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Comment by Dr. Krishna Kumari Challa on February 15, 2024 at 10:16am

Pesticides to help protect seeds can adversely affect earthworms' health

While pesticides protect crops from hungry animals, pesky insects, or even microbial infections, they also impact other vital organisms, including bees and earthworms. Now, research published in Environmental Science & Technology Letters reveals that worms are affected by the relatively small amounts of chemicals that can leach out of pesticide-treated seeds. Exposure to nonlethal amounts of these insecticides and fungicides resulted in poor weight gain and mitochondrial DNA (mtDNA) damage in the worms.

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Pesticide treatment can be introduced at several different stages of a plant's life, either by covering seeds before they're sown or spraying already grown crops. Oftentimes, different chemicals are applied at the same time to maximize their efficiency. Neonicotinoids, also known as neonics, are one common class of insecticides used today in the U.S. and other countries, though many of them are banned in the European Union.

Recent research has shown that these insecticides and many fungicides persist in groundwater and soil, where earthworms may encounter them. One method to monitor the health of the impacted worms is through changes to the organisms' weight and mtDNA damage. Unlike DNA held in a cell's nucleus, mtDNA can't repair itself as well, and thus can help indicate less obvious, "off target" effects of a particular environmental toxin.

Part 1

Comment by Dr. Krishna Kumari Challa on February 15, 2024 at 10:06am

This third magnetic sibling offers distinct advantages for the developing field of next-generation magnetic memory technology, known as spintronics. Whereas electronics makes use only of the charge of the electrons, spintronics also exploits the spin-state of electrons to carry information.

Juraj Krempaský, Altermagnetic lifting of Kramers spin degeneracy, Nature (2024). DOI: 10.1038/s41586-023-06907-7. www.nature.com/articles/s41586-023-06907-7

Part2

Comment by Dr. Krishna Kumari Challa on February 15, 2024 at 10:05am

Altermagnetism: A new type of magnetism, with broad implications for technology and research

There is now a new addition to the magnetic family: thanks to experiments at the Swiss Light Source SLS, researchers have proved the existence of altermagnetism. The experimental discovery of this new branch of magnetism is reported in Nature and signifies new fundamental physics, with major implications for spintronics.

Magnetism is a lot more than just things that stick to the fridge. This understanding came with the discovery of antiferromagnets nearly a century ago. Since then, the family of magnetic materials has been divided into two fundamental phases: the ferromagnetic branch known for several millennia and the antiferromagnetic branch.
The experimental proof of a third branch of magnetism, termed altermagnetism, was made at the Swiss Light Source SLS, by an international collaboration led by the Czech Academy of Sciences together with Paul Scherrer Institute PSI.

The fundamental magnetic phases are defined by the specific spontaneous arrangements of magnetic moments—or electron spins—and of atoms that carry the moments in crystals.

Ferromagnets are the type of magnets that stick to the fridge: here spins point in the same direction, giving macroscopic magnetism. In antiferromagnetic materials, spins point in alternating directions, with the result that the materials possess no macroscopic net magnetization—and thus don't stick to the fridge. Although other types of magnetism, such as diamagnetism and paramagnetism have been categorized, these describe specific responses to externally applied magnetic fields rather than spontaneous magnetic orderings in materials.

Altermagnets have a special combination of the arrangement of spins and crystal symmetries. The spins alternate, as in antiferromagnets, resulting in no net magnetization. Yet, rather than simply canceling out, the symmetries give an electronic band structure with strong spin polarization that flips in direction as you pass through the material's energy bands—hence the name altermagnets. This results in highly useful properties more resemblant to ferromagnets, as well as some completely new properties.

Part 1

Comment by Dr. Krishna Kumari Challa on February 14, 2024 at 10:05am

A car powered by ammonia?

Ammonia is combustible, and holds promise as a relatively low-effort way to decarbonize the internal combustion engine – but the devil’s in the details.

Comment by Dr. Krishna Kumari Challa on February 14, 2024 at 7:17am

Vibrio natriegens: Low-cost microbe could speed biological discovery

 Researchers have created a new version of a microbe to compete economically with E. coli—a bacteria commonly used as a research tool due to its ability to synthesize proteins—to conduct low-cost and scalable synthetic biological experiments.

As an inexpensive multiplier—much like having a photocopier in a test tube—the bacteria Vibrio natriegens could help labs test protein variants for creation of pharmaceuticals, synthetic fuels and sustainable compounds that battle weeds or pests. The microbe can work effectively without costly incubators, shakers or deep freezers and can be engineered within hours.

 Efficient Natural Plasmid Transformation of Vibrio natriegens Enables Zero-capital Molecular Biology, PNAS Nexus (2024). DOI: 10.1093/pnasnexus/pgad444

Comment by Dr. Krishna Kumari Challa on February 13, 2024 at 10:33am

Air pollution turns moths off flowers
Air pollution makes the scent of a night-blooming plant less enticing to pollinating moths. Researchers discovered that nitrate radicals severely degrade key odour components that attract pollinating insects to the pale evening primrose (Oenothera pallida). Nitrate radicals, which can come from various sources including vehicle emissions, are particularly abundant when there’s no sunlight to break them down. Artificial flowers spiked with the pollution-degraded scent received 70% fewer visits from wild hawkmoths than fake flowers with intact odour. Because hawkmoths are some of the primrose’s main pollinators this could reduce the plant’s fruit production by almost 30%.

https://www.science.org/doi/10.1126/science.adi0858

Comment by Dr. Krishna Kumari Challa on February 13, 2024 at 9:56am

Researchers develop eco-friendly 'magnet' to battle microplastics

Plastic pollution is a pressing environmental issue, and  researchers are leading the charge with an innovative solution.

Their research, published in Scientific Reports, centers on an intriguing solution: using natural deep eutectic solvents (NADES) to capture and remove these miniature particles from water.

Plastics don't break down easily, leading to massive piles of waste. Over time, these plastics break into smaller fragments. The smallest, nano-plastics, are so tiny they can't be seen without a microscope. Their size makes them a significant hazard, as they can be ingested by marine life and enter the human food chain.

These minute particles, often invisible to the naked eye, are the remnants of larger plastic pieces broken down by sunlight and physical stress. Their size makes them notoriously difficult to remove using conventional methods like centrifugation or filtration, which are either inefficient or too costly.

Now think of NADES as a kind of 'magnet' that specifically attracts and holds onto these small plastic pieces. Basically, the NADES mix with the water and 'stick' to the plastics, pulling them out of the water.

The molecules in the NADES can form bonds with the molecules in the plastics, a bit like how Velcro works: one side sticks to the other. This property makes NADES particularly good at grabbing onto and holding these plastic particles. NADES are also unique because they are effective and environmentally friendly. They're made from natural materials, meaning they don't add more pollutants to the environment while cleaning up the existing ones.

Derived from natural sources like plants and coconuts, these solvents transform from solid to liquid when mixed, creating an effective medium to extract these tiny plastic particles from water.

The researchers focused on polyethylene terephthalate (PET) like that found in plastic bottles, polystyrene (PS) used for materials such as packaging peanuts and polylactic acid (PLA) used for plastic films and food containers. Using computer simulations, they could see how these interactions work on a minute scale.

Their experiments revealed that certain NADES are particularly good at extracting these types of plastic from water. This discovery was crucial, offering a targeted approach to removing plastics.

Jameson R. Hunter et al, Green solvent mediated extraction of micro- and nano-plastic particles from water, Scientific Reports (2023). DOI: 10.1038/s41598-023-37490-6

Comment by Dr. Krishna Kumari Challa on February 13, 2024 at 8:31am

Researchers predict the young universe had two phases. During the first phase, high-speed outflows from black holes accelerated star formation, and then, in a second phase, the outflows slowed down. A few hundred million years after the big bang, gas clouds collapsed because of supermassive black hole magnetic storms, and new stars were born at a rate far exceeding that observed billions of years later in normal galaxies. The creation of stars slowed down because these powerful outflows transitioned into a state of energy conservation reducing the gas available to form stars in galaxies.

The future has more secrets to reveal!

Joseph Silk et al, Which Came First: Supermassive Black Holes or Galaxies? Insights from JWST, The Astrophysical Journal Letters (2024). DOI: 10.3847/2041-8213/ad1bf0

Part 2

Comment by Dr. Krishna Kumari Challa on February 13, 2024 at 8:30am

New light on Black holes

Black holes not only existed at the dawn of time, they birthed new stars and supercharged galaxy formation, a new analysis of James Webb Space Telescope data suggests.

The insights upend theories of how black holes shape the cosmos, challenging classical understanding that they formed after the first stars and galaxies emerged. Instead, black holes might have dramatically accelerated the birth of new stars during the first 50 million years of the universe, a fleeting period within its 13.8 billion-year history.

We know these monster black holes exist at the center of galaxies near our Milky Way, but the big surprise now is that they were present at the beginning of the universe as well and were almost like building blocks or seeds for early galaxies.

They really boosted everything, like gigantic amplifiers of star formation, which is a whole turnaround of what we thought possible before—so much so that this could completely shake up our understanding of how galaxies form.

Conventional wisdom holds that black holes formed after the collapse of supermassive stars and that galaxies formed after the first stars lit up the dark early universe. But the analysis by researchers suggests that black holes and galaxies coexisted and influenced each other's fate during the first 100 million years.

Researchers now think  that black hole outflows crushed gas clouds, turning them into stars and greatly accelerating the rate of star formation. Otherwise, it's very hard to understand where these bright galaxies came from because they're typically smaller in the early universe. Why on earth should they be making stars so rapidly?

Black holes are regions in space where gravity is so strong that nothing can escape their pull, not even light. Because of this force, they generate powerful magnetic fields that make violent storms, ejecting turbulent plasma and ultimately acting like enormous particle accelerators.

We can't quite see these violent winds or jets far, far away, but we know they must be present because we see many black holes early on in the universe. These enormous winds coming from the black holes crush nearby gas clouds and turn them into stars. That's the missing link that explains why these first galaxies are so much brighter than we expected.

Part 1

The work is newly published in the Astrophysical Journal Letters.

Comment by Dr. Krishna Kumari Challa on February 13, 2024 at 7:08am

Global deforestation leads to more mercury pollution, finds study

About 10% of human-made mercury emissions into the atmosphere each year are the result of global deforestation, according to a new MIT study.

The world's vegetation, from the Amazon rainforest to the savannahs of sub-Saharan Africa, acts as a sink that removes the toxic pollutant from the air. However, if the current rate of deforestation remains unchanged or accelerates, the researchers estimate that net mercury emissions will keep increasing.

The researchers' model shows that the Amazon rainforest plays a particularly important role as a mercury sink, contributing about 30% of the global land sink. Curbing Amazon deforestation could thus have a substantial impact on reducing mercury pollution.

The team also estimates that global reforestation efforts could increase annual mercury uptake by about 5%. While this is significant, the researchers emphasize that reforestation alone should not be a substitute for worldwide pollution control efforts.

Aryeh Feinberg et al, Deforestation as an Anthropogenic Driver of Mercury Pollution, Environmental Science & Technology (2024). DOI: 10.1021/acs.est.3c07851

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