In this AI-generated episode of The Zero Emission Zone, we explore a cutting-edge study that evaluates the most promising carbon capture and utilization (CCU) processes using a new Sustainable Feasibility Index (SFI). The researchers rigorously model and assess eleven CCU pathways—like acetic acid, formic acid, and calcium formate—based on environmental, economic, and market factors. Tune in to find out which technologies are truly viable for a net-zero future.
In this AI-generated episode of The Zero Emission Zone, we break down a 2025 perspective by Seger et al. on the dominant reaction mechanisms in CO₂ electrolysis. From C1 to elusive C3 products, this work synthesizes computational and experimental data into a coherent map of how CO₂ transforms into fuels and chemicals on copper catalysts. Listen in as we explore the formal rules that may unlock cleaner fuel production through electrified chemistry.
In this episode of The Zero Emission Zone, we explore how platinum distribution within PEM fuel cell cathodes impacts the measurement of proton transport resistance. Drawing from new research by Mehrazi et al. at Bosch, we unpack why measuring at the right potential is crucial—and how impedance spectroscopy can double as a diagnostic tool for catalyst aging. AI-generated summary based on the published journal paper.
In this AI-generated episode, we explore a recent study on lithium-ion battery aging under real-world automotive conditions. Using a P2D model and optimization techniques, researchers trace how key physical parameters evolve during use—revealing mechanisms like electrolyte breakdown and positive electrode cracking. The findings not only enhance our understanding of battery degradation, but also help validate diagnostics through post-mortem analysis. Read the full paper here: https://doi.org/10.1016/j.etran.2025.100410
In this episode of The Zero Emission Zone, we explore how engineered gold electroplating on titanium porous transport layers (PTLs) significantly improves corrosion resistance and efficiency in PEM water electrolyzers. Learn how optimized rotation during plating enhances durability and lowers voltage losses—insights from cutting-edge research at the Hydrogen Research Institute.
Episode content generated by AI. Read the full paper here: https://doi.org/10.1016/j.ijhydene.2025.02.047
How do you measure corrosion in radioactive environments? In this episode, we explore a recent study that demonstrates the long-term stability of silver/silver chloride quasi-reference electrodes under gamma radiation—critical for electrochemical monitoring in nuclear waste storage. This AI-generated summary dives into how these electrodes stand up to extreme conditions, enabling safer infrastructure through better data.
This episode explores a breakthrough in visualizing hydrogen storage mechanisms using in situ 4D-STEM. Researchers demonstrate subnanometer strain mapping in palladium nanocubes during hydride formation under 1 bar of hydrogen, offering new insight into nanoscale hydrogen absorption. This episode’s summary is AI-generated.
In this episode of The Zero Emission Zone, we explore how electrocatalysis can unlock a sustainable future for chemical manufacturing using abundant C2 and C3 hydrocarbons. Inspired by past breakthroughs and powered by modern clean electricity, researchers are reimagining how we convert ethane and propane into essential chemicals. This AI-generated summary breaks down the mechanisms, catalyst innovations, and reactor strategies behind this promising path toward decarbonization.
Read the full journal article here. https://doi.org/10.1021/acscatal.5c00393
Discover how in-line continuous flow Raman spectroscopy is revolutionizing our understanding of electrochemical interfaces. This episode explores a new technique for tracking interfacial pH dynamics during water electrolysis under realistic operating conditions. Tune in to learn how this innovation advances the design of more efficient electrolyzers. Content generated by AI.
In this episode of The Zero Emission Zone, we explore a groundbreaking electrochemical method to convert nitric oxide (NO)—a major pollutant—into concentrated nitric acid (HNO₃) at near-ambient conditions using carbon-based catalysts. This AI-generated summary breaks down how the process achieves high Faradaic efficiency, operates without added electrolytes, and presents a sustainable path for decentralized chemical manufacturing.
In this AI-generated episode of The Zero Emission Zone, we explore a cutting-edge study from Nature Nanotechnology on a platinum catalyst protected by graphene nanopockets. Designed for proton exchange membrane fuel cells in heavy-duty vehicles, this innovation delivers exceptional power density and a projected lifetime exceeding 200,000 hours—over seven times the DOE 2050 target. Tune in as we break down how nanotechnology is setting new standards for clean energy durability.
Original paper: https://doi.org/10.1038/s41565-025-01895-3
In this episode of The Zero Emission Zone, we unpack a breakthrough in sodium all-solid-state batteries. Drawing from a recent study in Advanced Energy Materials, we explore how a simple cathode presodiation technique using Na₂S can dramatically improve battery stability and capacity—paving the way for safer, more sustainable energy storage.
This episode features AI-generated dialogue based on peer-reviewed research. For full details, check out the original paper.
In this episode of The Zero Emission Zone, we delve into cutting-edge research that could revolutionize sustainable energy. Join us as we explore the innovative photothermocatalytic reactor designed to harness solar energy for creating liquid hydrocarbons—an essential step toward carbon-neutral aviation fuels. Discover how selective solar absorbers enable high-efficiency solar-to-thermal conversion and how this technology can scale to meet industrial needs. From technical breakthroughs to real-world implications, this episode uncovers how sunlight is being transformed into a tool to combat climate change. Don't miss this glimpse into the future of sustainable fuel synthesis!
In this episode, we dive into the transformative potential of long-duration energy storage (LDES) for achieving zero-emissions grids by 2050. Using insights from a study on the Western Interconnect grid in North America, we explore how varying grid conditions—from solar and wind capacity to hydropower availability—impact the value and optimal deployment of LDES. Join us as we unpack key findings, including the ability of LDES to reduce electricity costs during peak demand, support renewable-heavy grids, and lessen the need for extensive transmission expansion.
In this episode, we dive into the intricate world of electrochemical energy storage. Join us as we explore a groundbreaking approach to electrode design using topology optimization, aiming to boost energy storage capacity by up to 750%! Discover how innovative structures and materials can revolutionize battery and capacitor efficiency, paving the way for a greener, more energy-dense future.
In this episode, we dive into the innovative world of waste-to-ammonia technology, exploring how produced water from oil and gas activities could be transformed into a sustainable fuel source. This study explores three production paths—gray, blue, and green ammonia—analyzing their economic viability and carbon footprints. Discover how each approach leverages different technologies, from carbon capture to solar-thermal, and what it means for the future of green ammonia as a reliable, scalable hydrogen carrier.
In this episode, we dive into the innovative world of district heating with a twist—using waste heat from data centers! Join us as we explore how a data center in Finland could warm homes and reduce carbon emissions simultaneously. By repurposing the excess heat from servers, this study shows how we can move closer to net-zero carbon goals while lowering heating costs. Discover the challenges, potential savings, and environmental benefits of integrating data center heat into regional energy grids.
In this episode of The Zero Emission Zone, we dive into the innovative “cloud-milking” technology that’s helping to reforest drought-stricken and fire-damaged areas. Developed in the Canary Islands, this zero-energy technique collects water from fog using mesh structures that mimic pine needles. Join us to explore how cloud-milking is being used worldwide to keep young trees alive, irrigate crops, and even provide drinking water—all without the need for electricity or fossil fuels.
Electric vehicles are rapidly advancing, and battery technology is at the forefront of this revolution. In this episode, we explore the two leading contenders for the next generation of EV batteries: solid-state batteries and silicon anode batteries. We'll examine the pros and cons of each technology, the companies leading the charge, and the potential impact on the future of electric vehicles.
Source: https://insideevs.com/features/738508/high-silicon-anode-solid-state/
Discover how researchers are shaking up the world of 3D printing with a revolutionary cement-free method. Instead of traditional, carbon-heavy materials, they’re using a unique blend of earth-based substances—like sand, silt, and gravel—to build resilient structures. Tune in as we explore this sustainable approach, its benefits over concrete, and how it could shape the future of eco-friendly construction!