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Abstract: The distribution of Recent and living benthic foraminifera from nearshore, lagoonal and intertidal environments adjacent to the United Arab Emirates (UAE) coastline was studied in detail in order to 1) produce a taxonomic data bank of shallow marine foraminifera for this region; 2) identify foraminiferal associations in nearshore and transitional environments adjacent to the UAE coastline, including pristine natural environments and areas affected by anthropogenic activities: 3) provide an analogue for interpreting ancient shallow-marine and coastal depositional environments of the UAE.

Three hundred sediment samples were collected in different sedimentary environments characterized by carbonate sedimentation as nearshore shelf, beach, tidal channels, ooid shoals, lagoon, mangals, and intertidal ponds. Samples were collected within the first 15 m of water-depth. The water salinity at the sample locations ranged between 40‰ in the nearshore locations and 180‰ in the intertidal ponds. Miliolids belonging to the genera Quinqueloculina, Triloculina, Spiroloculina, Sigmoilinita are common in most of the studied locations. Larger benthic foraminifera Peneroplis and Coscinospira are particularly abundant in samples collected on seaweed and in intertidal hypersaline ponds. In hypersaline environment larger benthic foraminifera commonly show tests with abnormal growing. Hyaline foraminifera mostly belonging to the genera Elphidium, Ammonia, Bolivina and Rosalina are also common together with Miliolidae in the nearshore shelf, beach-front and outer lagoon. Ammonia and Elphidium are abundant in mangrove facies. Among the agglutinated foraminifera, the genus  Reophax occur only in the finest grain samples, particularly in lagoons and mangal environments.  Trochammina occurs exclusively and in high percentages in muddy samples collected near mangrove roots and Entzia only in high marsh facies. The majority of the ooid shoal sediments, the coarser sediments of the beach-front and samples collected in dredged channels contain a scarse number of foraminifera.

The detailed report of benthic foraminifera and sedimentary facies distribution may provide a modern analogue to understand shallow carbonate depositional environments of the past and to distinguish nearshore and lagoonal facies, mangals, marshes, and hypersaline ponds.

Biography: Flavia Fiorini was Assistant Professor of Geology/Paleontology in the Department of Earth Sciences at Khalifa University and at The Petroleum Institute (UAE) from 2009 to 2020. Prior to her appointment as Assistant Professor, she was Post Doctoral Researcher at Smithsonian Institute (Panama), Dalhousie University (Canada), and Bologna University (Italy).

Dr Fiorini is a micropaleontologist specialized in benthic foraminifera. She is interested in any aspect of foraminiferal research, in particular, recent and living foraminiferal distribution and diversity, paleoenvironmental reconstructions, and foraminifera taxonomy. Her research currently focuses on benthic foraminifera from natural and anthropogenic-affected coastal environments of the Arabian Gulf and of the South China Sea. She has several articles in paleontology and geology journals and presented her research at international conferences. Dr. Fiorini studied at the University of Modena and Reggio Emilia, Italy (Ph.D.) and at the University of Bologna (MSC).

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• CONTACTProf. Matteo Ravasi
• EMAILmatteo.ravasi@kaust.edu.sa

​ZOOM WEBINAR PRESENTATION

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• CONTACTProf. Tariq Alkhalifah
• EMAILtariq.alkhalifah@kaust.edu.sa

​ZOOM WEBINAR PRESENTATION

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• CONTACTProf. Daniel Peter
• EMAILdaniel.peter@kaust.edu.sa

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ABSTRACT: The mixed halide perovskites have emerged as efficient light absorbers to construct perovskite solar cells which continually break the power conversion efficiency (PCE) records recently. Upon element substitution, it reveals inhomogeneity in polycrystalline films due to composition separation, which leads to local lattice mismatches and thus emergent residual strains. Thus far, understanding the nature of these residual strains and their effects on photovoltaic device performance, is still absent. Herein we study the evolution of residual strain over the mixed perovskite films by using the depth-dependent grazing incident X-ray diffraction measurement. We identify the gradient distribution of in-plane strain component perpendicular to the substrate. We reveal its impacts on the carrier dynamics over corresponding devices, which is stemmed from the strain gradient induced energy bands bending of perovskite absorber as indicated by first-principles calculations. We further develop a feasible method to modulate the tensile or compressive nature and gradient distribution of residual strains in a controllable manner, which leads to enhanced PCEs up to 20.7% (certified) in devices via rational strain engineering. Moreover, we investigate the effects of strain on materials stability. It demonstrates the residual strains as a powerful toolbox to tailor the optoelectronic properties of hybrid halide perovskite materials, which further promotes device performance for not only perovskite solar cells but also quantum dot/organic solar cells.


BIOGRAPHY: Qi Chen received both his B.S. and M.S. degrees from Tsinghua University, and received his Ph.D. degree from the University of California, Los Angeles (UCLA). From 2013 to 2016, he worked as a postdoc fellow at the California Nanosystem Institute (CNSI), UCLA, under Prof. Yang Yang's supervision. In the year 2016, he joined the Beijing Institute of Technology (BIT). His research focuses on hybrid materials design, processing and applications in opto-electronics and for energy harvesting and storage. He is now working on the commercialization of perovskite photovoltaics. To date, he has published over 100 papers on highly impact journals such as Science, Nature Communications, Joule, Advanced Materails, Journal of American Chemical Society. These work has recieved wide attention over the research commuity with the total citation over 18000.

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• CONTACTMazen E. Mero

​Abstract:

The combustion of liquid fuels is of great interest in many practical applications, from industrial burners to diesel engines. Unfortunately, the combustion of a liquid feed in the form of a spray creates favorable conditions for the formation of soot particles, which represent a major concern because of their negative impact on combustion efficiency, global warming, and human health. The direct investigation of soot formation and evolution in spray combustion is a very challenging task, because of the multitude of the droplets and the interaction among numerous chemical and physical phenomena. In order to overcome these difficulties, in the latest decades significant experimental and modeling efforts have considered the combustion of simpler systems, like isolated droplets in microgravity conditions. Although the evident simplification with respect to spray combustion, microgravity droplets include most of the relevant physico-chemical processes occurring in practical combustors, including heat-up, phase-change, diffusion, radiation, and chemical reactions. From the modeling point of view, microgravity droplets represent an ideal system to study the sooting tendency for different fuels under transient conditions.

In this presentation we discuss and analyze the formation and evolution of soot from the combustion of isolated fuel droplets in microgravity conditions on the basis of a comprehensive numerical model, which includes detailed chemistry, non-ideal thermodynamics, detailed transport properties, and advanced radiative heat transfer models. Soot particles and aggregates are described using a Discrete Sectional Method validated on premixed and diffusion laminar flames, in a wide range of operating conditions. In particular, it is shown how the absence of buoyancy, combined with the effects of thermophoresis, leads to the formation and accumulation of soot clouds with concentrations significantly higher than those observed in conventional laminar flames, with impact on local temperatures, radiative heat transfer, and vaporization rates. The influence on soot tendency of addition of biofuels (such as ethanol and iso-butanol) to fossil fuels is also discussed.

Bio:

Alberto Cuoci is Associate Professor at the Department of Chemistry, Materials, and Chemical Engineering of Politecnico di Milano.  He holds a M.Sc. degree in Chemical Engineering and a Ph.D. in Industrial Chemistry and Chemical Engineering from Politecnico di Milano. He has been Invited Professor at Université Libre de Bruxelles in 2014 and at École Centrale de Paris in 2018. In 2020 he was awarded the Humboldt Research Fellowship for Experienced Researchers. The main scientific interests of Alberto Cuoci are in the field of numerical modeling of reactive flows with detailed kinetics, with special emphasis on formation of pollutants (NOx and soot) from laminar flames. He is also interested in the multiscale analysis of catalytic processes and numerical modeling of heterogeneous catalytic reactors.

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• CONTACTEmmanuelle Sougrat

Abstract:

For more than a century, carbon has been a primary component of energy systems that have enabled economies to prosper. But as the world seeks solutions to address the emissions challenge, the concept of a circular carbon economy has gained prominence.

Being an energy leader in a world of changing energy demand, we embrace our role to find effective energy solutions. The circular carbon economy is a pragmatic concept that can provide direction for a sustainable future.

In this talk I will discuss the concept of circular carbon economy. An overview of Saudi Aramco circular carbon economy activities will be presented.

Biography:

Dr. Mohammed Al-Juaied is a Research Science Consultant of the Technology Strategy & Planning at Saudi Aramco. His work is focused on developing climate-related technology strategies to support Saudi Aramco's sustainability business objectives. He has 25+ years R&D, technology development and commercialization, and project management experience, the majority with Saudi Aramco. He was the Chief Technologist of Carbon Management R&D Division and the Chief Technology Officer of Saudi Aramco Energy Ventures.

Mohammed received an MS degree in Petroleum Engineering and a Ph.D. degree in Chemical Engineering, both from the University of Texas at Austin. He completed the Mason Fellow Program in Public Policy and Management at the John F. Kennedy School of Government at Harvard University. He was also a visiting scholar at Harvard's Belfer Center with the Energy Technology Innovation Policy Research group working on the economics and policies of CCS. 

Registration link to join the seminar:

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• CONTACTEmmanuelle Sougrat