High volumetric-energy-density flexible supercapacitors based on PEDOT:PSS incorporated with carbon quantum dots hybrid electrodes

doi:10.1016/j.jmst.2024.08.073

Abstract

Abstract: Poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) is a highly successful conductive polymer utilized as an electrode material in energy storage units for portable and wearable electronic devices. Nevertheless, employing PEDOT:PSS in supercapacitors (SC) in its pristine state presents challenges due to its suboptimal electrochemical performance and operational instability. To surmount these limitations, PEDOT:PSS has been integrated with carbon-based materials to form flexible electrodes, which exhibit physical and chemical stability during SC operation. We developed a streamlined fabrication process for high-performance SC electrodes composed of PEDOT:PSS and carbon quantum dots (CQDs). The CQDs were synthesized under microwave irradiation, yielding green- and red-light emissions. Through optimizing the ratios of CQDs to PEDOT:PSS, the SC electrodes were prepared using a spray-coating technique, marking a significant improvement in device performance with a high volumetric capacitance (104.10 F cm^-3), impressive energy density (19.68 Wh cm^-3), and excellent cyclic stability, retaining ∼85 % of its original volumetric capacitance after 15,000 repeated GCD cycles. Moreover, the SCs, when utilized as a flexible substrate, demonstrated the ability to maintain up to ∼85 % of their electrochemical performance even after 3,000 bending cycles (at a bending angle of 60°). These attributes render this hybrid composite an ideal candidate for a lightweight smart energy storage component in portable and wearable electronic technologies.

Key words: PEDOT:PSS, Carbon quantum dots, Hybrid electrode, Supercapacitor, Flexible power sources

Dinh Cung Tien Nguyen, Seonghan Kim, Bo-Seok Kim, Sejung Kim, Soo-Hyoung Lee. High volumetric-energy-density flexible supercapacitors based on PEDOT:PSS incorporated with carbon quantum dots hybrid electrodes[J]. J. Mater. Sci. Technol., 2025, 223: 1-10.

References

[1] H. Du, M. Zhang, K. Liu, M. Parit, Z. Jiang, X. Zhang, B. Li, C. Si, Chem. Eng. J. 428(2022) 131994.
[2] V.;D.Mai V.;P.Vu, D.C.T. Nguyen, S.;H. Lee, ACS Appl. Energy Mater. 5(2022) 2211-2220.
[3] S. Khasim, A. Pasha, N. Badi, M. Lakshmi, Y.K. Mishra, RSC Adv. 10(2020) 10526-10539.
[4] J. Balamurugan, P.M. Austeria, J.B. Kim, E.S. Jeong, H.H. Huang, D.H. Kim, N. Koratkar, S.O. Kim, Adv. Mater. 35(2023) 2302625.
[5] J. Balamurugan, T.T. Nguyen, V. Aravindan, N.H. Kim, S.H. Lee, J.H. Lee, Nano Energy 65 (2019) 103999.
[6] V.;P. Vu, V.;D. Mai, S.;H. Lee, J. Alloy. Compd. 933(2023) 167823.
[7] H. Huang, Y. Zhao, T. Cong, C. Li, N. Wen, X. Zuo, Y. Guo, H. Zhang, Z. Fan, L. Pan, Adv. Funct. Mater. 32(2022) 2110777.
[8] D.C.T.Nguyen, J. Shin, S.;K. Kim, S.;H. Lee, ACS Appl. Energy Mater. 4(2021) 14014-14021.
[9] Q. He, J. Ye, Z. Peng, Y. Guo, L. Tan, Y. Chen, J. Power Sources 506 (2021) 230176.
[10] Y. Wang, X. Wu, Y. Han, T. Li, J. Energy Storage 42 (2021) 103053.
[11] X. Xin, Y. Xu, H. Wuliji, F. Sun, Q. Liu, Z. Wang, T.;R. Wei, X. Zhao, X. Song, L. Gao, ACS Nano 17 (2022) 657-667.
[12] Z. Xue, S. Chen, N. Gao, Y. Xue, B. Lu, O.A. Watson, L. Zang, J. Xu, Polym. Rev. 60(2020) 318-358.
[13] Z. Zhai, L. Zhang, T. Du, B. Ren, Y. Xu, S. Wang, J. Miao, Z. Liu, Mater. Des. 221(2022) 111017.
[14] A. Kanwade, P.M. Shirage, J. Energy Storage 55 (2022) 105692.
[15] N.S. Shaikh, S.B. Ubale, V.J. Mane, J.S. Shaikh, V.C. Lokhande, S. Praserthdam, C.D. Lokhande, P. Kanjanaboos, J. Alloy. Compd. 893(2022) 161998.
[16] Z. Su, Y. Jin, Y. Xiao, H. Zheng, Z. Yang, H. Wang, Z. Li, Chem. Commun. 58(2022) 5088-5091.
[17] J. Cárdenas;Martínez, B.L.España;Sánchez, R.Esparza, J.A. Ávila;Niño, Synth. Met. 267(2020) 116436.
[18] M. Lay, M.À. Pèlach, N. Pellicer, J.A. Tarrés, K.N. Bun, F. Vilaseca, Carbohydr. Polym. 165(2017) 86-95.
[19] P. Zhang, Y. Sui, W. Ma, N. Duan, Q. Liu, B. Zhang, H. Niu, C. Qin, Dalton Trans. 52(2023) 710-720.
[20] J. Xiao, P. Yu, K. Zhao, H. Gao, J. Colloid Interface Sci. 639(2023) 233-240.
[21] C. Li, S. Wang, Y. Cui, X. Wang, Z. Yong, D. Liang, Y. Chi, Z. Wang, ACS Appl. Mater. Interfaces 14 (2022) 9172-9182.
[22] R. Maharsi, A.F. Arif, T. Ogi, H. Widiyandari, F. Iskandar, RSC Adv. 9(2019) 27896-27903.
[23] M.A .A .M. Abdah, N.H.N. Azman, S. Kulandaivalu, Y. Sulaiman, Mater. Des. 186(2020) 108199.
[24] J. Garcia;Torres, C. Crean, Mater. Des. 155(2018) 194-202.
[25] S. Zhang, L. Sui, H. Dong, W. He, L. Dong, L. Yu, ACS Appl. Mater. Interfaces 10 (2018) 12983-12991.
[26] Q. Liu, J. Sun, K. Gao, N. Chen, X. Sun, D. Ti, C. Bai, R. Cui, L. Qu, Mater. Chem. Front. 4(2020) 421-436.
[27] D. Ghosh, K. Sarkar, P. Devi, K.;H. Kim, P.Kumar, Renew. Sustain. Energy Rev. 135(2021) 110391.
[28] G.;H. Oh, B.;S. Kim, Y. Song, S. Kim, Appl. Surf. Sci. 605(2022) 154690.
[29] D.N. Nguyen, S.H. Roh, D.;H. Kim, J.Y. Lee, D.H. Wang, J.K. Kim, Dyes Pigm. 194(2021) 109610.
[30] F.;P. Du, N.;N. Cao, Y.;F. Zhang, P. Fu, Y.;G. Wu, Z.;D. Lin, R. Shi, A. Amini, C. Cheng, Sci. Rep. 8(2018) 1-12.
[31] Y. Zeng, Y. Han, Y. Zhao, Y. Zeng, M. Yu, Y. Liu, H. Tang, Y. Tong, X. Lu, Adv. Energy Mater. 5(2015) 1402176.
[32] J.P. Jyothibasu, D.;W. Kuo, R.;H. Lee, Cellulose 26 (2019) 4495-4513.
[33] Y. Chen, K. Cai, C. Liu, H. Song, X. Yang, Adv. Energy Mater. 7(2017) 1701247.
[34] R. Xu, J. Wei, F. Guo, X. Cui, T. Zhang, H. Zhu, K. Wang, D. Wu, RSC Adv. 5(2015) 22015-22021.
[35] L. Qin, W. Ma, M. Hanif, J. Jiang, Z. Xie, Y. Ma, Macromolecules 50 (2017) 3565-3572.
[36] E. Song, K.;B. Chae, M.G. Gu, S.;H. Lee, S.;K. Kim, J. Electroanal. Chem. 853(2019) 113533.
[37] Y. Wang, Y. Ding, X. Guo, G. Yu, Nano Res. 12(2019) 1978-1987.
[38] Z. Tong, Y. Yang, J. Wang, J. Zhao, B.;L. Su, Y. Li, J. Mater. Chem. A 2 (2014) 4642-4651.
[39] D.C.T.Nguyen, V.;H. Tran, V.;P. Vu, S.;H. Lee, Org. Electron. 100(2021) 106388.
[40] D.C.T.Nguyen, J. Shin, S.;K. Kim, S.;H. Lee, ACS Appl. Energy Mater. 4(2021) 14014-14021.
[41] C.;W. Lei, M.;L. Hsieh, W.;R. Liu, Dyes Pigm. 169(2019) 73-80.
[42] A. Rezaei, L. Hadian;Dehkordi, H. Samadian, M. Jaymand, H. Targhan, A. Ramazani, H. Adibi, X. Deng, L. Zheng, H. Zheng, Sci. Rep. 11(2021) 4411.
[43] Z. Wang, F. Yuan, X. Li, Y. Li, H. Zhong, L. Fan, S. Yang, Adv. Mater. 29(2017) 1702910.
[44] J. Balamurugan, T.T. Nguyen, V. Aravindan, N.H. Kim, J.H. Lee, Adv. Funct. Mater. 28(2018) 1804663.
[45] H.M. Lee, G. Anoop, H.J. Lee, W.S. Kim, J.Y. Jo, RSC Adv. 9(2019) 11595-11601.
[46] R. Harish, K. Nisha, S. Prabakaran, S. Sridevi, S.M.Navaneethan Harish, S.Ponnusamy, Y. Hayakawa, C. Vinniee, M. Ganesh, Appl. Surf. Sci. 499(2020) 143817.
[47] M. Wang, M. Zhou, L. Zhu, Q. Li, C. Jiang, Sol. Energy 129 (2016) 175-183.
[48] A. Arjunan, S.;K. Kim, Energy Fuels 36 (2022) 9337-9346.
[49] M. Yang, J. Choi, S.K. Kim, P.V. Braun, Energy Technol. 6(2018) 1852-1858.
[50] A.S. Dezfuli, M.R. Ganjali, H.R. Naderi, P. Norouzi, RSC Adv. 5(2015) 46050-46058.
[51] B. De, J. Balamurugan, N.H. Kim, J.H. Lee, ACS Appl. Mater. Interfaces 9 (2017) 2459-2468.
[52] Z. Lei, Z. Liu, H. Wang, X. Sun, L. Lu, X. Zhao, J. Mater. Chem. A 1 (2013) 2313-2321.
[53] Y. Yang, S. Liao, W. Shi, Y. Wu, R. Zhang, S. Leng, RSC Adv. 7(2017) 10885-10890 .