Correction to: Bismuth Yttrium Oxide (Bi₃YO₆), A New Electrode Material For Asymmetric Aqueous Supercapacitors

1 Correction to: Journal of Inorganic and Organometallic Polymers and Materials https://doi.org/10.1007/s10904-020-01778-1

The original version of this article unfortunately contained mistakes. In line 9 of the abstract, 5% should read as 2%. The reference 41 at end of the XRD discussion should read as 42. All the references were not ordered and some references were missing. They are given below. The added references were mistakenly omitted from the original manuscript.

1. 42.

   R. Datta, J. Meehan, The System Bi₂O₃–R₂O₃ (R = Y, Gd), Zeitschrift für anorganische und allgemeine Chemie, 383 (1971) 328–337.

2. 43.

   A. Watanabe, Is It Possible to Stabilize δ-Bi₂O₃ by An Oxide Additive?, Solid State Ionics, 40–41 (1990) 889–892.

3. 44.

   C. Zhou, Y. Zhang, Y. Li, J. Liu, Construction of high-capacitance 3D CoO@ polypyrrole nanowire array electrode for aqueous asymmetric supercapacitor, Nano letters, 13 (2013) 2078–2085.

4. 45.

   A. Prasath, M. Athika, E. Duraisamy, A. Selva Sharma, V. Sankar Devi, P. Elumalai, Carbon Quantum Dot-Anchored Bismuth Oxide Composites as Potential Electrode for Lithium-Ion Battery and Supercapacitor Applications, ACS Omega, 4 (2019) 4943–4954.

5. 46.

   A. González, E. Goikolea, J.A. Barrena, R. Mysyk, Review on supercapacitors: technologies and materials, Renewable and Sustainable Energy Reviews, 58 (2016) 1189–1206.

6. 47.

   Y. Han, L. Li, Y. Liu, X. Li, X. Qi, L. Song, Fabrication of strontium bismuth oxides as novel battery-type electrode materials for high-performance supercapacitors, Journal of Nanomaterials, 2018 (2018) 1–10.

7. 48.

   L. Li, X. Zhang, Z. Zhang, M. Zhang, L. Cong, Y. Pan, S. Lin, A bismuth oxide nanosheet-coated electrospun carbon nanofiber film: a free-standing negative electrode for flexible asymmetric supercapacitors, Journal of Materials Chemistry A, 4 (2016) 16,635–16,644.

8. 49.

   N. Shinde, Q.X. Xia, J.M. Yun, S. Singh, R.S. Mane, K.-H. Kim, A binder-free wet chemical synthesis approach to decorate nanoflowers of bismuth oxide on Ni-foam for fabricating laboratory scale potential pencil-type asymmetric supercapacitor device, Dalton transactions, 46 (2017) 6601–6611.

9. 50.

   F.-L. Zheng, G.-R. Li, Y.-N. Ou, Z.-L. Wang, C.-Y. Su, Y.-X. Tong, Synthesis of hierarchical rippled Bi₂O₃ nanobelts for supercapacitor applications, Chemical Communications, 46 (2010) 5021–5023.

10. 51.

    L.G. Beka, X. Li, W. Liu, Nickel Cobalt Sulfide core/shell structure on 3D Graphene for supercapacitor application, Scientific reports, 7 (2017) 21–29.

11. 52.

    C.-S. Cheng, M. Serizawa, H. Sakata, T. Hirayama, Electrical conductivity of Co₃O₄ films prepared by chemical vapour deposition, Materials chemistry and physics, 53 (1998) 225–230.

12. 53.

    Y. Zhang, P. Wang, Y. Yin, X. Zhang, L. Fan, N. Zhang, K. Sun, Heterostructured SnS-ZnS@C hollow nanoboxes embedded in graphene for high performance lithium and sodium ion batteries, Chemical Engineering Journal, 356 (2019) 1042–1051.

13. 54.

    S. Wang, C. Jin, W. Qian, Bi₂O₃ with activated carbon composite as a supercapacitor electrode, Journal of Alloys and Compounds, 615 (2014) 12–17.

14. 55.

    S. Liu, Y. Wang, Z. Ma, Bi₂O₃ with Reduced Graphene Oxide Composite as a Supercapacitor Electrode, international journal of electrochemical science, 13 (2018) 12256–12265.

15. 56.

    H. Xu, X. Hu, H. Yang, Y. Sun, C. Hu, Y. Huang, Flexible Asymmetric Micro‐Supercapacitors Based on Bi₂O₃ and MnO₂ Nanoflowers: Larger Areal Mass Promises Higher Energy Density, Advanced Energy Materials, 5 (2015) 14–22.