​Abstract:

According to a United Nations report, chemicals production and consumption are to be doubled in the next 10 years to fulfil our essential needs. It's simply not going to happen unless we adopt a circular economy approach. The UKRI Interdisciplinary Centre for Circular Chemical Economy was established in January 2021 to kick start the timely transition of the UK's £32bn chemical industry into a circular system. In this talk, I will outline the vision and remit of the Centre, and discuss why we need a whole system approach and an interdisciplinary team to address the challenge. I will then give some examples of the on-going research in our lab to tackle the challenges in the development of the circular chemical economy. I will show how we combine classic electrochemical engineering with cutting-edge enabling tools such as deep learning and digital twin technologies to deliver novel chemical recycling systems to recover chemical feedstocks from end-of-life materials and captured CO₂ emissions.  

Bio:

Professor Jin Xuan graduated with a PhD in energy engineering from The University of Hong Kong in 2012. His academic career in the UK started in 2014, when he took up a Lectureship in the School of Engineering and Physical Sciences at Heriot-Watt University. Professor Xuan joined Loughborough University in 2018 as a Senior Lecturer, was promoted to Professor and awarded a Personal Chair in Low Carbon Processes in 2019 and became Head of the Department of Chemical Engineering in 2020. He is the Editor of Energy and AI (Elsevier), and is now working with IChemE as the founding Editor-in-Chief of the new journal Digital Chemical Engineering. Professor Xuan is currently leading the £4.5 million UKRI Interdisciplinary Centre for Circular Chemical Economy. Professor Xuan is the recipient of the Beilby Medal and Prize 2020 jointly from SCI, RSC and IoM3, Highly Commended Prizes for the IChemE Global Awards (Research Project, 2019) and IET Innovation Award in Energy and Power (2018) and Scottish Energy News Researcher of the Year Award in Energy and Materials in 2015.

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https://kaust.zoom.us/j/93661550863

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• CONTACTEmmanuelle Sougrat

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https://kaust.zoom.us/j/91819584759

Abstract: The petrochemical industry grew to become one of the world's largest industries during the 20th century. It is expected that it will continue to grow, as the world's population gets wealthier, social dynamics change and people demand more affordable and useful materials. The industry recognizes that the Earth's carrying capacity is limited. It is adapting to seek to become a truly sustainable ‘carbo’-chemical industry. This paper will address the three main challenges of this transition: shifting hydrocarbon stock, climate change and circular economy. As the energy sector transitions from oil, coal and eventually natural gas, it is expected that the chemical industry will have access to abundant hydrocarbon stocks for which it can find valuable uses. But rising CO2 prices and increasing upgrading costs will likely encourage greater use of alternative, low-carbon feedstocks. In particular, there may be a development of biomass for manufacturing oxygenated chemical intermediates and bio-based materials. To help tackle climate change, the industry will need to reduce the CO2 emissions of its processes and utilities (energy sources). Ways to achieve this will include efficiency improvements, electrification of utilities and processes and switching to renewable H2; upgrading by-products to chemicals, and CO2 capture and storage or utilization (CCS/CCU). The issue of plastic waste pollution is combining with the challenges discussed above to push society and governments towards a more circular economy. Customer demand for sustainable products is growing. New regulations (and technologies) are being rolled out for waste collection, sorting and recycling. In addition, the industry is making pledges to produce and use more sustainably. However, it is expected that fresh carbon will still have to enter the material cycle. It will be needed to feed the growth of the chemical industry and to compensate for inevitable recycling losses. For a truly circular industry, this fresh carbon would come from a renewable source, i.e. from atmospheric CO2, initially via biomass and later possibly from direct CO2 capture and utilization (CCU).

Biography: Jean-Paul Lange is a principal research scientist at Shell Projects & Technology in Amsterdam, the Netherlands, where he has been exploring novel catalytic processes for producing fuels and chemicals, initially from natural gas and oil and, since more than twenty years from biomass and plastic wastes. His research embraces heterogeneous catalysis, chemical engineering, conceptual process design, manufacturing economics and technology strategy. 

Jean-Paul Lange is also a Professor in Chemical Biorefining at the University of Twente, the Netherlands, where he is investigating thermo-chemical and -catalytic routes to convert biomass to fuels and chemicals and to recycle plastic wastes. Before joining Shell, he was a postdoctoral fellow at the Lehigh University in Bethlehem (Pennsylvania/US), got his Ph.D. at the Fritz-Haber Institute (Max Planck Society) in Berlin (Germany), and graduated at the University of Namur (Belgium). Jean-Paul Lange is co-author of >100 patent series, >60 scientific publications, 7 book chapters and is working on co-editing a scientific book. He is also contributing to public science through various advisory boards in the Netherlands, Europe and for the European Commission. 

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• CONTACTFawwaz Elahi
• EMAILfawwaz.elahi@kaust.edu.sa

ZOOM WEBINAR PRESENTATION

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Abstract: Almost universally, geoscientists interpreting the stratigraphic record infer processes based on incomplete data; in such settings, conceptual models provide an important framework for organizing observations, generating interpretations, and making predictions.  As powerful as these conceptual models may appear, they should be able to withstand independent testing, such as being consistent with the laws of physics.  The purpose of this presentation is to start a discussion regarding two conceptual paradigms prominent in sedimentary geology: 1) that unfilled atoll lagoons represent a transient state, destined to be filled by debris from their annular reef, and 2) that fair-weather and storm wave bases represent consistent, objectively definable datums for facies and stratigraphic interpretation.  Simple numerical hydrodynamic simulation models reveal several insights that cast doubt on the plausibility of these paradigms, in stark contrast with their widespread application in stratigraphic interpretations.

Biography: Gene Rankey is Professor of Geology at the University of Kansas, where he serves as Co-Director of the Kansas Interdisciplinary Carbonates Consortium.  His research program focuses on unravelling and quantifying the nature and controls on variability in surface processes and geomorphic forms in tropical marine and nearshore sedimentary systems.  It emphasizes field study of modern ramps and atolls, where both process (waves, tides, chemistry, etc.) and product (e.g., sediment, biota, geomorphology) can be observed, and their relations rigorously evaluated and numerically modelled. Recent field areas range from the Pacific (Kiribati, French Polynesia, Cook Islands), to Southeast Asia (Malaysia, Indonesia), to the Caribbean (Bahamas, Yucatan, Mexico, Turks and Caicos).  Beyond efforts that focus on modern systems, the research has direct application to understanding geologic analogs in the stratigraphic record via development of testable quantitative and conceptual models for the origin and heterogeneity of the stratigraphy of ancient carbonate reef, shoal, ramp, and platform successions. Key means include high-resolution, sequence-based analysis of subsurface analogs using core, log, and seismic data, and includes recent efforts in Malaysia, Kansas, Saudi Arabia, and Australia.  Rankey has served as editor of Journal of Sedimentary Research and numerous books, and as associate editor of Sedimentology, Journal of Sedimentary Research, and Geological Society of America.  He has won several awards for Outstanding Paper (2002, 2008, 2010, JSR), and Outstanding Poster (2017, AAPG), and was an AAPG Distinguished Lecturer (2008-2009).

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• CONTACTProf. Volker Vahrenkamp
• EMAILvolker.vahrenkamp@kaust.edu.sa

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https://kaust.zoom.us/j/97545030363

Abstract: Blood clotting or thrombosis is a major cause of morbidity and mortality whether as a consequence of cardiovascular disease, stroke, or pulmonary thromboembolism. Likewise, the clinical performance of artificial organs that interface with the cardiovascular system has been limited because of the risk of thrombosis. Current pharmacologic agents that prevent thrombosis are unfortunately associated with a significant risk of bleeding.  We will review current strategies to generate a safer generation of anticoagulants as well as materials-based approaches to improve the performance of blood-contacting devices.

Bio: Elliot L. Chaikof, MD, Ph.D. is the Johnson and Johnson Professor of Surgery at Harvard Medical School. Dr. Chaikof received his B.A. and M.D. degrees from Johns Hopkins University and his Ph.D. in Chemical Engineering from the Massachusetts Institute of Technology. He completed his training in General Surgery at the Massachusetts General Hospital and in Vascular Surgery at Emory University. Dr. Chaikof’s clinical interests focus on the surgical treatment of vascular disease. As an engineer and surgeon with expertise in biomolecular engineering, chemical biology, and materials science, Dr. Chaikof has published in the areas of biomaterials, tissue engineering, drug delivery, and drug discovery. To date, Dr. Chaikof has been the primary mentor for over 60 postdoctoral research associates and 17 doctoral students. Of his former graduate students and postdoctoral research fellows, 22 hold tenured faculty positions in Departments of Chemical, Mechanical, and Biomedical Engineering, as well as Chemistry in the United States and abroad. Many of his former students also hold major leadership positions in the pharmaceutical, biotechnology, and medical device industries. Dr. Chaikof currently serves as a member of the National Materials and Manufacturing Board Roundtable on Biomedical Engineering Materials and Applications (BEMA) and the Standing Committee on Biotechnology Capabilities and National Security Needs of the National Academies, as well as on the Committee on Emerging Science, Technology, and Innovation in Health and Medicine (CESTI) of the National Academy of Medicine.

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• CONTACTAliyah Fakim
• EMAILaliyah.fakim@kaust.edu.sa

​Abstract:

The validation of detonation simulations against experimental measurements requires engaging in an ensemble of modeling challenges. One of the more recent considerations for detonation modeling is thermal non-equilibrium. Recent works have shown that inclusion of non-equilibrium terms in detonation models have an effect on experimentally measured variables. In simplified terms, thermal equilibrium is the assumption that the gas temperature is a good parameter to describe the thermodynamics of the system. In systems with thermal non-equilibrium this no longer applies necessarily and thermodynamical models need to be adapted to reflect that fact. One possibility for modeling of non-equilibrium effects is the deployment of State-to-State (STS) chemical-kinetic models. This framework of modeling allows for a detailed description of the composition of the gas instead of an assumption of the relationship between gas temperature (or any other variables) and thermodynamics.

In this seminar we will examine what it means for the gas to be in thermal non-equilibrium, what the consequences are for modeling and how the STS framework can improve modeling of detonations.

Bio:

João Vargas has received both his masters and PhD degrees in Physics Engineering from University of Lisbon in Portugal, completed in November 2020. During his PhD he was a visiting scholar in the University of Illinois at Urbana Champaign in the United States. Since June 2021 João is a post-doctoral fellow at KAUST in the group of Professor Deanna Lacoste in the Clean Combustion Research Center. His research focus is on detailed kinetic and radiation models for gases and plasmas.

Registration link to join the seminar:

https://kaust.zoom.us/j/93661550863

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• CONTACTEmmanuelle Sougrat

​Abstract:

Hydrogen combustion in internal combustion engines is an attractive candidate for addressing climate change owing to its near-zero emissions. Hydrogen fuel has been studied in spark ignition (SI) engines and showed a high octane sensitivity, denoted as the difference between RON and MON. The only harmful emissions from hydrogen combustion in SI mode are nitrogen oxides as a result of high temperature nitrogen oxidation reactions. Homogeneous Charge Compression Ignition (HCCI) is a low temperature combustion technology that can potentially solve the problem of NOx emissions, at the same time achieving higher thermodynamic efficiency. Several studies have investigated the combustion of pure hydrogen in HCCI mode at different operating conditions. However, there has not been a comparison between hydrogen and reference hydrocarbon fuels, such as n-heptane and iso-octane. The present study focuses on evaluating the HCCI performance of hydrogen in the light of the Lund-Chevron HCCI fuel number. The experiments are conducted in a modified Cooperative Fuel Research (CFR) engine to run in HCCI conditions using hydrogen port injection. Here, the auto-ignition of hydrogen is compared to the auto-ignition of reference fuels at different engine speeds and intake temperatures. The results show that hydrogen HCCI combustion is sensitive to engine operating conditions with hydrogen behaving as a high octane fuel at low engine speeds and intake temperature, while low octane rating is encountered with increasing speed and intake temperature. The study also sheds light on the problems and drawbacks associated with hydrogen combustion in HCCI engines, as well as potential solutions to such problems.

Bio:

Abdulrahman obtained his bachelor degree in Mechanical engineering from King Fahd University of petroleum and minerals (KFUPM) in 2017. He then joined ROSEN technologies as a research engineer in the field of non-destructive testing of oil pipelines. In 2018, He joined KAUST as a master student and defended his thesis about the Argon power cycle under the supervision of Professor Bengt Johansson and Professor R. W. Dibble. He is now a PhD student in Professor Mani Sarathy group. His research focuses on the utilization of next generation carbon-free fuels such as hydrogen and ammonia in internal combustion engines.

Registration link to join the seminar:

https://kaust.zoom.us/j/93661550863

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• CONTACTEmmanuelle Sougrat

​Abstract:

The extensive concerns of limited resources, safety and the environmental issues of current energy storage techniques has fired new research to sustainable battery revolution to satisfy the burgeoning global market. Aqueous zinc-based batteries may be able to address these issues but suffer from fast capacity fade and poor ion diffusion kinetics; due to unstable structures and non-optimised cathode materials and electrolytes. The recent progress of cathode materials and electrolyte optimisation for zinc-based batteries from my group will be discussed in the talk.

Bio:

Dr. Guanjie He is an Associate Professor in Chemistry, University of Lincoln and an Honorary Lecturer in the Department of Chemistry and Department of Chemical Engineering, University College London (UCL). He received the PhD degree in Chemistry from UCL. Dr. He's research focused on materials for electrochemical energy storage and conversion applications, especially electrode materials in aqueous electrolyte systems. Dr. He has published over 90 papers in peer-reviewed journals with total citation of over 2700, and an h-index of 29.

Registration link to join the webinar:

https://kaust.zoom.us/j/93661550863

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• CONTACTEmmanuelle Sougrat