Company Filing History:
Years Active: 2022
Title: Joseph S. Ciampi: Innovator in Silicon Avalanche Photodiodes
Introduction
Joseph S. Ciampi is a notable inventor based in Westford, MA (US). He has made significant contributions to the field of photonics, particularly in the development of silicon avalanche photodiodes. His innovative work has led to advancements that enhance the performance and efficiency of these devices.
Latest Patents
Joseph S. Ciampi holds a patent for the "Rapid prototyping of single-photon-sensitive silicon avalanche photodiodes." This patent describes a chip-to-chip integration process for rapid prototyping of silicon avalanche photodiode (APD) arrays. The process offers several advantages over traditional wafer-level 3D integration, including reduced costs per development cycle, compatibility with previously fabricated read-out integrated circuits (ROICs), and an accelerated development schedule. Additionally, the method allows for shorter processing times and provides mechanical support for the APD device, enabling the integration of fast microlenses directly on the APD back surface. This innovation results in APDs with low dark count rates (DCRs) and higher radiation tolerance, making them suitable for harsh environments.
Career Highlights
Joseph S. Ciampi is affiliated with the Massachusetts Institute of Technology, where he continues to contribute to research and development in photonics. His work has been instrumental in advancing the technology behind silicon avalanche photodiodes, which are critical for various applications in science and industry.
Collaborations
Throughout his career, Joseph has collaborated with esteemed colleagues, including Brian F. Aull and Renee D. Lambert. These collaborations have further enriched his research and contributed to the success of his innovative projects.
Conclusion
Joseph S. Ciampi's contributions to the field of silicon avalanche photodiodes exemplify the impact of innovation in technology. His patented processes and collaborative efforts continue to push the boundaries of what is possible in photonics.