Company Filing History:
Years Active: 1988
Title: Sandor Kristyan – Innovator in Catalyst Activation Technology
Introduction
Sandor Kristyan, based in Budapest, Hungary, is a noteworthy inventor recognized for his contributions to catalyst activation technologies. With a focus on innovative methods, Kristyan has developed a unique approach that enhances catalyst performance through the application of electrical potentials.
Latest Patents
Kristyan holds a patent for his groundbreaking invention titled "In situ activation of catalysts by applied electrical potentials." This patent describes a novel method for activating conductive catalysts or catalyst compositions. By applying a high electrostatic potential of up to 3,000 vdc while exposing the catalyst's surface to an ionizable gas, he observes significant improvements in activation. Notably, this activation persists even after the electrical potential is removed, which is essential for maintaining catalyst efficiency during chemical reactions. This technology has been demonstrated effectively in the nickel-catalyzed hydrogenolysis of ethane and ethylene.
Career Highlights
Kristyan is affiliated with the University of Texas System, where he has contributed to advancing research in catalysis and materials science. His work has garnered recognition within the academic community, reflecting the impact of his innovations on both practical applications and further research.
Collaborations
In his innovative endeavors, Kristyan has collaborated with Richard B. Timmons, another professional in the field. This partnership has likely fostered further advancements and insights into catalyst technologies, enriching the research ecosystem.
Conclusion
Sandor Kristyan's contributions to catalyst activation through electrical potentials showcase his ingenuity as an inventor. His patent not only pushes the boundaries of existing technologies but also opens new avenues for research and applications in catalytic processes. With continued collaboration and innovation, Kristyan's work has the potential to significantly impact various industries reliant on efficient catalytic reactions.