Topics of Discussions

This session focuses on advanced semiconductor device architectures beyond conventional CMOS scaling, emphasizing emerging materials, heterogeneous integration, and novel computing paradigms. It covers ultra-scaled transistors, 2D semiconductor-based devices, and 3D integration strategies. Special attention is given to neuromorphic and in-memory computing systems that aim to enable energy-efficient and intelligent electronic platforms for future computing applications.

This session explores the development of quantum-enabled semiconductor systems for next-generation computing and communication technologies. Topics include semiconductor qubits, quantum dots, single-photon emitters, and topological materials. The session highlights experimental and theoretical advances toward scalable quantum architectures and integration of quantum devices with conventional semiconductor platforms.

This session addresses the rapidly growing field of photonic and optoelectronic devices for ultra-high-speed data transmission systems. It includes silicon photonics, integrated optical circuits, high-speed modulators, semiconductor lasers, and optical interconnects for data centers. The focus is on enabling 6G and beyond communication networks through photonic–electronic convergence.

This session focuses on semiconductor nanostructures for energy conversion and sustainability applications. It includes perovskite solar cells, nanostructured LEDs, photocatalytic hydrogen production, and energy harvesting systems. Research on improving efficiency, stability, and environmental compatibility of nanoscale energy materials is highlighted.

This session explores atomically thin materials such as graphene, transition metal dichalcogenides, and related van der Waals heterostructures. It emphasizes their unique electrical, optical, and mechanical properties and their applications in next-generation flexible and high-performance electronics.

This session focuses on quantum dots, nanowires, and nanosheets, emphasizing quantum confinement effects that govern optical and electronic behavior. It includes synthesis techniques, strain engineering, and development of nanoscale optoelectronic devices such as nanolasers and quantum light emitters.

This session investigates light–matter interaction at the nanoscale, including plasmonics, metasurfaces, and photonic crystals. It highlights advances in controlling light propagation, emission, and absorption for applications in nano-LEDs, ultrafast photonic devices, and compact optical systems.

This session highlights organic semiconductors, printed electronics, and flexible devices for wearable technologies. It includes smart textiles, bio-integrated sensors, and stretchable optoelectronic systems designed for healthcare and human–machine interaction applications.

This session focuses on hardware solutions for artificial intelligence, including memristors, resistive switching devices, and in-memory computing architectures. It explores energy-efficient neuromorphic systems and optical neural networks designed to mimic biological computation.

This session covers modern fabrication techniques such as atomic layer deposition, molecular beam epitaxy, electron beam lithography, and nanoimprint lithography. It also includes defect engineering, 3D integration, and emerging manufacturing approaches for nanoscale devices.

This session explores ultrafast carrier dynamics, terahertz generation and detection, and femtosecond spectroscopy in semiconductor systems. It focuses on non-equilibrium transport and ultrafast processes that govern material behavior at extremely short timescales.

This session focuses on the application of artificial intelligence and machine learning in semiconductor research. It includes data-driven material discovery, predictive modeling of device behavior, and AI-assisted fabrication techniques, enabling autonomous and accelerated materials research.

This session explores photonic integrated circuits, quantum key distribution, and on-chip quantum communication systems. It emphasizes the integration of quantum and photonic technologies for secure and high-speed information transfer.

This session focuses on environmentally sustainable semiconductor fabrication methods, including low-energy processes, recycling strategies, and reduction of critical material dependency. It highlights global efforts toward green electronics manufacturing.

This session addresses system-level scaling approaches such as chiplets, 2.5D/3D integration, advanced interconnects, and thermal management strategies. It reflects the industry shift from transistor scaling to system-level integration.

This session highlights advanced experimental methods used to study semiconductor materials and devices, including electron microscopy, X-ray diffraction, scanning probe techniques, and ultrafast spectroscopy for structural and electronic analysis.

This session focuses on defect physics, interface states, grain boundaries, and surface passivation strategies that strongly influence device performance, especially in nanoscale and 2D semiconductor systems.