Aluminium + Diamond-Like Carbon for Next-Gen Hydrogen Fuel Cells

April 11, 2025 ~ Matheus A. Tunes ~ Leave a comment

Our latest study just dropped as a preprint on the SSRN server: Is Nitrogen Doping of Diamond-Like Carbon Films a Viable Strategy for Bipolar Plates in Proton Exchange Membrane Fuel Cells? 💡 In this work, we challenge the idea that nitrogen doping improves Diamond-Like Carbon (DLC) coatings. Using a combination of electrochemical testing, electron microscopy, … Continue reading Aluminium + Diamond-Like Carbon for Next-Gen Hydrogen Fuel Cells

Our Paper Featured in the “Best of Advanced Engineering Materials 2024”

December 18, 2024 ~ Matheus A. Tunes ~ 1 Comment

We are thrilled to announce that our paper, “Limitations of hydrogen detection after 150 years of research on hydrogen embrittlement”, has been selected as one of the standout contributions in the Advanced Engineering Materials 2024 Virtual Issue. This special virtual collection, curated and selected by the Journal Editors, highlights some of the most exceptional research … Continue reading Our Paper Featured in the “Best of Advanced Engineering Materials 2024”

Probing the High-Entropy Concept Through the Irradiation Response of Near-Equimolar (CrNbTaTiW)C Ceramic Coatings

December 1, 2024December 5, 2024 ~ Matheus A. Tunes ~ Leave a comment

As researchers and enthusiasts of materials engineered for extreme environments, we are thrilled to share an exciting new advancement in the field of high-entropy ceramics (HECs). Our journey into the world of radiation-resistant materials has led us to examine the latest findings from a novel study: Probing the High-Entropy Concept Through the Irradiation Response of … Continue reading Probing the High-Entropy Concept Through the Irradiation Response of Near-Equimolar (CrNbTaTiW)C Ceramic Coatings

ACerS highlights Cr2AlC MAX Phases pathway to extreme environments

May 12, 2021 ~ Matheus A. Tunes ~ 1 Comment

MAX radiation protection for next-generation nuclear power plants, by Jonathon Foreman, Ceramic Tech Today. "The radiation tolerance of MAX phases is of particular interest to researchers because it makes these materials ideal candidates for use in next-generation nuclear power technologies. Studies that exposed various MAX compositions to low and high doses of high-energy ions found … Continue reading ACerS highlights Cr2AlC MAX Phases pathway to extreme environments