Science Beyond Category:
From Fundamental Physical Chemistry to Applied Atmospheric Science
Microenvironments are ubiquitous in nature and science. Examples include biological cells and atmospheric aerosols. Understanding the chemistry and physics occurring in these small, isolated compartments is essential to understanding human health and global climate, among other things. Our research aims to increase our understanding of micro-environmental properties to increase our understanding of the world and how we can improve it. The Davis Research Group specializes in the chemistry and physics of airborne droplets and aerosol particles.
Nucleation is one of the most fundamentally important processes in science. Crystal nucleation and growth from a liquid solution (i.e., crystallization) is of particular importance due to its widespread relevance in atmospheric science, pharmaceuticals, biology, architectural preservation, and many other applications where the overarching goals are to predict, control, inhibit and/or reverse nucleation. In atmospheric science, crystallization of an aqueous particle alters the particle’s effect on air quality and climate through impacts on heterogeneous chemical reactivity and optical properties of the particle. In pharmaceuticals, tight control of nucleation is essential because the crystalline form of a particular medication often dictates its bioavailability and efficacy. In many soft matter applications, inhibiting the formation of crystals is necessary to maintain the desired material properties. In biology, the formation of protein crystals or other crystal-like aggregates underlies multiple health concerns. Amazingly, despite this widespread importance, there is no comprehensive understanding of crystal nucleation. Included in our research focus is the goal to develop a more comprehensive understanding of crystal nucleation.
Crystallization is not the only possible fate of a liquid. For example, proteins and some simple inorganics can instead form self-assembled polymer aggregates and gels. One particular exciting and emerging area of research involves self-assembled marine polymer gels formed from dissolved organic carbon in sea water. Recently, marine gels have been detected in atmospheric particles, as well. These airborne gels have been proposed as important sources of cloud condensation nuclei when emitted into the atmosphere along with sea spray aerosol.
The formation of reactive oxygen species (ROS) is of growing interest and concern in atmospheric chemistry and biophysical processes. In the atmosphere, the formation of ROS is a driver of atmospheric chemistry, particularly in clouds/fog droplets in urban environments, such as that shown in the image below. In the human body, the formation of ROS is known to be damaging and thought to be linked to cancer. However, the processes that lead to ROS formation are currently not understood. Our research aims to bring a greater understanding of ROS production and the effects such reactive species have in the environment and the human body.
A new direction in the Davis Group is toward green chemistry practices. Our research focus in sustainable "green chemistry" is to reduce the global impact of scientific research and education by developing novel micro-devices that minimize waste and consumption of reagents and by utilizing the unique properties of microdroplets to facilitate chemical reactions in benign solvents such as water. As the innovation economy grows, so does its environmental footprint. In the Davis Group, we hope to reduce that footprint for a sustainable future.