參考文獻 |
[1] Kucheyev, S. O., Bradby, J. E., Williams, J. S., Jagadish, C., & Swain, M. V. (2002). Mechanical deformation of single-crystal ZnO. Applied Physics Letters, 80(6), 956-958.
[2] Kucheyev, S. O., Bradby, J. E., Williams, J. S., Jagadish, C., Toth, M., Phillips, M. R., & Swain, M. V. (2000). Nanoindentation of epitaxial GaN films. Applied Physics Letters, 77(21), 3373-3375.
[3] 黃淑綺. (2006). 以反應式濺鍍製備氧化鋅薄膜及其摻雜之研究 (Doctoral dissertation, 撰者).
[4] Schröer, P. (1993). Peter krüger, and Johannes Pollmann. Physical Review B, 47, 12.
[5] Özgür, Ü., et al. (2005). A comprehensive review of ZnO materials and devices. Journal of applied physics, 98(4), 11.
[6] McCluskey, M. D., & Jokela, S. J. (2009). Defects in zno. Journal of Applied Physics, 106(7), 10.
[7] Van de Walle, C. G. (2000). Hydrogen as a cause of doping in zinc oxide. Physical review letters, 85(5), 1012.
[8] Kato, H., Sano, M., Miyamoto, K., & Yao, T. (2002). Growth and characterization of Ga-doped ZnO layers on a-plane sapphire substrates grown by molecular beam epitaxy. Journal of Crystal Growth, 237, 538-543.
[9] Van de Walle, C. G. (2001). Defect analysis and engineering in ZnO. Physica B: Condensed Matter, 308, 899-903.
[10] Park, C. H., Zhang, S. B., & Wei, S. H. (2002). Origin of p-type doping difficulty in ZnO: The impurity perspective. Physical Review B, 66(7), 073202.
[11] Matsubara, M., Godet, J., Pizzagalli, L., & Bellotti, E. (2013). Properties of threading screw dislocation core in wurtzite GaN studied by Heyd-Scuseria-Ernzerhof hybrid functional. Applied Physics Letters, 103(26), 262107.
[12] 盧宥任, 謝余松, & 張益三. (2012). 橢圓偏光術於 ITO 透明導電膜量測應用 (上). 光連: 光電產業與技術情報, (98), 61-64.
[13] Sahu, D. R., & Huang, J. L. (2006). Characteristics of ZnO–Cu–ZnO multilayer films on copper layer properties. Applied Surface Science, 253(2), 827-832.
[14] Sahu, D. R., & Huang, J. L. (2006). Dependence of film thickness on the electrical and optical properties of ZnO–Cu–ZnO multilayers. Applied Surface Science, 253(2), 915-918.
[15] Sahu, D. R., Lin, S. Y., & Huang, J. L. (2007). Improved properties of Al-doped ZnO film by electron beam evaporation technique. Microelectronics Journal, 38(2), 245-250.
[16] Sahu, D. R., & Huang, J. L. (2007). The properties of ZnO/Cu/ZnO multilayer films before and after annealing in the different atmosphere. Thin Solid Films, 516(2-4), 208-211.
[17] Sahu, D. R., & Huang, J. L. (2007). Properties of ZnO/Cu/ZnO multilayer films deposited by simultaneous RF and DC magnetron sputtering at different substrate temperatures. Microelectronics journal, 38(3), 299-303.
[18] Sivaramakrishnan, K., Theodore, N. D., Moulder, J. F., & Alford, T. L. (2009). The role of copper in ZnO/Cu/ZnO thin films for flexible electronics. Journal of Applied Physics, 106(6), 063510.
[19] Tsukazaki, A., et al. (2005). Repeated temperature modulation epitaxy for p-type doping and light-emitting diode based on ZnO. Nature materials, 4(1), 42-46.
[20] Song, K., Noh, J., Jun, T., Jung, Y., Kang, H. Y., & Moon, J. (2010). Fully flexible solution‐deposited ZnO thin‐film transistors. Advanced materials, 22(38), 4308-4312.
[21] Ju, S., et al. (2007). Fabrication of fully transparent nanowire transistors for transparent and flexible electronics. Nature nanotechnology, 2(6), 378-384.
[22] Zhang, Y. H., Mei, Z. X., Liang, H. L., & Du, X. L. (2017). Review of flexible and transparent thin-film transistors based on zinc oxide and related materials. Chinese Physics B, 26(4), 047307.
[23] 林偉祺, & 張立. (2007). 水溶液法成長氧化鋅薄膜及其薄膜電晶體製作 (Doctoral dissertation).
[24] 曾心如, & 張立. (2013). 以水熱法在異質基板上成長氧化鋅之研究 (Doctoral dissertation).
[25] Guillen, C., & Herrero, J. (2011). TCO/metal/TCO structures for energy and flexible electronics. Thin Solid Films, 520(1), 1-17.
[26] Kumar, M. H., Yantara, N., Dharani, S., Graetzel, M., Mhaisalkar, S., Boix, P. P., & Mathews, N. (2013). Flexible, low-temperature, solution processed ZnO-based perovskite solid state solar cells. Chemical Communications, 49(94), 11089-11091.
[27] Fu, Y., et al. (2012). Fiber supercapacitors utilizing pen ink for flexible/wearable energy storage. Advanced materials, 24(42), 5713-5718.
[28] Lee, S. P., et al. (2018). Highly flexible, wearable, and disposable cardiac biosensors for remote and ambulatory monitoring. NPJ digital medicine, 1(1), 1-8.
[29] Liang, X., et al. (2018). High performance all-solid-state flexible supercapacitor for wearable storage device application. Chemical Engineering Journal, 345, 186-195.
[30] Xie, T., Zhang, L., Wang, Y., Wang, Y., & Wang, X. (2019). Graphene-based supercapacitors as flexible wearable sensor for monitoring pulse-beat. Ceramics International, 45(2), 2516-2520.
[31] Wang, D., Zhang, Y., Lu, X., Ma, Z., Xie, C., & Zheng, Z. (2018). Chemical formation of soft metal electrodes for flexible and wearable electronics. Chemical Society Reviews, 47(12), 4611-4641.
[32] Kim, C. S., et al. (2018). Self-powered wearable electrocardiography using a wearable thermoelectric power generator. ACS Energy Letters, 3(3), 501-507.
[33] Zhao, G., et al. (2016). Bendable solar cells from stable, flexible, and transparent conducting electrodes fabricated using a nitrogen‐doped ultrathin copper film. Advanced Functional Materials, 26(23), 4180-4191.
[34] Jeong, C. K., et al. (2014). Self-powered fully-flexible light-emitting system enabled by flexible energy harvester. Energy & Environmental Science, 7(12), 4035-4043.
[35] Alzoubi, K., Hamasha, M. M., Lu, S., & Sammakia, B. (2011). Bending fatigue study of sputtered ITO on flexible substrate. Journal of Display Technology, 7(11), 593-600.
[36] Cairns, D. R., Witte, R. P., Sparacin, D. K., Sachsman, S. M., Paine, D. C., Crawford, G. P., & Newton, R. R. (2000). Strain-dependent electrical resistance of tin-doped indium oxide on polymer substrates. Applied Physics Letters, 76(11), 1425-1427.
[37] Lian, J., Zhang, D., Hong, R., Qiu, P., Lv, T., & Zhang, D. (2018). Defect-induced tunable permittivity of epsilon-near-zero in indium tin oxide thin films. Nanomaterials, 8(11), 922.
[38] Kang, N. R., Kim, Y. C., Jeon, H., Kim, S. K., Jang, J. I., Han, H. N., & Kim, J. Y. (2017). Wall-thickness-dependent strength of nanotubular ZnO. Scientific reports, 7(1), 1-10.
[39] Bagal, A., Dandley, E. C., Zhao, J., Zhang, X. A., Oldham, C. J., Parsons, G. N., & Chang, C. H. (2015). Multifunctional nano-accordion structures for stretchable transparent conductors. Materials Horizons, 2(5), 486-494.
[40] Lee, B. R., Park, J. H., Lee, T. H., & Kim, T. G. (2019). Highly flexible and transparent memristive devices using cross-stacked oxide/metal/oxide electrode layers. ACS applied materials & interfaces, 11(5), 5215-5222.
[41] Jian, S. R. (2015). Pop-in effects and dislocation nucleation of c-plane single-crystal ZnO by Berkovich nanoindentation. Journal of Alloys and Compounds, 644, 54-58.
[42] Sung, T. H., Huang, J. C., Hsu, J. H., Jian, S. R., & Nieh, T. G. (2012). Yielding and plastic slip in ZnO. Applied Physics Letters, 100(21), 211903.
[43] Han, X., et al. (2007). Low-temperature in situ large strain plasticity of ceramic SiC nanowires and its atomic-scale mechanism. Nano letters, 7(2), 452-457.
[44] Frankberg, E. J., et al. (2019). Highly ductile amorphous oxide at room temperature and high strain rate. Science, 366(6467), 864-869.
[45] Narayan, B., et al. (2018). Electrostrain in excess of 1% in polycrystalline piezoelectrics. Nature materials, 17(5), 427-431.
[46] Miccoli, I., Edler, F., Pfnür, H., & Tegenkamp, C. (2015). The 100th anniversary of the four-point probe technique: the role of probe geometries in isotropic and anisotropic systems. Journal of Physics: Condensed Matter, 27(22), 223201.
[47] Day, R. B., & Stokes, R. J. (1966). Mechanical behavior of polycrystalline magnesium oxide at high temperatures. Journal of the American Ceramic Society, 49(7), 345-355.
[48] Wang, J. G., & Raj, R. (1984). Mechanism of superplastic flow in a fine‐grained ceramic containing some liquid phase. Journal of the American Ceramic Society, 67(6), 399-409.
[49] WAKAI, F., SAKAGUCHI, S., & MATSUNO, Y. (1986). Superplasticity of yttria-stabilized tetragonal ZrO 2 polycrystals. Advanced ceramic materials, 1(3), 259-263.
[50] Nieh, T. G., & Wadsworth, J. (1990). Superelastic behaviour of a fine-grained, yttria-stabilized, tetragonal zirconia polycrystal (Y-TZP). Acta Metallurgica et Materialia, 38(6), 1121-1133.
[51] Wakai, F., Kodama, Y., Sakaguchi, S., Murayama, N., Izaki, K., & Niihara, K. (1990). A superplastic covalent crystal composite. Nature, 344(6265), 421-423.
[52] Wakai, F., Kodama, Y., Sakaguchi, S., & Nonami, T. (1990). Superplasticity of hot isostatically pressed hydroxyapatite. Journal of the American Ceramic Society, 73(2), 457-460.
[53] Yoshizawa, Y., & Sakuma, T. (1992). Improvement of tensile ductility in high-purity alumina due to magnesia addition. Acta metallurgica et materialia, 40(11), 2943-2950.
[54] Xue, L. A., & Chen, I. W. (1992). Fabrication of mullite body using superplastic transient phase. Journal of the American Ceramic Society, 75(5), 1085-1091.
[55] Kajihara, K., Yoshizawa, Y., & Sakuma, T. (1993). Superplasticity in SiO2-containing tetragonal zirconia polycrystal. Scripta metallurgica et materialia, 28(5), 559-562.
[56] Karch, J., Birringer, R., & Gleiter, H. (1987). Ceramics ductile at low temperature. Nature, 330(6148), 556-558.
[57] Cogotsi, G. A., Zavada, V. P., & Kharitonov, F. Y. (1984). Strength and crack resistance of ceramics. Report No. 1. Cordierite. Strength of Materials, 16(12), 1651-1655.
[58] Fan, Y., Igarashi, G., Jiang, W., Wang, L., & Kawasaki, A. (2015). Highly strain tolerant and tough ceramic composite by incorporation of graphene. Carbon, 90, 274-283.
[59] Estili, M., Sakka, Y., & Kawasaki, A. (2013). Unprecedented simultaneous enhancement in strain tolerance, toughness and strength of Al2O3 ceramic by multiwall-type failure of a high loading of carbon nanotubes. Nanotechnology, 24(15), 155702.
[60] Gogotsi, G. A. (1987). Problems in studies of the strength characteristics of ceramics. Zavodskaia Laboratoriia, 53(10), 69-75.
[61] Gogotsi, G. A. (1991). Deformational behaviour of ceramics. Journal of the European Ceramic Society, 7(2), 87-92.
[62] Gogotsi, G. A., Komolikov, Y. I., Ostrovoi, D. Y., Pliner, S. Y., Rutman, D. S., & Toropov, Y. S. (1988). Strength and crack resistance of ceramics based on zirconium dioxide. Strength of Materials, 20(1), 61-64.
[63] Hengst, C., et al. (2017). Mechanical properties of ZTO, ITO, and a-Si: H multilayer films for flexible thin film solar cells. Materials, 10(3), 245.
[64] Reder, C., et al. (2003). Non-contacting strain measurements of ceramic and carbon single fibres by using the laser-speckle method. Composites Part A: Applied Science and Manufacturing, 34(11), 1029-1033.
[65] Kaps, S., et al. (2017). Piezoresistive response of quasi-one-dimensional ZnO nanowires using an in situ electromechanical device. Acs Omega, 2(6), 2985-2993.
[66] Vazinishayan, A., Yang, S., Lambada, D. R., Zhang, G., & Wang, Y. (2018). Investigation of the effects of tensile strain on optical properties of ZnO nanowire. Chinese journal of physics, 56(5), 1799-1809.
[67] Tuyaerts, R., Raskin, J. P., & Proost, J. (2017, March). Electromechanical testing of ZnO thin films under high uniaxial strain. In 2017 International Conference of Microelectronic Test Structures (ICMTS) (pp. 1-4). IEEE.
[68] He, J., Wu, J., Nagao, S., Qiao, L., & Zhang, Z. (2017). Size-dependent Phase Transformation and Fracture of ZnO Nanowires. Procedia IUTAM, 21, 86-93.
[69] Wang, W., Pi, Z., Lei, F., & Lu, Y. (2016). Understanding the tensile behaviors of ultra-thin ZnO nanowires via molecular dynamics simulations. AIP Advances, 6(3), 035111.
[70] Vazinishayan, A., et al. (2018). Effects of mechanical strain on optical properties of ZnO nanowire. AIP Advances, 8(2), 025306.
[71] Stan, C. V., O’Bannon, E. F., Mukhin, P., Tamura, N., & Dobrzhinetskaya, L. (2020). X-ray laue microdiffraction and raman spectroscopic investigation of natural silicon and moissanite. Minerals, 10(3), 204.
[72] St G, M., et al. (2000). The status of SiC bulk growth from an industrial point of view. Journal of Crystal Growth, 211(1-4), 325-332.
[73] Gaboriaud, R. J. Dislocations in Anion-Deficient Fluorite-type Oxides under harsh environment: RE2O3, Pyrochlores, δ-Phase.
[74] Skrotzki, W., & Siegesmund, S. (1993). Cordierite microstructure and texture in a Moldanubian gneiss. Physics and Chemistry of Minerals, 19(6), 401-408.
[75] van Roermund, H. L., & Konert, R. J. (1990). Deformation and recrystallisation mechanisms in naturally deformed cordierite. Physics and Chemistry of Minerals, 17(1), 52-61.
[76] Portelette, L., Amodeo, J., Madec, R., Soulacroix, J., Helfer, T., & Michel, B. (2018). Crystal viscoplastic modeling of UO2 single crystal. Journal of Nuclear Materials, 510, 635-643.
[77] Niki, K., Mochimaru, G., & Shindo, H. (2012). Participation of {1 0 0}< 0 1 1> Slip System in Sliding Friction at (0 0 1),(1 1 1) and (1 1 0) Surfaces of Fluorite (CaF2) Crystal. Tribology Online, 7(2), 81-86.
[78] Sekine, T., & Kobayashi, T. (2011). Time-resolved measurement of high-pressure phase transition of fluorite under shock loading. Physics and Chemistry of Minerals, 38(4), 305-310.
[79] Lu, W., Wang, H., Hu, Y., Huang, H., & Gu, H. (2009). First-principles prediction of the hardness of fluorite TiO2. Physica B: Condensed Matter, 404(1), 79-81.
[80] Heuer, A. H., Keller, R. J., & Mitchell, T. E. (1990). On the slip systems in uranium dioxide. In Deformation Processes in Minerals, Ceramics and Rocks (pp. 377-390). Springer, Dordrecht.
[81] Mann, A. W. (1974). Structural relationships and mechanisms for the stoichiometry change from MX3 (YF3-type) through MX2 (fluorite-type) to M2X3 (C-type sesquioxide). Journal of Solid State Chemistry, 11(2), 94-105.
[82] Brookes, C. A., O’neill, J. B., & Redfern, B. A. W. (1971). Anisotropy in the hardness of single crystals. Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences, 322(1548), 73-88.
[83] Brantley, W. A., & Bauer, C. L. (1970). Geometric analysis of charged dislocations in the fluorite structure. physica status solidi (b), 40(2), 707-715.
[84] Ashbee, K. H. G., & Frank, F. C. (1970). Dislocations in the fluorite structure. Philosophical Magazine, 21(169), 211-213.
[85] Carrez, P., Goryaeva, A. M., & Cordier, P. (2017). Prediction of mechanical twinning in magnesium silicate post-perovskite. Scientific reports, 7(1), 1-9.
[86] Gouriet, K., Carrez, P., & Cordier, P. (2014). Modelling [1 0 0] and [0 1 0] screw dislocations in MgSiO3 perovskite based on the Peierls–Nabarro–Galerkin model. Modelling and Simulation in Materials Science and Engineering, 22(2), 025020.
[87] Metsue, A., & Tsuchiya, T. (2013). Shear response of Fe-bearing MgSiO3 post-perovskite at lower mantle pressures. Proceedings of the Japan Academy, Series B, 89(1), 51-58.
[88] Miyagi, L., Kanitpanyacharoen, W., Kaercher, P., Lee, K. K., & Wenk, H. R. (2010). Slip systems in MgSiO3 post-perovskite: implications for D′′ anisotropy. Science, 329(5999), 1639-1641.
[89] Miyajima, N., & Walte, N. (2009). Burgers vector determination in deformed perovskite and post-perovskite of CaIrO3 using thickness fringes in weak-beam dark-field images. Ultramicroscopy, 109(6), 683-692.
[90] Miyagi, L., et al. (2008). Deformation and texture development in CaIrO3 post-perovskite phase up to 6 GPa and 1300 K. Earth and Planetary Science Letters, 268(3-4), 515-525.
[91] Mainprice, D., Tommasi, A., Ferré, D., Carrez, P., & Cordier, P. (2008). Predicted glide systems and crystal preferred orientations of polycrystalline silicate Mg-Perovskite at high pressure: Implications for the seismic anisotropy in the lower mantle. Earth and Planetary Science Letters, 271(1-4), 135-144.
[92] Carrez, P., Ferré, D., & Cordier, P. (2007). Peierls–Nabarro model for dislocations in MgSiO3 post-perovskite calculated at 120 GPa from first principles. Philosophical Magazine, 87(22), 3229-3247.
[93] Ferré, D., Carrez, P., & Cordier, P. (2007). First principles determination of dislocations properties of MgSiO3 perovskite at 30 GPa based on the Peierls–Nabarro model. Physics of the Earth and Planetary Interiors, 163(1-4), 283-291.
[94] Yamazaki, D., Yoshino, T., Ohfuji, H., Ando, J. I., & Yoneda, A. (2006). Origin of seismic anisotropy in the D ″layer inferred from shear deformation experiments on post-perovskite phase. Earth and Planetary Science Letters, 252(3-4), 372-378.
[95] Wang, Z., Karato, S. I., & Fujino, K. (1993). High temperature creep of single crystal strontium titanate (SrTiO3): a contribution to creep systematics in perovskites. Physics of the earth and planetary interiors, 79(3-4), 299-312.
[96] Grundmann, M. (2020). Universal relation for the orientation of dislocations from prismatic slip systems in hexagonal and rhombohedral strained heterostructures. Applied Physics Letters, 116(8), 082104.
[97] Heuer, A. H., Lagerlöf, K. P. D., & Castaing, J. (1998). Slip and twinning dislocations in sapphire (α-Al2O3). Philosophical Magazine A, 78(3), 747-763.
[98] Lagerlöf, K. P. D. (1995). Basal Slip and Twinning in Sapphire (α-Al 2 O 3). In Plastic Deformation of Ceramics (pp. 63-74). Springer, Boston, MA.
[99] Lagerlöf, K. P. D., Heuer, A. H., Castaing, J., Rivière, J. P., & Mitchell, T. E. (1994). Slip and twinning in sapphire (α‐Al2O3). Journal of the American Ceramic Society, 77(2), 385-397.
[100] Kotchick, D. M., & Tressler, R. E. (1980). Deformation behavior of sapphire via the prismatic slip system. Journal of the American Ceramic Society, 63(7‐8), 429-434.
[101] Snow, J. D., & Heuer, A. H. (1973). Slip systems in Al2O3. Journal of the American Ceramic Society, 56(3), 153-157.
[102] Klassen‐Neklyudova, M. V., Govorkov, V. G., Urusovskaya, A. A., Voinova, N. N., & Kozlovskaya, E. P. (1970). Plastic deformation of corundum single crystals. physica status solidi (b), 39(2), 679-688.
[103] May, C. A., & Ashbee, K. H. G. (1969). Deformation kinking in the corundum structure. Micron (1969), 1(1), 62-69.
[104] Xue, D. J., et al. (2020). Regulating strain in perovskite thin films through charge-transport layers. Nature communications, 11(1), 1-8.
[105] Ko, Y. H., Kim, M. S., & Yu, J. S. (2012). Controllable electrochemical synthesis of ZnO nanorod arrays on flexible ITO/PET substrate and their structural and optical properties. Applied surface science, 259, 99-104.
[106] Demirel, B., Yaraş, A., & Elçiçek, H. (2011). Crystallization behavior of PET materials.
[107] Persson, K. (2019). Materials Data on ZnO (SG: 186) by Materials Project.
[108] De Jong, M., et al. (2015). Charting the complete elastic properties of inorganic crystalline compounds. Scientific data, 2(1), 1-13.
[109] Cabrera-Covarrubias, F. G., Gómez-Soberón, J. M., Almaral-Sánchez, J. L., Arredondo-Rea, S. P., Gómez-Soberón, M. C., & Corral-Higuera, R. (2016). An experimental study of mortars with recycled ceramic aggregates: Deduction and prediction of the stress-strain. Materials, 9(12), 1029.
[110] Hetnarski, R. B. (Ed.). (2014). Encyclopedia of thermal stresses (p. 6643). Dordrecht: Springer Netherlands.
[111] Gogotsi, G. A., Lomonova, E. E., & Pejchev, V. G. (1993). Strength and fracture toughness of zirconia crystals. Journal of the European Ceramic Society, 11(2), 123-132.
[112] Gogotsi, G. A., Komolikov, Y. I., Ostrovoj, D. Y., Pliner, S. Y., Rutman, D. S., & Toropov, Y. S. (1988). Strength and crack resistance of ceramics on zirconium dioxide base. Problemy Prochnosti, 50-52.
[113] Tamayo-Arriola, J., Huerta-Barberà, A., Montes Bajo, M., Muñoz, E., Muñoz-Sanjosé, V., & Hierro, A. (2018). Rock-salt CdZnO as a transparent conductive oxide. Applied Physics Letters, 113(22), 222101.
[114] Ephraim, J., Lanigan, D., Staller, C., Milliron, D. J., & Thimsen, E. (2016). Transparent conductive oxide nanocrystals coated with insulators by atomic layer deposition. Chemistry of Materials, 28(15), 5549-5553.
[115] Hajibabaei, H., Zandi, O., & Hamann, T. W. (2016). Tantalum nitride films integrated with transparent conductive oxide substrates via atomic layer deposition for photoelectrochemical water splitting. Chemical science, 7(11), 6760-6767.
[116] Zeumault, A., & Subramanian, V. (2016). Mobility Enhancement in Solution‐Processed Transparent Conductive Oxide TFTs due to Electron Donation from Traps in High‐k Gate Dielectrics. Advanced Functional Materials, 26(6), 955-963.
[117] Chueh, C. C., Chen, C. I., Su, Y. A., Konnerth, H., Gu, Y. J., Kung, C. W., & Wu, K. C. W. (2019). Harnessing MOF materials in photovoltaic devices: recent advances, challenges, and perspectives. Journal of Materials Chemistry A, 7(29), 17079-17095.
[118] Lee, C. C., Chen, C. I., Liao, Y. T., Wu, K. C. W., & Chueh, C. C. (2019). Enhancing efficiency and stability of photovoltaic cells by using perovskite/Zr‐MOF heterojunction including bilayer and hybrid structures. Advanced Science, 6(5), 1801715.
[119] Liao, Y. T., Ishiguro, N., Young, A. P., Tsung, C. K., & Wu, K. C. W. (2020). Engineering a homogeneous alloy-oxide interface derived from metal-organic frameworks for selective oxidation of 5-hydroxymethylfurfural to 2, 5-furandicarboxylic acid. Applied Catalysis B: Environmental, 270, 118805.
[120] Konnerth, H., Matsagar, B. M., Chen, S. S., Prechtl, M. H., Shieh, F. K., & Wu, K. C. W. (2020). Metal-organic framework (MOF)-derived catalysts for fine chemical production. Coordination Chemistry Reviews, 416, 213319.
[121] Ci, J., Cao, C., Kuga, S., Shen, J., Wu, M., & Huang, Y. (2017). Improved performance of microbial fuel cell using esterified corncob cellulose nanofibers to fabricate air-cathode gas diffusion layer. ACS Sustainable Chemistry & Engineering, 5(11), 9614-9618.
[122] Wu, S., Yuan, S., Shi, L., Zhao, Y., & Fang, J. (2010). Preparation, characterization and electrical properties of fluorine-doped tin dioxide nanocrystals. Journal of colloid and interface science, 346(1), 12-16.
[123] Wang, J., et al. (2012). Oxygen vacancy induced band-gap narrowing and enhanced visible light photocatalytic activity of ZnO. ACS applied materials & interfaces, 4(8), 4024-4030.
[124] Zhou, T., & Gall, D. (2018). Resistivity scaling due to electron surface scattering in thin metal layers. Physical Review B, 97(16), 165406.
[125] Chiu, F. C. (2014). A review on conduction mechanisms in dielectric films. Advances in Materials Science and Engineering, 2014.
[126] 李正中. (2004). 薄膜光學與鍍膜技術.
[127] McPeak, K. M., Jayanti, S. V., Kress, S. J., Meyer, S., Iotti, S., Rossinelli, A., & Norris, D. J. (2015). Plasmonic films can easily be better: rules and recipes. ACS photonics, 2(3), 326-333.
[128] Al-Kuhaili, M. F., Alade, I. O., & Durrani, S. M. A. (2014). Optical constants of hydrogenated zinc oxide thin films. Optical Materials Express, 4(11), 2323-2331.
[129] Raut, H. K., Ganesh, V. A., Nair, A. S., & Ramakrishna, S. (2011). Anti-reflective coatings: A critical, in-depth review. Energy & Environmental Science, 4(10), 3779-3804. |