Prof. Mark Reed: At Yale University, Reed is one of the pioneers in molecular electronics. He conducted some of the first experiments that demonstrated quantum transport in molecular systems, paving the way for further research in the field.
Prof. Supriyo Datta: Based at Purdue University, Datta’s work focuses on quantum transport in molecular and nanoscale systems, providing crucial theoretical insights that have helped define the trajectory of molecular electronics.
Dr. James Tour: Operating out of Rice University, Tour’s multidisciplinary approach involves creating molecular switches, memories, and even molecular cars, furthering the possibilities of using organic molecules in computational devices.
Prof. Paul Weiss: At UCLA, Weiss’s work encompasses nanoscale and molecular electronics, focusing on the understanding and manipulation of molecules in electronic devices.
Dr. Michelle Simmons: Based at the University of New South Wales, Simmons explores quantum physics and molecular electronics, leading cutting-edge research in atomic-scale fabrication of electronic devices.
Prof. Herre van der Zant: Working at Delft University of Technology, van der Zant is renowned for his experiments on quantum transport and mechanical properties of molecular systems, elucidating the behavior of molecules in electronic circuits.
Prof. Nongjian Tao: At Arizona State University, Tao’s focus is on molecular and nano-electronics, specifically exploring charge transport in molecular systems and developing new techniques to study molecular processes.
Dr. Colin Lambert: Based at Lancaster University, Lambert is known for his theoretical contributions to understanding electron transport through molecules, providing valuable insights into molecular-scale conductance.
Prof. Christian Joachim: Working at the French National Centre for Scientific Research (CNRS), Joachim’s work in scanning tunneling microscopy has been instrumental in exploring molecular architectures and their potential in electronic devices.
Prof. Andrew Briggs: At the University of Oxford, Briggs investigates the boundaries of quantum mechanics and their implications for molecular electronics, looking into mechanisms like superposition in organic molecules.