-
Recently, Mg3(Sb,Bi)2-based thermoelectric materials have received extensive attention owing to excellent thermoelectric properties and the low cost. This study investigates the change and mechanism of thermoelectric transport properties of Mg3.275Mn0.025Sb1.49Bi0.5Te0.01/SiO2 nanocomposite. The results show that nano-SiO2 can effectively scatter phonons, promote the reduction of lattice thermal conductivity, and optimize the heat transport performance owing to the introduction of a large number of tiny grain boundaries. For example, when SiO2 content is 0.54%, the thermal conductivity decreases by 15% from 1.24 W/(m·K) to 1.04 W/(m·K) compared with that of 0% SiO2 sample at room temperature. At the same time, the material system also has a strong scattering effect on electrons. This leads to a sharp attenuation of power factor and electrical transport performance with decline of mobility and conductivity in the room temperature area. Nano SiO2 is an effective candidate for regulating thermoelectric properties of Mg3Sb2 based thermoelectric material. The thermoelectric transport performance of the material will be improved by combining with other methods, such as appropriate grain boundary modification to reduce the potential barrier of charge carrier transport.
-
Keywords:
- nano-SiO2 /
- Mg3Sb2-based materials /
- composite /
- thermoelectric transport properties
[1] Mao J, Liu Z, Zhou J, Zhu H, Zhang Q, Chen G, Ren Z 2018 Adv. Phys. 67 69Google Scholar
[2] Kim S I, Lee K H, Mun H A, Kim H S, Hwang S W, Roh J W, Yang D J, Shin W H, Li X S, Lee Y H 2015 Science 348 109Google Scholar
[3] Pei Y, Shi X, LaLonde A, Wang H, Chen L, Snyder G J 2011 Nature 473 66Google Scholar
[4] He J, Tritt T M 2017 Science 357 eaak9997Google Scholar
[5] Boona S R, Myers R C, Heremans J P 2014 Energy Environ. Sci. 7 885Google Scholar
[6] Zheng Y, Lu T, Polash M M, Rasoulianboroujeni M, Liu N, Manley M E, Deng Y, Sun P, Chen X, Hermann R P, Vashaee D, Heremans J P, Zhao H 2019 Sci. Adv. 5 eaat9461Google Scholar
[7] Imasato K, Kang S D, Snyder G J 2019 Energy Environ. Sci. 12 965Google Scholar
[8] Ren Z, Shuai J, Mao J, Zhu Q, Song S, Ni Y, Chen S 2018 Acta Mater. 143 265Google Scholar
[9] Imasato K, Kang S D, Ohno S, Snyder G J 2018 Mater. Horiz. 5 59Google Scholar
[10] Tamaki H, Sato H K, Kanno T 2016 Adv. Mater. 28 10182Google Scholar
[11] Shuai J, Ge B, Mao J, Song S, Wang Y, Ren Z 2018 J. Am. Chem. Soc. 140 1910Google Scholar
[12] Imasato K, Ohno S, Kang S D, Snyder G J 2018 APL Mater. 6 016106Google Scholar
[13] Wood M, Kuo J J, Imasato K, Snyder G J 2019 Adv. Mater. 31 1902337Google Scholar
[14] Mao J, Zhu H, Ding Z, Liu Z, Gamage G A, Chen G, Ren Z 2019 Science 365 495
[15] Yang J, Li G, Zhu H, Chen N, Lu T, Gao J, Guo L, Xiang J, Sun P, Yao Y 2022 Joule 6 193Google Scholar
[16] Ren P, Liu Y, He J, Lv T, Gao J, Xu G 2018 Inorg. Chem. Front. 5 2380Google Scholar
[17] Shi X, Wang X, Li W, Pei Y 2018 Small Methods 2 1800022Google Scholar
[18] Brod M K, Anand S, Snyder G J 2023 Mater. Today Phys. 31 100959Google Scholar
[19] Imasato K, Wood M, Anand S, Kuo J J, Snyder G J 2022 Adv. Energy Sustainability Res. 3 2100208Google Scholar
[20] Sharp J W, Volckmann E H, Goldsmid H J 2001 Phys. Status Solidi A 185 257Google Scholar
[21] Sharp J W, Goldsmid H J 1999 Proceedings of the 18th International Conference on Thermoelectrics Baltimore, USA, August 29–September 2, 1999 p709
[22] Jin H, Heremans J P 2018 Phys. Rev. Mater. 2 115401Google Scholar
[23] Kuo J J, Kang S D, Imasato K, Tamaki H, Ohno S, Kanno T, Snyder G J 2018 Energy Environ. Sci. 11 429Google Scholar
[24] Kanno T, Tamaki H, Sato H K, Kang S D, Ohno S, Imasato K, Kuo J J, Snyder G J, Miyazaki Y 2018 Appl. Phys. Lett. 112 033903Google Scholar
[25] Mao T, Qiu P, Liu J, Du X, Hu P, Zhao K, Ren D, Shi X, Chen L 2020 Phys. Chem. Chem. Phys. 22 7374Google Scholar
-
图 2 (a), (b), (d)不同SiO2含量的Mg3.275Mn0.025Sb1.49Bi0.5Te0.01电性能温度依赖曲线; (c)室温和723 K时样品的简约费米能级变化趋势图
Figure 2. (a), (b) and (d) are temperature dependence curves of electrical properties of Mg3.275Mn0.025Sb1.49Bi0.5Te0.01 with different SiO2 content; (c) change trend of reduced Fermi level of samples at room temperature and 723 K.
图 7 不同纳米SiO2含量的Mg3.3Sb1.5Bi0.49Te0.01样品ZT值温度依赖曲线; 插图为纳米SiO2复合的Mg3Sb2基材料样品电子和声子输运过程中的散射原理图
Figure 7. Temperature dependence curve of ZT value of Mg3.3Sb1.5Bi0.49Te0.01 samples with different nano-SiO2 content; the illustration shows the scattering schematic diagram of the electron and phonon transport process of the composite with Mg3Sb2-based material and nano-SiO2.
-
[1] Mao J, Liu Z, Zhou J, Zhu H, Zhang Q, Chen G, Ren Z 2018 Adv. Phys. 67 69Google Scholar
[2] Kim S I, Lee K H, Mun H A, Kim H S, Hwang S W, Roh J W, Yang D J, Shin W H, Li X S, Lee Y H 2015 Science 348 109Google Scholar
[3] Pei Y, Shi X, LaLonde A, Wang H, Chen L, Snyder G J 2011 Nature 473 66Google Scholar
[4] He J, Tritt T M 2017 Science 357 eaak9997Google Scholar
[5] Boona S R, Myers R C, Heremans J P 2014 Energy Environ. Sci. 7 885Google Scholar
[6] Zheng Y, Lu T, Polash M M, Rasoulianboroujeni M, Liu N, Manley M E, Deng Y, Sun P, Chen X, Hermann R P, Vashaee D, Heremans J P, Zhao H 2019 Sci. Adv. 5 eaat9461Google Scholar
[7] Imasato K, Kang S D, Snyder G J 2019 Energy Environ. Sci. 12 965Google Scholar
[8] Ren Z, Shuai J, Mao J, Zhu Q, Song S, Ni Y, Chen S 2018 Acta Mater. 143 265Google Scholar
[9] Imasato K, Kang S D, Ohno S, Snyder G J 2018 Mater. Horiz. 5 59Google Scholar
[10] Tamaki H, Sato H K, Kanno T 2016 Adv. Mater. 28 10182Google Scholar
[11] Shuai J, Ge B, Mao J, Song S, Wang Y, Ren Z 2018 J. Am. Chem. Soc. 140 1910Google Scholar
[12] Imasato K, Ohno S, Kang S D, Snyder G J 2018 APL Mater. 6 016106Google Scholar
[13] Wood M, Kuo J J, Imasato K, Snyder G J 2019 Adv. Mater. 31 1902337Google Scholar
[14] Mao J, Zhu H, Ding Z, Liu Z, Gamage G A, Chen G, Ren Z 2019 Science 365 495
[15] Yang J, Li G, Zhu H, Chen N, Lu T, Gao J, Guo L, Xiang J, Sun P, Yao Y 2022 Joule 6 193Google Scholar
[16] Ren P, Liu Y, He J, Lv T, Gao J, Xu G 2018 Inorg. Chem. Front. 5 2380Google Scholar
[17] Shi X, Wang X, Li W, Pei Y 2018 Small Methods 2 1800022Google Scholar
[18] Brod M K, Anand S, Snyder G J 2023 Mater. Today Phys. 31 100959Google Scholar
[19] Imasato K, Wood M, Anand S, Kuo J J, Snyder G J 2022 Adv. Energy Sustainability Res. 3 2100208Google Scholar
[20] Sharp J W, Volckmann E H, Goldsmid H J 2001 Phys. Status Solidi A 185 257Google Scholar
[21] Sharp J W, Goldsmid H J 1999 Proceedings of the 18th International Conference on Thermoelectrics Baltimore, USA, August 29–September 2, 1999 p709
[22] Jin H, Heremans J P 2018 Phys. Rev. Mater. 2 115401Google Scholar
[23] Kuo J J, Kang S D, Imasato K, Tamaki H, Ohno S, Kanno T, Snyder G J 2018 Energy Environ. Sci. 11 429Google Scholar
[24] Kanno T, Tamaki H, Sato H K, Kang S D, Ohno S, Imasato K, Kuo J J, Snyder G J, Miyazaki Y 2018 Appl. Phys. Lett. 112 033903Google Scholar
[25] Mao T, Qiu P, Liu J, Du X, Hu P, Zhao K, Ren D, Shi X, Chen L 2020 Phys. Chem. Chem. Phys. 22 7374Google Scholar
Catalog
Metrics
- Abstract views: 3613
- PDF Downloads: 60
- Cited By: 0