參考文獻 |
1. 朱旭山, 熱電材料與元件之原理與應用. 2005, 工業材料雜誌.
2. Zhang, S., S.-H. Wei, and A. Zunger, Intrinsic n-type versus p-type doping asymmetry and the defect physics of ZnO. Physical Review B, 2001. 63(7).
3. Bell, L.E., Cooling, heating, generating power, and recovering waste heat with thermoelectric systems. Science, 2008. 321(5895)
4. Gurevich, Y.G. and G. Logvinov, Physics of thermoelectric cooling. Semiconductor science and technology, 2005. 20(12)
5. Ioffe, A.F., Semiconductor thermoelements and thermoelectric cooling. 1957.
6. Kim, D. and C.I. Ferreira, Solar refrigeration options–a state-of-the-art review. International Journal of refrigeration, 2008. 31(1)
7. Valenti, I., et al., Electrical, optical, and electronic properties of Al: ZnO films in a wide doping range. Journal of Applied Physics, 2015. 118(16)
8. Mele, P., et al., Effect of substrate on thermoelectric properties of Al-doped ZnO thin films. Applied Physics Letters, 2013. 102(25)
9. Yu, F., et al., Enhanced thermoelectric figure of merit in nanocrystalline Bi 2 Te 3 bulk. Journal of Applied Physics, 2009. 105(9)
10. Rahaman, M.N., Ceramic processing and sintering. 2003: CRC press.
11. Kim, K.H., K.C. Park, and D.Y. Ma, Structural, electrical and optical properties of aluminum doped zinc oxide films prepared by radio frequency magnetron sputtering. Journal of Applied Physics, 1997. 81(12)
12. 吳奇韋, P型金屬氧化物與硫化物之研究, in 電機工程學系. 2017, 國立中央大學: 桃園縣.
13. Mele, P., et al., Development of thermoelectric module based on dense Ca 3 Co 4 O 9 and Zn 0.98 Al 0.02 O legs. Metals and Materials International, 2014. 20(2)
14. Sui, Y., et al., Effects of (P, N) dual acceptor doping on band gap and p-type conduction behavior of ZnO films. Journal of Applied Physics, 2013. 113(13)
15. Funahashi, R., et al., A portable thermoelectric-power-generating module composed of oxide devices. 2006, AIP.
16. Schroder, D.K., Semiconductor material and device characterization. 2006: John Wiley & Sons.
17. 維基百科編者. 阿基米德浮體原理. https://zh.wikipedia.org/w/index.php?title=%E9%98%BF%E5%9F%BA%E7%B1%B3%E5%BE%B7%E6%B5%AE%E9%AB%94%E5%8E%9F%E7%90%86&oldid=49198877.
?
18. Schriempf, J., A laser flash technique for determining thermal diffusivity of liquid metals at elevated temperatures. Review of Scientific Instruments, 1972. 43(5)
19. Pungor, E. and G. Horvai, A practical guide to instrumental analysis. 1994: CRC press.
20. Bayraktaroglu, B., K. Leedy, and R. Bedford, High temperature stability of postgrowth annealed transparent and conductive ZnO: Al films. Applied Physics Letters, 2008. 93(2)
21. Salahinejad, E., et al., The effect of sintering time on the densification and mechanical properties of a mechanically alloyed Cr–Mn–N stainless steel. Materials & Design, 2010. 31(1)
22. Yoshizawa, S., et al., Optimization of CIP process on superconducting property of Bi-2223/Ag wires composite bulk. IEEE transactions on applied superconductivity, 2005. 15(2)
23. Nomoto, J.-i., T. Miyata, and T. Minami, Transparent conducting Si-codoped Al-doped ZnO thin films prepared by magnetron sputtering using Al-doped ZnO powder targets containing SiC. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 2009. 27(4)
24. Ohtaki, M., R. Hayashi, and K. Araki. Thermoelectric properties of sintered ZnO incorporating nanovid structure: Influence of the size and number density of nanovoids. in Thermoelectrics, 2007. ICT 2007. 26th International Conference on. 2007. IEEE.
25. Saini, S., et al., Thermoelectric properties of Al-doped ZnO thin films. Journal of Electronic Materials, 2014. 43(6)
26. Ohtaki, M., S. Maehara, and S. Shige. Thermoelectric properties of Al-doped ZnO sintered with nanosized void forming agents. in Thermoelectrics, 2003 Twenty-Second International Conference on-ICT. 2003. IEEE.
27. 王威傑, 矽基熱電模組開發及特性研究; The Research and Development of Si-based Thermoelectric Modules. 2017, 國立中央大學.
28. Brittain, J., Thevenin′s theorem. Ieee Spectrum, 1990. 27(3)
29. Johnson, D.H., Origins of the equivalent circuit concept: the voltage-source equivalent. Proceedings of the IEEE, 2003. 91(4) |