Company Filing History:
Years Active: 2025
Title: Innovations in Liquid Crystal Elastomers: The Work of Joselle McCracken
Introduction
Joselle McCracken is an innovative inventor based in Westminster, Colorado. With a focus on liquid crystal elastomers (LCEs), she has made significant contributions to the field of materials science. Her research aims to enhance the properties of liquid crystalline materials, paving the way for novel applications in technology and engineering.
Latest Patents
McCracken holds a patent for "Liquid crystal elastomer compositions and methods of making the same." This invention features a liquid crystal elastomer created from liquid crystalline monomers with a mesogenic core consisting of 4-(6-(acryloyloxy)n-oxy)phenyl-4-(6-(acryloyloxy)m-oxy)benzoate (CnBAPE). The resulting LCEs exhibit improved thermotropic characteristics, including lower activation temperatures. Additionally, the incorporation of azobenzene in her designs enhances the phototropic properties of the elastomers, broadening their potential applications.
Career Highlights
Joselle McCracken is affiliated with the University of Colorado, where she continues to enhance her expertise in polymer science and material innovations. Her dedication to research and development in elastomers distinguishes her as a leading figure in her field. Notably, her patent reflects her commitment to advancing material properties that could benefit a wide array of industries.
Collaborations
Throughout her career, McCracken has collaborated with talented colleagues like Timothy White and Tayler Hebner. These partnerships foster a dynamic environment for innovation, enabling groundbreaking research and the exchange of ideas. Together, they drive progress in the field of liquid crystal elastomers, contributing to advancements in both academic research and practical applications.
Conclusion
Joselle McCracken's contributions to the development of liquid crystal elastomers exemplify the intersection of creativity and science. Her patented innovations promise to enhance thermotropic and phototropic properties, leading to broader applications and improved performance in various fields. As she continues her work at the University of Colorado, McCracken remains a vital contributor to the future of material innovation.