Simple Physical Mixing of Graphitic Wood-Derived Carbon For High-Performance Ni(OH)₂ Electrodes: A Sustainable Strategy Beyond Metal Additives

Xingyan Zhang¹, Sadaf Saeedi Garakani¹, Gunder Karlsson¹, Dag Noréus¹

Affiliations

PMID: 41552460
PMCID: PMC12809764
DOI: 10.1021/acsomega.5c11266

Simple Physical Mixing of Graphitic Wood-Derived Carbon For High-Performance Ni(OH)₂ Electrodes: A Sustainable Strategy Beyond Metal Additives

Xingyan Zhang et al. ACS Omega. 2025.

. 2025 Dec 22;11(1):2170-2180.

doi: 10.1021/acsomega.5c11266. eCollection 2026 Jan 13.

Authors

Xingyan Zhang¹, Sadaf Saeedi Garakani¹, Gunder Karlsson¹, Dag Noréus¹

Affiliation

¹ Department of Chemistry, Stockholm University, SE 106 91 Stockholm, Sweden.

PMID: 41552460
PMCID: PMC12809764
DOI: 10.1021/acsomega.5c11266

Abstract

The replacement of expensive metal powders in Ni-(OH)₂-based cathodes is essential for reducing cost and environmental impact in aqueous Ni-Zn batteries. This work investigates graphitic wood-derived carbon (GWC) as a sustainable conductive additive to boost the performance of Ni-(OH)₂ pasted electrodes prepared by a simple physical mixing process. A number of graphitic wood-derived carbon qualities are explored as functional additives replacing expensive cobalt and nickel powder additives while maintaining the electrochemical performance of Ni-(OH)₂ electrodes in aqueous rechargeable Ni-Zn batteries. The GWC offers high electrical conductivity and a unique microsized particulate morphology. Optimizing the GWC content to 25 wt % yields a specific capacity of 284.2 mAh g^-1 at 0.2C, which is better than that of electrodes containing only Ni-(OH)₂, with Ni/Co powders, or commercial carbon black. Furthermore, the open-circuit voltage hysteresis and state of charge are studied to understand the charge/discharge process, suggesting that GWC is an effective alternative to expensive metal powders, providing a low-cost and sustainable strategy for improving Ni-(OH)₂-based electrodes through a straightforward manufacturing process.

PubMed Disclaimer

Figures

1
Characterizations of GWC: (a and b) SEM images of top-view, (c and d) SEM images of cross-view, (e and f) TEM images, (g) XRD pattern, (h) Raman spectrum, and (i) N₂ sorption isotherm, the inset is the pore size distribution curve.

2
(a-c) SEM images of Ni(OH)₂ powders, and (d) XRD patterns of the materials and pasted electrodes.

3
Compared electrochemical performance of electrodes with/without GWC additives: (a) the cycling curves, (b) the compared charge/discharge curves of the 10th cycle, (c) compared Nyquist plots, and the inset is a partial enlargement, and (d) the cycling stability at different current densities.

4
(a) charge/discharge curves of different electrodes with different carbon contents at 0.2C, (b) discharge specific capacities of electrodes with/without different contents of GWC at 0.2C for 10 cycles, (c) Nyquist plots of different cells with different carbon, and (d) XRD patterns of the Ni(OH)₂ electrode without carbon addition before and after electrochemical testing.

5
(a–c) The open-circuit voltage hysteresis and 100% state of charge of different cells with different Ni-electrodes containing different GWC contents at 0.2C and different rest time, and (d) the compared open-circuit voltage hysteresis of different cells at 0.2C at a rest time of 4 min.

6
Open-circuit voltage hysteresis and state of charge of different cells with different carbon additives at 0.2C with a rest time of 4 min, and the corresponding SEM images of the carbons: GWC (a), S,N-codoped wood carbon (b), commercial carbon black (c), graphitic carbon black 2 (d), graphene-1 (e), and graphene-2 (f), respectively.

7
Electrochemical performance of different electrodes in a three-electrode system: (a) CV curves at 0.2 mV s^–1, and (b) the relationship between the peak current and the square root of scan rate.

See this image and copyright information in PMC

References

1. Zhang H., Wang R., Lin D., Zeng Y., Lu X.. Ni-based nanostructures as high-performance cathodes for rechargeable Ni-Zn battery. ChemNanoMat. 2018;4:525–536. doi: 10.1002/cnma.201800078. - DOI
1. Islam J., Anwar R., Shareef M., Zabed H. M., Sahu J. N., Qi X., Khandaker M. U., Ragauskas A., Boukhris I., Rahman M. R., Islam Chowdhury F.. Rechargeable metal-metal alkaline batteries: Recent advances, current issues and future research strategies. J. Power Sources. 2023;563:232777. doi: 10.1016/j.jpowsour.2023.232777. - DOI
1. Zhang X., Liu Y., Noréus D.. Phosphide-enhanced hierarchical NiMoO4 composite in binder-free Ni-electrodes for high-capacity aqueous rechargeable NiZn batteries. ACS Appl. Energy Mater. 2024;7:517–527. doi: 10.1021/acsaem.3c02450. - DOI
1. Liu T., Yu L., Liu J., Lu J., Bi X., Dai A., Li M., Li M., Hu Z., Ma L., Luo D., Zheng J., Wu T., Ren Y., Wen J., Pan F., Amine K.. Understanding Co roles towards developing Co-free Ni-rich cathodes for rechargeable batteries. Nat. Energy. 2021;6:277–286. doi: 10.1038/s41560-021-00776-y. - DOI
1. Yu W., Ding R., Jia Z., Li Y., Wang A., Liu M., Yang F., Sun X., Liu E.. Pseudocapacitive Co-free trimetallic Ni-Zn-Mn perovskite fluorides enable fast-rechargeable Zn-based aqueous batteries. Adv. Funct. Mater. 2022;32:2112469. doi: 10.1002/adfm.202112469. - DOI

LinkOut - more resources

Full Text Sources
- PubMed Central

Save citation to file

Email citation

Add to Collections

Add to My Bibliography

Your saved search

Create a file for external citation management software

Your RSS Feed

Simple Physical Mixing of Graphitic Wood-Derived Carbon For High-Performance Ni(OH)₂ Electrodes: A Sustainable Strategy Beyond Metal Additives

Affiliation

Simple Physical Mixing of Graphitic Wood-Derived Carbon For High-Performance Ni(OH)₂ Electrodes: A Sustainable Strategy Beyond Metal Additives

Authors

Affiliation

Abstract

Figures

References

LinkOut - more resources

Full Text Sources