Company Filing History:
Years Active: 2024
Title: Innovations of Jordan Brophy in Nanoporous Materials
Introduction
Jordan Brophy is an innovative inventor based in Laramie, Wyoming. He has made significant contributions to the field of materials science, particularly in the development of ordered functional nanoporous materials. His work focuses on creating materials with unique properties that can be utilized in various applications.
Latest Patents
Jordan Brophy holds a patent for "Synthetically modifiable ion channels." This patent describes a new class of ordered functional nanoporous material (OFNMs) that exhibits a unique combination of electronic conductivity, gas transport ability, and ion transport properties. The OFNM is highly ordered and features nanometer-scale pores lined with nitrogen atoms. These pores range in dimensions from 1.2 nm to 82 nm in their longest linear extent. The functionality within the pore can be controlled by selecting groups that extend into the pore. Additionally, the degree of conjugated aromaticity can be adjusted to modify the electrical conductivity properties of the resulting structure. By altering the groups external to the pore, three-dimensional structures can be formed that mimic organic zeolites, metal-organic frameworks (MOF), or perovskites.
Career Highlights
Jordan Brophy is affiliated with the University of Wyoming's Office of Research & Economic Development. His role at the university allows him to engage in cutting-edge research and contribute to advancements in material science. His innovative work has garnered attention in the scientific community.
Collaborations
Jordan has collaborated with notable colleagues, including Bruce Alan Parkinson and John Hoberg. These collaborations have further enhanced his research and contributed to the development of new technologies in the field.
Conclusion
Jordan Brophy's contributions to the field of nanoporous materials demonstrate his innovative spirit and commitment to advancing material science. His patent on synthetically modifiable ion channels showcases the potential for new applications in various industries.