Guest Seminar - Scalable Decision-Making in Chemical Engineering for a Greener Future

Humans are facing many unprecedented environmental problems, such as waste pollution and climate change. Addressing these urgent issues calls for advanced decision-making frameworks to design, plan, and operate various infrastructures for waste valorization and energy transition with high efficiency and reliability. First, I will describe a unified optimization framework that enables the optimal design and operation of large-scale waste valorization infrastructures. This framework reveals the economic viability and environmental benefits of such infrastructures and informs policy implications. Second, I will outline an optimization framework that integrates smart electrification with chemical processes. This offers grid flexibility, smoothens the energy transition, and reduces chemical production costs. Additionally, I will present the algorithms and software we've developed to address these complex, large-scale decision-making challenges, leveraging graph theory, classical decomposition methods, and new computing architectures like GPUs.