Company Filing History:
Years Active: 2017
Title: Inventor Spotlight: Lauren E. Rosebrugh
Introduction: Lauren E. Rosebrugh, based in Pasadena, CA, is a noted inventor recognized for her contributions to the field of metathesis catalysis. With a focus on developing innovative catalysts, she has made significant strides in the realm of organic chemistry, impacting various industrial applications.
Latest Patents: Lauren has been awarded a patent for her work on Z-selective metathesis catalysts. This novel chelated ruthenium-based catalyst features an N-2,6-diisopropylphenyl group and exhibits remarkable selectivity for Z-olefins, achieving over 95% selectivity. The catalyst also boasts unparalleled turnover numbers (TONs) of up to 7,400, demonstrating efficiency across a variety of homodimerization and industrially relevant metathesis reactions. Her synthesis method involves an innovative use of sodium carboxylates for inducing salt metathesis and C—H activation of these chelated complexes, resulting in the creation of highly effective ruthenium-based catalysts.
Career Highlights: Lauren is affiliated with the California Institute of Technology, where her research is focused on advancing the field of catalysis. Her academic background and hands-on experience have positioned her as a leading figure in her domain, contributing to both theoretical and practical advancements in metathesis reactions.
Collaborations: Throughout her career, Lauren has collaborated with esteemed colleagues, including Myles Benton Herbert and Vanessa M. Marx. These collaborations have enriched her research endeavors, fostering an environment of innovation and shared knowledge in the field of catalysis.
Conclusion: Lauren E. Rosebrugh is a pioneering inventor whose work on Z-selective metathesis catalysts exemplifies the spirit of innovation. Her patent signifies a meaningful advancement in catalysis, with potential implications for various industrial applications. Through her ongoing research and collaboration, Lauren continues to push the boundaries of what's possible in chemical engineering and catalysis.