PNNL researchers worked to decouple the effects that solvents impose on reactions catalyzed in the liquid phase.

Triton is piloting research on the interactions of receptors and anthropogenic light associated with marine energy devices.

New research finds that reaction rates for cyclic alcohol dehydration increase as ionic strength increases, independent of reaction mechanism.

The Triton Initiative introduces its next generation of projects focused on researching stressor/receptor interactions for marine energy applications.

Internship focused on detecting and characterized baleen whale vocalization activity near the future PacWave test site in Newport, Oregon.

The Triton Initiative supports projects funded through U.S. Department of Energy funding opportunity announcements developing environmental monitoring technologies for marine energy.

Voice for ocean-based climate solutions and strategist for PNNL’s Coastal Sciences Division, Simon Geerlofs, speaks about the Triton Initiative.

Local ionic strength within zeolite pores tailors the chemical potential of reacting molecules, leading to high cyclohexanol dehydration activity

Tetranuclear molybdenum sulfide clusters encaged in zeolites mimic the FeMo-cofactor of nitrogenase, offering a new opportunity for improving industrial hydrotreatment processes.

New research uncovers the mechanism of carbon dioxide reduction by metal-O-Fe bonds of single-metal atoms and metal nanoparticles supported by oxidic surfaces.

Samantha Eaves discusses the future of marine energy and her role with Triton from the Department of Energy Water Power Technologies Office perspective.  

Characterizing the electron redistribution that allows the binding of molecular nitrogen to the catalytic core of nitrogenase.

Coastal Sciences Division group leader, Meg Pinza, helped build Triton into a thought leader in the field of marine energy environmental monitoring.

A new approach uses CO₂ to favorably co-produce methanol and glycols in a simple one-pot reaction.

A nanosized metal catalyst directly bonded to a metal-organic framework is active in converting carbon dioxide to methanol.

Scientists at PNNL's Center for Molecular Electrocatalysis (CME) are working to understand the fundamental reactivity of H2 that could contribute to making hydrogen a more widely used fuel source.

Using a bio-inspired design that mimics nature's catalysts-enzymes, researchers at PNNL have designed a rarely seen reversible synthetic catalyst.

At PNNL, scientists have mapped the reaction that turns wind-generated electricity into fuel and the amount of energy needed for each step.

Dr. Morris Bullock and Dr. Monte Helm reviewed the catalysis research at the Center for Molecular Electrocatalysis, where Bullock is the director, in a recent article in Accounts of Chemical Research.

Generating power without gasoline, diesel, or coal could change our nation's energy and security landscape. However, replacing technologies that use fossil fuel with ones that require rare metals is unsustainable.