Dr. Ayoub H. Jaafar, University of Nottingham, United Kingdom
Dr. Ayoub H. Jaafar is an accomplished physicist and Research Fellow at the School of Physics and Astronomy, University of Nottingham, UK. 🌍 He holds a PhD in Physics from the University of Hull and is renowned for his pioneering work on optically tunable memristors and nanocomposite devices for neuromorphic and photonic computing. Over the years, he has held prestigious research roles across leading UK institutions and contributed extensively to state-of-the-art advances in memory technologies. With a strong portfolio of publications and active participation in peer-review and scientific mentoring, Dr. Jaafar exemplifies academic excellence and leadership in applied physics. 🧪✨
🧑💼 Profile
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🎓 Education
Dr. Jaafar earned his PhD in Physics (2014–2018) from the University of Hull, UK, with a thesis focused on organic-inorganic composite materials for memristors. His MSc in Applied Physics (2010–2012) and BSc in Applied Physics (2004–2009) were both obtained from the University of Technology, Baghdad, where he graduated top of his class during his MSc and ranked fifth during his undergraduate studies. His education was supported by a fully funded scholarship from the Iraqi Ministry of Higher Education, covering tuition, living expenses, and English language training in the UK. 🎓📘
🧪 Experience
Dr. Jaafar’s career spans key academic and industrial research appointments. He currently serves as a Research Fellow at the University of Nottingham (2022–present), where he is developing optically tunable memristors for AI-driven photonic systems. Previously, he was a Research Fellow at the University of Southampton (2020–2022), focusing on phase-change memories and chalcogenide materials as part of the EPSRC-funded ADEPT project. At the University of Hull (2018–2019), he worked on graphene oxide-based optical memory devices. His broad technical skills include device fabrication, thin-film deposition, and advanced material characterization. 🧑🏫🔬
🔬 Research Interests
Dr. Jaafar’s research centers on next-generation memory systems, with a strong emphasis on resistive switching devices, optoelectronics, and neuromorphic computing. His focus areas include hybrid nanostructures, memristive behavior under optical control, and energy-efficient hardware for AI. His innovative work explores how memristors can mimic synaptic behaviors for brain-inspired computing. He also delves into reservoir computing, phase-change materials, and electrodeposited thin films. 🌐⚡
🏅 Awards
Dr. Jaafar was honored with the 2022/2023 Dean’s Award from the Faculty of Engineering and Physical Sciences at the University of Southampton for his exceptional contribution to research. He also received a fully funded PhD scholarship from the Iraqi Ministry of Higher Education. These accolades underscore his scientific excellence, leadership, and impactful research in emerging memory technologies. 🏆📈
📚 Publications
“Integrated Ovonic Threshold Switching Selector and Resistive Switching Memory 1S1R in Electrodeposited ZnTe Thin Films”, Advanced Materials Technologies, 2025 – cited by 2 articles.
“Light-Mediated Multi-Level Neuromorphic Switching in a Hybrid Organic-Inorganic Memristor”, ACS Omega, 2024 – cited by 5 articles.
“Unique Co-existence of Two Resistive Switching Modes in a Memristor Device Enables Multifunctional Neuromorphic Computing Properties”, ACS Applied Materials & Interfaces, 2024 – cited by 3 articles.
“Tunable Neuromorphic Switching Dynamics via Porosity Control in Mesoporous Silica Diffusive Memristors”, ACS Applied Materials & Interfaces, 2024 – cited by 4 articles.
“Optically Controlled Memristor Using Hybrid ZnO Nanorod/Polymer Material”, NANOARCH 2023 Proceedings, 2023 – cited by 2 articles.
“Printed and Flexible Organic and Inorganic Memristor Devices”, Journal of Physics D, 2023 – cited by 6 articles.
“Optoelectronic Switching Memory Based on ZnO Nanoparticle/Polymer Nanocomposite”, ACS Applied Polymer Materials, 2023 – cited by 3 articles.
“Flexible Memristor Devices Using Hybrid Polymer/Electrodeposited GeSbTe”, ACS Applied Nano Materials, 2022 – cited by 7 articles.
“3D-Structured Mesoporous Silica Memristor for Neuromorphic Switching and Reservoir Computing”, Nanoscale, 2022 – cited by 8 articles.
“Anodic Sb₂S₃ Electrodeposition for RRAM Devices”, Electrochimica Acta, 2022 – cited by 4 articles.