The field of catalysis has revolutionized industries and everyday life, with around 80% of all chemical products relying on this principle. One particularly effective catalyst is platinum, but its rarity and expense make it essential to use it efficiently. Researchers at ETH Zurich have made a groundbreaking discovery by mapping the atomic environments of single platinum atoms in solid supports, paving the way for optimized production of single-atom catalysts.

Using nuclear magnetic resonance (NMR), a team led by Javier Pérez-Ramírez and Christophe Copéret was able to study the individual platinum atoms in detail. This method, typically used for investigating molecules, allowed them to show that the atomic environments of these atoms can have very different properties, influencing their catalytic action.

The researchers found that each platinum atom has a unique combination of neighboring atoms and spatial orientation, similar to the distinct tones in an orchestra. By developing a computer code with the help of a simulation expert, they were able to filter out the different “tones” and create a map of the atomic environments surrounding the platinum atoms.

This breakthrough enables the optimization of production protocols for single-atom catalysts, where all platinum atoms can have tailored environments. The researchers aim to develop more efficient catalytic materials, which is crucial for a greener future in industries such as fuel cells and exhaust catalysts.

The discovery has significant intellectual property implications, allowing the precise description of catalysts at the atomic level and enabling patent protection. This innovation has far-reaching consequences for the development of more sustainable technologies and could transform the field of catalysis forever.

Physicists at the University of Bayreuth and Johannes Gutenberg University Mainz have made a groundbreaking discovery that could transform the way we generate magnetic fields. Prof. Dr. Ingo Rehberg and Dr. Peter Blümler developed an innovative approach to create homogeneous magnetic fields using compact, permanent magnets. This breakthrough design outperforms the traditional Halbach arrangement, which is ideal only for infinitely long and therefore unrealizable magnets.

The new approach presents optimal three-dimensional arrangements of very compact magnets, idealized by point dipoles. The researchers investigated the optimal orientation of the magnets for two geometries relevant to practical use: a single ring and a stacked double ring. This “focused” design allows the generation of homogeneous fields outside the magnet plane, enabling applications such as magnetic levitation systems.

To validate their theoretical predictions, Rehberg and Blümler constructed magnet arrays from 16 FeNdB cuboids mounted on 3D-printed supports. The resulting magnetic fields were measured and compared with theoretical calculations, revealing excellent agreement. In terms of both magnetic field strength and homogeneity, the new configurations clearly outperform the classical Halbach arrangement.

The potential applications of this breakthrough design are vast. Conventional MRI technology relies on powerful superconducting magnets, which are technically complex and extremely costly. The new approach offers a promising alternative for generating homogeneous magnetic fields using permanent magnets. Additionally, this innovation could lead to advancements in particle accelerators and magnetic levitation systems.

This study was published in the renowned interdisciplinary journal Physical Review Applied, showcasing significant advances at the intersection of physics with engineering, materials science, chemistry, biology, and medicine. The implications of this breakthrough design are far-reaching, and further research is expected to uncover new possibilities for its applications.

The researchers at Rice University have made a groundbreaking discovery that vastly improves the stability of electrochemical devices converting carbon dioxide into useful fuels and chemicals. Their innovative approach involves simply sending the CO2 through an acid bubbler, which dramatically extends the operational life of these devices by more than 50 times.

Electrochemical CO2 reduction (CO2RR) is a promising green technology that uses electricity to transform climate-warming CO2 into valuable products like carbon monoxide, ethylene, or alcohols. These products can be further refined into fuels or used in industrial processes, potentially turning a major pollutant into a feedstock.

However, the practical implementation of this technology has been hindered by poor system stability due to salt buildup in gas flow channels. This issue occurs when potassium ions migrate from the anolyte across the anion exchange membrane to the cathode reaction zone and combine with CO2 under high pH conditions.

To combat this problem, the Rice team tried a clever twist on standard procedures. Instead of using water to humidify the CO2 gas input into the reactor, they bubbled the gas through an acid solution such as hydrochloric, formic, or acetic acid.

The vapor from the acid altered local chemistry in trace amounts, preventing salt crystallization and channel blockage. The effect was remarkable: systems operated stably for over 4,500 hours in a scaled-up electrolyzer, compared to just about 80 hours under standard water-humidified CO2 conditions.

This breakthrough has significant implications for the development of carbon capture and utilization technologies. By extending the lifespan of CO2 electrolyzers, this innovation can help make these technologies more commercially viable and sustainable.

The simplicity of this approach is noteworthy, as it requires only small tweaks to existing humidification setups, which means it can be adopted without significant redesigns or added costs. This makes it an attractive solution for industries looking to integrate carbon utilization technologies into their operations.

This work was supported by the Robert A. Welch Foundation, Rice University, the National Science Foundation, and the David and Lucile Packard Foundation. The researchers’ findings have the potential to transform the field of CO2RR and pave the way for more durable, scalable electrochemical devices that can efficiently convert CO2 into valuable products.

The study’s authors highlight the significance of this discovery, saying it “addresses a long-standing obstacle with a low-cost, easily implementable solution.” They also emphasize its potential impact on making carbon utilization technologies more commercially viable and sustainable.