Enhanced electromechanical behavior of cellulose film by zinc oxide nanocoating and its vibration energy harvesting

Acta Materialia

Volumn 114, Issue , 2016, Pages 1-6

  Mun, Seongcheol ^a   Ko, Hyun U ^a   Zhai, Lindong ^a   Min, Seung Ki ^a   Kim, Hyun Chan ^a   Kim, Jaehwan ^a  

^a Inha University   (South Korea)

Author keywords

Cellulose; Nanocoating; Piezoelectricity; Vibration energy harvester; Zinc oxide

Indexed keywords

BIOCOMPATIBILITY; CELLULOSE FILMS; CRYSTALLOGRAPHY; ENERGY HARVESTING; PIEZOELECTRICITY; ZINC; ZINC OXIDE;

ELECTROMECHANICAL BEHAVIOR; ELECTROMECHANICAL CHARACTERISTICS; NANO-COATINGS; REGENERATED CELLULOSE FILMS; SENSORS AND ACTUATORS; VIBRATION ENERGY HARVESTERS; VIBRATION ENERGY HARVESTING; ZINC OXIDE NANO-COATING;

CELLULOSE;

ACTUATORS; CELLULOSE FILM; ENERGY; SENSORS; ZINC OXIDE;

EID: 84990961131     PISSN: 13596454     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.actamat.2016.05.021     Document Type: Article

References (27)

1. [1] Kukula, E.P., Sutton, M.J., Elliott, S.J., The human-biometric-sensor interaction evaluation method: biometric performance and usability measurements. IEEE T. Instrum. Meas. 59 (2010), 784–791.
2. [2] Lo, P., Tseng, S., Yeh, J., Fang, W., Development of a proximity sensor with vertically monolithic integrated inductive and capacitive sensing units. J. Micromech. Microeng., 23, 2013, 035013.
3. [3] Kim, H.S., Kim, J.-H., Kim, J., A review of piezoelectric energy harvesting based on vibration. Int. J. Precis. Eng. Manuf. 12 (2011), 1129–1141.
4. [4] Kim, J., Mun, S., Ko, H., Yun, G., Kim, J., Disposable chemical sensors and biosensors made on cellulose paper. Nanotechnology, 25, 2014, 092001.
5. [5] Choi, H., Choi, J.S., Kim, J., Choe, J., Chung, K.H., Shin, J., Kim, J.T., Youn, D., Kim, K., Lee, J., Choi, S., Kim, P., Choi, C., Yu, Y., Flexible and transparent gas molecule sensor integrated with sensing and heating graphene layers. Small 10 (2014), 3685–3691.
6. [6] Eichhorn, S.J., Dufresne, A., Aranguren, M., Marcovich, N.E., Capadona, J.R., Rowan, S.J., Weder, C., Thielemans, W., Roman, M., Renneckar, S., Gindl, W., Veigel, S., Keckes, J., Yano, H., Abe, K., Nogi, M., Nakagaito, A.N., Mangalam, A., Simonsen, J., Benight, A.S., Bismarck, A., Berglund, L.A., Peijs, T., Review: current international research into cellulose nanofibres and nanocomposites. J. Mater. Sci. 45 (2010), 1–33.
7. [7] Bazhenov, V.A., Piezoelectric Properties of Woods. 1961, Consultants Bureau, New York.
8. [8] Kim, J., Yun, S., Ounaies, Z., Discovery of cellulose as a smart material. Macromolecules 39 (2006), 4202–4206.
9. [9] Kim, H.S., Li, Y., Kim, J., Electro-mechanical behavior and direct piezoelectricity of cellulose electro-active paper. Sens. Actuat. A 147 (2008), 304–309.
10. [10] Kim, J.H., Yun, S., Kim, J.–H., Kim, J., Fabrication of piezoelectric cellulose paper and audio application. J. Bionic Eng. 6 (2009), 18–21.
11. [11] Abas, Z., Kim, H.S., Zhai, L., Kim, J., Experimental Study of vibrational energy harvesting using electro-active paper. Int. J. Precis. Eng. Manuf. 16 (2015), 1187–1195.
12. [12] Yun, G.–Y., Kim, J., Kim, J.–H., Kim, S.–Y., Fabrication and testing of piezoelectric EAPap actuators for haptic application. Sens. Act. A Phys. 164 (2010), 68–73.
13. [13] Janotti, A., Van de Walle, C.G., Fundamentals of zinc oxide as a semiconductor. Rep. Prog. Phys., 72, 2009, 126501.
14. [14] Özgür, Ü., Alivov, YaI., Liu, C., Teke, A., Reshchikov, M.A., Doğan, S., Avrutin, V., Cho, S.–J., Morkoç, H., A comprehensive review of ZnO materials and devices. J. Appl. Phys., 98, 2005, 041301.
15. [15] Brown, H.E., Zinc Oxide: Properties and Applications. 1976, International Lead Zinc Research Organization, New York.
16. [16] Willander, M., Nur, O., Zhao, Q.X., Yang, L.L., Lorenz, M., Cao, B.Q., Zúñiga Pérez, J., Czekalla, C., Zimmermann, G., Grundmann, M., Bakin, A., Behrends, A., Al-Suleiman, M., El-Shaer, A., Che Mofor, A., Postels, B., Waag, A., Boukos, N., Travlos, A., Kwack, H.S., Guinard, J., Le Si Dang, D., Zinc oxide nanorod based photonic devices: recent progress in growth, light emitting diodes and lasers. Nanotechnology, 20, 2009, 332001.
17. [17] Yun, S., Kim, J., Lee, K.–S., Evaluation of cellulose electro-active paper made by tape casting and zone stretching methods. Int. J. Precis. Eng. Manuf. 11 (2010), 987–990.
18. [18] Oh, H., Hong, Y.J., Kim, K.-S., Yoon, S., Baek, H., Kang, S.-H., Kwon, Y.-K., Kim, M., Yi, G.-C., Architectured van der Waals epitaxy of ZnO nanostructures on hexagonal BN. NPG Asia Mater., 6, 2014, e145.
19. [19] Sun, Q., Lu, Y., Zhang, H., Yang, D., Wang, Y., Xu, J., Tu, J., Liu, Y., Li, J., Improved UV resistance in wood through the hydrothermal growth of highly ordered ZnO nanorod arrays. J. Mater. Sci. 47 (2012), 4457–4462.
20. [20] Zhang, W., Zhang, X., Liang, M., Lu, C., Mechanochemical preparation of surface-acetylated cellulose powder to enhance mechanical properties of cellulose-filler-reinforced NR vulcanizates. Compos. Sci. Technol. 68 (2008), 2479–2484.
21. [21] Piezo Film Sensors Technical Manual, 1999, Measurement Specialties, Inc. https://www.sparkfun.com/datasheets/Sensors/Flex/MSI-techman.pdf.
22. [22] Agrawal, R., Espinosa, H.D., Giant Piezoelectric size effects in zinc oxide and gallium nitride nanowires. a first principles investigation. Nano Lett. 11 (2011), 786–790.
23. [23] Sharma, N.D., Landis, C.M., Sharma, P., Piezoelectric thin-film superlattices without using piezoelectric materials. J. Appl. Phy., 108, 2010, 024304.
24. [24] Dai, S., Gharbi, M., Sharma, P., Park, H.S., Surface piezoelectricity: size effects in nanostructures and the emergence of piezoelectricity in non-piezoelectric materials. J. Appl. Phys., 110, 2011, 104305.
25. [25] Wang, Z.L., Song, J., Piezoelectric nanogenerators based on zinc oxide nanowire arrays. Science 312 (2006), 242–246.
26. [26] Wang, X., Song, J., Liu, J., Wang, Z.L., Direct-current nanogenerator driven by ultrasonic waves. Science 316 (2007), 102–105.
27. [27] Cha, S.N., Seo, J.S., Kim, S.M., Kim, H.J., Park, Y.J., Kim, S.W., Kim, J.M., Sound-driven piezoelectric nanowire-based nanogenerators. Adv. Mater. 22 (2010), 4726–4730.