Papadokonstantakis, Stavros

Wang, Pingping

2026-01-14T13:36:11Z

2026-01-14T13:36:11Z

2025-04-08

<div class="csl-bib-body"> <div class="csl-entry">Papadokonstantakis, S., &#38; Wang, P. (2025, April 8). <i>A prospective life cycle optimization framework of integrating CCS/CCU for sustainable industrial future</i> [Poster Presentation]. Carbon capture, utilization and storage, Gordon research conference, Ventura, United States of America (the). http://hdl.handle.net/20.500.12708/224385</div> </div>

http://hdl.handle.net/20.500.12708/224385

Hard-to-abate industrial sectors, including cement, steel, chemical, and refinery industries, account for approximately 25% of global energy consumption and around 20% of total CO₂ emissions. Integrating Carbon Capture and Storage/Utilization (CCS/CCU) systems offers a promising pathway to decarbonize these sectors. However, the transformation of energy and industry presents significant integration challenges, particularly in the context of rapidly evolving environmental conditions and technologies. This study introduces a Prospective Life Cycle Optimization (pLCO) framework that addresses these dynamic changes in both background and foreground systems to model and evaluate CCS/CCU networks for hard-to-abate sectors, focusing on the cement and chemical industries in Europe. The framework optimizes integration designs across a range of scenarios from 2025 to 2050. The optimization problem is formulated as a multi-objective mixed-integer linear programming (MILP) model, balancing environmental metrics assessed through prospective life cycle assessment (pLCA) and total levelized production costs evaluated via prospective techno-economic assessment (pTEA). To tackle uncertainties in prospective system integration, a two-stage stochastic optimization approach is employed, considering factors such as emissions, carbon pricing, production costs, CO₂ storage capacities, and product pricing uncertainties. This framework serves as a critical tool for governments and businesses to identify Pareto-optimal decision strategies under diverse economic and environmental policies. It provides a comprehensive evaluation of the integration potential of emerging CCS/CCU technologies across various countries and regions over long-term periods, supporting the development of sustainable industrial futures through informed decision-making.

en

Carbon Capture and Storage

Life Cycle Assessment

Life Cycle Optimization

A prospective life cycle optimization framework of integrating CCS/CCU for sustainable industrial future

Presentation

Vortrag

Poster Presentation

E6

C6

E3

Sustainable Production and Technologies

Modeling and Simulation

Climate Neutral, Renewable and Conventional Energy Supply Systems

30

50

20

E166-06-3 - Forschungsgruppe Prozesssystematik für nachhaltige Ressourcen

0009-0002-1196-4035

Carbon capture, utilization and storage, Gordon research conference

06-04-2025

11-04-2025

On Site

Event for scientific audience

Ventura

US

Gordon research conference

Wang, Pingping

Single Track

Chemische Verfahrenstechnik

Biologie

Industrielle Biotechnologie

2040

1060

2090

50

35

15

conference poster not in proceedings

http://purl.org/coar/resource_type/c_18co

Publications

en

none

no Fulltext

E166-06 - Forschungsbereich Bioressourcen und Pflanzenwissenschaften

E166-06-3 - Forschungsgruppe Prozesssystematik für nachhaltige Ressourcen

0009-0002-1196-4035

E166 - Institut für Verfahrenstechnik, Umwelttechnik und technische Biowissenschaften

E166-06 - Forschungsbereich Bioressourcen und Pflanzenwissenschaften