Company Filing History:
Years Active: 2011
Title: **Scott M Olig: Innovator in Conductive Nanoparticle Technology**
Introduction
Scott M Olig, based in Oshkosh, WI, is an innovator known for his contributions to the field of materials science, particularly in the development of electrically conductive surfaces. With a focus on how nanoparticles can enhance the functionality of materials, Olig’s work has significant implications for various applications across industries.
Latest Patents
Scott M Olig holds a noteworthy patent for a "Submerged surface with conductive nanoparticles." This invention introduces an electrically conductive surface for submerged objects that utilizes a polymer matrix, such as resin, embedded with a range of electrically conductive nanoparticles. These nanoparticles are ideally smaller than 100 nanometers, alongside larger conductive particles, which can exceed 300 nanometers in size. The uniformity achieved by homogeneously suspending nanotubes, ferrules, and carbon particles within the polymer matrix leads to optimal electrical conduction through the composite layer.
Career Highlights
Scott's professional journey has included a significant position at Brunswick Corporation, a leader in the marine, leisure, and fitness sectors. His expertise and innovative approach have contributed to advancing the company's research capabilities and product offerings.
Collaborations
Throughout his career, Scott has collaborated with esteemed colleagues, including Christopher J Misorski and Kevin R Anderson. These partnerships have facilitated a dynamic exchange of ideas, fostering creativity and innovation within their projects.
Conclusion
Scott M Olig exemplifies the spirit of innovation in the realm of nanotechnology and materials engineering. His patented invention not only enhances the functionality of submerged surfaces but also opens doors to new possibilities in the field. Driven by collaboration and research, Olig continues to be an influential figure in his industry, pushing the boundaries of what is achievable with conductive materials.