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Category: chemistry

From fullerenes to 2D structures: A unified design principle for boron nanostructures

Boron, a chemical element next to carbon in the periodic table, is known for its unique ability to form complex bond networks. Unlike carbon, which typically bonds with two or three neighboring atoms, boron can share electrons among several atoms. This leads to a wide variety of nanostructures. These include boron fullerenes, which are hollow, cage-like molecules, and borophenes, ultra-thin metallic sheets of boron atoms arranged in triangular and hexagonal patterns.

Dr. Nevill Gonzalez Szwacki has developed a model explaining the variety of boron nanostructures. The analysis, published in the journal 2D Materials, combines more than a dozen known boron nanostructures, including the experimentally observed B₄₀ and B₈₀ fullerenes.

Using first-principles quantum-mechanical calculations, the study shows that the structural, energetic, and electronic properties of these systems can be predicted by looking at the proportions of atoms with four, five, or six bonds. The results reveal clear links between finite and extended boron structures. The B₄₀ cage corresponds to the χ₃ borophene layer, while B₆₅, B₈₀, and B₉₂ connect with the β₁₂, α, and bt borophene sheets, respectively. These structural links suggest that new boron cages could be created by using known two-dimensional boron templates.

How to build a genome: Scientists release troubleshooting manual for synthetic life

Leading synthetic biologists have shared hard-won lessons from their decade-long quest to build the world’s first synthetic eukaryotic genome in a Nature Biotechnology paper. Their insights could accelerate development of the next generation of engineered organisms, from climate-resilient crops to custom-built cell factories.

“We’ve assembled a comprehensive overview of the literature on how to build a lifeform where we review what went right—but also what went wrong,” says Dr. Paige Erpf, lead author of the paper and postdoctoral researcher at Macquarie University’s School of Natural Sciences and the Australian Research Council (ARC) Center of Excellence in Synthetic Biology.

The Synthetic Yeast Genome Project (Sc2.0) involved a large, evolving global consortium of 200-plus researchers from more than ten institutions, who jointly set out to redesign and chemically synthesize all 16 chromosomes of baker’s yeast from scratch. Macquarie University contributed to the synthesis of two of these chromosomes, comprising around 12% of the project overall.

Two-step method enables controllable WS₂ epitaxy growth

In a study published in Journal of the American Chemical Society, a team led by Prof. Song Li from the University of Science and Technology of China (USTC) of the Chinese Academy of Sciences synthesized monolayer WS2 lateral homojunctions via in situ domain engineering, and enabled controllable direct chemical vapor deposition (CVD) growth of these structures.

Two-dimensional (2D) are ideal candidates to replace silicon-based semiconductors due to their exceptional electrical properties at atomic scales. However, device applications require heterogeneous field-effect modulation behaviors across low-dimensional units. Van der Waals interactions or lateral atomic bonding allow damage-free integration into homojunctions/heterojunctions, but direct epitaxy growth remains challenging due to strict atomic species constraints.

In this study, researchers first determined optimal intrinsic defect configurations through theoretical simulations. Then they employed a two-step CVD method to achieve the in situ modulation of defect structures at the domain level, yielding homojunctions with tailored defect architectures.

Enlarging the Periodic Table of Laser-Cooled Molecules

A class of molecules with two valence electrons has been laser cooled and trapped for the first time.

Over the past 70 years, physicists have developed laser-based methods for controlling atoms and molecules, but much of this success has been concentrated on a few columns of the periodic table. For molecules, laser cooling has been limited to diatomic species that have a single unpaired valence electron for interacting with light. Extending laser cooling to molecules with two valence electrons has long been sought after (Fig. 1). The most promising nonreactive candidates are diatomic molecules that partner a halogen, such as fluorine (F) or chlorine (Cl), with a p-block atom, such as aluminum (Al) or thallium (Tl). Several research groups have specifically targeted AlF, AlCl, and TlF, but these molecules are difficult to work with because of their deep-ultraviolet transitions, complicated energy-level structures, and small magnetic moments.

Medications change our gut microbiome in predictable ways

The bacteria in our poop are a reasonable representation of what’s living in our digestive system. To understand how different drugs can impact the gut microbiome, the team cultured microbial communities from nine donor fecal samples and systematically tested them with 707 different clinically relevant drugs.

The researchers examined changes in the growth of different bacterial species, the community composition, and the metabolome – the mix of small molecules called metabolites that microbes produce and consume. They found that 141 drugs altered the microbiome of the samples and even short-term treatments created enduring changes, entirely wiping out some microbial species. The primary force behind how the community responds to drug inhibition was competition over nutrients.

“The winners and losers among our gut bacteria can often be predicted by understanding how sensitive they are to the medications and how they compete for food,” said the first author on the paper. “In other words, drugs don’t just kill bacteria; they also reshuffle the ‘buffet’ in our gut, and that reshuffling shapes which bacteria win.”

Despite the complexity of the bacterial communities, the researchers were able to create data-driven computer models that accurately predicted how they would respond to a particular drug. They factored in the sensitivity of different bacterial species to that drug and the competitive landscape – essentially, who was competing with whom for which nutrients.

Their work provides a framework for predicting how a person’s microbial community might change with a given drug, and could help scientists find ways to prevent these changes or more easily restore a healthy gut microbiome in the future.

Our gut microbiome is made up of trillions of bacteria and other microbes living in our intestines. These help our bodies break down food, assist our immune system, send chemical signals to our brain, and potentially serve many other functions that researchers are still working to understand. When the microbiome is out of balance – with not enough helpful bacteria or the wrong combination of microbes – it can affect our whole body.

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Like living cells, oil-in-water droplets form ‘arms’ in response to their environment

Oil-in-water droplets respond to chemical cues by forming arm-like extensions that resemble filopodia, which are used by living cells to sense and explore their environment.

A research team led by chemists at Penn State studies the droplets to glimpse how matter may have transitioned to life billions of years ago. The researchers have dissected the mechanism through which these arms form and shown that they respond directionally, growing toward or away from specific chemicals.

The research appears in the Journal of the American Chemical Society and will be featured on the front cover of an upcoming issue. The society also featured the research in its Research Headlines video series, which spotlights new and interesting work published in the society’s journals.

Mini-vortices in nanopores accelerate ion transport for faster supercapacitor charging

Tiny cavities in energy storage devices form small vortices that help with charging, according to a research team led by TU Darmstadt. This previously unknown phenomenon could advance the development of faster storage devices.

Solar and wind are the energy sources of the future, but they are subject to significant natural fluctuations. Storage solutions are therefore particularly important for a successful energy transition. Rechargeable batteries achieve very high energy densities by storing energy chemically. However, this high energy density comes at the price of long charging times and a dependence on precious raw materials such as cobalt.

In contrast to rechargeable batteries, so-called supercapacitors store energy in electric double layers: a voltage is applied between two electrodes. They are immersed in a liquid in which tiny charged particles, ions, float. The positive and negative ions move in opposite directions and accumulate in charged, nanometer-thick layers, the electric double layers, on the surfaces of the electrodes. In order to provide as much surface area as possible for the accumulation of ions, supercapacitors use porous electrodes that have many tiny pores, like a sponge.

Durable catalyst shields itself for affordable green hydrogen production

An international research team led by Professor Philip C.Y. Chow at The University of Hong Kong (HKU) has unveiled a new catalyst that overcomes a major challenge in producing green hydrogen at scale. This innovation makes the process of producing oxygen efficiently and reliably in the harsh acidic environment used by today’s most promising industrial electrolyzers.

Spearheaded by Ci Lin, a Ph.D. student in HKU’s Department of Mechanical Engineering, the team’s work was published in ACS Energy Letters.

Green hydrogen is seen as a clean fuel that can help reduce carbon emissions across industries like steelmaking, chemical production, long-distance transportation, and seasonal energy storage. Proton exchange membrane (PEM) electrolyzers are preferred for their compact design and rapid response, but they operate in acidic conditions that are exceptionally demanding on the oxygen evolution reaction (OER) catalyst.

Imaging Uncovers Hidden Structures in Exploding Stars

“Novae are more than fireworks in our galaxy — they are laboratories for extreme physics,” said Dr. Laura Chomiuk.

What can imaging supernovae (plural for supernova) explosions teach astronomers about their behavior and physical characteristics? This is what a recent study published in Nature Astronomy hopes to address as an international team of researchers investigated the mechanisms behind the thermonuclear eruptions that supernovae cause. This study has the potential to help scientists better understand supernovae, as they are hypothesized to be responsible for spreading the chemical elements and molecules needed for life throughout the universe.

For the study, the researchers used the Georgia State University CHARA Array to observe exploding supernovae from two separate white dwarfs: nova V1674 Her and nova V1405 Cas, which are located approximately 16,200 and 5,500 light-years from Earth, and were observed days 2 & 3 and days 53, 55, & 67 after first light of eruption, also known as t0, respectively. For nova V1674 Her, the researchers observed outflows during days 2 & 3, while they observed this same behavior for nova V1405 Cas during days 53, 55, & 67. The researchers note these contrasting observations challenge longstanding hypotheses regarding supernovae behavior during their eruption periods.

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