Abdelouahid Seidi | Physics | Best Researcher Award

Dr. Abdelouahid Seidi | Physics | Best Researcher Award

PHD at University moulay ismail, Morocco

Abdelouahed Seidi holds a Master’s degree in Materials and Applications for Solar Energy from Université Moulay Ismaïl, following his Licence in Science de la Matière Physique and a DEUG in Sciences de la Matière Physique Chimie. Professionally, he has experience in electrical security and photovoltaic solar panel installation at FaslaElec and has been teaching in various support centers in Meknès and Fès since 2020. He is proficient in AutoCAD, SketchUp, Word, PPT, Excel, MATLAB, PYTHON, and LATEX, and is fluent in English and French. He holds driving licenses for categories “B” and “C”.

Professional Profiles

  • Scopus
  • Googlescholar
  • Researchgate
  • LinkedIn

Education

University moulay ismail

Professional Experience

Stage en laboratoire de chimie: Étude des propriétés physico-chimiques des céramiques naturelles et polymères 2015: Permis de conduire catégories “B” et “C” 2015: Cinq mois de travail chez FaslaElec en sécurité électrique et installation de panneaux solaires photovoltaïques Depuis 2020: Enseignant dans divers centres de soutien à Meknès et à Fès

Publications

  1. A systematic review and meta-analysis of machine learning, deep learning, and ensemble learning approaches in predicting EV charging behavior, Publication date: 2024.
.

Elaheh Yaghoubi | High Energy Physics | Best Researcher Award

Dr. Elaheh Yaghoubi | High Energy Physics | Best Researcher Award

PHD at Karabuk University, Turkey

Elaheh Yaghoubi is a Ph.D. candidate in Electronic and Electrical Engineering at Karabuk University, Turkey, with a perfect GPA of 4.0. Her research focuses on power control in smart grids, model predictive control, and renewable energy. She earned her M.Sc. in Electrical Engineering from Islamic Azad University, Iran, also with a GPA of 4.0. Elaheh has extensive experience in quality control, having served as a senior manager in electronics companies and as a representative for the Iran Standard Organization. She is skilled in web design and programming and is actively involved in the PEDAR research group.

Professional Profiles

Education

Ph.D. Candidate in Electronic and Electrical Engineering Karabuk University, Turkey (2021-Present) GPA: 4.0/4.0 Thesis: Optimal power control of grid-connected distributed generation in a hierarchical framework based on Model Predictive Control Master of Science in Electrical Engineering Islamic Azad University, Qaemshahr, Mazandaran, Iran (2016-2018) GPA: 4.0/4.0 Thesis: Provide a routing algorithm for the proposed topology for a grid on a large-scale chip to detect an error Bachelor of Science in Electrical Engineering Aryan Institute of Science and Technology University, Iran (2012-2014) GPA: 4.0/4.0 Associate’s Degree in Electrical Engineering University College of Rouzbahan, Iran (2010-2012) GPA: 3.5/4.0

Professional Experience

Principal Researcher PEDAR Group, Remote (2023-Present) Investigation, teaching, and designing in power electrical engineering. Website Designer WebCore Company, Mazandaran, Iran (2019-2021) Designed front-end with HTML, CSS, JavaScript; back-end with PHP, Laravel. Senior Manager Rico Electronics Company, Mazandaran, Iran (2018-2019) Oversaw product quality assurance, ensuring compliance with industry standards, and implemented design modifications. Senior Manager Kati Kabl Tabarestan Factory, Mazandaran, Iran (2015-2018) Managed quality assurance for wire and cable products, proficient in troubleshooting and resolving technical issues.

Research Interests

Power System Analysis, Power System Stability, Power Management Microgrid and Smart Grids Renewable Energies Model Predictive Controllers (MPC) Artificial Neural Networks, Machine Learning, Deep Learning Plasmonic, Nano-Electronic Devices

Awards and Honors

1st Rank among M.Sc. students of Electronics, Islamic Azad University, Qaemshahr, Mazandaran, Iran (2018) 1st Rank among B.Sc. students of Electronics, Aryan Institute of Science and Technology University, Babol, Mazandaran, Iran

Publications

  1. A systematic review and meta-analysis of machine learning, deep learning, and ensemble learning approaches in predicting EV charging behavior, Publication date: 2024.
  2. A systematic review and meta-analysis of artificial neural network, machine learning, deep learning, and ensemble learning approaches in field of geotechnical engineering, Publication date: 2024.
  3. Electric vehicles in China, Europe, and the United States: Current trend and market comparison, Publication date: 2024.
  4. The role of mechanical energy storage systems based on artificial intelligence techniques in future sustainable energy systems, Publication date: 2023.
  5. Reducing the vulnerability in microgrid power systemsPublication date: 2023.
  6. Controlling and tracking the maximum active power point in a photovoltaic system connected to the grid using the fuzzy neural controller, Publication date: 2023.
  7. Modeling and Control of Decentralized Microgrid Based on Renewable Energy and Electric Vehicle Charging Station, Publication date: 2022.
  8. Tunable band-pass plasmonic filter and wavelength triple-channel demultiplexer based on square nanodisk resonator in MIM waveguide, Publication date: 2022.
  9. Triple-channel glasses-shape nanoplasmonic demultiplexer based on multi nanodisk resonators in MIM waveguide, Publication date: 2021.
.

Amirali Farmani | High energy physics | Best Researcher Award

Mr. Amirali Farmani | High energy physics | Best Researcher Award

PHD at Sahand University of Technology, Iran

Amirali Farmani is a Ph.D. candidate in Material Science at Sahand University of Technology, focusing on enhancing hydrogen and oxygen evolution reactions on electrodeposited nickel electrodes. He holds a Bachelor of Engineering in Material Engineering with a specialization in Metallurgy from Bonab University and a Master of Science in Material Science from Sahand University. His research includes innovative approaches to corrosion protection, nanocrystalline nickel films, and electrochemical water splitting. Amirali has contributed significantly to his field with several publications in esteemed journals and has been involved in consultancy projects, including designing novel corrosion protection systems. High energy physics

Professional Profiles

Academic and Professional Background

From September 2013 to August 2017, Amirali Farmani pursued a Bachelor of Engineering in Material Engineering with a specialization in Metallurgy at Bonab University, East Azerbaijan. Continuing his academic journey, from September 2017 to June 2020, he completed a Master of Science in Material Science focusing on Corrosion and Material Protection at Sahand University of Technology, Tabriz, East Azerbaijan. Currently, he is a Ph.D. candidate in Material Science, also at Sahand University of Technology, where his research has focused on enhancing hydrogen and oxygen evolution reactions on electrodeposited nickel electrodes through innovative approaches, as evidenced by several publications in esteemed journals.  High energy physics

Areas of Research

Functional Nanomaterials Energy Materials Corrosion and Surface Science. High energy physics

Research Focus

The researcher in question appears to focus on the fields of material science and electrochemistry, with a specific interest in the synthesis and characterization of electrode materials. Their work includes studying the enhancement of hydrogen and oxygen evolution reactions on nickel electrodes, exploring the effects of mesoporosity, magnetohydrodynamics, and high gradient magnetic forces. They also investigate the corrosion behavior and ion release of chromium-cobalt alloys, particularly under the influence of chemical passivation. Additionally, they have delved into the production of nanocrystalline nickel films using ultrasonic-assisted pulse electrodeposition, examining the competition between mass transport and nucleation in determining corrosion resistance. High energy physics

Publications

  1. Ultrasonic-assisted pulse electrodeposition process for producing nanocrystalline nickel films and their corrosion behavior: Competition between mass transport and nucleation, Publication date: 2024.
  2. Effect of chemical passivation on corrosion behavior and ion release of a commercial chromium-cobalt alloy, Publication date: 2020.
  3. Boosting hydrogen and oxygen evolution reactions on electrodeposited nickel electrodes via simultaneous mesoporosity, magnetohydrodynamics and high gradient magnetic forcePublication date: 2020.
.

Assaad Elouafi | Materials Physics | Best Researcher Award

Dr. Assaad Elouafi | Materials Physics | Best Researcher Award

PHD at Hassan II University of Casablanca, Morocco

Assaad El Ouafi specializes in the elaboration and characterization of nanomaterials, including perovskites, iron oxides, pyrochlores, ferrites, hexaferrites, and phosphate-based oxides. His expertise extends to various synthesis methods such as sol-gel, ceramic route, co-precipitation, inverse sol-gel, and hydrothermal techniques. He is proficient in using a range of instruments including tensile, flexure, and compression tests, hardness tests, UV-Visible spectrometry, Mössbauer spectrometry, X-ray diffraction, SQUID, and vibrating-sample magnetometer (VSM).

Professional Profiles

Education

Faculty of Sciences Ain Chock, Hassan II University of Casablanca-Morocco Ph.D. in Materials Physics and Energetics (2016 – 2021) Master’s Degree in Renewable Energy and Energy Systems (2014 – 2016) Bachelor’s Degree in Physics Materials (2011 – 2014) Moulay Idriss 1st High School-Anfa, Casablanca Morocco High School Diploma in Life and Earth Sciences (2010 – 2011)

Experience

Anfous Center for Coaching and Personal Development, Casablanca-Morocco ENNEAGRAM WORKSHOP (Relational intelligence) (March 2023) Higher School of Technology Hassan II University of Casablanca, Morocco Substitute Teacher (2018-2023) Courses taught: Physics, mathematics, thermodynamics, heat treatment. Practical work: metrology, mechanical maintenance, fluid mechanics, heat exchangers, electricity, thermodynamics, materials, and heat treatment. Mentored Graduate and PhD Students (2021-2023) Provided guidance for research projects.

Skills

Nanomaterials synthesis and characterization Various methods: sol-gel, ceramic route, co-precipitation, inverse sol-gel, hydrothermal Proficient with instruments: tensile, flexure and compression tests, hardness tests, UV-Visible spectrometry, Mössbauer spectrometry, X-ray diffraction, SQUID, VSM

Research Focus

Assaad El Ouafi’s research predominantly focuses on the synthesis and characterization of nanomaterials, especially their structural, magnetic, and optical properties. His studies include detailed morphological and structural analyses of materials such as treated sisal fibers, hematite, γ-Fe₂O₃ nanoparticles, amorphous alloys, and various perovskites and pyrochlores. Key areas of interest are the magnetocaloric effects for magnetic refrigeration applications and the enhancement of materials’ optical properties for optoelectronic applications. His work employs advanced techniques like Mössbauer spectrometry, X-ray diffraction, and various forms of magnetometry.

Publications

  1. Electric field mapping by Pockels effect and I (V) characteristic of CdTe nuclear detectors by different Pt contact deposition, Publication date: 2024.
  2. Magneto-transport and optical properties of La0.7K0.3Mn(1−x)GaxO3 (0 ≤ x ≤ 0.25) ceramicsPublication date: 2024.
  3. Optical properties investigation of Sr2CaFe2WO9 triple perovskite for optoelectronic applications, Publication date: 2023.
  4. Structural, Magnetic, and Magnetocaloric Studies of the Potassium Diphosphate KCrP2O7, Publication date: 2023.
  5. Excellent magnetocaloric effect at cryogenic temperature in amorphous (Fe35RE65)(RE= Er, Dy and Gd) alloys, Publication date: 2023.
  6. Near room temperature magnetocaloric effect of Cr1− xRuxO2 (x= 0.000, 0.125, and 0.250) for magnetic refrigeration, Publication date: 2023.
  7. Effect of cerium doping in tuning the optical and photoluminescence properties of TiO2 nanoparticles, Publication date: 2023.
  8. Structural, magnetic and magnetocaloric effect of pyrochlore iridate Er2Ir2O7, Publication date: 2023.
  9. Large magnetocaloric effect and magnetic properties of EuRhO3, Publication date: 2023.
  10. Effect of sisal fibre treatment on the hydration and thermophysical properties of a cement biocomposite, Publication date: 2023.
.

Sunil Chaki | Condensed Matter Physics | Lifetime achievement Award

Prof Dr. Sunil Chaki | Condensed Matter Physics | Lifetime achievement Award

Professor at Sardar Patel University’s, India

Sunil Chaki is a distinguished professor at Sardar Patel University’s PG Department of Physics and the Associate Director of the Department of Applied and Interdisciplinary Sciences. He pioneered the M.Sc. Applied Physics program and leads several entrepreneurial initiatives at the university. Recognized among the top 2% scientists worldwide by Stanford University in 2023, Dr. Chaki boasts an h-index of 30 on Google Scholar and 28 on Scopus. His research focuses on experimental condensed matter physics, particularly on single crystals and compound semiconductors. He has published over 161 papers and completed six major research projects, mentoring numerous Ph.D. and M.Phil. students.

Professional Profiles

Education

M.Sc. (Physics) 1990 Ph.D. (Physics) 1996

Professional Positions/Responsibilities

Current Roles Professor, PG Department of Physics, Sardar Patel University Associate Director, Department of Applied and Interdisciplinary Sciences, Sardar Patel University Initiated M.Sc. Applied Physics program in June 2018 Coordinator, SPU-SSIP-Navadhara (Student Startup, Innovation & Entrepreneur Cell), Sardar Patel University Director & Founder, Sardar Patel Startup & Entrepreneurship Council (SPSEC), Section – 8 Company of Sardar Patel University Nodal Officer, Entrepreneurship Development Cell, Sardar Patel University

Professional Achievements

Featured in the Stanford University list of top 2% Scientists of the world in October 2023 Google Scholar Citations: h Index: 30 i10 Index: 83 (June 2024) Google Scholar Profile Scopus Citations: h Index: 28 (June 2024) Scopus Profile Fellow of Indian Physical Society Patents: Six filed

Area of Specialization

Growth of single crystals of transition metal chalcogenides Study of compound semiconductors in thin films and nano forms Thermal studies of materials using iso-conversional models

Awards & Recognitions

Teresa Muller Prize for scoring highest marks in Mathematics at Secondary School Examination 1983 CSIR-Senior Research Fellowship 1993-1995 INSA-Visiting Fellowship 1997-1998 Hari Ohm Ashram Prerit Shri Bhaikaka Inter University Smarak Trust Award for best research paper (twice) 2000 & 2010

Research Focuse

Sunil Chaki’s research focuses on experimental condensed matter physics, particularly on the synthesis, growth, and characterization of nanomaterials and thin films. His work includes extensive studies on transition metal chalcogenides, compound semiconductors, and metal oxide nanoparticles. He employs various chemical synthesis techniques, such as chemical bath deposition, dip coating, and wet chemical reduction, to create and analyze materials like SnS, CuS, NiO, and CdSe. Chaki’s investigations into photoluminescence, Raman scattering, and electrical transport properties of these materials contribute significantly to advancements in nanoscience and semiconductor processing, with applications in optoelectronics and material sciences.

Publications

  1. Flexible photodetector for broadband detection using wurtzite phase CuFeS2 nanoparticles, Publication date: 2024/8/15
  2. Kinetic study of adsorption and photocatalytic degradation of methylene blue dye using TiO2 nanoparticles with activated carbon, Publication date: 2024
  3. CVT grown CuSe single crystals: Unveiling photodetection advancements and thermoelectric promise, Publication date: 2024
  4. Enhancing thermoelectric behavior of Bismuth Selenide crystal via substitution of Sulfur and Tellurium, Publication date: 2024
  5. Chemical bath deposited CdTe thin film: Optical, electrical, and photoresponse aspects, Publication date: 2024
  6. Dielectric performance of nanostructured magnesium oxide and effect of cobalt substitution, Publication date: 2024
  7. Studies on thermoelectric performance of pristine and Selenium alloyed Bismuth Sulfide crystals grown by vertical Bridgman technique, Publication date: 2024
  8. Unveiling the optoelectronic characteristics of SnTe thin films: An extensive investigation via structural & photoresponse analysis of drop-cast depositionPublication date: 2024
  9. Growth of a CuSbSe 2 single crystal by the Bridgman technique and its utility as a photodetector and thermoelectric material. Publication date: 2024
  10. Характеристики тонкой пленки нанокристаллического сульфида свинца для фотодетектора видимого света, Publication date: 2023.
.

Ali Al Shamy | Nuclear Interactions | Best Researcher Award

Assist Prof Dr. Ali Al Shamy | Nuclear Interactions | Best Researcher Award

PHD at the University of Calicut, India

Ali Mohammed Ali Naje Al-Shamy is a dedicated Research Scholar pursuing his Ph.D. in Physics at the University of Calicut, India. Serving as an Assistant Professor at the University of Thamar, Yemen, since 2007, he has extensive teaching experience in subjects like Nuclear Physics, Quantum Mechanics, and Electromagnetic Theory. Ali holds an M.Sc. in Nuclear Physics from the University of Sanaa and a B.Sc. in Physics from the University of Thamar. His research focuses on high-energy nuclear interactions, particle physics, and simulation methods like the Monte Carlo Method and Geant4. Proficient in MATLAB, FORTRAN, and Mathematica, he is fluent in English and Arabic.

Professional Profiles

Education

Ph.D. in Physics University of Calicut, India (2022 – Present) M.Sc. in Nuclear Physics (Total: 89%) University of Sanaa, College of Science, 2014 B.Sc. in Physics (Total: 83.06%) University of Thamar.

Work Experience

Research Scholar University of Calicut, India (Since 2022) Lecturer Physics Department, College of Science, Thamar University (Since 2007) Subjects Taught: Nuclear Physics, Atomic Physics, Quantum Mechanics, Mathematical Methods of Physics, Electromagnetic Theory

Skills

Computer Programs: MATLAB, FORTRAN, Mathematica, Geant4 simulation. Languages: English, Arabic

Research Focus

Based on the provided references, A.M. Alshamy and M.M. Musthafa appear to focus on nuclear physics and computational simulations in their research. Specifically, they study the interaction of neutrons with materials, such as the transparency of optical potential barriers for fast neutrons and the reduction of neutron flux through iron using GEANT4 simulations. Their work involves both theoretical and computational approaches to understanding neutron behavior, which is crucial for applications in nuclear reactor design, radiation shielding, and nuclear safety. The calculation of neutron cross-sections for iron group nuclei also indicates a detailed focus on the scattering processes and nuclear reactions involving neutrons and iron isotopes.

Publications

  1. Calculation of the neutron cross-section for iron group nuclei in ℓ ≠ 0 case, Publication date: 2023.
  2. Study of the Reduction of Neutron Flux Through the Iron Material Using GEANT4 Simulations, Publication date: 2024.
  3. Optical Potential Barrier Transparency for the Fast Neutron, Publication date: 2024.
.

Machine Learning in Physics

 

Introduction to Machine Learning in Physics:

Machine learning has emerged as a transformative tool in the field of physics, offering novel ways to model, analyze, and interpret complex physical phenomena. By leveraging computational techniques, algorithms, and data-driven approaches, machine learning has enabled physicists to tackle intricate problems, optimize experiments, and uncover hidden patterns in vast datasets.

Quantum Machine Learning:

Explore the intersection of quantum computing and machine learning, where quantum algorithms are employed to solve quantum physics problems, optimize quantum circuits, and simulate quantum systems more efficiently.

Particle Physics and Collider Experiments:

Investigate the use of machine learning in the analysis of high-energy physics data, including event reconstruction, particle identification, and the search for new physics phenomena in experiments like the Large Hadron Collider (LHC).

Quantum Materials and Condensed Matter Physics:

Delve into applications of machine learning for the discovery and characterization of novel quantum materials, predicting material properties, and understanding complex condensed matter systems.

Astrophysics and Cosmology:

Focus on the use of machine learning in astrophysical data analysis, cosmological simulations, and the discovery of celestial objects, such as exoplanets, gravitational wave events, and dark matter distributions.

Plasma Physics and Fusion Research:

Examine machine learning's role in modeling and controlling plasma behavior for fusion energy research, addressing challenges in plasma confinement and stability prediction.

 

 

  Introduction of Chiral spinors and helicity amplitudes Chiral spinors and helicity amplitudes are fundamental concepts in the realm of quantum field theory and particle physics    They play a
  Introduction to Chiral Symmetry Breaking: Chiral symmetry breaking is a pivotal phenomenon in the realm of theoretical physics, particularly within the framework of quantum chromodynamics (QCD) and the study
  Introduction to Effective Field Theory and Renormalization: Effective field theory (EFT) and renormalization are foundational concepts in theoretical physics, particularly in the realm of quantum field theory. They provide
  Introduction to Experimental Methods: Experimental methods are the backbone of scientific investigation, enabling researchers to empirically explore and validate hypotheses, theories, and concepts. These techniques encompass a wide array
  Introduction to Free Particle Wave Equations: Free particle wave equations are fundamental concepts in quantum mechanics, describing the behavior of particles that are not subject to external forces. These
  Introduction to High Energy Physics: High-energy physics, also known as particle physics, is a branch of science dedicated to the study of the most fundamental building blocks of the
  Introduction to Interactions and Fields: Interactions and fields form the foundation of modern physics, providing the framework for understanding how particles and objects interact with one another and the
  Introduction to Invariance Principles and Conservation Laws: Invariance principles and conservation laws are fundamental concepts in physics that play a pivotal role in understanding the behavior of the physical
  Introduction to Lepton and Quark Scattering and Conservation Laws: Lepton and quark scattering processes are fundamental phenomena in particle physics, allowing us to probe the structure and interactions of
  Introduction to Particle Physics and Cosmology: Particle physics and cosmology are two closely intertwined fields of scientific inquiry that seek to unravel the mysteries of the universe at both