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Language: English

Conflict of Interest: In relation to this article, we declare that there is no conflict of interest.

Publication history: Received August 13, 2025
Revised November 14, 2025
Accepted December 28, 2025
Available online April 25, 2026

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/bync/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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A Comprehensive Review, Future Possibilities and the Impact of Sustainable Battery Technologies for Practical Applications

Maryam Sadat Kiai¹ Navid Aslfattahi^2† Hikmet Karakoc^{3 4 5} Nilgun Baydogan⁶ Lingenthiram Samylingam⁷ Kumaran Kadirgama^{8 9 10†} Chee Kuang Kok¹¹ Hana Schmirlerova²

Nano-Science and Nano-Engineering Program, Graduate School of Science, Engineering and Technology , Istanbul Technical University ¹Center for BioNano Interactions, School of Chemistry , University College of Dublin ²Department of Fluid Dynamics and Thermodynamics, Faculty of Mechanical Engineering , Czech Technical University in Prague ³Airframe and Powerplant Maintenance , Eskisehir Technical University ⁴Piri Reis University ⁵National Aviation Academy ⁶Energy Institute , Ayazaga Campus Istanbul Technical University Maslak ⁷Department of Data Science and Artifi cial Intelligence, School of Smart Computing and Cyber Resilience, Faculty of Engineering and Technology , Sunway University ⁸Faculty of Mechanical & Automotive Engineering Technology , University Malaysia Pahang Al-Sultan Abdullah (UMPSA) ⁹Centre for Research in Advanced Fluid and Process , University Malaysia Pahang Al-Sultan Abdullah ¹⁰Centre for Sustainable Materials & Surface Metamorphosis (CSMSM) ¹¹Center for Advanced Mechanical and Green Technology, Center of Excellence for Robotics & Sensing Technologies, Faculty of Engineering and Technology , Multimedia University

navid.aslfattahi@fs.cvut.cz, kumaran@umpsa.edu.my

Korean Journal of Chemical Engineering, April 2026, 43(5), 1245-1275(31)
https://doi.org/10.1007/s11814-025-00642-7

Abstract

Recent studies have concentrated on the feasibility of several type of batteries including silicon-based, thin fi lm, bio based

and fl exible graphene-based batteries to expedite the commercial deployment of high-energy batteries. In the fi eld of

advanced battery technologies, it is essential to allocate additional research resources towards the investigation of innovative

silicon-based, graphene based, bio-based and thin fi lm batteries. This approach is crucial for achieving elevated volumetric

energy density. A key aspect of this endeavor is the strategic design of novel environmentally friendly components

alongside with employing theoretical simulations and in situ characterization techniques to examine the energy storage

mechanisms to gain a comprehension of the relationship between material structure and its performance. This review

study explores futuristic battery technology including silicon-based anodes, polymer-based batteries, ceramic batteries, 3D

printed batteries and graphene-based batteries for the fi rst time. All the above-mentioned battery technologies could be

suitable for environmentally sustainable methods for large-scale production, even if this necessitates minor reductions in

energy density. This review tries to highlight the technological feasibility of newer batteries, which are essential to foster

closer collaborations between academia and industry, as well as to invest more eff ort in streamlining synthetic processes

and reducing costs, thereby facilitating a broader range of consumer electronics with signifi cant societal implications. Silicon-based

anodes, utilizing alloying and conversion mechanisms, have attracted considerable interest in research owing to

their impressive theoretical capacities. The advancement of innovative techniques for thin fi lm ceramics has paved the way

for a new generation of lithium-ion batteries. The miniaturization of solid-state chemistries into fi lm form is expected to

enhance the diversity of lithium conductors. The bio-based batteries use extraction of organic molecules or polymers from

sources such as green plants, algae, and bacteria has emerged as promising candidates for cathode, anode and electrolyte.

Keywords

Futuristic battery technology · Electrode materials · Energy storage · Structural design · Electrochemical performance · Environmentally friendly · Energy effi ciency