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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 陳建彰 | zh_TW |
dc.contributor.advisor | Jian-Zhang Chen | en |
dc.contributor.author | 蔡定緯 | zh_TW |
dc.contributor.author | Ting-Wei Tsai | en |
dc.date.accessioned | 2023-08-09T16:31:49Z | - |
dc.date.available | 2023-11-09 | - |
dc.date.copyright | 2023-08-09 | - |
dc.date.issued | 2023 | - |
dc.date.submitted | 2023-07-11 | - |
dc.identifier.citation | 1. Benhaddouch, T.E., et al., Micro-Fuel Cell Principal Biosensors for Monitoring Transdermal Volatile Organic Compounds in Humans. ECS Sensors Plus, 2022. 1(4): p. 041602.
2. Young, S.-J. and Y.-H. Liu, Perspective—Doped ZnO Nanostructures Based on Ultraviolet Photosensors. ECS Sensors Plus, 2022. 1(4): p. 043602. 3. Gautam, A., Towards modern-age advanced sensors for the management of neurodegenerative disorders: current status, challenges and prospects. ECS Sensors Plus, 2022. 4. Moonla, C., et al., Lab-in-a-mouth and advanced point-of-care sensing systems: detecting bioinformation from the oral cavity and saliva. ECS Sensors Plus, 2022. 1(2): p. 021603. 5. Upasham, S., et al., Passive sweat-based pruritic cytokine detection and monitoring system. ECS Sensors Plus, 2022. 1(3): p. 031602. 6. Das, S.K., et al., Electrochemistry and other emerging technologies for continuous glucose monitoring devices. ECS Sensors Plus, 2022. 7. Scott, A., et al., A Smartphone Operated Electrochemical Reader and Actuator that Streamlines the Operation of Electrochemical Biosensors. ECS Sensors Plus, 2022. 1(1): p. 014601. 8. Chaudhary, V., et al., Towards 5th generation ai and iot driven sustainable intelligent sensors based on 2d mxenes and borophene. ECS Sensors Plus, 2022. 9. Feng, T., et al., A robust mixed‐lanthanide polyMOF membrane for ratiometric temperature sensing. Angewandte Chemie, 2020. 132(48): p. 21936-21941. 10. Guan, X., et al., Carbon nanotubes-adsorbed electrospun PA66 nanofiber bundles with improved conductivity and robust flexibility. ACS applied materials & interfaces, 2016. 8(22): p. 14150-14159. 11. Hong, S.Y., et al., Stretchable active matrix temperature sensor array of polyaniline nanofibers for electronic skin. Advanced materials, 2016. 28(5): p. 930-935. 12. Bae, G.Y., et al., Pressure/temperature sensing bimodal electronic skin with stimulus discriminability and linear sensitivity. Advanced Materials, 2018. 30(43): p. 1803388. 13. Byun, J., et al., Electronic skins for soft, compact, reversible assembly of wirelessly activated fully soft robots. Science Robotics, 2018. 3(18): p. eaas9020. 14. Park, D., et al. Design of wireless temperature monitoring system for measurement of magnet temperature of IPMSM. in 2018 IEEE Transportation Electrification Conference and Expo (ITEC). 2018. IEEE. 15. Liu, D., et al., A new kind of thermocouple made of p-type and n-type semi-conductive oxides with giant thermoelectric voltage for high temperature sensing. Journal of Materials Chemistry C, 2018. 6(13): p. 3206-3211. 16. Kanao, K., et al., Highly selective flexible tactile strain and temperature sensors against substrate bending for an artificial skin. Rsc Advances, 2015. 5(38): p. 30170-30174. 17. Ozioko, O., Y. Kumaresan, and R. Dahiya. Carbon nanotube/PEDOT: PSS composite-based flexible temperature sensor with enhanced response and recovery time. in 2020 IEEE International Conference on Flexible and Printable Sensors and Systems (FLEPS). 2020. IEEE. 18. Gao, W., et al., Efficient carbon nanotube/polyimide composites exhibiting tunable temperature coefficient of resistance for multi-role thermal films. Composites Science and Technology, 2020. 199: p. 108333. 19. Gao, F.-L., et al., Integrated temperature and pressure dual-mode sensors based on elastic PDMS foams decorated with thermoelectric PEDOT: PSS and carbon nanotubes for human energy harvesting and electronic-skin. Journal of Materials Chemistry A, 2022. 20. Vuorinen, T., et al., Inkjet-printed graphene/PEDOT: PSS temperature sensors on a skin-conformable polyurethane substrate. Scientific reports, 2016. 6(1): p. 1-8. 21. Seifi, M., S. Hamedi, and Z. Kordrostami, Fabrication of a high-sensitive wearable temperature sensor with an improved response time based on PEDOT: PSS/rGO on a flexible kapton substrate. Journal of Materials Science: Materials in Electronics, 2022. 33(9): p. 6954-6968. 22. Yu, Y., et al., Wearable temperature sensors with enhanced sensitivity by engineering microcrack morphology in PEDOT: PSS–PDMS sensors. ACS applied materials & interfaces, 2020. 12(32): p. 36578-36588. 23. Soni, M., et al., Printed temperature sensor based on PEDOT: PSS-graphene oxide composite. IEEE Sensors Journal, 2020. 20(14): p. 7525-7531. 24. Kim, B.-J., S.-H. Han, and J.-S. Park, Sheet resistance, transmittance, and chromatic property of CNTs coated with PEDOT: PSS films for transparent electrodes of touch screen panels. Thin Solid Films, 2014. 572: p. 68-72. 25. Tian, Y., et al., Improved resistance stability of transparent conducting films prepared by PEDOT: PSS hybrid CNTs treated by a two-step method. Materials Research Express, 2019. 6(11): p. 116425. 26. Kumaresan, Y., O. Ozioko, and R. Dahiya, Multifunctional electronic skin with a stack of temperature and pressure sensor arrays. IEEE Sensors Journal, 2021. 21(23): p. 26243-26251. 27. Chen, C.-H., et al., Superhydrophobic, Oleophobic, Self-Cleaning Flexible Wearable Temperature Sensing Device. ECS Advances, 2022. 1(3): p. 036502. 28. Honda, W., et al. Printed wearable temperature sensor for health monitoring. in SENSORS, 2014 IEEE. 2014. IEEE. 29. Yang, J.C., et al., Electronic skin: recent progress and future prospects for skin‐attachable devices for health monitoring, robotics, and prosthetics. Advanced Materials, 2019. 31(48): p. 1904765. 30. Vedel, J. and J. Roll, Response to pressure and vibration of slowly adapting cutaneous mechanoreceptors in the human foot. Neuroscience letters, 1982. 34(3): p. 289-294. 31. Guo, H., et al., Transparent, flexible, and stretchable WS2 based humidity sensors for electronic skin. Nanoscale, 2017. 9(19): p. 6246-6253. 32. Wang, X., et al., Dynamic pressure mapping of personalized handwriting by a flexible sensor matrix based on the mechanoluminescence process. Advanced Materials, 2015. 27(14): p. 2324-2331. 33. Chen, J., et al., Self-healing materials-based electronic skin: mechanism, development and applications. Gels, 2022. 8(6): p. 356. 34. Park, J., et al., Micro/nanostructured surfaces for self-powered and multifunctional electronic skins. Journal of Materials Chemistry B, 2016. 4(18): p. 2999-3018. 35. Song, K.W., et al. Lotio: Lotion-Mediated Interaction with an Electronic Skin-Worn Display. in Proceedings of the 2023 CHI Conference on Human Factors in Computing Systems. 2023. 36. Yu, Y., et al., Biofuel-powered soft electronic skin with multiplexed and wireless sensing for human-machine interfaces. Science robotics, 2020. 5(41): p. eaaz7946. 37. Shih, B., et al., Electronic skins and machine learning for intelligent soft robots. Science Robotics, 2020. 5(41): p. eaaz9239. 38. Hou, C., et al., Borophene pressure sensing for electronic skin and human-machine interface. Nano Energy, 2022. 97: p. 107189. 39. Zarei, M., et al., Advances in biodegradable electronic skin: Material progress and recent applications in sensing, robotics, and human–machine interfaces. Advanced Materials, 2023. 35(4): p. 2203193. 40. Someya, T. and M. Amagai, Toward a new generation of smart skins. Nature biotechnology, 2019. 37(4): p. 382-388. 41. Schwartz, G., et al., Flexible polymer transistors with high pressure sensitivity for application in electronic skin and health monitoring. Nature communications, 2013. 4(1): p. 1859. 42. Lee, H., et al., Wearable/disposable sweat-based glucose monitoring device with multistage transdermal drug delivery module. Science advances, 2017. 3(3): p. e1601314. 43. Wang, L., K. Jiang, and G. Shen, Wearable, implantable, and interventional medical devices based on smart electronic skins. Advanced Materials Technologies, 2021. 6(6): p. 2100107. 44. Wang, X., et al., Recent progress in electronic skin. Advanced Science, 2015. 2(10): p. 1500169. 45. Yang, W., et al., A breathable and screen‐printed pressure sensor based on nanofiber membranes for electronic skins. Advanced Materials Technologies, 2018. 3(2): p. 1700241. 46. He, Z., et al., Capacitive pressure sensor with high sensitivity and fast response to dynamic interaction based on graphene and porous nylon networks. ACS applied materials & interfaces, 2018. 10(15): p. 12816-12823. 47. Gao, Y., et al., Sandpaper-molded wearable pressure sensor for electronic skins. Sensors and Actuators A: Physical, 2018. 280: p. 205-209. 48. Tang, X., et al., Multilevel microstructured flexible pressure sensors with ultrahigh sensitivity and ultrawide pressure range for versatile electronic skins. Small, 2019. 15(10): p. 1804559. 49. Gao, Y., et al., Laser micro-structured pressure sensor with modulated sensitivity for electronic skins. Nanotechnology, 2019. 30(32): p. 325502. 50. Zeng, X., et al., Tunable, ultrasensitive, and flexible pressure sensors based on wrinkled microstructures for electronic skins. ACS applied materials & interfaces, 2019. 11(23): p. 21218-21226. 51. Liu, Q., et al., A high‐performances flexible temperature sensor composed of polyethyleneimine/reduced graphene oxide bilayer for real‐time monitoring. Advanced Materials Technologies, 2019. 4(3): p. 1800594. 52. Cui, Z., F.R. Poblete, and Y. Zhu, Tailoring the temperature coefficient of resistance of silver nanowire nanocomposites and their application as stretchable temperature sensors. ACS applied materials & interfaces, 2019. 11(19): p. 17836-17842. 53. Song, J., et al., Highly sensitive flexible temperature sensor made using PEDOT: PSS/PANI. ACS Applied Polymer Materials, 2022. 4(2): p. 766-772. 54. Zhu, G., et al., Highly flexible TPU/SWCNTs composite-based temperature sensors with linear negative temperature coefficient effect and photo-thermal effect. Composites Science and Technology, 2022. 217: p. 109133. 55. Zhou, K., et al., Tunable and Nacre‐Mimetic Multifunctional Electronic Skins for Highly Stretchable Contact‐Noncontact Sensing. Small, 2021. 17(31): p. 2100542. 56. Dai, Y. and S. Gao, A flexible multi-functional smart skin for force, touch position, proximity, and humidity sensing for humanoid robots. IEEE Sensors Journal, 2021. 21(23): p. 26355-26363. 57. Li, C., et al., Flexible, multi-functional sensor based on all-carbon sensing medium with low coupling for ultrahigh-performance strain, temperature and humidity sensing. Chemical Engineering Journal, 2021. 426: p. 130364. 58. Chen, L., et al., Stretchable and transparent multimodal electronic-skin sensors in detecting strain, temperature, and humidity. Nano Energy, 2022. 96: p. 107077. 59. Ahn, C., et al., Direct fabrication of thin film gold resistance temperature detection sensors on a curved surface using a flexible dry film photoresist and their calibration up to 450° C. Journal of Micromechanics and Microengineering, 2013. 23(6): p. 065031. 60. Joh, H., et al., Engineering the Charge Transport of Ag Nanocrystals for Highly Accurate, Wearable Temperature Sensors through All‐Solution Processes. Small, 2017. 13(24): p. 1700247. 61. Hua, Q., et al., Skin-inspired highly stretchable and conformable matrix networks for multifunctional sensing. Nature communications, 2018. 9(1): p. 244. 62. Turkani, V.S., et al., Nickel based RTD fabricated via additive screen printing process for flexible electronics. IEEE Access, 2019. 7: p. 37518-37527. 63. Singgih, S., M. Toifur, and S. Suryandari, Experimental Design in Constructing Low Temperature Sensor Based on Resistance Temperature Detector (RTD). Indonesian Journal of Science and Education, 2020. 4(2): p. 99-110. 64. Li, W., S. Xiong, and X. Zhou, Lead-Wire-Resistance compensation technique using a single zener diode for Two-Wire resistance temperature detectors (RTDs). Sensors, 2020. 20(9): p. 2742. 65. Maiti, T.K., A novel lead-wire-resistance compensation technique using two-wire resistance temperature detector. IEEE Sensors Journal, 2006. 6(6): p. 1454-1458. 66. Kamat, R.K. and G.M. Naik, Thermistors–in search of new applications, manufacturers cultivate advanced NTC techniques. Sensor Review, 2002. 67. EDN Taiwan. 電阻溫度偵測器配線. 2023; Available from: https://www.edntaiwan.com/20190901ta71-realization-of-a-fully-integrated-4-wire-rtd-temperature-measurement-system/. 68. Kuzubasoglu, B.A. and S.K. Bahadir, Flexible temperature sensors: A review. Sensors and Actuators A: Physical, 2020. 315: p. 112282. 69. Aggarwal, R. and S. Markanda, A review on thermocouple for power generation. International Journal of Applied Science and Engineering Research, 2012. 1(2): p. 98-105. 70. Shao, Q., et al., High-temperature quenching of electrical resistance in graphene interconnects. Applied Physics Letters, 2008. 92(20): p. 202108. 71. Sun, P., et al., Small temperature coefficient of resistivity of graphene/graphene oxide hybrid membranes. ACS applied materials & interfaces, 2013. 5(19): p. 9563-9571. 72. Sadasivuni, K.K., et al., Reduced graphene oxide filled cellulose films for flexible temperature sensor application. Synthetic Metals, 2015. 206: p. 154-161. 73. Di Bartolomeo, A., et al., Multiwalled carbon nanotube films as small-sized temperature sensors. Journal of Applied Physics, 2009. 105(6): p. 064518. 74. Xiao, Y., et al., Screen-printed flexible negative temperature coefficient temperature sensor based on polyvinyl chloride/carbon black composites. Smart Materials and Structures, 2021. 30(2): p. 025035. 75. Romarís, L.H., et al., Multifunctional electromechanical and thermoelectric polyaniline–poly (vinyl acetate) latex composites for wearable devices. Journal of Materials Chemistry C, 2018. 6(31): p. 8502-8512. 76. Mahadeva, S.K., S. Yun, and J. Kim, Flexible humidity and temperature sensor based on cellulose–polypyrrole nanocomposite. Sensors and Actuators A: Physical, 2011. 165(2): p. 194-199. 77. Khalaf, A.M., et al., Highly sensitive interdigitated thermistor based on PEDOT: PSS for human body temperature monitoring. Flexible and Printed Electronics, 2022. 7(4): p. 045012. 78. Khalaf, A.M., et al., All inkjet-printed temperature sensors based on PEDOT: PSS. IEEE Access, 2022. 10: p. 61094-61100. 79. Kuzubasoglu, B.A., E. Sayar, and S.K. Bahadir, Inkjet-printed CNT/PEDOT: PSS temperature sensor on a textile substrate for wearable intelligent systems. IEEE Sensors Journal, 2021. 21(12): p. 13090-13097. 80. Zhang, X., et al. A printed MWCNTs/PDMS based flexible resistive temperature detector. in 2020 IEEE International Conference on Electro Information Technology (EIT). 2020. IEEE. 81. Cui, J., et al., Fabrication and characterization of nickel thin film as resistance temperature detector. Vacuum, 2020. 176: p. 109288. 82. Yan, C., J. Wang, and P.S. Lee, Stretchable graphene thermistor with tunable thermal index. ACS nano, 2015. 9(2): p. 2130-2137. 83. Sahoo, S., S. Parashar, and S. Ali, CaTiO3 nano ceramic for NTCR thermistor based sensor application. Journal of Advanced Ceramics, 2014. 3(2): p. 117-124. 84. Kumar, S., et al., Laser patterned, high-power graphene paper resistor with dual temperature coefficient of resistance. RSC advances, 2019. 9(15): p. 8262-8270. 85. Ren, X., et al., A low‐operating‐power and flexible active‐matrix organic‐transistor temperature‐sensor array. Advanced materials, 2016. 28(24): p. 4832-4838. 86. Tsai, T.-W., et al., Effect of Solution Aging on Temperature Sensitivity of CNT/PEDOT: PSS. ECS Journal of Solid State Science and Technology, 2023. 12(2): p. 027001. 87. Fujii, T., PDMS-based microfluidic devices for biomedical applications. Microelectronic Engineering, 2002. 61: p. 907-914. 88. Raj M, K. and S. Chakraborty, PDMS microfluidics: A mini review. Journal of Applied Polymer Science, 2020. 137(27): p. 48958. 89. Chen, C.-H., I.-C. Cheng, and J.-Z. Chen, Facile method to convert petal effect surface to lotus effect surface for superhydrophobic polydimethylsiloxane. Surfaces and Interfaces, 2022. 30: p. 101901. 90. Khorasani, M. and H. Mirzadeh, In vitro blood compatibility of modified PDMS surfaces as superhydrophobic and superhydrophilic materials. Journal of applied polymer science, 2004. 91(3): p. 2042-2047. 91. Ammar, S., et al., Amelioration of anticorrosion and hydrophobic properties of epoxy/PDMS composite coatings containing nano ZnO particles. Progress in Organic Coatings, 2016. 92: p. 54-65. 92. Pretti, C., et al., An ecotoxicological study on tin-and bismuth-catalysed PDMS based coatings containing a surface-active polymer. Ecotoxicology and environmental safety, 2013. 98: p. 250-256. 93. Meuler, A.J., et al., Relationships between water wettability and ice adhesion. ACS applied materials & interfaces, 2010. 2(11): p. 3100-3110. 94. SiMPore Inc. PDMS sheet. 2023; Available from: https://simpore.com/product/pdms-sheet/. 95. Zahid, M., et al., Strain-responsive mercerized conductive cotton fabrics based on PEDOT: PSS/graphene. Materials & Design, 2017. 135: p. 213-222. 96. Abbasi, M.A.B., P. Vryonides, and S. Nikolaou. Humidity sensor devices using PEDOT: PSS. in 2015 IEEE International Symposium on Antennas and Propagation & USNC/URSI National Radio Science Meeting. 2015. IEEE. 97. Kang, T.-G., et al., A real-time humidity sensor based on a microwave oscillator with conducting polymer PEDOT: PSS film. Sensors and Actuators B: Chemical, 2019. 282: p. 145-151. 98. Reid, D.O., et al., Solvent treatment of wet-spun PEDOT: PSS fibers for fiber-based wearable pH sensing. Sensors, 2019. 19(19): p. 4213. 99. Yang, J., et al., PEDOT: PSS/PVA/Te ternary composite fibers toward flexible thermoelectric generator. Composites Communications, 2021. 27: p. 100855. 100. Zhou, J., et al., The temperature-dependent microstructure of PEDOT/PSS films: insights from morphological, mechanical and electrical analyses. Journal of Materials Chemistry C, 2014. 2(46): p. 9903-9910. 101. Sun, K., et al., Review on application of PEDOTs and PEDOT: PSS in energy conversion and storage devices. Journal of Materials Science: Materials in Electronics, 2015. 26: p. 4438-4462. 102. Shi, H., et al., Effective approaches to improve the electrical conductivity of PEDOT: PSS: a review. Advanced Electronic Materials, 2015. 1(4): p. 1500017. 103. Kim, J., et al., Enhancement of electrical conductivity of poly (3, 4-ethylenedioxythiophene)/poly (4-styrenesulfonate) by a change of solvents. Synthetic Metals, 2002. 126(2-3): p. 311-316. 104. Lai, S., et al., Concentration effect of glycerol on the conductivity of PEDOT film and the device performance. Materials Science and Engineering: B, 2003. 104(1-2): p. 26-30. 105. Fan, B., X. Mei, and J. Ouyang, Significant conductivity enhancement of conductive poly (3, 4-ethylenedioxythiophene): poly (styrenesulfonate) films by adding anionic surfactants into polymer solution. 2008. 106. Tevi, T., et al., Effect of Triton X-100 on the double layer capacitance and conductivity of poly (3, 4-ethylenedioxythiophene): poly (styrenesulfonate)(PEDOT: PSS) films. Synthetic metals, 2014. 191: p. 59-65. 107. Xia, Y. and J. Ouyang, Salt-induced charge screening and significant conductivity enhancement of conducting poly (3, 4-ethylenedioxythiophene): poly (styrenesulfonate). Macromolecules, 2009. 42(12): p. 4141-4147. 108. Cruz-Cruz, I., M. Reyes-Reyes, and R. López-Sandoval, Formation of polystyrene sulfonic acid surface structures on poly (3, 4-ethylenedioxythiophene): Poly (styrenesulfonate) thin films and the enhancement of its conductivity by using sulfuric acid. Thin Solid Films, 2013. 531: p. 385-390. 109. Tsai, T.-C., et al., A facile dedoping approach for effectively tuning thermoelectricity and acidity of PEDOT: PSS films. Organic Electronics, 2014. 15(3): p. 641-645. 110. Zhang, L., et al., The role of mineral acid doping of PEDOT: PSS and its application in organic photovoltaics. Advanced Electronic Materials, 2020. 6(1): p. 1900648. 111. Fan, Z. and J. Ouyang, Thermoelectric properties of PEDOT: PSS. Advanced Electronic Materials, 2019. 5(11): p. 1800769. 112. Yi, C., et al., Enhanced thermoelectric properties of poly (3, 4-ethylenedioxythiophene): poly (styrenesulfonate) by binary secondary dopants. ACS applied materials & interfaces, 2015. 7(17): p. 8984-8989. 113. Massonnet, N., et al., Improvement of the Seebeck coefficient of PEDOT: PSS by chemical reduction combined with a novel method for its transfer using free-standing thin films. Journal of Materials Chemistry C, 2014. 2(7): p. 1278-1283. 114. Yemata, T.A., et al., Modulation of the doping level of PEDOT: PSS film by treatment with hydrazine to improve the Seebeck coefficient. RSC advances, 2020. 10(3): p. 1786-1792. 115. Chang-Jian, C.-W., et al., Thermally conductive polymeric composites incorporating 3D MWCNT/PEDOT: PSS scaffolds. Composites Part B: Engineering, 2018. 136: p. 46-54. 116. Meng, C., C. Liu, and S. Fan, A promising approach to enhanced thermoelectric properties using carbon nanotube networks. Advanced Materials, 2010. 22(4): p. 535-539. 117. Kim, J.-Y., et al., Wet-spinning and post-treatment of CNT/PEDOT: PSS composites for use in organic fiber-based thermoelectric generators. Carbon, 2018. 133: p. 293-299. 118. Moriarty, G.P., et al., Thermoelectric behavior of organic thin film nanocomposites. Journal of Polymer Science Part B: Polymer Physics, 2013. 51(2): p. 119-123. 119. Jiang, Q., et al., High-performance hybrid organic thermoelectric SWNTs/PEDOT: PSS thin-films for energy harvesting. Materials Chemistry Frontiers, 2018. 2(4): p. 679-685. 120. Liu, S., H. Li, and C. He, Simultaneous enhancement of electrical conductivity and seebeck coefficient in organic thermoelectric SWNT/PEDOT: PSS nanocomposites. Carbon, 2019. 149: p. 25-32. 121. Lee, W., et al., Improving the thermoelectric power factor of CNT/PEDOT: PSS nanocomposite films by ethylene glycol treatment. Rsc Advances, 2016. 6(58): p. 53339-53344. 122. Alshammari, A.S., et al., Inkjet printing of polymer functionalized CNT gas sensor with enhanced sensing properties. Materials Letters, 2017. 189: p. 299-302. 123. Wang, J., et al., Design of room-temperature infrared photothermoelectric detectors based on CNT/PEDOT: PSS composites. Journal of Materials Chemistry C, 2022. 10(40): p. 15105-15113. 124. Jabbar, F., et al., Robust fluidic biocompatible strain sensor based on pedot: Pss/cnt composite for human-wearable and high-end robotic applications. Sensors and Materials, 2020. 32(12): p. 4077-4093. 125. He, X., et al., PEDOT: PSS/CNT composites based ultra-stretchable thermoelectrics and their application as strain sensors. Composites Communications, 2021. 27: p. 100822. 126. Lam, T.N., et al., Microfluidic preparation of highly stretchable natural rubber microfiber containing CNT/PEDOT: PSS hybrid for fabric-sewable wearable strain sensor. Composites Science and Technology, 2021. 210: p. 108811. 127. Harrick Plasma Inc. Plasma Cleaner. 2023; Available from: https://www.smarteamsci.com/plasma-cleaner.html. 128. Mbraun Inc. LABstar Glove Box Workstation. Available from: https://trends.medicalexpo.com/mbraun/project-108344-412592.html. 129. Celia, E., et al., Recent advances in designing superhydrophobic surfaces. Journal of colloid and interface science, 2013. 402: p. 1-18. 130. Wang, J., et al., Influence of surface roughness on contact angle hysteresis and spreading work. Colloid and Polymer Science, 2020. 298: p. 1107-1112. 131. Metrohm Ltd. Autolab 電化學工作站. 2023; Available from: https://www.metrohm.com/zh_tw/products/a/ut20/aut204_s.html. 132. Sutton, M.A., et al., Scanning electron microscopy for quantitative small and large deformation measurements part I: SEM imaging at magnifications from 200 to 10,000. Experimental mechanics, 2007. 47: p. 775-787. 133. Kim, K.H., et al., Charging effects on SEM/SIM contrast of metal/insulator system in various metallic coating conditions. Materials transactions, 2010. 51(6): p. 1080-1083. 134. Baer, D.R., et al., XPS guide: Charge neutralization and binding energy referencing for insulating samples. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 2020. 38(3): p. 031204. 135. Stevie, F.A. and C.L. Donley, Introduction to x-ray photoelectron spectroscopy. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 2020. 38(6): p. 063204. 136. Bao, W., et al., Effect of carbon nanotube geometry upon tunneling assisted electrical network in nanocomposites. Journal of Applied Physics, 2013. 113(23): p. 234313. 137. Liu, Y.-X., et al., Thermoelectric behavior of PEDOT: PSS/CNT/graphene composites. Journal of Polymer Engineering, 2018. 38(4): p. 381-389. 138. Guo, X., et al., O 2 plasma-functionalized SWCNTs and PEDOT/PSS composite film assembled by dielectrophoresis for ultrasensitive trimethylamine gas sensor. Analyst, 2013. 138(18): p. 5265-5273. 139. Unsworth, N.K., et al., Comparison of dimethyl sulfoxide treated highly conductive poly (3, 4-ethylenedioxythiophene): poly (styrenesulfonate) electrodes for use in indium tin oxide-free organic electronic photovoltaic devices. Organic Electronics, 2014. 15(10): p. 2624-2631. 140. Plonska‐Brzezinska, M.E., et al., Preparation and Characterization of Carbon Nano‐Onion/PEDOT: PSS Composites. ChemPhysChem, 2012. 13(18): p. 4134-4141. 141. He, H. and J. Ouyang, Enhancements in the mechanical stretchability and thermoelectric properties of PEDOT: PSS for flexible electronics applications. Accounts of Materials Research, 2020. 1(2): p. 146-157. 142. Zhu, Z., et al., Effective treatment methods on PEDOT: PSS to enhance its thermoelectric performance. Synthetic Metals, 2017. 225: p. 31-40. 143. Sakunpongpitiporn, P., et al., Facile synthesis of highly conductive PEDOT: PSS via surfactant templates. RSC advances, 2019. 9(11): p. 6363-6378. 144. Gu, Z.-Z., et al., Highly conductive sandwich-structured CNT/PEDOT: PSS/CNT transparent conductive films for OLED electrodes. Applied Nanoscience, 2019. 9(8): p. 1971-1979. 145. Lee, S.H., et al., Novel solution-processable, dedoped semiconductors for application in thermoelectric devices. Journal of Materials Chemistry A, 2014. 2(33): p. 13380-13387. 146. Park, H., et al., Enhanced thermoelectric properties of PEDOT: PSS nanofilms by a chemical dedoping process. Journal of Materials Chemistry A, 2014. 2(18): p. 6532-6539. 147. Hwang, J., F. Amy, and A. Kahn, Spectroscopic study on sputtered PEDOT· PSS: Role of surface PSS layer. Organic electronics, 2006. 7(5): p. 387-396. | - |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/88320 | - |
dc.description.abstract | 本研究以奈米碳管 (CNT)/ 聚 (3,4-乙烯二氧噻吩) 聚苯乙烯磺酸 (PEDOT:PSS)製作不同比例的溫度感測層混合溶液(CNT/PEDOT:PSS 1/5, 1/9, 1/13)滴定於PDMS基板和奈米銀線電極上並烤乾,製作可撓性溫度感測器。經銅膠電極連接並使用線性掃描伏安法(LSV)及熱電偶溫度計量測電阻溫度係數(TCR)及熱指標(TI),證實1/5、1/9、1/13三種比例的混合溶液經過長時間的老化0、3、6天後TCR由-1.97、-1.99、-2.15 (%/°C)改善至-2.80、-2.61、-2.51 (%/°C);TI也由2242.5、2249.1、2503.8 (K)增加至3530.1、3085.7、3002.5 (K)。使用X射線光電子能譜(XPS)分析可知,混合薄膜隨著老化時間的增加PSS-H鍵逐漸轉換為PSS-Na鍵,也就是PEDOT:PSS被去摻雜,透過自製的賽貝克係數量測平台量測薄膜的賽貝克係數,薄膜的賽貝克係數由52.4增加至114.5 μV K−1同樣說明了去摻雜現象的產生。因此本實驗提出一種簡便的溶液老化製程,能夠大幅增加CNT/PEDOTPSS溫度感測器的溫度靈敏度及賽貝克係數,應用於34-42°C下小範圍高精度的人體溫度量測。 | zh_TW |
dc.description.abstract | In this study, flexible temperature sensors were fabricated using a mixture of carbon nanotubes (CNT) and poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) at different ratios (CNT/PEDOT:PSS 1/5, 1/9, 1/13). The mixture solution was drop-cast onto PDMS substrates with silver nano wires (AgNWs) electrodes and dried. The temperature coefficient of resistance (TCR) and thermal index (TI) were measured using linear sweep voltammetry (LSV) and a thermocouple thermometer. The results showed that after aging for 0, 3, and 6 days, the absolute value of TCR increased from 1.97, 1.99, 2.15 (%/°C) to 2.80, 2.61, 2.51 (%/°C) for the 1/5, 1/9, and 1/13 ratios, respectively. The TI values increased from 2242.5, 2249.1, 2503.8 (K) to 3530.1, 3085.7, 3002.5 (K) for the corresponding ratios. X-ray photoelectron spectroscopy (XPS) analysis revealed that with increasing aging time, the PSS-H bonds in the mixed films gradually transformed into PSS-Na bonds, indicating the dedoping of PEDOT:PSS. The Seebeck coefficient of the films, measured using a homemade Seebeck coefficient measurement platform, increased from 52.4 to 114.5 μV K−1, further confirming the dedoping treatment. Therefore, this study presents a facile aging process that significantly enhances the temperature sensitivity and Seebeck coefficient of CNT/PEDOT:PSS temperature sensors, making them suitable for high-precision human body temperature measurements within a small range of 34-42°C. | en |
dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-08-09T16:31:49Z No. of bitstreams: 0 | en |
dc.description.provenance | Made available in DSpace on 2023-08-09T16:31:49Z (GMT). No. of bitstreams: 0 | en |
dc.description.tableofcontents | 目錄
致謝 i 摘要 ii Abstract iii 目錄 iv 圖目錄 vii 表目錄 x 第一章 緒論 1 1.1 前言 1 1.2 研究動機 2 1.3 論文大綱 3 第二章 理論與文獻回顧 4 2.1 電子皮膚(Electronic Skin) 4 2.2 可撓性溫度感測器 8 2.2.1 電阻溫度偵測器(Resistance Temperature Detector) 8 2.2.2 熱電偶(Thermocouple) 9 2.2.3 熱敏電阻(Thermistor) 10 2.2.4 溫度靈敏度 12 2.3 溫度感測器材料 15 2.3.1 聚二甲基矽氧烷(PDMS) 15 2.3.2 聚(3,4-乙烯二氧噻吩)聚苯乙烯磺酸(PEDOT:PSS) 16 2.3.3 奈米碳管(CNT)/聚(3,4-乙烯二氧噻吩)聚苯乙烯磺酸(PEDOT:PSS) 21 第三章 實驗方法與儀器介紹 24 3.1 實驗藥品與儀器清單 24 3.2 實驗製程相關儀器 27 3.2.1 旋轉塗布機 27 3.2.2 電漿清洗機 28 3.2.3 氮氣手套箱 29 3.2.4 噴塗機及移動平台 30 3.3 實驗量測相關儀器 31 3.3.1 水接觸角量測儀 31 3.3.2 電化學工作站量測溫度靈敏度 32 3.3.3 場發射鎗掃描式電子顯微鏡 33 3.3.4 X射線光電子能譜儀 35 3.3.5 塞貝克係數熱電量測平台 37 3.4 實驗製作流程 38 3.4.1 溶液配置 38 3.4.2 溶液老化 38 3.4.3 溫度感測器製作 39 3.4.4 電子顯微鏡量測樣品製作 41 3.4.5 塞貝克係數量測樣品製作 42 第四章 結果與討論 43 4.1 電漿處理及水接觸角分析 43 4.2 表面型態與化學元素分佈 44 4.3 溫度靈敏度 47 4.3.1 溫度感測層製程溫度之影響 47 4.3.2 溶液老化之影響 49 4.4 表面化學成分分析 55 4.5 賽貝克係數 64 第五章 結論與未來展望 65 參考文獻 66 個人期刊著作發表 77 | - |
dc.language.iso | zh_TW | - |
dc.title | 溶液老化對奈米碳管/聚 (3,4-乙烯二氧噻吩) 聚苯乙烯磺酸之溫度靈敏度影響 | zh_TW |
dc.title | Solution Aging Effect on Temperature Sensitivity of CNT/PEDOT:PSS | en |
dc.type | Thesis | - |
dc.date.schoolyear | 111-2 | - |
dc.description.degree | 碩士 | - |
dc.contributor.oralexamcommittee | 陳奕君;徐振哲 | zh_TW |
dc.contributor.oralexamcommittee | I-Chun Cheng;Cheng-Che Hsu | en |
dc.subject.keyword | 奈米碳管(CNT),聚 (3,4-乙烯二氧噻吩) 聚苯乙烯磺酸 (PEDOT:PSS),電阻溫度係數,熱指標,溶液老化, | zh_TW |
dc.subject.keyword | carbon nanotube (CNT),poly(3,4- ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS),temperature coefficient of resistance (TCR),thermal index (TI),aging, | en |
dc.relation.page | 77 | - |
dc.identifier.doi | 10.6342/NTU202301308 | - |
dc.rights.note | 同意授權(全球公開) | - |
dc.date.accepted | 2023-07-12 | - |
dc.contributor.author-college | 工學院 | - |
dc.contributor.author-dept | 應用力學研究所 | - |
顯示於系所單位: | 應用力學研究所 |
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