Tayebeh Naseri | Nanophotonics | Member

Dr. Tayebeh Naseri | Nanophotonics | Member

PHD at Sharif University of Technology, Iran

Tayebeh Naseri is a seasoned physicist with a Ph.D. from Sharif University of Technology, Iran. Her expertise lies in the intricate realm of quantum physics, particularly in the study of light-atom interface and Quantum Interference. She has made significant contributions to the field through her research and teaching experiences at institutions such as Razi University and the University of Calgary. Naseri’s work spans experimental investigations on laser cooling of atoms to theoretical explorations of nonlinear optical phenomena. With a strong publication record and notable honors, she continues to push the boundaries of quantum science, captivating audiences worldwide with her insights and discoveries.

Professional Profiles:

Education

Ph.D. Physics, Sharif University of Technology, Iran, 2016 Specialization: Study of light-atom interface and Quantum Interference and Coherence in multi-level atomic systems Advisor: Prof. Rasoul Sadighi-bonabi Research Assistant, University of Calgary, Canada, 2013 Focus: Experimental work on laser cooling of Rb atoms and interaction with evanescent field of tapered nano-fiber Advisor: Professor Alexandre Lvovsky MSc. Physics, Sharif University of Technology, Iran, 2009 Thesis: Bistability analysis of semiconductor micro-ring lasers Advisor: Prof. Alireza Bahrampour BSc. Physics, University of Tehran, Iran, 2008

Research Experience

Razi University, Iran, 2020-Ongoing Development of efficient and enhanced optical switches based on saturation absorption via composite of 2D materials Investigation Of Entangled Quantum States Via Trapped Ions Razi University, Iran, 2016-2020 Assistant Professor of Physics Research focus: Nonlinear optical phenomena in nano structures and monolayer of graphene Center for Quantum Technology (CQT), Singapore, Summer 2016 Visiting Researcher Focus: Interfacing of atoms and photons via cavity QED Supervisor: Dr. Murray Barrett Sharif University of Technology, Iran, 2015-2016 Research Fellow Projects: Electromagnetic Induced Grating, P-T symmetry in coherent atomic media. Post Graduate Level: Quantum Optics, Quantum Computing, Photonics I, II, Laser Physics, Nonlinear Optics Under Graduate Level: General Physics I, II, Analytical Mechanics I, II, Quantum mechanics I, II, Electromagnetic I, II, Laser Laboratory, Optics Laboratory

Honors and Awards

2nd Rank, PhD entrance exam in Physics of Sharif University of Technology PhD. scholarship, Iran Ministry of Science and Researches Full scholarship, University of Calgary, Canada

Skills

Programming: Matlab, Python English Level: Advanced (IELTS: 8)

Research Focus:

Tayebeh Naseri’s research focuses on exploring the optical properties and phenomena of various atomic and nanostructured systems. Her work delves into understanding the behavior of four-level media under coherent and incoherent pumping fields, elucidating phenomena like electromagnetically induced phase grating and population trapping conditions. Naseri has contributed significantly to the field through her investigations into optical bistability in plasmonic nanoparticles and the realization of electromagnetically induced phase grating in graphene ensembles. Her research also extends to hybrid semiconductor quantum dot-metallic nanorod systems, exploring their optical properties and electromagnetically induced grating. Naseri’s expertise lies at the intersection of quantum physics and nanotechnology, driving advancements in optical science and technology.

Publications 

  1. Bimetallic Core-Shell With Graphene Coating Nanoparticles: Enhanced Optical Properties And Slow Light Propagation, cited by: 13, Publication date: 2020.
  2. Optical Properties and Electromagnetically Induced Grating in a Hybrid Semiconductor Quantum Dot-Metallic Nanorod System, cited by: 12, Publication date: 2019.
  3. Two-dimensional induced grating in Rydberg atoms via microwave fieldcited by: 7, Publication date: 2019.
  4. Electromagnetically Induced Grating in Semiconductor Quantum Dot and Metal Nanoparticle Hybrid System by Considering Nonlocality Effects, cited by: 6, Publication date: 2020.
  5. Convenient Dual Optical Bistability In Cavity-Free Structure Based On Nonlinear Graphene-Plasmonic Nanoparticles Composite Thin Layers, cited by: 5, Publication date: 2019.
  6. Tunable Coherent Perfect Absorption Via An Asymmetric Graphene-Based Structure, cited by: 2, Publication date: 2020.
  7. Introducing a Novel Approach to Investigate Linear and Nonlinear Electrical Conductivity of 𝑀𝑜𝑆2, cited by: 1, Publication date: 2021.
  8. Electromagnetically Induced Grating with Second Field Quantization in Spherical Semiconductor Quantum Dots, cited by: 1, Publication date: 2020.
  9. Enhancement of Second Harmonic Field and Nonlinear Dispersion via a Composite of Elliptical Cylinder Nanoparticles, Publication date: 2023.

 

.

Muhammad Junaid | Nanotechnology | Member

Prof. Muhammad Junaid | Nanotechnology | Member

PHD at The Islamia University Bahawalpur, Pakistan

Muhammad Junaid is a dedicated physicist and academician with a passion for research in nanotechnology and renewable energy. He holds a Ph.D. in Physics (ongoing) from The Islamia University Bahawalpur, Pakistan, and an M.Phil. in Nano-Technology from UMT, Lahore. With expertise in synthesizing photo catalysts and nanomaterials, Junaid has contributed significantly to the field. Currently serving as a Lecturer at The Superior College/University Multan Campus, he focuses on enhancing photocatalytic activity for hydrogen generation and green energy production. His research interests and commitment to academia mark him as a promising figure in the scientific community.

Professional Profiles:

Education

Ph.D. in Physics (Continuing) Institute of Physics, The Islamia University Bahawalpur, Pakistan 2020-2023 M. Phil in Nano-Technology Department of Physics, UMT, Lahore, Pakistan 2017-2019 M. Sc. in Physics Department of Physics, Baha Ud din Zakariya University, Multan, Pakistan 2014-2017 B.Sc. in Physics, Math A, Math B, English Govt. College Civil line, Multan 2011-2013 F. Sc. HSSC (Pre-Engineering) B. I. S. E. Rawal Pindi 2008-2010 Matriculation SSC (Science) B. I. S. E. Mardan KPK 2006-2008

Professional Experiences

Current Position: Lecturer of Physics and Physical Chemistry, Department of Physics, The Superior College/University Multan Campus, Pakistan. Employment Record: PhD Candidate (Continuing) Institute of Physics, The Islamia University Of Bahawalpur Pakistan April 2021 – 2023 M.Phil. Research School of Science, Department of Physics, UMT Lahore Pakistan Feb 2019 – April 2020 Lecturer The ILM Group of Colleges, Multan May 2013 – Aug 2015 Lecturer Pak Turk Int School and Colleges, Multan Feb 2017 – April 2017 Lecturer The Superior Group of Colleges Multan Campus Aug 2018 – Till date

Research Interests

Development of Photo Catalysts for the Photo Reduction of CO2, H2, Water Splitting, and Photo Degradation of Organic Pollutants. Synthesis of Photo Catalysts, Magnetic/Electric Nanomaterials, and Metal Oxides based Nano Particles for Sensors. Synthesis of Nanomaterials/Doped Materials by Various Techniques. Synthesis of Graphene Single/Multiple Layers/Quantum Dots by Hummer Method.

Research Focus:

Muhammad Junaid’s research primarily focuses on the structural, spectral, dielectric, and magnetic properties of various ferrite materials. His investigations span across a wide range of doped and substituted ferrites, including lithium, cobalt, nickel, manganese, and copper-based systems. Through techniques such as micro-emulsion synthesis and sol-gel methods, Junaid explores the impact of doping elements like terbium, indium, gadolinium, dysprosium, and neodymium on the physical characteristics of ferrite materials. This extensive body of work contributes significantly to understanding the intricate relationships between structural modifications and the resulting electromagnetic properties of ferrites, advancing the field of magnetic materials science.

Publications 

  1. Structural, spectral, dielectric and magnetic properties of indium substituted copper spinel ferrites synthesized via sol gel technique, cited by: 34, Publication date: 2020.
  2. Structural, spectral, magnetic and dielectric properties of Bi substituted Li-Co spinel ferrites, cited by: 32, Publication date: 2020.
  3. Impact of Bi–Cr substitution on the structural, spectral, dielectric and magnetic properties of Y-type hexaferrites, cited by: 16, Publication date: 2020.
  4. The influence of Zr and Ni co-substitution on structural, dielectric and magnetic traits of lithium spinel ferrites, cited by: 13, Publication date: 2022.
  5. Investigation into the structural and magnetic features of nickel doped U-type hexaferrites prepared through sol–gel method, cited by: 13, Publication date: 2022.
  6. Structural spectral, dielectric, and magnetic properties of Mg substituted Ba3CoFe24O41 Z-type hexaferrites, cited by: 12, Publication date: 2022.
  7. Structural, spectral, dielectric, and magnetic properties of indium substituted Cu0.5Zn0.5Fe2−xO4 magnetic oxides, cited by: 10, Publication date: 2022.
  8. Effect of Nd3+ ions on structural, spectral, magnetic, and dielectric properties of Co–Zn soft ferrites synthesized via sol-gel technique, cited by: 8, Publication date: 2022.
  9. Evaluations of structural, thermal, spectral, and magnetic properties of Li0. 5Fe2. 5O4 multi magnetic oxide fabricated via sol-gel auto-ignition technique, cited by: 8, Publication date: 2022.
  10. Insight of terbium substitution on the structural, spectroscopic, and dielectric characteristics of the Ba–Mg–Fe–O system, cited by: 5, Publication date: 2023.

 

.