General Information

Top of Page
Org Chart

Our Research Mission

Scientists in Brookhaven's Chemistry Department conduct basic and applied chemical research with an emphasis on new energy conversion pathways.

Primary research subjects include catalysis and electrocatalysis for sustainable fuel synthesis and use, solar energy conversion to fuels, fundamental gas and condensed phase molecular dynamics, radiation chemistry, and advanced chemical separations for energy applications. Fundamental studies of neutrino properties are also conducted in several international collaborations in nuclear and particle physics. 

  1. AUG




    "Atmospheric Chemistry Colloquium for Emerging Senior Scientists (ACCESS XII)"

    8 am, Berkner Hall, Room B

    Saturday, August 1, 2015, 8:00 am

    Hosted by: Ernie Lewis

Artificial Photosynthesis

Advances fundamental knowledge of processes leading to efficient conversion of sunlight to viable chemical fuels.

Catalysis: Reactivity and Structure

Pursues an improved understanding of chemical catalysis for advanced fuels synthesis and energy conversion processes by elucidating catalytically important properties of well-defined surfaces, powders and nanostructures.

Electron- and Photo-Induced Processes

Applies both photoexcitation and ionization by short pulses of fast electrons to investigate fundamental chemical problems relevant to the production and efficient use of energy 

Gas Phase Molecular Dynamics

Develops and applies high resolution spectroscopic and quantum theoretic tools to study the structure, dynamics, and chemical reactivity of molecular species relevant to hydrocarbon combustion.

Surface Electrochemistry and Electrocatalysis

Explores problems of electrocatalysis of fuel cell reactions focusing on platinum monolayer (PtML) electrocatalysts for the O2 reduction reaction, the electrocatalysts for ethanol and methanol oxidation to CO2, H2 evolution and H2 oxidation reactions. 

Neutrino and Nuclear Chemistry

Participates in international collaborations including Low Energy Neutrino Spectroscopy (LENS), "SNO+", the Daya Bay neutrino experiment, and the long-baseline neutrino experiment (LBNE)

Surface Chemical Dynamics

Works to understand the underlying physical processes that determine the products and yield of chemical transformations relevant to energy-related chemistry on catalytic and nanostructured surfaces. 

The Chemistry Department is part of Brookhaven National Laboratory's Energy Sciences Directorate.