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Scandium-44 is a promising medical isotope for positron emission tomography (PET) imaging for identifying cancer, heart disease, and other conditions. Scandium-44 can be produced through the radioactive decay of titanium-44, but the challenge is to reliably separate scandium-44 from titanium-44 at hospitals. A new approach produces an isotope generator that is portable, uses facilities routinely available at hospitals, and works efficiently and reliably. This will enable medical staff to more easily use scandium-44 for PET scans and other applications.

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In chemical reactions, molecules transform from reactants into reaction products through a critical geometry called a transition state that lasts less than one millionth of one millionth of a second. Scientists recently captured a critical geometry using the ultra-high speed “electron camera” at SLAC. The research will help explain why reactions generate only specific reaction products.

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One approach to the question of why matter is more abundant than antimatter in our observable universe is observing an extremely rare nuclear process called neutrinoless double-beta decay. The MAJORANA DEMONSTRATOR experiment was designed to detect this decay. Although it did not observe the decay, it achieved world-leading energy resolutions and showed the feasibility of using a larger detector to search for the hypothesized decay.

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Individual features in a community, like microbes or types of chemicals, affect the overall community’s development and help determine the similarity of different communities over time and space. Scientists developed a novel ecological metric, called βNTIfeat, that helps to investigate the roles of different features in community development. The resulting information can inform models of how ecosystems respond to disturbances such as climate change.

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Researchers have modified the surface of nickel-platinum nanoparticles to improve their ability to act as catalysts to make reactive oxygen ions. Using a specialized X-ray scattering imaging technique, the researchers examined the modified nanoparticles and discovered a platinum-rich outer layer.

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Genetic engineers use synthetic biology to provide novel functions in microbes by introducing new genes. A new method called Serine recombinase-Assisted Genome Engineering (SAGE) borrows components from bacterial viruses to aid the stable insertion of genes into bacterial chromosomes. This new tool has the potential to work well in many species of bacteria, including newly discovered bacteria that must grow outside controlled laboratory conditions. These features will help accelerate synthetic biology research for bioenergy.

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Microbes have enormous potential to produce metabolites with potential industrial applications. To do so, microbes use groups of genes called biosynthetic gene clusters (BGCs) that code for the sets of necessary enzymes. Scientists have computationally predicted the products of hundreds of thousands of BGCs, but have experimentally confirmed fewer than 2,000 of them. Researchers have now developed a computational and experimental strategy to redesign BGCs and determine the natural chemical products they create.

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Although electrons usually move in three dimensions, scientists can force electrons to move in two dimensions (2D) by creating ultra-thin materials. In this new work, however, researchers found that by adding superconductivity to 3D electrons in a bulk material, the superconducting electrons form 2D superconducting “puddles.” These puddles of electrons may be a way for some superconductors to reorganize themselves before undergoing an abrupt phase transition into an insulating state.

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Coastal forests are increasingly exposed to the effects of climate change and sea level rise. New experimental research examined how soils change when transplanted between parts of a tidal creek that differed in salinity. Scientists found that soils with a history of salinity and inundation by seawater were more resistant to changes in water conditions, suggesting that soils learn from their history of inundation.

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Halide perovskites have applications in solar energy, radiation detection, and potentially in thermal harvesting. Cesium lead bromide is among the simplest of lead halide perovskite materials (LHPs). New research examined structural instabilities and large atomic fluctuations that may affect LHPs’ optical and thermal properties. It found that the atomic vibrations (phonons) of bromine octahedrons have large amplitudes but cannot oscillate for long amounts of time. Instead, the vibrations are strongly damped.

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University of Washington professor Xiaodong Xu studies the properties of single atomic layer semiconductors, looking for new materials and new ways to control electrical conductivity.

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A new study that aims to resolve uncertainty in projections of future changes in the U.S. Midwest rainy season projects that while future seasonal mean precipitation will not change significantly, late spring precipitation will increase and late summer rainfall will decrease. The study indicates these changes will be driven by the poleward shift in the North American westerly jet due to climate change. The results may mean an increased risk of late-spring deluges and late-summer droughts for the Midwest.

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Recent research sheds light on the mechanism behind how quantum materials change from an electrical conductor to an electric insulator. Below a critical temperature, strontium doped lanthanum strontium nickel oxide is an insulator due the separation of introduced holes from the magnetic regions, forming “stripes.” These stripes fluctuate and melt at 240K, at which temperature the material should become a conducting metal. Instead, it remains an insulator. This is because of certain atomic vibrations that trap electrons and impede electrical conduction.

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The ARM Data Center collects and manages global observational and experimental data amassed by the Department of Energy (DOE) Office of Science’s Atmospheric Radiation Measurement user facility. The ARM Data Center gathers and curates some 50 terabytes of data per month from more than 460 instruments located in climate-critical locations worldwide. The data center processes and packages the information from these instruments into over 11,000 distinct data products. For the past 30 years, ARM has been making this data accessible to scientists around the world.

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To do research, chemists need data to predict and explain the direction, outcome, and amount of energy released or used during a chemical reaction. This information – called thermochemical data – is essential for a good deal of fundamental chemical science and for understanding and improving industrial processes. Argonne National Laboratory developed the Active Thermochemical Tables (ATcT) over the last two decades to meet the growing need for such data in many sectors.

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Urbanization has noticeable effects on processes at and near the Earth’s surface, affecting weather and climate. An international team of scientists reviewed more than 500 sources from the scientific literature produced over nearly 200 years on effects of urbanization on extreme weather and regional climate to better synthesize this knowledge and direct future research.

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Researchers recently reviewed the current standard procedure to determine the nuclear weak distribution, which describes the distribution of active protons in a nucleus. The new analysis found significant differences with previous model-based determinations of the nuclear weak distribution. The results provide a partial explanation for a discrepancy between predictions from particle physics theory and experimental measurement of a fundamental quantity.

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Quantum systems decohere due to unwanted interactions with their environment. Correcting for the effects of decoherence is a major challenge for quantum information systems. Previous error correction methods have not kept up with decoherence.

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Researchers investigated how large-scale urbanization and irrigation in the United States affect the three dominant types of summer precipitation in the mid-Atlantic region. They found that urbanization suppresses all three types of precipitation. Irrigation enhances non-convective and isolated deep convection precipitation, and its effects on mesoscale convective systems (MCS) depends on whether an MCS formed locally or remotely.

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Detecting drizzle in its early stages in marine stratocumulus clouds is important for studying how water in clouds becomes rainfall. However, detecting the initial stages of drizzle is challenging for ground-based remote-sensing observations.

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Nuclei can absorb energy, pushing the nuclei into excited states. When these states decay, the nuclei emit different particles. The interplay between these decay channels and the internal characteristics of the excited states gives rise to phenomena such as superradiance. In superradiance, a nucleus with high excitation energy has excited states so dense that neighboring excited states overlap. Scientists recently found evidence of the superradiance effect in the differences between decaying states in Oxygen-18 and Neon-18.

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A new study investigated the role of the genes in individual switchgrass plants in determining the composition of the bacterial communities associated with the plants’ roots.

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Supported by his Early Career Research Program award, physicist Junjie Zhu’s work at the CERN Large Hadron Collider led to the first-ever evidence of two rare but important physics processes. These interactions produce the particles responsible for nuclear decay.

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Creating efficient, self-sustaining fusion power requires good confinement of the heat in the plasma. This requires understanding particle and energy losses due to turbulence. A new analysis studied the complex interaction in turbulence between the slow, large-scale motion of hydrogen fuel ions and the fast, small-scale motion of electrons. It found that this so-called “multi-scale turbulence” is mostly responsible for the heat losses in the edge region of tokamak experiments.

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When some semiconductors absorb light, the process can create excitons, quasi-particles made of an electron bound to an electron hole. Two-dimensional crystals of tungsten disulfide have unique but short-lived exciton states. Scientists developed a new approach called time-resolved momentum microscopy to create separate images of these individual quantum states. The study found that the coupling mechanisms that lead to mixing of the states may not fully match current theories.

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Recent data from the Relativistic Heavy Ion Collider show how three distinct variations of particles called upsilons “melt,” or dissociate, in the hot particle soup that existed in the very early universe. The results from the STAR experiment support the theory that this hot matter is a soup of “free” quarks and gluons. Measuring how different upsilons dissociate helps scientists learn about the quark-gluon plasma.

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To study microbes, scientists need to collect, process, and share data in a standardized way. The National Microbiome Data Collaborative (NMDC) Ambassador Program launched in 2021 to increase awareness and adoption of microbiome metadata standards. During the program’s year-long term in 2021 and 2022, more than 800 researchers attended 23 Ambassador-hosted presentations.

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Bottomonium mesons consist of a heavy bottom quark bound to an antibottom quark, and the two quarks can be bound loosely, more tightly, and very tightly (creating the smallest bottomonium meson). New calculations that predict the temperature at which these mesons will melt show that the smallest bottomonium particles can stay intact at very high temperatures. This may explain why collisions at different particle accelerators produce different numbers of bottomonium particles.

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Miscanthus thrives on marginal lands with limited fertilization and tolerates drought and cool temperatures, making it an ideal bioenergy candidate. Previous efforts to genetically improve miscanthus focused on introducing external genes at random places in the plant’s genomes. This research developed gene-editing procedures using CRISPR/Cas9 that will allow scientists to selectively target existing genes to knock out their function and introduce new genes into precise locations.

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Kevin Wilson studies how chemistry proceeds at liquid interfaces on cloud droplets, atmospheric aerosols, and ocean surfaces. With the support of his 2012 Early Career award, his team focused on reactions between gases and surfaces of ozone and hydroxyl radicals in the atmosphere.

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Targeted alpha therapy using radioisotopes such as actinium-225 can destroy cancerous cells without harming healthy cells. However, making actinium-225 by bombarding radium targets with neutrons poses a challenge: how to chemically separate the radium from the actinium. A new approach uses radiation-resistant inorganic resin scaffolds as platforms for separating radium, actinium, and lead, improving production time, cost, and safety.

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Nuclei such as Indium-115 (In-115) are extremely long lived, with half-lives of more than 100 billion years. These nuclei allow scientists to probe elusive high energy nuclear states. In a new study, scientists theoretically determined the electron energy spectrum from decays of In-115 based on data collected in a specialized detector. The scientists also performed the world’s most precise measurement of the half-life of In-115.

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Studying radioactive materials is very difficult due to the potential health risks, the cost, and the difficulty of producing some radioisotopes. Scientists recently developed a new approach to harvest detailed chemical information on radioactive and/or enriched stable isotopes. The new approach is much more efficient, requiring 1,000 times less material than previous state-of-the-art methods, with no loss of data quality.

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systematically varying the amount of energy involved in collisions of gold nuclei, scientists have shown that the quark-gluon plasma (QGP) exists in collisions at energies from 200 billion electron volts (GeV) at least to 19.6 GeV. However, its production appears to be “turned off” at the lowest collision energy, 3 GeV. The “off” signal shows up as a sign change in data that describe the distribution of protons produced in these collisions. The findings will help physicists further study the QGP and phases of nuclear matter.

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Understanding the behavior of nuclear matter is extremely complicated, especially when working in three dimensions. Mathematical techniques from condensed matter physics that consider interactions in just one spatial dimension (plus time) greatly simplify the problem. Using this two-dimensional approach, scientists solved the complex equations that describe how low-energy excitations ripple through a system of dense nuclear matter such as exists at the center of neutron stars.

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Theoretical calculations involving the strong force are complex in part because of the large number of ways these calculations can be performed. These options include “gauge choices.” All gauge choices should produce the same result for the calculation of any quantity that can be measured in an experiment. However, it is difficult to obtain consistent results when using one particular choice, “axial gauge.” New research resolves this puzzle.

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Outside atomic nuclei, neutrons are unstable, disintegrating in about fifteen minutes due to the weak nuclear force to leave behind a proton, an electron, and an antineutrino. New research identified a shift in the strength with which a spinning neutron experiences the weak nuclear force, due to emission and absorption of photons and pions. The finding impacts high precision searches of new, beyond the Standard Model interactions in beta decay.