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Abstract: The production of hydrogen by water electrolysis suffers from the kinetic barriers in the oxygen evolution reaction (OER) that limits the overall efficiency. As spin-dependent kinetics exist in OER, the spin alignment in active OER catalysts is critical for reducing the kinetic barriers in OER. However, most active OER catalysts go for surface reconstruction to oxyhydroxides that have dynamic open-shell orbital configurations with disordered magnetic moments, without showing an apparent long-range interatomic ferromagnetism; thus, controlling the spin alignment of these active catalysts is challenging. In this presentation, I will introduce our recent progress in finding the spin pinning effect to make the spins in active oxyhydroxides more aligned for higher intrinsic OER activity. The spin pinning effect is found at the interface of oxide_FM/oxyhydroxide. The spin pinning effect can promote spin selective electron transfer on OER intermediates to generate oxygens with parallel spin alignment, which facilitates the production of triplet oxygen and increases the intrinsic activity of oxyhydroxide by ~ 1 order of magnitude. Under spin pinning, the spins in oxyhydroxide can become more aligned after magnetization as long-range ferromagnetic ordering is established on the magnetic domains in oxide_FM. The spin polarization process in OER under spin pinning is also believed to be sensitive to the existence of active oxygen ligand (O(-)) in oxyhydroxide. When the O(-) is created in 1^st deprotonation step under high pH, the spin polarization of ligand oxygens will be acilitated, which reduces the barrier for subsequent O-O coupling and promotes the O₂ turnover. 

BiographyZhichuan is a professor in the School of Materials Science and Engineering, Nanyang Technological University. He received his PhD degree in Electroanalytical Chemistry and B.S. degree in Chemistry from Lanzhou University, China. His PhD training was received in Lanzhou University, Institute of Physics, CAS, and Brown University. Since 2007, he worked in State University of New York at Binghamton as a Research Associate and from 2009 he worked in Massachusetts Institute of Technology as a Postdoctoral Researcher. Dr. Xu has received several awards such as Chun-Tsung Endowment Outstanding Contribution Award - Excellent Scholar at 2018 and the Zhaowu Tian Prize for Energy Electrochemistry by International Society of Electrochemistry (ISE) in 2019. He was awarded Fellow of Royal Society of Chemistry (FRSC) on Nov. 2017. He served as the president of ECS Singapore Section. Dr. Xu is a Highly Cited Researcher by Clarivate Analytics, Web of Science (2018, 2019, and 2020).

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

Abstract:

Control of thermal transport is of significant interest for a wide range of applications, such as thermoregulation of individuals, buildings, vehicles and batteries, thermo-electric and solar-thermal energy conversion, bio/chemical sensing, and micro/nanomanufacturing. However, heat transfer processes are often difficult to actively control: heat conduction is usually diffusive in nature owing to the incoherence of heat carriers (phonons and electrons) and thermal radiation is generally broadband or have wide energy distribution. If one could engineer the transport of thermal energy, arguably the most ubiquitous form of energy, with similar degree of controllability as optical energy, a variety of energy transport and conversion technologies can be improved.  In this talk, I will introduce a thermo-photonic engineering approach to manipulate nanoscale heat transport by using surface phonon polaritons (SPhP). I will mainly focus on how the SPhP can be utilized to tailor thermal radiation properties, especially to achieve a coherent, near-monochromatic far-field thermal emission, which is a big departure from the incandescent behaviour in the classic textbook as described by the Planck's law. 

Bio: 

Dr. Shin is an Assistant Professor in the Department of Mechanical Engineering at National University of Singapore (NUS). Prior to joining NUS, she received her Ph.D. in Materials Science and Engineering from UC San Diego in 2019. She specializes in experimental investigation of fundamental nanoscale heat transport for thermal management and development of personalized thermoregulators and energy harvesting devices using thermoelectric energy conversion. In particular, she is interested in solving multidisciplinary problems, such as thermo-electric and thermo-optical engineering for controlled thermal management. She was a selected participant in 'Asian Deans' Forum 2018 The Rising Stars Women in Engineering Workshop' and a recipient of 2020 Chancellor's Dissertation Medal at UC San Diego.

Registration link to join the seminar:

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• CONTACTEmmanuelle Sougrat

​Please click this link to join the webinar:

https://kaust.zoom.us/j/98440011880

Abstract: Recently, new opportunities to deploy metal organic frameworks in membrane separation and devices have rapidly emerged. Overcoming some of the challenges of synthesizing thin, coherent films as well as integration with polymeric substrates have meant that the unique properties of MOFs can now be exploited in form factors which are viable for potential industrial applications as well as a platform to control enzymatic reactions. The high compatibility of nanosize MOF particles in polymer matrix allows fabrication of ultrathin mixed matrix coatings on porous supports which provide mechanical stability. Applications range from enhancing gas separation with functionalized UiO-66 to pervaporation desalination where defect engineered MOFs can enhance water transport for dewatering of high salinity brines. 

We also explored several approaches in facilitating pure MOF film formation on polymeric membrane substrates. First, functionalization of polymer substrates with sol-gel coatings allows more facile attachment of ligands to promote MOF nucleation as well as providing a rigid exo-skeleton for thin MOF layers to grow.  This has resulted in submicron ZIF-8 films to be readily grown for gas separation applications. Another approach is to use bioinspired polydopamine/polyethylenimine (PDA-PEI) coatings which can also nucleate thin ZIF-8 films. The ease of MOF deposition with the PDA-PEI approach in itself opens up new opportunities in spatial patterning MOFs on surfaces to exploit both the optical properties of thin MOF films as well as biomedical devices with spatially imprinted MOF-enzyme complexes for sensing. 

Biblioagraphy: Vicki Chen is the Executive Dean of the Faculty of Engineering, Architecture and Information Technology at The University of Queensland.  The faculty has over 7,000 undergraduate and postgraduate students enrolled in its programs and an extensive research portfolio and engagement with industry. She is a graduate from the Massachusetts Institute of Technology with a Bachelor of Science in Chemical Engineering and from the University of Minnesota with a Ph.D. in Chemical Engineering. Prior to joining the University of Queensland, she was the head of the School of Chemical Engineering at the University of New South Wales (UNSW). At UNSW, she was the director of the UNESCO Centre for Membrane Science and Technology (2006 – 2014). Her research interests span water/wastewater treatment, gas separation, nanomaterials, and membrane manufacturing. She has published over 192 journal papers and 12 book chapters. She also led multi-institutional projects, including a collaboration with the European Union Framework programme in advanced desalination. She was the 2017 Barrer Centre Distinguished Lecturer at Imperial College and council member of the Aseanian Membrane Society (2007 – 2014). Her research sponsors ranged from government to SMEs and multinational industrial partners and include the Australian Research Council, Australian Low Emission Coal R&D, Coal Innovation New South Wales (CINSW), Simplot, Beijing OriginWater, Printed Energy, Dairy Innovation Australia, Bluescope Steel, Sydney Water, BASF, the Cooperative Research Centre (CRC) for Polymer, and the Cooperative Research Centre for Greenhouse Gases Technologies (CO2CRC).

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

​ Zoom link: https://kaust.zoom.us/j/97352129718

ABSTRACT: The demand for renewable energy resources has become increasingly urgent due to global warming and related environmental issues.  Renewable energy systems require an energy storage solution because they are intermittent in nature. Among various alternatives, rechargeable aqueous zinc ion batteries (RAZIBs) with merits of cost-effectiveness, high safety, and environment-friendliness attracted great promise for grid-scale energy storage. Inspired by these merits, great efforts have been devoted to designing and fabricating Zn-based energy storage devices. However, the suitable cathode materials for RAZIBs and the details of the Zn2+ storage mechanism and have not been fully understood. Several methods have been proposed to tackle the issues for both at the cathode and anode side of the ZIB in this dissertation, including cathode structure engineering, interlayer strategy, and zinc anode protection.

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• CONTACTJing Guo
• EMAILjing.guo.1@kaust.edu.sa

​

ZOOM WEBINAR PRESENTATION

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Abstract: The increasing reliance of renewable energy sources such as wind and solar is a key component in the energy transition to a net-zero, carbon-free economy. Supplanting traditionally reliable energy sources such as coal, oil-and-gas, and nuclear with distributed renewable systems creates uncertainty the security of energy supply and deliverability on which the Nation depends. Underground energy storage can help to mitigate this issue through the use of gas storage in geologic traps and engineered salt caverns. Economically and socially critical gases already in underground storage include natural gas, CO₂, compressed air, natural-gas liquids such as propane and ethane, and, increasingly hydrogen, along with crude oil in the US Strategic Petroleum Reserve. Maintaining storage containment and mitigating migration of energy-related products out of the storage zone into groundwater systems, the ground surface, or the atmosphere requires both increased technical understanding and increased public awareness of the benefits and safety of underground storage systems.

In this presentation we provide an overview of the drivers for underground storage of natural gas, hydrocarbons, carbon dioxide, hydrogen, thermal energy, compressed energy, and nuclear waste in the subsurface and explore opportunities for improved characterization, lab testing, monitoring, risk analysis, and identification of key learnings and future opportunities.

Biography: A geomechanicist by training, Richard A. Schultz works to advance underground energy storage and the energy transition toward a low-carbon energy future. Currently the owner of Orion Geomechanics LLC of Cypress, Texas, he was Senior Research Scientist at The University of Texas at Austin, Principal Geomechanicist with ConocoPhillips, and Foundation Professor of Geological Engineering and Geomechanics with the University of Nevada, Reno. He has published more than 115 research papers, 5 edited volumes, 15 chapters in books or edited volumes, and delivered more than 350 presentations to academia and industry worldwide including 94 invited; his book Geologic Fracture Mechanics was published by Cambridge University Press. Dr. Schultz is a member of the Interstate Oil and Gas Compact Commission (IOGCC), the National Association of Corporate Directors (NACD), the nonprofit resource BoardSource, a Fellow of the Geological Society of America, and a licensed Professional Geologist in the State of Texas. He serves on ARMA's Board of Directors, is the Founding Chair of its Technical Committee on Underground Storage and Utilization and its Distinguished Service Award Committee.

www.raschultzunr.net

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• CONTACTProf. Thomas Finkbeiner
• EMAILthomas.finkbeiner@kaust.edu.sa

​Link to join Webinar
https://kaust.zoom.us/j/91860868841

ABSTRACT: The nanopore sensor, consisting of an individual pore with diameter of few nanometers, can detect the shape and the structure of many individual biopolymers. Combining single-molecule detection with a high-throughput, it allows us to explore rare structures in biopolymers, sometimes with atomic precision. The nanopores have been employed for DNA sequencing, protein fingerprinting, and virus detection. 

We employed a new nanopore-based technique to precisely analyse the knotting of long DNA chains in equilibrium, and to explore the dynamics of knots in single digit nanopores. We showed that DNA becomes malleable in nanoscale constrictions at short timescales, and capable of sharp buckling beyond the limit of the standard polymer model. By precisely quantifying the DNA knotting probability – which is a very sensitive measure of the inter-DNA interactions – we observed onset of inter-DNA attraction moderated by monovalent ions at high concentration. Strong DNA attraction has been observed in the past for multivalent ions, but never for monovalent ions due to a lack of instrumental techniques that could quantify moderate interactions. 

Our results are relevant not only for the understanding of DNA packing and manipulation in living cells, but also for the development of nanopore-based sequencing technologies. As we strive to employ synthetic biological machinery in different environments, unshackled from physiology, understanding inter-DNA interaction at high molarity becomes even more so biotechnologically important.

BIOGRAPHY: Slaven Garaj's research is focused on curious nanoscale phenomena at the interfaces between soft and hard matter, with particular interest in nanopores single-molecule sensors, nano-fluidics and nano-electronics. His research has been features in top journals such as Nature, Science, Nature sister journals, and PNAS, and received a keen attention in the media. While pursuing in-depth scientific understanding, his research group drives the development of technologies in the fields of medical diagnostics, water filtration and energy harvesting. His patents are licensed by biotech companies, and he is a founder of cleantech start-up company ReActo, focused on removing persistent contaminants from water.

Prof. Slaven Garaj joined National University of Singapore in 2012 as faculty member in the Departments of Physics and Biomedical Engineering, and has been awarded NRF Fellowship. Previously, he worked as a research scientist at Harvard University, where he pioneered work on 2D nanopores for DNA sequencing. He conducted his PhD thesis at the Swiss Federal Institute of Technology in Lausanne (EPFL), Switzerland in the field of condensed-matter physics.

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• CONTACTMazen E. Mero

Abstract: 

In today's fast-paced, constantly changing world, innovation plays a vital role in creating an impact on environmental technical, economical and societal fronts. Cultivating innovation as a systematic method in our formal education is expected to improve innovation culture and entrepreneurial behavior. TRIZ, a Russian acronym, which translates as "Theory of Inventive Problem Solving" developed by Genrich Altshuller in 1964 aids individuals and organizations to develop this systematic innovation culture. TRIZ is an efficient technique that provides tools and methods that allows solving challenging problems very systematically, as opposed to normal trial and error.  Although TRIZ was originally developed to solve inventive problems in engineering, it has been extended to numerous fields such as education, business, agriculture, transportation, health, etc. Fundamentally TRIZ is based on 40 inventive principles and eliminating engineering and physical contradictions. Many organizations such as Apple, BMW, GE, GM, Mahindra, NASA, P&G, Siemens, Samsung, Schneider Electric, and many more. Recently, TRIZ has been introduced as a part of basic education in France and Japan

Through this talk, the author provides a brief overview of TRIZ with some examples to inspire young engineers and researchers, so that they can consider TRIZ to solve challenging research problems.

Short Bio: 

Dr. Sreenivasa Rao Gubba is a Research Scientist at KAUST Innovation and Clean Combustion Research Center (CCRC). Dr. Gubba has 17 years of professional experience comprising of 9 years at General Electric Global Research Center (GRC) in Bangalore and 8 years at academic institutions in the UK and India. He is a level 3 TRIZ practitioner. He trained many engineers on TRIZ methodology at GE. Dr. Gubba used TRIZ to solve many real-world problems during his tenure at GE. Few technologies to mention are Boiler tube health monitoring (BTHM), an IOT based solution for addressing boiler tube health, the ducted fuel injector (DFI), a technology that is capable of reducing soot greater than 50% in large bore IC engines and late lean injectors (LLI), a technology used in current GE power gas turbines for low NOx and higher T39. His current research interests are low emission combustion technologies, alternative fuels, and gasification.

Registration link to join the webinar:

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

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• CONTACTEmmanuelle Sougrat