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Synchronized infrared lasers control molecular shape changes and expose hidden fingerprints

Researchers from the Molecular Physics and Physical Chemistry departments of the Fritz Haber Institute have shown how two highly synchronized infrared (IR) laser beams can control molecules as they switch between different structural conformations. Their study provides a new window into how molecules rearrange themselves during chemical reactions, offering fundamental insights into the microscopic processes that govern chemistry.

Chemical reactions are the foundation of all the processes that sustain life. Researchers around the world are working to develop precise physical descriptions of these processes to better understand, predict or specifically control them.

In chemical reactions, molecules undergo various structural transformations, changing their 3D shapes between different conformations. These changes can be visualized as movements across an energy landscape, where the shape of the terrain determines how fast a reaction proceeds. Similar to a ball rolling through a hilly landscape, a molecule must overcome energy barriers—the “mountains”—to settle into a new, stable state in the next “valley.”

MOF thin films reveal hidden dense packing, challenging decades of porous assumptions

Due to their high porosity, metal-organic frameworks (MOFs) are regarded as promising materials for innovative applications, which is why the Nobel Prize in Chemistry was awarded in 2025 for their discovery. They are used, for example, to store gases, to capture CO2 and for the targeted delivery of medicines.

While the structure of MOFs in the form of large crystals can be determined with relative ease, thin films have largely remained a mystery. Yet it is precisely the structure that is decisive for the properties and for potential applications.

A team led by Roland Resel and Egbert Zojer from the Institute of Solid State Physics at Graz University of Technology (TU Graz), together with colleagues from the Institute of Physical and Theoretical Chemistry (led by Paolo Falcaro) and the Karlsruhe Institute of Technology (led by Christof Wöll), has now solved this puzzle.

Unlocking the ‘black box’ of carbon materials: Study reveals origins of defect peaks

Carbon materials, such as carbon fibers and activated carbons, are essential across a wide variety of fields, encompassing everything from aerospace engineering to fuel cells and thermal insulation. For decades, Raman, infrared and X-ray photoelectron spectroscopy (XPS) have been the primary tools used to analyze carbon materials. However, because of their diverse structural conditions and inconsistencies in their interpretation, researchers have found it challenging to assign specific spectral peaks to exact, localized chemical structures.

The detailed origin and nature of these peaks, and their exact effect on important material characteristics, have often remained unclear.

To tackle this issue, a research team led by Associate Professor Yasuhiro Yamada from the Graduate School of Engineering, Chiba University, Japan, used isotropic pitch-based carbon fiber—a cost-effective material widely used for high-temperature thermal insulation—as a general model to analyze carbon materials prepared at high temperatures of 1,473 K (1,200 °C) or higher.

Strange Things Are Happening in Quantum Computing

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Quantum computing is supposed to be one of the most exciting new technologies that humanity is working on, with companies promising it can be used in chemistry, material science, logistics, and finance. Over the years, those use cases have been slowly eroded, but investment in quantum tech has only increased. Why? Let’s take a look.

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Electrochemical research takes major strides towards harvesting a vital battery material

The supply of lithium—the battery material that keeps digital devices humming, EVs racing and renewable energy on the grid— will not meet even half the expected demand by 2040.

Ramping up production using old methods will create new problems, including environmental damage, pollution, cost and water scarcity. Unconventional ways must be found to fill this lithium gap.

One promising solution is electrochemical intercalation. Common in the world of batteries and supercapacitors, it’s when researchers apply electricity to insert ions between the layers of a different material.

Abundant catalyst converts methane into valuable liquid chemicals

Scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory and their collaborators have demonstrated a promising new approach for converting methane—the primary component of natural gas—into liquid chemicals that are precursors for many industrial chemicals and fuels. The research, described in a paper just published in Advanced Functional Materials, shows how molybdenum disulfide (MoS2), an earth-abundant industrial catalyst, can be used with minimal tweaking to selectively convert methane into methyl peroxide and other liquid oxygenate compounds at temperatures below 100°C (212°F). Methyl peroxide is a precursor for making methanol, an energy-dense liquid fuel that can be transported easily.

“The fact that this catalyst is an earth-abundant, domestically sourced material could change the game for converting natural gas into liquid chemicals,” said Brookhaven Lab chemist Sanjaya Senanayake, a corresponding author on the publication. “The catalyst achieves very high yields and high specificity for making important precursors for methanol and a wide range of other industrial processes.”

The project is part of a long-term strategy of the Catalysis: Reactivity and Structure group in Brookhaven Lab’s Chemistry Division to develop methane-conversion catalysts and processes. This group includes co-authors Senanayake, chemist Juan Jiménez and research associate Arephin Islam—all co-authors on the new publication.

H. pylori screening could return fivefold value in gastric cancer prevention

Each unit of cost invested in Helicobacter pylori screening can generate approximately a fivefold return in gastric cancer prevention benefits.

The gastric cancer prevention research team at National Taiwan University Hospital and College of Public Health, National Taiwan University, has pioneered a globally applicable preventive model for gastric cancer control. To inform public health policymaking, the research team developed a globally adaptable decision-tree model to evaluate the cost-effectiveness of H. pylori screening. The findings were published in JAMA on June 1, 2026.

Building on Taiwan’s nationwide fecal immunochemical test-based colorectal cancer screening program, the gastric cancer prevention team has conducted a 10-year randomized clinical trial demonstrating that the additional use of an H. pylori stool antigen test (HPSA) alongside fecal occult blood testing could simultaneously achieve the dual goals of colorectal cancer and gastric cancer prevention. The findings were previously published on Sept. 30, 2024, in JAMA.

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