V. Basil Hans | International Journal of Chemical Engineering and Processing | Vol 12, Issue 1 | pp. 52-61 | ISSN: 2455-5576
Abstract
The chemical industry is a major contributor to global greenhouse gas emissions due to its reliance on fossil-based feedstocks, energy-intensive processing routes, and long-lived capital infrastructure. Achieving international climate targets therefore requires deep decarbonisation across the entire chemical value chain, a transition complicated by technological limitations, economic risks, and systemic operational barriers. This article critically evaluates key emission-reduction pathways, including electrification of process heat, substitution of fossil resources with bio-based and renewable alternatives, deployment of green hydrogen, carbon capture utilisation and storage strategies, and the adoption of circular production models supported by advanced process intensification. Emphasis is placed on integrating digital optimisation, life-cycle thinking, and resource efficiency to enhance sustainability performance without compromising productivity or product quality. The discussion also examines enabling factors such as policy incentives, carbon pricing mechanisms, industrial symbiosis, and collaborative innovation ecosystems that accelerate commercial deployment of low-carbon technologies. Persistent constraints are analysed, including capital investment challenges, infrastructure readiness, supply chain transformation, and uncertainties surrounding technology maturity and scale-up feasibility. By synthesising recent technological developments with strategic industrial priorities, the article outlines practical transition pathways that allow chemical manufacturers to remain economically competitive while aligning with net-zero ambitions. Overall, it provides a comprehensive framework for guiding stakeholders toward resilient, low-carbon, and resource-efficient chemical manufacturing systems capable of meeting future global demand responsibly. It further highlights workforce reskilling, cross-sector electrification linkages, transparent sustainability metrics, and robust techno-economic assessment methodologies as essential components for informed decision-making, risk mitigation, and long-term industrial transformation planning across global chemical clusters worldwide.Keywords: Decarbonisation, the chemical industry, green hydrogen, electrification, carbon capture and use (CCU), sustainable feedstocks, and the industrial energy transition
Keywords
Green Hydrogen, chemical industry decarbonization, Carbon capture utilization and storage (CCUS), circular chemical manufacturing
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How to cite this article
@article{HansVB2026,
author = {V. Basil Hans},
title = {Getting Rid of Carbon: A New Direction for the Chemical Industry},
journal = {International Journal of Chemical Engineering and Processing},
year = {2026},
volume = {12},
number = {1},
pages = {52--61},
issn = {2455-5576},
url = {https://journalspub.com/publication/ijocep/article=26400}
}