Alexander Migdal | Scientific Breakthroughs | Best Researcher Award

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Prof. Alexander Migdal | Scientific Breakthroughs | Best Researcher Award 

Prof. Alexander Migdal | Institute for Advanced Study | United States

Alexander A. Migdal is a renowned theoretical physicist with a lifetime of pioneering contributions to mathematical and theoretical physics. Currently a Member of the School of Mathematics at the Institute for Advanced Study, Princeton, he has advanced key areas of physics including quantum field theory, gauge theory, turbulence, and quantum gravity. Educated at the Landau Institute for Theoretical Physics, Migdal has held leading academic positions at prestigious institutions such as Princeton University and New York University. His groundbreaking work includes the Migdal–Kadanoff recursion equations, the Makeenko–Migdal loop equations in large-N QCD, the matrix model solution of two-dimensional quantum gravity, and recent advances in the exact solution of turbulence. Internationally recognized for his achievements, he has received distinguished honors such as the Landau–Weizmann Award and has delivered invited lectures across the globe, continuing to shape modern physics and inspire new generations of researchers.

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Featured Publications

Migdal, A. (2025). Spontaneous quantization of the Yang–Mills gradient flow. Nuclear Physics B. Advance online publication.

Migdal, A. (2025). Duality of Navier–Stokes to a one-dimensional system. International Journal of Modern Physics A. Advance online publication.

Migdal, A. (2024, December 23). Fluid dynamics duality and solution of decaying turbulence. Preprints.

Migdal, A. (2024, November 12). Duality of the Navier–Stokes dynamics and lack of finite-time explosion (Version 2). Preprints.

Migdal, A. (2024, November 5). Duality of the Navier–Stokes dynamics and lack of finite-time explosion (Version 1). Preprints.

Migdal, A. (2024). Quantum solution of classical turbulence: Decaying energy spectrum. Physics of Fluids, 36(9), 095117.

Migdal, A. (2024, August 4). Quantum solution of classical turbulence: Decaying energy spectrum (Version 3). Qeios.

Migdal, A. (2024, July 9). Quantum solution of classical turbulence: Decaying energy spectrum (Version 14). Preprints.

Migdal, A. (2024, July 9). Quantum solution of classical turbulence: Decaying energy spectrum (Version 2). Qeios.

Migdal, A. (2024, July 3). Quantum solution of classical turbulence: Decaying energy spectrum. Qeios.

Migdal, A. (2024, June 3). Quantum solution of classical turbulence: Decaying energy spectrum (Version 12). Preprints.

Migdal, A. (2024, May 6). Quantum solution of classical turbulence: Decaying energy spectrum (Version 11). Preprints.

Mudassir Iqbal | Green Chemistry | Best Researcher Award

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Prof. Dr. Mudassir Iqbal | Green Chemistry | Best Researcher Award

National University of Sciences and Technology | Pakistan

Dr. Mudassir Iqbal is a Tenured Professor of Chemistry at the National University of Sciences and Technology (NUST), Islamabad, and is internationally recognized for his contributions to cutting-edge research in chemistry and materials science. His academic journey spans prestigious institutions in Europe and Asia, where he gained expertise in nanomaterials, ligand design, organic synthesis, and quantum dot functionalization. His current research explores biopolymers for biomedical applications, advanced nanomaterials for clean energy, task-specific ionic liquids, environmental remediation, and the development of novel therapeutic agents. Alongside his extensive publication record, he has successfully led major funded projects, trained young scientists, and contributed to the advancement of sustainable technologies. Dr. Iqbal’s work continues to bridge fundamental science with real-world applications, making him a highly respected scholar and innovator in his field.

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Featured Publications

“Synthesis and characterization of layered Nb2C MXene/ZnS nanocomposites for highly selective electrochemical sensing of dopamine”

“Highly efficient diglycolamide‐based task‐specific ionic liquids: synthesis, unusual extraction behaviour, irradiation, and fluorescence studies”

“Diglycolamide-functionalized calix [4] arenes showing unusual complexation of actinide ions in room temperature ionic liquids: role of ligand structure, radiolytic stability”

“Green synthesis and characterization of silver nanoparticles using Cydonia oblong seed extract”

“A highly efficient solvent system containing functionalized diglycolamides and an ionic liquid for americium recovery from radioactive wastes”

“Extraction of Am (III) using novel solvent systems containing a tripodal diglycolamide ligand in room temperature ionic liquids: a ‘green’ approach for radioactive waste processing”

“A novel CMPO-functionalized task specific ionic liquid: synthesis, extraction and spectroscopic investigations of actinide and lanthanide complexes”

“Preorganization of diglycolamides on the calix [4] arene platform and its effect on the extraction of Am (III)/Eu (III)”

“Magnetic phase transition from paramagnetic in Nb2AlC-MAX to superconductivity-like diamagnetic in Nb2C-MXene: an experimental and computational analysis”

“Synthesis and Am/Eu extraction of novel TODGA derivatives”

“6-deoxy-aminocellulose derivatives embedded soft gelatin methacryloyl (GelMA) hydrogels for improved wound healing applications: In vitro and in vivo studies”

“Plutonium (IV) complexation by diglycolamide ligands—coordination chemistry insight into TODGA-based actinide separations”