SCOPUS 정보 검색 플랫폼

Volumn 33, Issue , 2017, Pages 462-468

Mechanical and electrical characterization of PVDF-ZnO hybrid structure for application to nanogenerator

(7) Choi, Moonkang a Murillo, Gonzalo b Hwang, Sungmin a Kim, Jae Woong a Jung, Jong Hoon a Chen, Chih Yen c Lee, Minbaek a

a Inha University (South Korea)

b INSTITUTO DE MICROELECTRÓNICA DE BARCELONA (Spain)

c Georgia Institute of Technology (United States)

Author keywords

Ferroelectric; Nanogenerator; Nanowire; Piezoelectric; PVDF; Zinc oxide

Indexed keywords

ATOMIC FORCE MICROSCOPY; ELECTRIC FORCE MICROSCOPY; ELECTROSTATIC FORCE; FERROELECTRIC MATERIALS; NANOTECHNOLOGY; NANOWIRES; PIEZOELECTRICITY; ZINC; ZINC OXIDE;

ELECTRICAL POWER OUTPUT; ELECTROSTATIC FORCE MICROSCOPY; MECHANICAL AND ELECTRICAL; NANOGENERATOR; PIEZO-ELECTRIC STRUCTURES; PIEZOELECTRIC; POLY (VINYLIDENE FLUORIDE)(PVDF); PVDF;

FINITE ELEMENT METHOD;

EID: 85012136597 PISSN: 22112855 EISSN: None Source Type: Journal
DOI: 10.1016/j.nanoen.2017.01.062 Document Type: Article

Times cited : (152)

References (23)

1
- 0035891408
- Alternative energy technologies
- [1] Dresselhaus, M.S., Thomas, I.L., Alternative energy technologies. Nature 414 (2001), 332–337.
- (2001) Nature , vol.414 , pp. 332-337
- Dresselhaus, M.S.¹ Thomas, I.L.²

2
- 84964725424
- silk nanofiber-networked bio-Triboelectric generator: silk bio-TEG
- [2] Kim, H.-J., Kim, J.-H., Jun, K.-W., Kim, J.-H., Seung, W.-C., Kwon, O.H., Park, J.-Y., Kim, S.-W., Oh, I.-K., silk nanofiber-networked bio-Triboelectric generator: silk bio-TEG. Adv. Energy Mater., 6, 2016, 1502329.
- (2016) Adv. Energy Mater. , vol.6 , pp. 1502329
- Kim, H.-J.¹ Kim, J.-H.² Jun, K.-W.³ Kim, J.-H.⁴ Seung, W.-C.⁵ Kwon, O.H.⁶ Park, J.-Y.⁷ Kim, S.-W.⁸ Oh, I.-K.⁹

3
- 84929943914
- A reconfigurable rectified flexible energy harvester via solid-state single crystal grown PMN–PZT
- [3] Hwang, G.-T., Yang, J., Yang, S.H., Lee, H.-Y., Lee, M., Park, D.Y., Han, J.H., Lee, S.J., Jeong, C.K., Kim, J., Park, K.-I., Lee, K.J., A reconfigurable rectified flexible energy harvester via solid-state single crystal grown PMN–PZT. Adv. Energy Mater., 5, 2015, 150051.
- (2015) Adv. Energy Mater. , vol.5 , pp. 150051
- Hwang, G.-T.¹ Yang, J.² Yang, S.H.³ Lee, H.-Y.⁴ Lee, M.⁵ Park, D.Y.⁶ Han, J.H.⁷ Lee, S.J.⁸ Jeong, C.K.⁹ Kim, J.¹⁰ Park, K.-I.¹¹ Lee, K.J.¹²

4
- 84902203625
- Theoretical comparison, equivalent transformation, and conjunction operations of electromagnetic induction generator and triboelectric nanogenerator for harvesting mechanical energy
- [4] Zhang, C., Tang, W., Han, C., Fan, F., Wang, Z.L., Theoretical comparison, equivalent transformation, and conjunction operations of electromagnetic induction generator and triboelectric nanogenerator for harvesting mechanical energy. Adv. Mater. 26 (2014), 3580–3591.
- (2014) Adv. Mater. , vol.26 , pp. 3580-3591
- Zhang, C.¹ Tang, W.² Han, C.³ Fan, F.⁴ Wang, Z.L.⁵

5
- 78650130636
- Piezoelectric BaTiO3 thin film nanogenerator on plastic substrates
- [5] Park, K.-I., Xu, S., Liu, Y., Hwang, G.-T., Kang, S.-J.L., Wang, Z.L., Lee, K.J., Piezoelectric BaTiO3 thin film nanogenerator on plastic substrates. Nano Lett. 10 (2010), 4939–4943.
- (2010) Nano Lett. , vol.10 , pp. 4939-4943
- Park, K.-I.¹ Xu, S.² Liu, Y.³ Hwang, G.-T.⁴ Kang, S.-J.L.⁵ Wang, Z.L.⁶ Lee, K.J.⁷

6
- 84860429400
- Piezoelectric nanofibers for energy scavenging applications
- [6] Chang, J., Domnner, M., Chang, C., Lin, L., Piezoelectric nanofibers for energy scavenging applications. Nano Energy 1 (2012), 356–371.
- (2012) Nano Energy , vol.1 , pp. 356-371
- Chang, J.¹ Domnner, M.² Chang, C.³ Lin, L.⁴

7
- 84978405443
- Nanogenerators consisting of direct-grown piezoelectrics on multi-walled carbon nanotubes using flexoelectric effects
- [7] Han, J.K., Jeon, D.H., Cho, S.Y., Kang, S.W., Yang, S.A., Bu, S.D., Myung, S., Lim, J., Choi, M., Lee, M., Lee, M.K., Nanogenerators consisting of direct-grown piezoelectrics on multi-walled carbon nanotubes using flexoelectric effects. Sci. Rep., 6, 2016, 29562.
- (2016) Sci. Rep. , vol.6 , pp. 29562
- Han, J.K.¹ Jeon, D.H.² Cho, S.Y.³ Kang, S.W.⁴ Yang, S.A.⁵ Bu, S.D.⁶ Myung, S.⁷ Lim, J.⁸ Choi, M.⁹ Lee, M.¹⁰ Lee, M.K.¹¹

8
- 0035831290
- Nanobelts of semiconducting oxides
- [8] Pan, Z.W., Dai, Z.R., Wang, Z.L., Nanobelts of semiconducting oxides. Science 291 (2001), 1947–1949.
- (2001) Science , vol.291 , pp. 1947-1949
- Pan, Z.W.¹ Dai, Z.R.² Wang, Z.L.³

9
- 57349110722
- Patterned growth of vertically aligned ZnO nanowire arrays on inorganic substrates at low temperature without catalyst
- [9] Xu, S., Wei, Y., Kirkham, M., Liu, J., Mai, W., Davidovic, D., Snyder, R.L., Wang, Z.L., Patterned growth of vertically aligned ZnO nanowire arrays on inorganic substrates at low temperature without catalyst. J. Am. Chem. Soc. 130 (2008), 14958–14959.
- (2008) J. Am. Chem. Soc. , vol.130 , pp. 14958-14959
- Xu, S.¹ Wei, Y.² Kirkham, M.³ Liu, J.⁴ Mai, W.⁵ Davidovic, D.⁶ Snyder, R.L.⁷ Wang, Z.L.⁸

10
- 84953792301
- Flexible nanogenerators for energy harvesting and self‐powered Electronics
- [10] Feng, F.R., Tang, W., Wang, Z.L., Flexible nanogenerators for energy harvesting and self‐powered Electronics. Adv. Mater. 28 (2016), 4283–4305.
- (2016) Adv. Mater. , vol.28 , pp. 4283-4305
- Feng, F.R.¹ Tang, W.² Wang, Z.L.³

11
- 84894186413
- Performance Optimization of Vertical Nanowire‐based Piezoelectric Nanogenerators
- [11] Hinchet, R., Lee, S., Ardila, G., Montès, L., Mouis, M., Wang, Z.L., Performance Optimization of Vertical Nanowire‐based Piezoelectric Nanogenerators. Adv. Funct. Mater. 24 (2014), 971–977.
- (2014) Adv. Funct. Mater. , vol.24 , pp. 971-977
- Hinchet, R.¹ Lee, S.² Ardila, G.³ Montès, L.⁴ Mouis, M.⁵ Wang, Z.L.⁶

12
- 71549168996
- Growth of ZnO nanotube arrays and nanotube based piezoelectric nanogenerators
- [12] Xi, Y., Song, J., Xu, S., Yang, R., Gao, Z., Hu, C., Wang, Z.L., Growth of ZnO nanotube arrays and nanotube based piezoelectric nanogenerators. J. Mater. Chem. 19 (2009), 9260–9264.
- (2009) J. Mater. Chem. , vol.19 , pp. 9260-9264
- Xi, Y.¹ Song, J.² Xu, S.³ Yang, R.⁴ Gao, Z.⁵ Hu, C.⁶ Wang, Z.L.⁷

13
- 84869389455
- All-solution-processed flexible thin film piezoelectric nanogenerator
- [13] Chung, S.Y., Kim, S., Lee, J.H., Kim, K., Kim, S.W., Kang, C.Y., Yoon, S.J., Kim, Y.S., All-solution-processed flexible thin film piezoelectric nanogenerator. Adv. Mater. 24 (2012), 6022–6027.
- (2012) Adv. Mater. , vol.24 , pp. 6022-6027
- Chung, S.Y.¹ Kim, S.² Lee, J.H.³ Kim, K.⁴ Kim, S.W.⁵ Kang, C.Y.⁶ Yoon, S.J.⁷ Kim, Y.S.⁸

14
- 33645810366
- Piezoelectric nanogenerators based on zinc oxide nanowire arrays
- [14] Wang, Z.L., Song, J.H., Piezoelectric nanogenerators based on zinc oxide nanowire arrays. Science 312 (2006), 242–246.
- (2006) Science , vol.312 , pp. 242-246
- Wang, Z.L.¹ Song, J.H.²

15
- 84859128209
- A hybrid piezoelectric structure for wearable nanogenerators
- [15] Lee, M., Chen, C.-Y., Wang, S., Cha, S.N., Park, Y.J., Kim, J.M., Chou, L.-J., Wang, Z.L., A hybrid piezoelectric structure for wearable nanogenerators. Adv. Mater. 24 (2012), 1759–1764.
- (2012) Adv. Mater. , vol.24 , pp. 1759-1764
- Lee, M.¹ Chen, C.-Y.² Wang, S.³ Cha, S.N.⁴ Park, Y.J.⁵ Kim, J.M.⁶ Chou, L.-J.⁷ Wang, Z.L.⁸

16
- 84555218597
- Lead-free NaNbO3 nanowires for a high output piezoelectric nanogenerator
- [16] Jung, J.H., Lee, M., Hong, J.-I., Ding, Y., Chen, C.-Y., Chou, L.-J., Wang, Z.L., Lead-free NaNbO3 nanowires for a high output piezoelectric nanogenerator. ACS Nano 5 (2011), 10041–10046.
- (2011) ACS Nano , vol.5 , pp. 10041-10046
- Jung, J.H.¹ Lee, M.² Hong, J.-I.³ Ding, Y.⁴ Chen, C.-Y.⁵ Chou, L.-J.⁶ Wang, Z.L.⁷

17
- 84942851600
- Electrospun ion gel nanofibers for flexible triboelectric nanogenerator: electrochemical effect on output power
- [17] Ye, B.U., Kim, B.J., Ryu, J., Lee, J.Y., Baik, J.M., Hong, K., Electrospun ion gel nanofibers for flexible triboelectric nanogenerator: electrochemical effect on output power. Nanoscale 7. 39, 2015, 16189–16194.
- (2015) Nanoscale 7. 39 , pp. 16189-16194
- Ye, B.U.¹ Kim, B.J.² Ryu, J.³ Lee, J.Y.⁴ Baik, J.M.⁵ Hong, K.⁶

18
- 80955144235
- One-dimensional ZnO nanostructures: solution growth and functional properties
- [18] Xu, S., Wang, Z.L., One-dimensional ZnO nanostructures: solution growth and functional properties. Nano Res. 4 (2011), 1013–1098.
- (2011) Nano Res. , vol.4 , pp. 1013-1098
- Xu, S.¹ Wang, Z.L.²

19
- 27744434058
- Dynamic response of the piezoelectric polymer PVDF
- [19] Vinogradov, A.M., Schumacher, S.C., Rassi, E.M., Dynamic response of the piezoelectric polymer PVDF. Int. J. Appl. Electromagn. Mech. 22 (2005), 39–51.
- (2005) Int. J. Appl. Electromagn. Mech. , vol.22 , pp. 39-51
- Vinogradov, A.M.¹ Schumacher, S.C.² Rassi, E.M.³

20
- 0003811536
- Ferroelectric Polymers: chemistry: Physics, and Applications
- CRC Press
- [20] Nalwa, H.S., Ferroelectric Polymers: chemistry: Physics, and Applications. 1995, CRC Press.
- (1995)
- Nalwa, H.S.¹

21
- 38049036230
- Spin cast ferroelectric beta poly (vinylidene fluoride) thin films via rapid thermal annealing
- [21] Kang, S.J., Park, Y.J., Sung, J., Jo, P.S., Park, C., Kim, K.J., Cho, B.O., Spin cast ferroelectric beta poly (vinylidene fluoride) thin films via rapid thermal annealing. Appl. Phys. Lett., 92, 2008, 012921.
- (2008) Appl. Phys. Lett. , vol.92 , pp. 012921
- Kang, S.J.¹ Park, Y.J.² Sung, J.³ Jo, P.S.⁴ Park, C.⁵ Kim, K.J.⁶ Cho, B.O.⁷

22
- 0037577893
- Scanning-electrostatic-force microscopy: self-consistent method for mesoscopic surface structures
- [22] Li, Z.-Y., Scanning-electrostatic-force microscopy: self-consistent method for mesoscopic surface structures. Phys. Rev. B. 57 (1998), 9225–9233.
- (1998) Phys. Rev. B. , vol.57 , pp. 9225-9233
- Li, Z.-Y.¹

23
- 85026579539
- The negative piezoelectric effect of the ferroelectric polymer poly(vinylidene fluoride)
- [23] Katsouras, I., Asadi, K., Li, M., van Driel, T.B., K. S. K, Zhao, D., Lenz, T., Gu, Y., Blom, P.W.M., Damjanovic, D., Nielsen, M.M., de Leeuw, D.M., The negative piezoelectric effect of the ferroelectric polymer poly(vinylidene fluoride). Nature 15 (2016), 78–85.
- (2016) Nature , vol.15 , pp. 78-85
- Katsouras, I.¹ Asadi, K.² Li, M.³ van Driel, T.B.⁴ K. S. K⁵ Zhao, D.⁶ Lenz, T.⁷ Gu, Y.⁸ Blom, P.W.M.⁹ Damjanovic, D.¹⁰ Nielsen, M.M.¹¹ de Leeuw, D.M.¹²

* 이 정보는 Elsevier사의 SCOPUS DB에서 KISTI가 분석하여 추출한 것입니다.