Improving Hydrogen Storage Kinetics of Polymeric Composites via Additions of La_0.6Ce_0.4Ni₅ and Carbon Particles

Authors

• Muhammad M. Rahman, Air Force Institute of Technology
• Fenil J. Desai, Wichita State University
• Ramazan Asmatulu, Wichita State University
• Md. Nizam Uddin, Texas A & M University - College Station
• Karina Suarez-Alcantara, Universidad Nacional Autonoma de Mexico

Document Type

Article

Publication Date

3-14-2026

Abstract

Nanostructured metal hydrides have garnered interest in their potential to store hydrogen safely and effectively as an energy carrier. By partially substituting lanthanum (La) with cerium (Ce), the structure of lanthanum pentanickel (LaNi₅) was maintained to create a novel encapsulated La–Ce–Ni-based metal hydride (La_0.6Ce_0.4Ni₅). The incorporation of metal-polymer composites can protect metal hydrides from oxidation and enhance cyclic stability. Carbon-based materials such as graphene and multi-walled carbon nanotubes (MWCNTs) not only store hydrogen but also improve the reaction kinetics and address thermal management issues. This study presents La_0.6Ce_0.4Ni₅ composites using porous polymers—polymethyl methacrylate (PMMA) and polyvinylidene fluoride (PVDF) and carbon-based materials (graphene, MWCNTs) synthesized via a solvent-based method. The aim is to enhance hydrogen storage kinetics and stability. The composite’s thermal stability was analyzed using differential scanning calorimetry, and its structural phase composition was examined through X-ray diffraction. Fourier transform infrared (FTIR) spectroscopy and X-ray photoelectron spectroscopy (XPS) were employed to qualitatively estimate the surface functional groups. Hydrogen storage kinetics were measured using temperature-programmed desorption in a Sieverts-type apparatus. The creation of surface functional groups on La_0.6Ce_0.4Ni₅ improved the dispersion of the polymer and carbon particles. Hydrogen storage kinetics were evaluated through dehydrogenation (DHH) experiments in a Sieverts-type apparatus. The composite, consisting of La_0.6Ce_0.4Ni₅ with 8% PMMA and 8% MWCNTs can store 0.8 wt% H₂ at room temperature and pressure in under 20 min with good stability over three cycles, while the hydrogenation (HH) at 5 bar pressure can store 1.05 wt% of hydrogen in less than three minutes. La_0.6Ce_0.4Ni₅ is highly promising material for hydrogen storage due to its reversible hydrogen absorption and desorption capabilities, along with its high volumetric hydrogen density compared to many other options. These properties make it an ideal candidate for various applications such as fuel cell vehicles, portable power systems, thermal storage, and hydrogen compression.

Comments

© 2026 The Authors. 

This article is published by Springer, licensed under a Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. 

 Sourced from the published version of record cited below.

Co-author M. Rahman is the Dean of the  Graduate School of Engineering and Management, Air Force Institute of Technology.  He was co-affiliated with Wichita State University at the time of this article.

Plain text title form: Improving hydrogen storage kinetics of polymeric composites via additions of La0.6Ce0.4Ni5 and carbon particles

DOI

10.1007/s40243-025-00338-2

Source Publication

Materials for Renewable and Sustainable Energy (ISSN 2194-1459 | eISSN 2194-1467)

Recommended Citation

Desai, F.J., Uddin, M.N., Suarez-Alcantara, K. et al. Improving hydrogen storage kinetics of polymeric composites via additions of La0.6Ce0.4Ni5 and carbon particles. Mater Renew Sustain Energy 15, 14 (2026). https://doi.org/10.1007/s40243-025-00338-2