Company Filing History:
Years Active: 2024-2025
Title: Innovator Spotlight: Eric Lewis Danielson and His Pioneering Work in BioFET Technology
Introduction
Eric Lewis Danielson, a notable inventor based in Santa Clara, California, has made significant strides in the field of biotechnology. With a keen focus on innovations in electronic devices, he holds a unique patent that combines materials science and biological engineering.
Latest Patents
Danielson's key invention is a patent titled "Method of manufacturing a graphene-based biological field-effect transistor." This groundbreaking method involves several steps: preparing a carbonaceous dispersion by adding three-dimensional (3D) graphene into a solvent, depositing this dispersion onto a p-type silicon wafer, and applying positive photoresist over the mixture. He implements a process to form source and drain terminals on the silicon wafer, ensuring they connect with the 3D graphene. The method also includes removing residual photoresist and biofunctionalizing the dispersion with a molecular recognition element that adjusts the electrical properties of the BioFET when in contact with specific analytes.
Career Highlights
Danielson's focus on developing advanced electronic devices has been pivotal in his career. Currently, he works at Lyten, Inc., a company dedicated to transforming advanced materials into significant technological advancements. His expert knowledge and innovative approaches have solidified his reputation as a forward-thinking inventor in the realm of biosensors and electronic interfaces.
Collaborations
Throughout his career, Danielson has collaborated with several brilliant minds, including his coworker, Maurizio Tarsia. These partnerships highlight the importance of teamwork and shared knowledge in driving innovation and the development of cutting-edge technologies.
Conclusion
Eric Lewis Danielson stands as an exemplary figure in the landscape of inventors, particularly for his contributions to graphene-based technologies. His patent on the BioFET manufacturing method represents a significant leap forward in bioelectronics, paving the way for future advancements in the detection and analysis of biological substances. As he continues to collaborate with industry professionals, his work is poised to impact both biotechnology and electronic engineering profoundly.