Keith A Bormann

Title: Keith A. Bormann: Innovator in Magnetostrictive Materials

Introduction: Keith A. Bormann, a distinguished inventor based in State Center, Iowa, has made significant contributions to the field of material science through his innovative work on cobalt ferrite-based magnetostrictive materials. His pioneering research has implications for the development of advanced sensors and actuators.

Latest Patents: Bormann holds a patent for "Cobalt ferrite based magnetostrictive materials for magnetic stress sensor and actuator applications." This invention centers around a magnetostrictive material that utilizes cobalt ferrite, which is further enhanced by the substitution of transition metals such as manganese (Mn), chromium (Cr), zinc (Zn), and copper (Cu). These substitutions replace iron or cobalt within the material's structure, resulting in mechanical properties that enhance the effectiveness of cobalt ferrite for applications in sensing and actuation. Noteworthy is how this substitution lowers the Curie temperature while maintaining substantial magnetostriction, making it a suitable candidate for stress sensing applications.

Career Highlights: Keith A. Bormann is an essential part of the Iowa State University Research Foundation, Inc., contributing to groundbreaking research that bridges theoretical knowledge and practical applications in the realm of materials science. His work has broad implications across various industries, particularly in creating more efficient and functional sensors.

Collaborations: Throughout his career, Bormann has collaborated with notable colleagues such as David C. Jiles and Jason A. Paulsen. Their combined expertise has further propelled advancements in their research endeavors, fostering innovation and sharing of ideas that lead to impactful discoveries in magnetostrictive materials.

Conclusion: With a patent that emphasizes the intersection of material science and practical applications, Keith A. Bormann stands out as an influential inventor. His continued research and collaboration with fellow experts promise to further enhance the potential of magnetostrictive materials for future technologies.