Basaad Hamza | Theoretical Advances | Editorial Board Member

Posted on by ScienceFather

Assist. Prof. Dr. Basaad Hamza | Theoretical Advances | Editorial Board Member

Mustansiriyah university | Iraq

Dr. Basaad Hadi Hamza is an Assistant Professor in Electro-Optical Physics at Mustansiriyah University, College of Sciences. With a Ph.D. in Electro-Optical Physics (2004) from Mustansiriyah University, his academic expertise spans simulation programs for electro-optical tracking systems and optical systems. His commitment to advancing the field of electro-optical physics is evident through his teaching and research contributions.

👨‍🎓Profile

Google scholar

Scopus

ORCID

Early Academic Pursuits 🎓

Dr. Basaad’s academic journey began at Mustansiriyah University, where he earned his B.Sc. in Physics (1992), followed by a M.Sc. in Nuclear Physics (1998), and eventually his Ph.D. in Electro-Optical Physics (2004). His doctoral thesis focused on the development of a simulation program for electro-optical tracking systems, laying the foundation for his career in applied physics.

Professional Endeavors 💼

Dr. Basaad has an extensive teaching background, contributing to the development of future scientists and engineers. He taught various undergraduate courses in Physics 1, Electricity and Magnetism, Thermodynamics, and Analytical Mechanics. He has also guided graduate students, particularly in specialized topics for Ph.D. comprehensive examinations. His professional affiliations include serving as the Chairman of the Diversity Committee, overseeing curriculum preparation, and leading both undergraduate and graduate examination committees.

Contributions and Research Focus 🔬

Dr. Basaad’s research focus includes polarization effects on soliton propagation, radiance calculations, and the discrimination of targets from background in infrared (IR) imagery. He is particularly interested in the development of simulation programs for transforming IR images across various bands, a significant contribution to remote sensing and infrared imaging technologies. His work also includes improving detector performance in optical spectral ranges to enhance the accuracy of images.

Impact and Influence 🌍

Dr. Basaad’s research has had a broad impact, particularly in IR imaging, target discrimination, and optical physics. His innovative work on transforming IR images from band to band, coupled with his simulation techniques, has contributed to advancements in defense technologies, remote sensing, and optical systems. His publications, including in journals like the International Journal of Application or Innovation in Engineering & Management and Mustansiriyah Journal of Science, highlight his significant role in these fields.

Research Skills 🔍

Dr. Basaad possesses strong analytical skills, particularly in the areas of simulation programming, optical imaging, and IR technology. His proficiency in simulation software and knowledge of IR wavelength bands make him a leader in image transformation techniques. His work on target discrimination using multi-channel data and threshold methods highlights his ability to solve complex problems in infrared imagery.

Teaching Experience 📘

Dr. Basaad’s teaching experience spans over two decades, during which he has taught a range of undergraduate and graduate-level physics courses. He has taught Physics 1, Electricity and Magnetism, Thermodynamics, and Analytical Mechanics, and has supervised graduate theses. His guidance on special topics for Ph.D. students and his role in preparing students for comprehensive exams demonstrates his deep commitment to academic development.

Legacy and Future Contributions 🌱

Dr. Basaad’s legacy is marked by his contributions to electro-optical physics, especially in the development of simulation techniques for infrared imaging. Looking ahead, he plans to continue advancing research in target discrimination and optical systems, with potential applications in remote sensing, security, and environmental monitoring. His ongoing mentorship of graduate students will further ensure his influence in academic research and scientific innovation.

Publications Top Notes

Green Synthesis of Silver Nanoparticles and Their Effect on the Skin Determined Using IR Thermography

  • Authors: Alaabedin Alrabab Ali Zain, Majeed Aseel Musafa Abdul, Basaad Hadi Hamza
    Journal: Kuwait Journal of Science
    Year: 2024

Infrared Imaging of Skin Cancer Cell Treated with Copper Oxide and Silver Nanoparticles

  • Authors: M.M. Mowat, M.S. Khallaf, B.H. Hamza
    Journal: Bionatura
    Year: 2023

People Identification via Tongue Print Using Fine-Tuning Deep Learning

  • Authors: A.S. Obaid, M.Y. Kamil, B.H. Hamza
    Journal: International Journal of Reconfigurable and Embedded Systems
    Year: 2023

People Recognition via Tongue Print Using Deep and Machine Learning

  • Authors: A.S. Obaid, M.Y. Kamil, B.H. Hamza
    Journal: Journal of Artificial Intelligence and Technology
    Year: 2023

Improved Detector Performance Rendering in the Optical Spectral Ranges to Provide Accurate Image

  • Authors: Basaad Hadi Hamza
    Journal: Mustansiriyah Journal of Science
    Year: 2019

 

Chadha Henchiri | Experimental methods | Member

Posted on by ScienceFather

Dr. Chadha Henchiri | Experimental methods | Member

PHD at University of Sfax, Tunisia

Chadha Henchiri, a Tunisian physicist born on September 19, 1993, specializes in Materials Science with a keen interest in Magnetism and Dielectrics. She obtained her doctoral thesis from the University of Sfax under the supervision of Pr. E. Dhahri. With a solid foundation in physics from the University of Gafsa, Chadha has showcased her expertise through publications in esteemed journals and active participation in scientific events. She possesses a diverse skill set in synthesis methodologies, experimental design, and data analysis. Currently serving as an Assistant Teacher at the Preparatory Institute for Engineering Studies of Gafsa, Chadha continues to contribute significantly to her field.

Professional Profiles:

Education

Doctoral Thesis: Physics – Material physics University: University of Sfax Supervisor: Pr. E. Dhahri Research Master’s Degree: Physics – Materials Physics and Energy Management University: University of Gafsa Supervisor: Pr. E. Dhahri Fundamental License: Physics University: University of Gafsa

Professional Experiences

Chadha Henchiri has served as a temporary assistant at the Faculty of Science of Gafsa and currently holds the position of Assistant Teacher at the Preparatory Institute for Engineering Studies of Gafsa.

Research Experiences / Skills

Chadha Henchiri possesses expertise in various synthesis methodologies, experimental designs, instrument handling, and characterization techniques, including crystal structure analysis, surface morphology examination, thermal analysis, and magnetic property analysis. She is proficient in several research packages and software for data analysis and interpretation.

Area of Research Interests

Chadha Henchiri’s primary interest lies in Materials Science, with a focus on Magnetism, Dielectrics, and the modulation of magnetic properties using MATLAB software. She is enthusiastic about engaging in challenging fields of physics and delivering her best efforts.

Research Focus:

Chadha Henchiri’s research focuses primarily on the structural and magnetic properties of various materials, particularly manganites and spinel ferrites. Her work delves into understanding the intricate relationships between structural characteristics and magnetic behavior, with a particular emphasis on magnetocaloric effects at room temperature. Through theoretical studies and experimental investigations, Chadha has contributed significantly to the understanding of magnetocaloric phenomena in lanthanum manganite lacunar compounds and CoFeCuO4 spinel ferrite nanoparticles. Her research not only advances the fundamental understanding of these materials but also holds promise for potential applications in areas such as energy conversion and magnetic refrigeration.

Publications 

  1. Structural, dielectric, electrical and modulus spectroscopic characteristics of CoFeCuO4 spinel ferrite nanoparticles, cited by: 31, Publication date: 2021.
  2. Structural and magnetic properties of La1-xxMnO3 (x = 0.1; 0.2 and 0.3) manganites, cited by: 18, Publication date: 2019.
  3. Structural study and large magnetocaloric entropy change at room temperature of La 1− x□ x MnO 3 compounds, cited by: 14, Publication date: 2020.
  4. Theoretical study of the magnetic properties and the magnetocaloric effect in lanthanum manganite lacunar compounds, cited by: 8, Publication date: 2022.
  5. Study of structural properties and conduction mechanisms of La0. 67Ca0. 2Ba0. 13Fe0. 97Ti0. 03O3 perovskite, cited by: 6, Publication date: 2022.
  6. Study of structural, magnetic, magnetocaloric properties and critical behavior of CoFeCuO4 spinel ferrite, cited by: 6, Publication date: 2021.
  7. Landau mean-field analysis and estimation of the spontaneous magnetization from magnetic entropy change, cited by: 5, Publication date: 2021.
  8. Modeling the Magnetocaloric Effect of La0.8MnO3 by the Mean-Field Theorycited by: 4, Publication date: 2020.
  9. Theoretical study of magnetic and magnetocaloric properties and MCE modeling by the mean-field theory in CoFeCuO4 spinel ferrite, cited by: 2, Publication date: 2022.
  10. Correlation between electronic and magnetic properties of LaMnO 3-δ: experimental study and DFT-MBJ calculationPublication date: 2024.

 

 

.

Collider Phenomenology

Posted on by ScienceFather

 

Introduction to Collider Phenomenology:

Collider phenomenology is a field of theoretical physics that bridges the gap between theoretical predictions and experimental observations in the realm of high-energy particle physics. It involves the development of theoretical models and calculations to predict the outcomes of particle collisions in high-energy accelerators, such as the Large Hadron Collider (LHC). Collider phenomenologists play a crucial role in interpreting experimental data, searching for new particles, and testing the predictions of fundamental theories.

Standard Model Phenomenology:

Explore the application of collider phenomenology to the Standard Model of particle physics, including the precise prediction of particle collision processes and the study of electroweak and quantum chromodynamics (QCD) phenomena.

Beyond the Standard Model (BSM) Searches:

Investigate collider phenomenology's role in searching for physics beyond the Standard Model, including the identification of new particles, forces, and symmetries that extend our understanding of the universe.

Precision Measurements and Higgs Physics:

Delve into collider experiments aimed at making precision measurements of known particles, including the Higgs boson, to test the Standard Model and uncover potential deviations from its predictions.

Dark Matter and Exotic Particle Searches:

Focus on the use of colliders in the search for dark matter candidates and exotic particles, including discussions on missing energy signatures, supersymmetry, and extra dimensions.

Collider Physics for Cosmology:

Examine the connection between collider phenomenology and cosmology, where high-energy particle collisions offer insights into the early universe, such as the production of primordial particles and their role in cosmic evolution.

 

 

Chiral spinors and helicity amplitudes
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 pivotal
Chiral Symmetry Breaking
  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
Effective field theory and renormalization
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 a
Experimental Methods
  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
Free Particle Wave Equations
  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
High energy physics
  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
Interactions and fields
  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
Invariance principles and conservation laws
  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
Lepton and quark scattering
  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
Particle physics and cosmology
  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