Abstract:   

We study singular jets from the collapse of drop-impact craters, when the drop and pool are of different immiscible liquids. The fastest jets emerge from a dimple at the bottom of the rebounding crater, when no bubble is pinched off. The parameter space is considerably more complex than for identical liquids, revealing intricate compound-dimple shapes. In contrast to the universal capillary–inertial drop pinch-off regime, where the neck radius scales as R∼t2/3 , for a purely inertial air dimple the collapse has R∼t1/2 . The bottom dimple dynamics is not self-similar but possesses memory effects, being sensitive to initial and boundary conditions. Sequence of capillary waves can therefore mould the air dimple into different collapse shapes, such as bamboo-like and telescopic forms. The finest jets are only 12 μm in diameter and the normalized jetting speeds are up to one order of magnitude larger than for jets from bursting bubbles. We study the cross-over between the two power laws approaching the singularity. The singular jets show the earliest cross-over into the inertial regime. The fastest jets can pinch off a toroidal micro-bubble from the cusp at the base of the jet.

Bio:  

Ziqiang Yang earned his Bachelor degree in Process Equipment & Control Engineering from China University of Petroleum (Beijing) in 2014. Then he obtained his Master's degree in Mechanical Engineering (Thermofluids direction) in Khalifa University of Science and Technology, Sas Al Nakhl Campus in Abu Dhabi, UAE in 2016. Now Ziqiang Yang is a PhD candidate of High-Speed Fluids Imaging Laboratory at KAUST working under the supervision of Professor Sigurdur Thoroddsen. His research interests have been focusing on the use of ultra-high-speed video imaging to study the dynamics of free-surface flows and Tomo-PIV studies in turbulence. This includes the breakup of drops and bubbles, singularities in hydrodynamics and viscoelastic fluids.

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• CONTACTEmmanuelle Sougrat

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Abstract: In 2004, the introduction of the polymers of intrinsic microporosity — PIMs — initiated the modern age of membrane polymers. In contrast to state-of-the-art materials, PIMs permit order of magnitude higher permeability, which is paramount for a minimal capital cost of membrane systems. In this seminar, the rationale behind the engineering of ultramicroporous polymers is introduced with some gas separation examples. The focus is then narrowed down to the carbon dioxide/methane separation case study to display how gas mixture effects depress the performance of such advanced materials. Specifically, the experimental analysis of the multicomponent gas transport behavior of conventional and modern materials discloses the relationship between microstructure and chemical structure vs. separation performance. These observations suggest that polymer functionalization can improve the gas selectivity of PIMs — for truly efficient membrane systems — and simultaneously contrast the discussed adverse mixture effects. Finally, it is shown that more work is needed to understand the PIMs functionalization effect on separation performance; and, ultimately, ¬to develop the next-generation polymers for energy-efficient gas separations

Biography:  Dr. Giuseppe Genduso is a Research Scientist in the Advanced Membranes and Porous Materials (AMPM) center at KAUST. He received his BSc and MSc (2012) from the University of Palermo in Italy and his Ph.D. in Chemical Engineering from Katholieke Universiteit Leuven (KULeuven, Belgium) in 2016. He pursued a postdoctoral fellowship at KAUST in the group of Prof. I. Pinnau. His research interests are in gas and liquid separation through membrane-based systems, analysis of the fundamental of sorption/adsorption and diffusion of gases and liquid in bulk- and thin-films, advanced polymer and carbon molecular sieve membrane materials, process engineering for conventional/membrane hybrid systems, and novel desalination methods. His early work on membrane science and technology was recognized by the North American Membrane Society (NAMS) with the 2020 Young Membrane Scientist Award.

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• CONTACTFawwaz Elahi
• EMAILfawwaz.elahi@KAUST.EDU.SA

Abstract: 

Modern IC engines are characterized by high efficiency and low emission. These could be achieved by a pre-chamber assisted ultra-lean combustion or by operating SI engines at higher compression ratios. But there are challenges associated with both, which will be addressed in the current work.

Understanding pre-chamber combustion

The current work uses computational fluid dynamics (CFD) to unravel the fundamental understanding of the ignition characteristics of pre-chamber (PC) combustion engines. Despite being around for decades, fundamentals of the underlying physics of pre-chamber combustion engines are relatively unexplored. Under the Fuelcom III consortium, CCRC and Saudi Aramco are working towards understanding the fundamental quantities of PC systems. Preliminary results regarding the ignition mechanism of the main chamber by pre-chamber turbulent jets will be presented.

Unraveling Knock in modern SI engines

Even though knock in SI engine is a familiar topic for many decades; it is rather underexplored due to its stochastic behavior. The unusual knocking cycles are few and far between even in knocking conditions in engines. The main objective of the study is to understand the physics behind knock and use that knowledge to find better-operating conditions for future SI engines. Preliminary results of numerical experiments performed to benchmark the commercial software Converge against the in house DNS solver KARFS will be presented.

Bio:

Sangeeth Sanal, obtained his Bachelor's degree in Mechanical Engineering from the Indian Institute of Technology Hyderabad in 2014. He then joined The University of Tokyo, Japan as a JICA fellow and completed Masters working under the supervision of Prof Yuji Suzuki. During Masters, he worked on elucidating chemical quenching in narrow channels using TALIF. Sangeeth joined the Computational Reacting Flow Lab (CRFL) as a Ph.D. student in 2017 under the supervision of Prof. Hong G Im. 

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• CONTACTEmmanuelle Sougrat

Zoom Link:
https://kaust.zoom.us/j/95353466504


ABSTRACT: Finding luminescent materials with narrow-band emissions, high stability, and high photoluminescence quantum yield (PLQY), yet relatively fast radiative decay rates, has been an outstanding research challenge. This thesis aims to develop different luminescent materials and examine their structural and optical properties for light-emitting applications. The first part of this thesis covers the controversy regarding the origin of emission in zero-dimensional perovskites (0D), Cs₄PbBr₆ and Cs₄PbI₆, through a comparative analysis between 0D and three-dimensional (3D) perovskites. A series of optical studies excluded the 3D phases as the origin of emission in these materials. In parallel, the results from the DFT proposed the defects as a possible origin of emission. 

The second part of the thesis addresses the shortcoming of lead-based perovskites in terms of toxicity and stability, motivated by the high demand for sustainable materials with analogous electrical and structural properties. Thus, a series of solid-state Zn-based and Mn-based ternary compounds were investigated with and without doping. The compounds' photoluminescence peaks were between 520 nm – 525 nm, with PLQY between 34% - 60%. 

Finally, CsMnBr₃ NCs were synthesized revealing an intense red PL peak centered at 650 nm and a PLQY as high as 54% along with a remarkable excitation spectrum and surprisingly short lifetimes. The single crystals of this composition were also reported with a PL peak at 640 nm and a relatively high PLQY of 6.7% under the excitation at 360 nm.

Further, a combination of structural and optical analysis attributed the green and red luminescence to the tetrahedral and octahedral environment of Mn²⁺, respectively. These materials represent a milestone towards lead-free luminescent materials with interesting optical properties.  

This dissertation aims at engineering different materials to address critical aspects in the field including stability and good luminescence properties while simultaneously examining the photophysics and mechanisms of the corresponding properties. This work paves the way for finding sustainable light-emitting materials for the next generation of light-emitting applications.

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• CONTACTJawaher Almutlaq
• EMAILJawaher.Almutlaq@kaust.edu.sa

​Zoom meeting:
https://kaust.zoom.us/j/94165188647

ABSTRACT: Over the last decade, impressive developments in lead halide perovskites (LHPs) have made them leading candidate materials for photovoltaics (PVs), X-ray scintillators, and light-emitting diodes (LEDs). The success of LHPs NCs in lighting and display applications is mainly due to their tunable bandgap, narrow emission, high photoluminescence quantum yield (PLQY), and cost-effective fabrication. Consequently, a comprehensive understanding of the design principles of LHP NCs will fuel further innovations in their optoelectronic applications. 

This dissertation centers on the synthesis and self-assembly of LHP NCs. At first, we examine the chemistry and capability of different colloidal synthetic routes with regard to controlling the shape, size, and dimensionality of the resulting LHPs NCs, including 0D nanospheres, 2D nanoplates, and 3D nanocubes. Starting from the LHPs NCs, nanowires, nanoplates, and superstructures were successfully obtained via various self-assembly strategies. We systematically investigated the mechanisms of LHP NC self-assembly, the kinetics of their morphological evolution and phase transitions, and driving forces that govern the self-assembly process. The assembled LHP NCs manifest desirable properties (e.g., superfluorescence, improved photoluminescence lifetime; and enhanced stability against moisture, light, electron-beam irradiation, and thermal-degradation) that translate into dramatic improvements in device performance.

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• CONTACTLiu Jiakai
• EMAILliu.jiakai@kaust.edu.sa

ZOOM WEBINAR PRESENTATION

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Abstract: Outcrop and shallow subsurface examination of the Miami oolite (MO) of South Florida suggest it is representative of a grainstone-rich reservoir layer (high-frequency sequence) that has been surficially karsted (eogenetic karst), and therefore may be considered an analog for subsurface reservoirs/aquifers with “high” permeability extremes. The deposit can potentially serve to illustrate heterogeneity in this type of reservoir, as imparted by facies changes and early meteoric diagenesis.

The MO displays the preserved morphology of a fossilized ooid sand body, even though it has been subaerially exposed in a tropical climate since its deposition during the last interglacial highstand. The depositional motif is one of a dip-oriented tidal bar belt of shoals and shallow channels fronted by a strike-oriented barrier bar. The barrier bar comprises cross-stratified grainstones and locally bioturbated grain/packstones, whereas the tidal shoals and channels are more commonly bioturbated pack/grainstones. Surficial karst features (dolines and stratiform caves) have been added during ca 120 kyr of subaerial exposure, but of more significance is the associated solution-enhancement of the widespread burrowed facies.

Since the MO is the uppermost portion of the Biscayne Aquifer, there is a rich understanding of fluid flow through the deposit which sheds valuable insight on the larger-scale, shallow subsurface plumbing. The pore system comprises matrix pores (interparticle and separate vugs) and touching-vug macropores that are commonly associated with burrowed [Ophiomorpha] intervals. GPR, well, and flow-test data indicate that matrix porosity provides most of the groundwater storage, whereas the various types of touching vug macropores account for the majority of flow. The dolines and shallow caves seem to be sufficiently spaced to prevent direct connection, with the result that they are less important in terms of regional flow than the prevailing pore system.

The key observations of the MO reported here are that depositional facies (burrowed intervals) have directed early-stage dissolution (creating touching-vug macropores) to produce the stratiform high-permeability zones that dominate flow at the larger scale. This reinforces the notion that a fundamental understanding of depositional facies variation remains critical for characterizing reservoir quality and performance, even in reservoirs impacted by substantial diagenetic overprint.

Biography: Paul M. (Mitch) Harris received a B.S. (1971) and M.S. (1973) from West Virginia University and a Ph.D. (1977) from the University of Miami, Florida. He is an Adjunct Professor at the University of Miami (Florida) CSL — Center for Carbonate Research. Currently, he is involved in research projects focusing on the controls and patterns of carbonate sediment production and dispersal on shallow platforms.

Mitch retired in 2014 after a 36 year-long industry career with Chevron. As a senior research consultant and Chevron Fellow, he performed carbonate research, technical service projects, consulting, and training for the various operating units of Chevron. His career’s work centered on facies-related, stratigraphic, and diagenetic problems that pertain to carbonate reservoirs and exploration plays in most carbonate basins worldwide.

Mitch has published numerous papers, edited several books, and been active in geologic societies, especially AAPG and SEPM. For AAPG he has been a distinguished lecturer in 1987–1988 and international distinguished lecturer in 2000–2001; received the Wallace E. Pratt Memorial Award for best original article published in the AAPG Bulletin in 1998; received the Robert H. Dott Sr. Memorial Award twice for best memoirs published by AAPG in 2004 and 2006; received the John W. Shelton Search & Discovery Award for best contribution to the AAPG Search and Discovery website in 2009; received Honorary Membership in 2012; received the Sidney Powers Memorial Award, AAPG’s most distinguished award, in 2015; and in 2017 was included in the AAPG Division of Professional Affairs publication Heritage of the Petroleum Geologist honoring top geologists. He was awarded Honorary Membership from SEPM in 2002, served as a president of SEPM in 2010–2011, and received an Honorary Life Award from the Permian Basin Section of SEPM in 2011.

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

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ABSTRACT: We discuss the discovery and recent developments of colloidal lead halide perovskite nanocrystals (LHP NCs_, NCs, A=Cs⁺, FA⁺, FA=formamidinium; X=Cl, Br, I) [1-5].  LHP NCs exhibit spectrally narrow (<100 meV) fluorescence, originating form bright triplet excitons [6], and tunable over the entire visible spectral region of 400-800 nm. Cs- and FA-based perovskite NCs are promising for LCD displays, for light-emitting diodes and as precursors/inks for perovskite solar cells.  Perovskite NCs also readily form long-range ordered superlattices, which exhibit accelerated coherent emission (superfluorescence) [7]. Unique structure engineerability of perovskites allows for (nearly) independent tuning of the emission color and radiative rates, which can be used in printable unicolor security tags [8].

1. L. Protesescu et al. Nano Letters 2015, 15, 3692–3696
2. L. Protesescu et al. J. Am. Chem. Soc. 2016, 138, 14202–14205
3. L. Protesescu et al. ACS Nano 2017, 11, 3119–3134
4. M. V. Kovalenko et al. Science 2017, 358, 745-750
5. Q.A. Akkerman et al. Nature Materials 2018, 17, 394–405
6. M. A. Becker et al, Nature 2018, 553, 189-193
7. G. Raino et al. Nature 2018, 563, 671–675
8. S. Yakunin et al. submitted

BIOGRAPHY: Maksym Kovalenko is a professor at ETH Zürich (Swiss Federal Institute of Technilogy in Zürich), Switzerland. He received his PhD degree in nanoscience and nanotechnology from Johannes Kepler University Linz, Austria, in 2007. He then joined the University of Chicago as a postdoctoral fellow, studying the surface chemistry and self-assembly of colloidal nanocrystals. In 2011, Kovalenko joined ETH Zürich and Empa (Swiss Federal Laboratories for Materials Science and Technology) as a tenure-track assistant professor, an associate professor in 2017, and a full professor in 2020. His research interests include chemistry, physics, and applications of functional inorganic materials, including colloidal quantum dots, novel solid-state compounds, and materials for electrochemical energy storage. Present research efforts of the Functional Inorganic Materials group concern: (i) the precision synthesis of highly luminescent semiconductor nanocrystals; (ii) nanocrystal surface chemistry; (iii) exploration of novel semiconductor materials by solution- and solid-state synthesis; (iv) novel semiconductors for hard radiation detection; (iv) novel materials and concepts for Li-ion and post-Li-ion rechargeable batteries. Many of these activities are strongly linked to industrial partners. Academic collaborations involve various groups ranging from first-principles theory of materials to applications in photovoltaics and thermoelectrics He has co-authored 270 publications, 3 book chapters, and holds 11 patent applications. He has been the recipient of highly prestigious awards including ERC Consolidator Grant (2018), ERC Starting Grant (2012), Ruzicka Preis (2013), and Werner Prize (2016). He is a Clarivate Highly Cited Researcher since 2018. He also serves as an associate editor of the Chemistry of Materials.

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• CONTACTMazen E. Mero