Chemical Vapour Deposition of Nitrides by Carbon-free Precursors

Presented by Stefano Leone, Group leader of Nitride-MOCVD team, Fraunhofer Institute IAF

Awaiting presentation abstract.

D3GaN Power Modules for Automotive Inverters Achieving 99.7% WLTP Efficiency

Presented by Dieter Liesabeths, SVP of Product, VisIC Technologies

This presentation highlights VisIC Technologies’ latest D3GaN technology, integrated into power modules for inverters driving electric motors in battery electric vehicles. Dyno tests achieved over 130 kW, surpassing SiC performance with the same e-machine. We will present WLTP efficiency results, switching loss data, and insights on implementing lateral GaN in real-world power modules. The talk also addresses key system-level design considerations and limitations when using lateral versus vertical devices.

Presentation 1 by Yole Group

Presented by Name to be advised, Yole Group

Awaiting presentation abstract.

Presentation by Malvern Panalytical

Presented by Name to be advised, Malvern Panalytical

Awaiting presentation abstract.

Presentation by Semi Zabala

Presented by Antxon Arrizabalaga, Director of Applications, Semi Zabala

Awaiting presentation abstract.

Presentation by imec

Presented by Pierre Gassot, Business Director - Team Lead Specialty Devices, Foundries & GaN, imec

Awaiting presentation abstract.

Nanofabrication Strategies for High-Yield microLED Manufacturing and Design Innovation

Presented by Name to be advised, Raith

Scaling microLED production requires precision patterning at the nanoscale alongside high throughput and yield. This presentation explores how advanced electron beam lithography and nanofabrication technologies support next-generation microLED architectures. Attendees will gain insights into how precision structuring enables improved efficiency, enhanced brightness and scalable manufacturing pathways for commercial microLED deployment.

Presentation 2 by Yole Group

Presented by Name to be advised, Yole Group

Awaiting presentation abstract.

Presentation by VueReal

Presented by Reza Chaji, Founder and CEO, VueReal

Awaiting presentation abstract.

Accelerating SiC and GaN Power Electronics with AI-Enhanced Process Innovation

Presented by Name to be advised, Aixtron

AI is rapidly reshaping power electronics manufacturing as the demand for both SiC and GaN continues to rise. This presentation explores how AI-driven process control, predictive maintenance and defect detection are transforming SiC and GaN production lines. We will outline how intelligent automation improves tool utilisation, reduces variability, enhances yield, and accelerates time-to-production for next-generation power devices.

Advanced Metrology Strategies for High-Yield SiC Manufacturing in Mature and Emerging Power Markets

Presented by Tamzin Lafford, Senior Applications Scientist, Bruker UK

Shrinking margins in SiC manufacturing demand unprecedented control over material quality and process stability. This presentation examines how advanced analytical and metrology techniques enable early defect detection, process consistency and yield improvement across SiC substrates and epitaxial layers. Attendees will gain insight into how precision measurement drives improved reliability and competitive advantage in SiC device production.

Further Growth Opportunities for SiC in New Application Fields

Presented by Peter Friedrichs, Fellow SiC, Infineon

Awaiting presentation abstract.

Optimising Thermal Processing for High-Quality SiC Substrates and Epitaxy at Scale

Thermal processing plays a critical role in achieving uniformity, defect reduction and performance stability in SiC production. This presentation explores advanced furnace technologies and process optimisation strategies that support consistent substrate and epitaxial quality. The session highlights how controlled thermal environments enable higher throughput, reduced variability and enhanced device reliability for next-generation SiC power electronics.

Presentation by A*STAR

Presented by Umesh Chand, Senior Scientist and Project Lead, A*STAR

Awaiting presentation abstract.

Presentation by Siconnex

Presented by Name to be advised, Siconnex Customized Solutions GmbH

Awaiting presentation abstract.

Quantifying What Matters: In-Line TXRF for Surface-Metal Control and Yield Optimization in SiC Fabs. An Integrated Study Using in-line TXRF to Predict and Prevent Yield Excursions

Presented by Meredith Beebe, Sales Account Manager, Rigaku

Awaiting presentation abstract.

Development of Strain-compensated Distributed Bragg Reflectors for GaN-based VCSELs With Potential for Faster Growth and Higher Productivity

Presented by Takeshi Kawashima, Researcher, Ricoh

In this presentation, we introduce novel strain-compensated AlGaN/InGaN DBRs for GaN-based VCSELs. By adopting an asymmetric structure in which the InGaN layer is thicker than λ/4 and the AlGaN layer is thinner than λ/4, and by compensating for strain, we achieved a larger refractive index contrast compared to conventional λ/4 structures. Through a high growth rate of 1–several µm/h and minimizing growth interruption, we successfully fabricated DBRs with over 99.9% reflectivity in approximately 5 hours. With further optimization, this technology has the potential to reduce growth time to 2–3 hours, comparable to GaAs-based DBRs, and could significantly lower the manufacturing cost of GaN VCSEL wafers.

Manufacturing VCSELs on 150mm and 200mm Wafer Formats

Presented by Peter Smowton, Professor of Optoelectronic Device Physics and Managing Director of the Institute for Compound Semiconductors, Cardiff University

Vertical-cavity surface-emitting lasers (VCSELs) emitting in the 800 – 1100 nm range play a significant role in short-reach data communication as well as 3D sensing applications. High-volume VCSEL production on 150-mm (6-inch) diameter substrates is becoming standard and work has begun on transitioning to 200-mm (8-inch) production. Here we discuss the relative advantages of GaAs and Ge large area substrates, the reduction in substrate thickness that can be achieved using Ge and the latest results for high speed generic VCSEL designs.

Presentation by DCA Instruments

Presented by Name to be advised, DCA Instruments Oy

Awaiting presentation abstract.

Presentation by Veeco

Presented by Name to be advised, Veeco

Awaiting presentation abstract.

Unlocking the Future: Nanoporous Compound Semiconductor Technology for Next-Gen Sensing, Digital Health and Energy-Efficient Data Centers Optical Interconnect

Presented by Jung Han, Chief Scientist and Inventor, InPHRED

Awaiting presentation abstract.

Gallium Oxide RF Electronics: Recent Advances Toward Unlocking UWBG Potential

Presented by Min Zhou, Postdoctoral Researcher, Xidian University

Beta-phase gallium oxide (β-Ga₂O₃) has emerged as a competitive ultra-wide bandgap (UWBG) semiconductor for next-generation RF electronics, leveraging its exceptional material properties—including an ultra-large bandgap (4.7–4.9 eV), high theoretical breakdown field (8 MV/cm), and electron saturation velocity (2×107 cm/s). Crucially, its unique capability for low-cost melt-growth of bulk substrates enables high-quality, large-scale wafer production, overcoming economic barriers faced by other UWBG materials. It is generally accepted that the low electron mobility and extremely low thermal conductivity are major obstacles towards realizing high performance β-Ga₂O₃-based RF power FETs. This presentation highlights our group’s recent breakthroughs in advancing β-Ga₂O₃-based RF power devices and technologies. Here we report heterogenous integration of single-crystal gallium oxide thin film onto high thermal conductivity substrate and explore the great promise of β-Ga₂O₃ for future high-voltage, high-power and low-noise RF electronics.

High Voltage Power Technology with Gallium Oxide and AlGaN

Presented by Martin Kuball, Royal Academy of Engineering Chair in Emerging Technologies at the University of Bristol, University of Bristol

Awaiting presentation abstract.

Presentation by Lapmaster Wolters GmbH

Presented by Name to be advised, Lapmaster Wolters GmbH

Awaiting presentation abstract.

Towards More Efficient Power Transistors: Modulation-Doped β-(AlₓGa₁₋ₓ)₂O₃/Ga₂O₃ Heterostructures with Enhanced Electron Mobility

Presented by Andreas Fiedler, Group leader: Aluminum-Gallium-Oxide-Electronics (All-GO-HEMT NanoMatFutur project funded by BMBF), Leibniz-Institut für Kristallzüchtung (IKZ)

Semiconductor-based power electronics is a key technology for solving the greatest challenge facing society - sustainable energy generation. This challenge is to be tackled by developing modulation-doped β-(AlxGa1-x)2O3/Ga2O3 heterostructures with high electron mobility for highly efficient power transistors. In Ga2O3 in particular, this approach to increase the charge carrier mobility promises a high innovation potential, as it was also theoretically predicted that the significantly limiting scattering process on polar-optical phonons would be screened. If this scattering process is suppressed, a similar charge carrier mobility is expected in Ga2O3 as in silicon, as the effective electron mass is similar. Effective screening of polar-optical phonons only occurs at a carrier density in the two-dimensional electron gas (2DEG) around 1013 cm-2, which requires a conduction band discontinuity of at least 1 eV. Theoretical predictions show that this requires an aluminum content of at least 50% (x ≥ 0.5) in the barrier. This structure has not yet been realized and is to be developed for the first time in the All-GO-HEMT project. The requirements for high crystalline perfection, a homogeneous layer thickness and smooth interface with a high Al content and delta doping over the entire substrate size of up to 2 inches must be met to provide a material basis for more efficient power electronics.

Presentation by Thermofisher

Presented by Name to be advised, Thermofisher

Awaiting presentation abstract.

Presentation by EV Group

Presented by Name to be advised, EV Group

Awaiting presentation abstract.