cobaltite." Ceramics International 42, no. 8 (2016): 9744–48. http://dx.doi.org/10.1016/j.ceramint.2016.03.065.

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33

Klyndyuk, A. I., E. A. Chizhova, and S. V. Shevchenko. "Spin–state transition in the layered barium cobaltite derivatives and their thermoelectric properties." Chimica Techno Acta 7, no. 1 (2020): 26–33. http://dx.doi.org/10.15826/chimtech.2020.7.1.04.

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Ba1.9Me0.1Co9O14 (Me = Ba, Sr, Ca) (BCO) layered cobaltites were prepared by means of solid-state reactions method. Crystal structure, microstructure, thermal expansion, electrical conductivity, and thermo-EMF for the obtained oxides were studied; the values of their linear thermal expansion coefficient, activation energy of electrical transport, and power factor values were calculated. It was found that BCO are p-type semiconductors, in which the spin-state transition occurs within 460-700 K temperature interval due to change in spin state of cobalt ions, which accompanied the sharp increase in electrical conductivity, activation energy of electrical conductivity, and linear thermal expansion coefficient, while thermo-EMF coefficient decreased. Partial substitution of barium by strontium or calcium in BCO leads to the increase in spin-state transition temperature and electrical conductivity of the samples, and, at the same time, thermo-EMF coefficient; consequently, their power factor values decrease.
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34

Yu, Jincheng, Yabin Chang, Ewa Jakubczyk, et al. "Modulation of electrical transport in calcium cobaltite ceramics and thick films through microstructure control and doping." Journal of the European Ceramic Society 41, no. 9 (2021): 4859–69. http://dx.doi.org/10.1016/j.jeurceramsoc.2021.03.044.

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35

Yu, Jincheng, Xiaodong Liu, Wei Xiong, Bing Wang, Michael J. Reece, and Robert Freer. "The effects of dual-doping and fabrication route on the thermoelectric response of calcium cobaltite ceramics." Journal of Alloys and Compounds 902 (May 2022): 163819. http://dx.doi.org/10.1016/j.jallcom.2022.163819.

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36

Rubešová, K., V. Jakeš, O. Jankovský, M. Lojka, and D. Sedmidubský. "Bismuth calcium cobaltite thermoelectrics: A study of precursor reactivity and its influence on the phase formation." Journal of Physics and Chemistry of Solids 164 (May 2022): 110631. http://dx.doi.org/10.1016/j.jpcs.2022.110631.

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37

Bochmann, Arne, Timmy Reimann, Thomas Schulz, Steffen Teichert, and Jörg Töpfer. "Transverse thermoelectric multilayer generator with bismuth-substituted calcium cobaltite: Design optimization through variation of tilt angle." Journal of the European Ceramic Society 39, no. 9 (2019): 2923–29. http://dx.doi.org/10.1016/j.jeurceramsoc.2019.03.036.

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38

Schulz, Thomas, Timmy Reimann, Arne Bochmann, et al. "Sintering behavior, microstructure and thermoelectric properties of calcium cobaltite thick films for transversal thermoelectric multilayer generators." Journal of the European Ceramic Society 38, no. 4 (2018): 1600–1607. http://dx.doi.org/10.1016/j.jeurceramsoc.2017.11.017.

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39

Wu, Jiajing, Jiancheng Tang, Xiaoxiao Wei, Nan Ye, and Fangxin Yu. "Preparation process and mechanism of ultra-fine spherical cobalt powders by hydrogen reduction of calcium cobaltite." Journal of Alloys and Compounds 726 (December 2017): 1119–23. http://dx.doi.org/10.1016/j.jallcom.2017.08.070.

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40

Ramasubramaniam, Ashwin. "First-principles Studies of the Electronic and Thermoelectric Properties of Misfit Layered Phases of Calcium Cobaltite." Israel Journal of Chemistry 57, no. 6 (2016): 522–28. http://dx.doi.org/10.1002/ijch.201600065.

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41

Araújo, Allan J. M., Francisco J. A. Loureiro, Laura I. V. Holz, et al. "Composite of calcium cobaltite with praseodymium-doped ceria: A promising new oxygen electrode for solid oxide cells." International Journal of Hydrogen Energy 46, no. 55 (2021): 28258–69. http://dx.doi.org/10.1016/j.ijhydene.2021.06.049.

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42

Klyndyuk, A. I., I. V. Matsukevich, M. Janek, et al. "Effect of Copper Additions on the Thermoelectric Properties of a Layered Calcium Cobaltite Prepared by Hot Pressing." Inorganic Materials 56, no. 11 (2020): 1198–205. http://dx.doi.org/10.1134/s0020168520110059.

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43

Prasoetsopha, Natkrita, Supree Pinitsoontorn, Atipong Bootchanont, et al. "Local structure of Fe in Fe-doped misfit-layered calcium cobaltite: An X-ray absorption spectroscopy study." Journal of Solid State Chemistry 204 (August 2013): 257–65. http://dx.doi.org/10.1016/j.jssc.2013.05.038.

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44

Mishra, Avinna, Aneeya K. Samantara, Swagatika Kamila, Bikash Kumar Jena, U. Manju, and Sarama Bhattacharjee. "Non-precious transition metal oxide calcium cobaltite: Effect of dopant on oxygen/hydrogen evolution reaction and thermoelectric properties." Materials Today Communications 15 (June 2018): 48–54. http://dx.doi.org/10.1016/j.mtcomm.2018.02.022.

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45

Gholizadeh, Ahmad, Hamid Yousefi, Azim Malekzadeh, and Faiz Pourarian. "Calcium and strontium substituted lanthanum manganite–cobaltite [La1−(Ca,Sr) Mn0.5Co0.5O3] nano-catalysts for low temperature CO oxidation." Ceramics International 42, no. 10 (2016): 12055–63. http://dx.doi.org/10.1016/j.ceramint.2016.04.134.

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46

Boyle, Cullen, Liang Liang, Yun Chen, et al. "Competing dopants grain boundary segregation and resultant seebeck coefficient and power factor enhancement of thermoelectric calcium cobaltite ceramics." Ceramics International 43, no. 14 (2017): 11523–28. http://dx.doi.org/10.1016/j.ceramint.2017.06.029.

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47

Bayata, Fatma. "Enhancement of high temperature thermoelectric performance of cobaltite based materials for automotive exhaust thermoelectric generators." Smart Materials and Structures 31, no. 2 (2021): 025017. http://dx.doi.org/10.1088/1361-665x/ac4120.

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Abstract Thermoelectric (TE) generators can directly convert exhaust waste heat into electricity in vehicles. However, the low conversion efficiency of TE generators is the main obstacle to their commercialization in automotive. Their efficiency mainly depends on the performance of the used materials which is quantified by the figure of merit (ZT value). In the present study, single- and co-doped calcium cobaltites (CCO) with rare-earth (Tb) and transition metals (Cu, Fe, Ni, Mn, Cr) were produced using sol–gel technique in order to improve their high temperature TE properties for heat recovery in exhaust manifold applications. By the combined effect of doping approach and the production technique used in this study, a remarkable decrease in the grain size of CCO was obtained, and thus its thermal conductivity dramatically decreased. Besides, thermopower values were improved significantly. The reduction in thermal conductivity and the increase in thermopower led to an enhancement in ZT value of CCO ceramics. Among all the co-doped samples, Tb–Cu co-doped CCO displayed the maximum ZT value of 0.116 at 873 K which is 2.5 times larger than that of pure CCO. The high thermal stability and the enhanced TE performance make Tb–Cu co-doped CCO material a potential candidate for heat recovery in automotive exhaust TE generators.
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48

Klyndyuk, A. I., E. A. Chizhova, R. S. Latypov, S. V. Shevchenko та V. M. Kononovich. "Effect of the Addition of Copper Particles on the Thermoelectric Properties of the Ca3Co4O9 + δ Ceramics Produced by Two-Step Sintering". Russian Journal of Inorganic Chemistry 67, № 2 (2022): 237–44. http://dx.doi.org/10.1134/s0036023622020073.

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Abstract Composite thermoelectric materials based on layered calcium cobaltite Ca3Co4O9 + δ doped with copper particles were synthesized by two-step sintering, and their microstructure, and electrotransport and thermoelectric properties were studied. It was determined that the introduction of copper particles into the ceramics improves their sinterability at moderate sintering temperatures (Tsint ≤ 1273 K), leading to a decrease in the porosity of the samples and an increase in their electrical conductivity and power factor, whereas the oxidation of copper to less conductive copper(II) oxide significantly decreases the electrical conductivity and power factor of the ceramics sintered at elevated temperatures (Tsint ≥ 1373 K). The power factor is maximum for the Ca3Co4O9 + δ + 3 wt % Cu ceramic sintered at 1273 K (335 μW/(m K2) at a temperature of 1100 K), which is by a factor of 2.3 higher than the power factor of the base material Ca3Co4O9 + δ with the same thermal history (145 μW/(m K2) at 1100 K) and more than 3 times higher than the power factor of the Ca3Co4O9+δ ceramic synthesized by the conventional solid-phase method.
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49

Bangert, U., U. Falke, and A. Weidenkaff. "Nature of domains in lanthanum calcium cobaltite perovskite revealed by atomic resolution Z-contrast and electron energy loss spectroscopy." Materials Science and Engineering: B 133, no. 1-3 (2006): 30–36. http://dx.doi.org/10.1016/j.mseb.2006.04.044.

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50

Dziedzic, Andrzej, Szymon Wójcik, Mirosław Gierczak, et al. "Planar Thermoelectric Microgenerators in Application to Power RFID Tags." Sensors 24, no. 5 (2024): 1646. http://dx.doi.org/10.3390/s24051646.

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This paper presents an innovative approach to the integration of thermoelectric microgenerators (μTEGs) based on thick-film thermopiles of planar constantan–silver (CuNi-Ag) and calcium cobaltite oxide–silver (Ca3Co4O9-Ag) thick-film thermopiles with radio frequency identification (RFID) technology. The goal was to consider using the TEG for an active or semi-passive RFID tag. The proposed implementation would allow the communication distance to be increased or even operated without changing batteries. This article discusses the principles of planar thermoelectric microgenerators (μTEGs), focusing on their ability to convert the temperature difference into electrical energy. The concept of integration with active or semi-passive tags is presented, as well as the results of energy efficiency tests, considering various environmental conditions. On the basis of the measurements, the parameters of thermopiles consisting of more thermocouples were simulated to provide the required voltage and power for cooperation with RFID tags. The conclusions of the research indicate promising prospects for the integration of planar thermoelectric microgenerators with RFID technology, opening the way to more sustainable and efficient monitoring and identification systems. Our work provides the theoretical basis and practical experimental data for the further development and implementation of this innovative technology.
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