Intermolecular interactions revisited-Flaws in the fabric and applications to lower-dimensional structures. This project aims to capitalise on recent developments, that have shown that previously accepted theories are deeply flawed, in various applications in fundamental physics and in unsolved problems in biology that involve electromagnetic fields. Interactions driven
by electromagnetic fluctuation forces, and real photon exchange, between molecules will be investigated. The project will inv ....Intermolecular interactions revisited-Flaws in the fabric and applications to lower-dimensional structures. This project aims to capitalise on recent developments, that have shown that previously accepted theories are deeply flawed, in various applications in fundamental physics and in unsolved problems in biology that involve electromagnetic fields. Interactions driven
by electromagnetic fluctuation forces, and real photon exchange, between molecules will be investigated. The project will investigate how dispersion interactions change in mesoscopic pores, in electrolytes, and at finite temperatures. Applications involve
catalysis, molecular formation, and quantum logic. The project also aims to develop a unified theory for energy and charge transfer, relevant for photosynthesis and the way biological molecules transfer information.Read moreRead less
Theoretical Studies on the KcsA Potassium Channel and the L-type Calcium Channel. All electrical activities in the brain are regulated by opening and closing of ion channels. Thus, understanding their mechanisms is a fundamental problem in biology. The project is aimed at developing a theoretical model of two important types of ion channels. Using a supercomputer, we will first deduce the shape of the microstructure formed by a protein wall. Then, using a computer simulation technique, we will c ....Theoretical Studies on the KcsA Potassium Channel and the L-type Calcium Channel. All electrical activities in the brain are regulated by opening and closing of ion channels. Thus, understanding their mechanisms is a fundamental problem in biology. The project is aimed at developing a theoretical model of two important types of ion channels. Using a supercomputer, we will first deduce the shape of the microstructure formed by a protein wall. Then, using a computer simulation technique, we will construct a set of physical models of biological ion channels, which will correctly replicate experimental observations. Such a theory will link the structure and function of an ion channel through the fundamental principles of physics.Read moreRead less