原子層沉積金屬氧化物熱電性質研究：不同氧化物插層對鉿摻雜氧化鋅薄膜之影響

Han-Ting Liao; 廖涵婷

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/69960

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔡豐羽(Feng-Yu Tsai)
dc.contributor.author	Han-Ting Liao	en
dc.contributor.author	廖涵婷	zh_TW
dc.date.accessioned	2021-06-17T03:36:08Z	-
dc.date.available	2020-08-24
dc.date.copyright	2020-08-24
dc.date.issued	2020
dc.date.submitted	2020-08-19
dc.identifier.citation	REFERENCE [1] Qi-Hao, Z., Sheng-Qiang, B., Li-Dong, C. (2019). Technologies and Applications of Thermoelectric Devices: Current Status, Challenges and Prospects. [2] Rull-Bravo, M., Moure, A., Fernandez, J. F., Martín-González, M. (2015). Skutterudites as thermoelectric materials: revisited. Rsc Advances, 5(52), 41653-41667. [3] Vaqueiro, P., Powell, A. V. (2010). Recent developments in nanostructured materials for high-performance thermoelectrics. Journal of Materials Chemistry, 20(43), 9577-9584. [4] Cutler, M., Mott, N. F. (1969). Observation of Anderson localization in an electron gas. Physical Review, 181(3), 1336. [5] Ou, C., Hou, J., Wei, T. R., Jiang, B., Jiao, S., Li, J. F., Zhu, H. (2015). High thermoelectric performance of all-oxide heterostructures with carrier double-barrier filtering effect. NPG Asia Materials, 7(5), e182. [6] Pakdel, A., Guo, Q., Nicolosi, V., Mori, T. (2018). Enhanced thermoelectric performance of Bi–Sb–Te/Sb 2 O 3 nanocomposites by energy filtering effect. Journal of Materials Chemistry A, 6(43), 21341-21349. [7] Kulkarni, A. K., Schulz, K. H., Lim, T. S., Khan, M. (1999). Dependence of the sheet resistance of indium-tin-oxide thin films on grain size and grain orientation determined from X-ray diffraction techniques. Thin solid films, 345(2), 273-277. [8] Tsurekawa, S., Kido, K., Watanabe, T. (2007). Interfacial state and potential barrier height associated with grain boundaries in polycrystalline silicon. Materials Science and Engineering: A, 462(1-2), 61-67. [9] Mao, J., Wang, Y., Kim, H. S., Liu, Z., Saparamadu, U., Tian, F., ... Ren, Z. (2015). High thermoelectric power factor in Cu–Ni alloy originate from potential barrier scattering of twin boundaries. Nano Energy, 17, 279-289. [10] Bachmann, M., Czerner, M., Heiliger, C. (2012). Ineffectiveness of energy filtering at grain boundaries for thermoelectric materials. Physical Review B, 86(11), 115320. [11] L. D. Hicks, T. C. Harman, M. S. Dresselhaus, Appl. Phys. Lett. 1993, 63, 3230. [12] Hochbaum, A. I. et al. Enhanced thermoelectric performance of rough silicon nanowires. Nature 451, 163–167 (2008). [13] Sothmann, B., Sanchez, R. Jordan, A. N. Thermoelectric energy harvesting with quantum dots. Nanotechnology 26, 032001 (2015). [14] Yang, L., Chen, Z. G., Dargusch, M. S., Zou, J. (2018). High performance thermoelectric materials: progress and their applications. Advanced Energy Materials, 8(6), 1701797. [15] Venkatasubramanian, R., Siivola, E., Colpitts, T., O'quinn, B. (2001). Thin-film thermoelectric devices with high room-temperature figures of merit. Nature, 413(6856), 597-602. [16] Ohta, H., Kim, S., Mune, Y., Mizoguchi, T., Nomura, K., Ohta, S., ... Hosono, H. (2007). Giant thermoelectric Seebeck coefficient of a two-dimensional electron gas in SrTiO 3. Nature materials, 6(2), 129-134. [17] Koga, T., Cronin, S. B., Dresselhaus, M. S., Liu, J. L., Wang, K. L. (2000). Experimental proof-of-principle investigation of enhanced Z 3D T in (001) oriented Si/Ge superlattices. Applied Physics Letters, 77(10), 1490-1492. [18] Yang, B., Liu, W. L., Liu, J. L., Wang, K. L., Chen, G. (2002). Measurements of anisotropic thermoelectric properties in superlattices. Applied Physics Letters, 81(19), 3588-3590. [19] Ohta, H., Kim, S., Mune, Y., Mizoguchi, T., Nomura, K., Ohta, S., ... Hosono, H. (2007). Giant thermoelectric Seebeck coefficient of a two-dimensional electron gas in SrTiO3. Nature materials, 6(2), 129-134. [20] Sarnet, T., Hatanpää, T., Puukilainen, E., Mattinen, M., Vehkamäki, M., Mizohata, K., ... Leskelä, M. (2015). Atomic layer deposition and characterization of Bi2Te3 thin films. The Journal of Physical Chemistry A, 119(11), 2298-2306. [21] Sarnet, T., Hatanpää, T., Vehkamäki, M., Flyktman, T., Ahopelto, J., Mizohata, K., ... Leskelä, M. (2015). (Et 3 Si) 2 Se as a precursor for atomic layer deposition: growth analysis of thermoelectric Bi 2 Se 3. Journal of Materials Chemistry C, 3(18), 4820-4828. [22] Zastrow, S., Gooth, J., Boehnert, T., Heiderich, S., Toellner, W., Heimann, S., ... Nielsch, K. (2013). Thermoelectric transport and Hall measurements of low defect Sb2Te3 thin films grown by atomic layer deposition. Semiconductor science and technology, 28(3), 035010. [23] DeCoster, M. E., Chen, X., Zhang, K., Rost, C. M., Hoglund, E. R., Howe, J. M., ... Hopkins, P. E. (2019). Thermal Conductivity and Phonon Scattering Processes of ALD Grown PbTe–PbSe Thermoelectric Thin Films. Advanced Functional Materials, 29(46), 1904073. [24] Lin, Y.-Y., Hsu, C.-C., Tseng, M.-H., Shyue, J.-J. Tsai, F.-Y. Stable and High- Performance Flexible ZnO Thin-Film Transistors by Atomic Layer Deposition. ACS Applied Materials Interfaces 7, 22610–22617 (2015). [25] Lim, S. J. et al. Atomic Layer Deposition ZnO:N Thin Film Transistor: The Effects of N Concentration on the Device Properties. J. Electrochem. Soc. 157, H214–H218 (2010). [26] Chou, C.-T. et al. Transparent Conductive Gas-Permeation Barriers on Plastics by Atomic Layer Deposition. Adv. Mater. 25, 1750–1754 (2013). [27] Macco, B. et al. Atomic layer deposition of high-mobility hydrogen-doped zinc oxide. Solar Energy Materials and Solar Cells 173, 111–119 (2017). [28] Boyadjiev, S. I., Georgieva, V., Yordanov, R., Raicheva, Z. Szilágyi, I. M. Preparation and characterization of ALD deposited ZnO thin films studied for gas sensors. Applied Surface Science 387, 1230–1235 (2016). [29] Lin, P., Chen, X., Zhang, K. Baumgart, H. Improved Gas Sensing Performance of ALD AZO 3-D Coated ZnO Nanorods. ECS J. Solid State Sci. Technol. 7, Q246– Q252 (2018). [30] Lee, S. H., Lee, J. H., Choi, S. J., Park, J. S. (2017). Studies of thermoelectric transport properties of atomic layer deposited gallium-doped ZnO. Ceramics International, 43(10), 7784-7788. [31] Park, N. W., Ahn, J. Y., Park, T. H., Lee, J. H., Lee, W. Y., Cho, K., ... Lee, S. K. (2017). Control of phonon transport by the formation of the Al 2 O 3 interlayer in Al 2 O 3–ZnO superlattice thin films and their in-plane thermoelectric energy generator performance. Nanoscale, 9(21), 7027-7036. [32] Lee, J. H., Park, T. H., Lee, S. H., Park, N. W., Lee, W. Y., Lim, J. H., ... Park, J. S. (2016). Enhancing the thermoelectric properties of super-lattice Al2O3/ZnO atomic film via interface confinement. Ceramics International, 42(13), 14411-14415. [33] Tynell, T., Yamauchi, H., Karppinen, M. (2014). Hybrid inorganic–organic superlattice structures with atomic layer deposition/molecular layer deposition. Journal of Vacuum Science Technology A: Vacuum, Surfaces, and Films, 32(1), 01A105. [34] Tynell, T., Terasaki, I., Yamauchi, H., Karppinen, M. (2013). Thermoelectric characteristics of (Zn, Al) O/hydroquinone superlattices. Journal of Materials Chemistry A, 1(43), 13619-13624. [35] Lee, W. Y., Park, N. W., Kang, S. Y., Kim, G. S., Koh, J. H., Saitoh, E., Lee, S. K. (2019). Enhanced Cross-Plane Thermoelectric Figure of Merit Observed in an Al2O3/ZnO Superlattice Film by Hole Carrier Blocking and Phonon Scattering. The Journal of Physical Chemistry C, 123(23), 14187-14194. [36] Lee, Mi Gyoung, et al. 'Solution-processed metal oxide thin film nanostructures for water splitting photoelectrodes: A review.' Journal of the Korean Ceramic Society 55.3 (2018): 185-202. [37] High-κ Complex Oxides for Advanced Gate Dielectric Applications Grown by Atomic Layer Deposition [38] Cahill, D. G. (2004). Analysis of heat flow in layered structures for time-domain thermoreflectance. Review of scientific instruments, 75(12), 5119-5122. [39] Meng, X., Liu, Z., Cui, B., Qin, D., Geng, H., Cai, W., ... Sui, J. (2017). Grain boundary engineering for achieving high thermoelectric performance in n‐type skutterudites. Advanced Energy Materials, 7(13), 1602582. [40] Aarik, J., Aidla, A., Uustare, T., Ritala, M., Leskelä, M. (2000). Titanium isopropoxide as a precursor for atomic layer deposition: characterization of titanium dioxide growth process. Applied surface science, 161(3-4), 385-395. [41] Gurram, S. K. (2017). Atomic Layer Deposition of Zinc Based Transparent Conductive Oxides. BoD–Books on Demand. [42] Doctor dissertation of Bo-wei Shih:Thermoelectricity of metal oxide and metal oxide/polymer superlattice composites by atomic layer deposition
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/69960	-
dc.description.abstract	優秀的熱電性能需同時擁有高電導率、高賽貝克係數以及低熱導率，但三種因子彼此的抗衡是熱電領域中最大的阻礙，其中能量過濾效應被視為能打破電導率與賽貝克係數之間抗衡的方法之一。本研究利用原子層沉積技術，製備以鉿摻雜氧化鋅作為母材，在其中週期性的插入多種金屬氧化物插層的超晶格結構之熱電薄膜。利用異質介面降低母材熱導率的同時，透過不同能階匹配之插層，以達到最佳的能量過濾效應與熱電性質之提升。研究發現，在母材中插入高原子量的純二氧化鉿插層，雖在抑制熱導率方面有優異的表現，但其高能障卻阻擋了過多的電子以致不佳的電導與ZT。而插入能障較二氧化鉿低的純二氧化鈦或純二氧化鋯插層，能使更多的電子通過而提升電導率，但其低原子量使抑制熱導率的效果不佳，限制了ZT之提升。因此，我們在母材中插入二氧化鈦和二氧化鉿之混合插層，使其達到適當的能障高度，卻仍保有二氧化鉿的高原子量以抑制熱導率，最終使ZT相較只插層雜純氧化鉿的效率高了將近四十二個百分比之多。結果表明，選擇適當的能障高度與高原子量之插層，能透過能量過濾效應保持高PF的同時，大幅降低熱導率並有效地改善熱電效率。	zh_TW
dc.description.abstract	High thermoelectric performances require high electrical conductivity (), high Seebeck coefficient (S) and low thermal conductivity (), but simultaneously achieving the three requisite properties is challenging due to the trade-off relations among them. This study utilized atomic layer deposition (ALD) to prepare superlattice films composed of a conductive Hf:ZnO matrix periodically inserted with interlayers of TiO2, ZrO2, HfO2, or mixtures of the three, leveraging the energy-filtering and phonon-scattering effects of the interlayers to enhance  and S while lowering . The pure HfO2 interlayer were the most effective in suppressing k due to the high atomic mass of Hf, and its high energy barrier with the Hf:ZnO matrix significantly enhanced S through energy filtering, but it also caused a large decline in , limiting the attainable thermoelectric figure of merit, ZT. Conversely, the pure TiO2 and ZrO2 interlayers, with their lower energy barriers and the lower atomic mass of Ti and Zr, yielded higher , lower S, and higher , resulting in ZT values that were only marginally higher than that with the HfO2 interlayer. Combining the low-energy-barrier/low-atomic-mass TiO2 and the high-energy-barrier/high-atomic-mass HfO2 into a mixture interlayer achieved an optimal balance in the energy-filtering and phonon-scattering effects, obtaining a 42% enhancement in ZT over that of the Hf:ZnO matrix. The results provided a quantified guidance for designing interlayer structures in superlattice films for optimal thermoelectric performance.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T03:36:08Z (GMT). No. of bitstreams: 1 U0001-1708202021154800.pdf: 2595465 bytes, checksum: 7c0438606bdbeb199879f2b42bf9221e (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	口試委員會審定書 # 誌謝 i 中文摘要 ii Abstract iii CONTENTS v LIST OF FIGURES viii LIST OF TABLES x Chapter 1 Introduction 1 1.1 Overview of thermoelectricity 1 1.2 Fundamental concept of thermoelectric effect 3 1.2.1 Basic principles of thermoelectric (TE) effect 3 1.2.2 Trade-off among three key properties, S, σ, and κ in ZT 5 1.2.3 Energy filtering effect 9 1.2.4 Effects of grain size and grain boundary on TE effects 11 1.2.5 Thermal conductivity of materials 13 1.3 Thermoelectricity in thin films 14 1.3.1 Advantages for thermoelectricity in thin films 14 1.3.2 Promising strategies to enhance TE properties in thin films 16 1.4 Advantages of depositing thin film thermoelectric materials by atomic layer deposition (ALD) 18 1.4.1 Literature review of thin film thermoelectric materials deposited by ALD 19 1.5 Motivation and objectives statements 21 Chapter 2 Experimental Methods 23 2.1 Equipment and Experiment Details 23 2.1.1 Atomic Layer Deposition Systems 23 2.1.2 Experimental parameters 23 2.2 Thin film characteristics analysis 25 2.2.1 Measurements of electrical conductivity and Seebeck coefficient 25 2.2.2 Measurement of thermal conductivity by time-domain thermoreflectance method (TDTR) 27 2.2.3 Quartz crystal microbalance (QCM) 30 2.2.4 Spectral characterization 30 Chapter 3 Results and discussions 31 3.1 Selection and comparison of different interlayer oxide 31 3.1.1 Energy filtering effects of TiO2 and ZrO2 interlayers compared with HfO2 31 3.1.2 Effects of TiO2 and ZrO2 interlayer thicknesses 37 3.2 Using TTIP as Ti source of TiO2 as interlayer oxides 42 3.2.1 Thermoelectric properties of superlattice films with x Å TTIP interlayers 42 3.2.2 Interface modification by depositing HfO2 at the interface of TiO2 and ZnO 50 3.3 Interlayer of mixing TiO2 and HfO2 55 3.3.1 Mixing interlayer oxides of TiO2 (TDMAT) and HfO2 55 3.3.2 Mixing interlayer oxides of TiO2 (TTIP) and HfO2 60 Chapter 4 Conclusions 64 REFERENCE 66
dc.language.iso	en
dc.subject	薄膜熱電材料	zh_TW
dc.subject	原子層沉積技術	zh_TW
dc.subject	氧化鋅	zh_TW
dc.subject	超晶格薄膜	zh_TW
dc.subject	能量過濾效應	zh_TW
dc.subject	superlattice films	en
dc.subject	thin film thermoelectric	en
dc.subject	atomic layer deposition	en
dc.subject	energy filtering effect	en
dc.subject	Zinc oxide	en
dc.title	原子層沉積金屬氧化物熱電性質研究：不同氧化物插層對鉿摻雜氧化鋅薄膜之影響	zh_TW
dc.title	Effects of Different Oxide Interlayers on the Thermoelectric Properties of Hafnium Doped Zinc Oxide Thin Films by Atomic Layer Deposition	en
dc.type	Thesis
dc.date.schoolyear	108-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳敏璋(Miin-Jang Chen),郭錦龍(Chin-Lung Kuo)
dc.subject.keyword	薄膜熱電材料,原子層沉積技術,氧化鋅,超晶格薄膜,能量過濾效應,	zh_TW
dc.subject.keyword	thin film thermoelectric,atomic layer deposition,Zinc oxide,superlattice films,energy filtering effect,	en
dc.relation.page	72
dc.identifier.doi	10.6342/NTU202003868
dc.rights.note	有償授權
dc.date.accepted	2020-08-19
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	材料科學與工程學研究所	zh_TW
顯示於系所單位：	材料科學與工程學系

文件中的檔案：

檔案	大小	格式
U0001-1708202021154800.pdf 未授權公開取用	2.53 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。