Dr. Zeinab Ramezani began her academic journey with a strong foundation in mathematics and physics, ranking 1st among 120 students in high school. She pursued her B.Sc. in Electrical Engineering at Shariaty Technical College, Tehran, graduating top of her class in 2010. Her passion for Semiconductor Devices was evident early on, culminating in her M.Sc. and Ph.D. studies at Semnan University, where she ranked 1st among all M.Sc. and Ph.D. graduates in Electronics Engineering. Her academic path laid the groundwork for her specialized focus on Semiconductor Devices, nanoelectronics, and cutting-edge modeling techniques.
💼 Professional Endeavors
Throughout her career, DR. Ramezani has demonstrated excellence in both academia and research. She held several teaching and research positions, including Assistant Professor and Lecturer at Islamic Azad University and Shariaty Technical College, where she instructed courses in Semiconductor Devices and Devices , digital design, and linear integrated circuits. Her international experience includes serving as a Teaching Assistant at the University of Miami, where she was involved in practical instruction for Digital Design courses and labs. Additionally, she contributed to DARPA’s prestigious N3 project and NSF-funded research, focusing on magnetoelectric nanoparticles for brain-computer interfacing, bridging the gap between nanotechnology and neuroengineering.
🔬 Contributions and Research Focus
Dr. Zeinab Ramezani has significantly contributed to the modeling and analysis of Semiconductor Devices across micro and nanoscale technologies. Her research spans a broad spectrum, including SOI technology, Schottky barrier devices, junctionless transistors, FinFETs, and memristors. Her first Ph.D. focused on modeling short channel effects in nanoscale transistors, while her second Ph.D. at the University of Miami explored magnetoelectric nanoparticles for medical stimulation applications. Her interdisciplinary contributions reflect a deep understanding of both traditional Semiconductor Devices and futuristic applications like nanomedicine and neuromodulation.
🌍 Impact and Influence
Dr. Ramezani's influence is widely acknowledged in both Iranian and international academic communities. She has supervised over 80 theses, reviewed more than 40 graduate and undergraduate projects, and established laboratories for electronics and FPGA systems. Recognized for her innovative teaching and mentorship, she was awarded Top Female Inventor (2019) and Top Electrical Engineering Professor (2018) by IAU. Her contributions have influenced a generation of engineers in the field of Semiconductor Devices, as well as emerging fields like bioelectronics and neurotechnologies.
🏆Academic Cites
Dr. Ramezani's research output has been well received in scientific communities. Her thesis work, journal publications, and technical modeling in Semiconductor Devices and medical electronics have attracted citations in both domestic and international research. Her work has been referenced in key areas such as transistor scaling, ion drift models in memristors, and advanced circuit simulation, underlining her position as a trusted authority in nanoelectronics and medical applications.
🌟 Legacy and Future Contributions
Dr. Zeinab Ramezani’S legacy is built on academic excellence, technological innovation, and a commitment to nurturing future engineers. Her future goals include expanding research on multifunctional nanoparticles, deepening her work in neuro-nanotechnology, and continuing to develop smarter, more efficient Semiconductor Devices for medical and computational purposes. Her efforts will not only shape next-generation electronics but also push forward the integration of nanotechnology in medicine and cognitive interfaces.
📝Semiconductor Devices
Her distinguished research in Semiconductor Devices has redefined modeling strategies for modern electronics, particularly in SOI and nanoscale transistor structures. By integrating her deep knowledge of Semiconductor Devices with applications in neural stimulation and multifunctional nanoparticles, she bridges multiple domains. Her continued innovations in Semiconductor Devices are expected to influence future trends in electronics, neuromodulation, and medical diagnostics.
Notable Publication
📝Functionalized Terahertz Plasmonic Metasensors: Femtomolar-level Detection of SARS-CoV-2 Spike Proteins
Authors: A. Ahmadivand, B. Gerislioglu, Z. Ramezani, A. Kaushik, P. Manickam, ...
Journal: Biosensors and Bioelectronics, 2021
Citations: 307
📝Gated Graphene Island-enabled Tunable Charge Transfer Plasmon Terahertz Metamodulator
Authors: A. Ahmadivand, B. Gerislioglu, Z. Ramezani
Journal: Nanoscale, 2019
Citations: 136
📝Attomolar Detection of Low-molecular Weight Antibiotics Using Midinfrared-resonant Toroidal Plasmonic Metachip Technology
Authors: A. Ahmadivand, B. Gerislioglu, Z. Ramezani, S.A. Ghoreishi
Journal: Physical Review Applied, 2019
Citations: 67
📝Generation of Magnetoelectric Photocurrents Using Toroidal Resonances: A New Class of Infrared Plasmonic Photodetectors
Authors: A. Ahmadivand, B. Gerislioglu, Z. Ramezani
Journal: Nanoscale, 2019
Citations: 62
📝A Nanoscale‐modified Band Energy Junctionless Transistor with Considerable Progress on the Electrical and Frequency Issue
Authors: M.K. Anvarifard, Z. Ramezani, I.S. Amiri, A.M. Nejad
Journal: Materials Science in Semiconductor Processing, 2020
Citations: 51
📝High Ability of a Reliable Novel TFET-based Device in Detection of Biomolecule Specifies—A Comprehensive Analysis on Sensing Performance
Authors: M.K. Anvarifard, Z. Ramezani, I.S. Amiri
Journal: IEEE Sensors Journal, 2020
Citations: 48
📝Designing Chitosan Nanoparticles Embedded into Graphene Oxide as a Drug Delivery System
Authors: S.M. Hosseini, S. Mazinani, M. Abdouss, H. Kalhor, K. Kalantari, I.S. Amiri, ...
Journal: Polymer Bulletin, 2021
Citations: 39