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Electrochemical C–H Chalcogenation ! #worldresearchawards #researchaward #researcher #chalcogenation

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Electrochemical C–H chalcogenation is rapidly emerging as a transformative strategy in modern organic synthesis, offering a greener and more sustainable route to construct valuable C–S, C–Se, and C–Te bonds. By using electricity as a clean reagent, this approach eliminates the need for stoichiometric oxidants and harsh chemical conditions, aligning perfectly with the principles of green chemistry. This video explores the latest breakthroughs that are reshaping chalcogen chemistry through electrochemical innovation. Traditional C–H functionalization methods often rely on expensive catalysts, toxic oxidants, or multi-step procedures. In contrast, electrochemical chalcogenation enables direct activation of inert C–H bonds under mild conditions with high atom economy. Both metal-catalyzed and metal-free electrochemical systems have been developed, allowing precise control over reactivity and selectivity through applied potential and electrode design. Recent advances highlight the use of su...
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Direct Air Capture and CO₂ Storage #worldresearchawards #researchaward #researcher #carboncapture

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Carbon dioxide (CO₂) sequestration is one of the most promising strategies for mitigating climate change and reducing global greenhouse gas emissions. This video explores the science, chemistry, and technology behind CO₂ sequestration, revealing how captured carbon dioxide can be safely stored or transformed to support a sustainable, low-carbon future. CO₂ sequestration involves capturing carbon dioxide from industrial sources or directly from the atmosphere and storing it in secure locations such as deep geological formations, depleted oil and gas reservoirs, or saline aquifers. Advanced chemical methods, including absorption using amine solutions, adsorption on porous materials, and mineral carbonation, play a crucial role in efficiently trapping CO₂. Emerging materials like metal–organic frameworks (MOFs), porous carbons, and functionalized polymers are significantly improving capture efficiency and selectivity. Beyond storage, researchers are exploring ways to utilize captured CO...
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Smart Cryopreservation Solutions #worldresearchawards #researchaward #researcher #DMSOFree

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Cryopreservation plays a critical role in modern biomedical science, enabling long-term storage of cells, tissues, and biological samples for research and clinical applications. Traditionally, dimethyl sulfoxide (DMSO) has been widely used as a cryoprotectant due to its ability to prevent ice crystal formation. However, DMSO is associated with cytotoxicity, adverse patient reactions, and challenges in clinical translation. This video explores the exciting breakthroughs in DMSO-free cryopreservation solutions that are redefining the future of cryobiology. Recent advances in chemistry and biotechnology have led to the development of alternative cryoprotectants, including sugars, polymers, antifreeze proteins, and bio-inspired compounds. These DMSO-free systems reduce cellular stress, improve post-thaw viability, and maintain functional integrity across a wide range of cell types, including stem cells, immune cells, and engineered tissues. By minimizing toxicity, these solutions are part...
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Periodate–Borohydride Magic #worldresearchawards #researchaward #researcher #periodateoxidation

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Nanofluids engineered fluids containing nanoparticles are opening exciting new possibilities in biomedical science, especially when it comes to understanding how fluids move through the human body. This video takes you on a fascinating chemistry and bioengineering deep dive into how nanofluid flow behaves inside arteries, revealing insights that could revolutionize diagnostics, targeted drug delivery, and therapeutic technologies. Inside arteries, the interaction between nanoparticles and blood components creates complex yet highly valuable fluid dynamics. By dispersing materials like gold, silver, graphene, or metal oxides into biological fluids, researchers can enhance thermal conductivity, improve imaging contrast, and influence flow characteristics at the microscopic level. These enhancements help scientists simulate and understand physiological conditions more accurately than ever before. Nanofluids also play an important role in medical heat transfer crucial for hyperthermia ca...
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Next-Gen Amino Acid Design #worldresearchawards #researchaward #researcher #BoronChemistry

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Boron, a unique and versatile element, is gaining increasing attention for its powerful role in transforming ordinary amino acids into “super” biomolecules. In this video, we explore how boron chemistry enhances the structure, stability, and functionality of amino acids, opening new frontiers in biochemistry, medicinal chemistry, and materials science. Unlike conventional elements found in biological systems, boron possesses electron-deficient bonding properties that enable the formation of reversible covalent interactions. When incorporated into amino acid frameworks, boron can dramatically improve molecular recognition, binding selectivity, and reactivity. These enhanced properties are especially valuable in drug discovery, where boron-containing amino acids are being explored for enzyme inhibition, antimicrobial activity, and cancer therapeutics. Boron-based amino acids also play an important role in supramolecular chemistry and sensor design. Their ability to interact selectively w...
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Why Alkali-Activated Slag Lasts #worldresearchawards #researchaward #researcher #arterialflow

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Nanofluids engineered fluids containing nanoparticles—are opening exciting new possibilities in biomedical science, especially when it comes to understanding how fluids move through the human body. This video takes you on a fascinating chemistry and bioengineering deep dive into how nanofluid flow behaves inside arteries, revealing insights that could revolutionize diagnostics, targeted drug delivery, and therapeutic technologies. Inside arteries, the interaction between nanoparticles and blood components creates complex yet highly valuable fluid dynamics. By dispersing materials like gold, silver, graphene, or metal oxides into biological fluids, researchers can enhance thermal conductivity, improve imaging contrast, and influence flow characteristics at the microscopic level. These enhancements help scientists simulate and understand physiological conditions more accurately than ever before. Nanofluids also play an important role in medical heat transfer—crucial for hyperthermia ca...
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Cryogenic Freeze Experiment #worldresearchawards #researchaward #researcher #CoolScience

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Cryogenic science offers a captivating look at how materials behave when exposed to extremely low temperatures, and this video takes you right into the heart of that frozen world. In this cryogenic surface experiment, we explore how metals, polymers, glass, and everyday materials respond when subjected to temperatures as low as –196°C using liquid nitrogen. From instant frosting to shattering effects, each reaction reveals something incredible about the chemistry and physics of ultra-cold environments. As materials rapidly cool, their molecular motion slows dramatically, leading to sudden changes in brittleness, elasticity, conductivity, and structural integrity. These transformations help scientists understand real-world applications such as spacecraft engineering, superconductivity, cryopreservation, and low-temperature fabrication. The experiment also highlights surface chemistry effects like ice crystal formation, thermal shock, and rapid phase transitions—phenomena that are both ...
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