Overcoming cost, energy, and process barriers for industrially viable nanocellulose production
Sumona Garg, Avanthi Althuri
Abstract
Nanocellulose, a sustainable and biodegradable nanomaterial derived from plant biomass and bacterial sources, has emerged as a promising candidate to drive innovation across industries, including biomedical, energy, and environmental sectors. The exceptional mechanical properties, high surface area, and tunable surface chemistry position nanocellulose as a versatile alternative to petroleum-based materials. However, despite extensive laboratory-scale research, large-scale commercialization is limited by high production costs, energy demands, and scalability challenges. This review critically explores recent advancements in combined and hybrid isolation techniques that integrate mechanical, chemical, and enzymatic processes to enhance yield, reduce environmental impact, and preserve nanocellulose integrity. A particular focus is placed on pilot-scale initiatives, emphasizing strategies that address economic barriers. Innovations such as green solvents, process intensification, bioreactor design optimization, and valorisation of agricultural and industrial waste are examined as promising solutions to enable cost-effective and energy-efficient nanocellulose production. Furthermore, this review repositions nanocellulose as a scalable and industrially relevant material, capable of supporting circular economy models and reducing reliance on fossil-based resources. It highlights the role of cross-disciplinary collaboration, regulatory frameworks, and emerging technologies in translating nanocellulose from laboratory breakthroughs to industrial realities. By addressing critical gaps in processing and scalability, nanocellulose holds immense potential to contribute to a sustainable industrial revolution, fostering eco-friendly alternatives across multiple sectors while minimizing environmental impacts.