Connect with us

Published

4 months ago

on

Life on Earth may have emerged not from a single, dramatic lightning strike but through countless tiny electrical discharges occurring in water droplets. Research indicates that microlightning, generated by crashing waves or waterfalls, could have led to the formation of essential organic molecules. Scientists have long debated how life began, with theories suggesting that lightning interacting with early atmospheric gases may have created crucial compounds. However, new findings suggest that small electrical charges produced in water spray could have played a key role in the process, offering an alternative explanation to the widely known Miller-Urey hypothesis.

Organic Molecules Formed Without External Electricity

According to the study published in Science Advances, water droplets subjected to a mixture of gases believed to be present in Earth’s early atmosphere resulted in the formation of organic molecules. The research, led by Richard Zare, the Marguerite Blake Wilbur Professor of Natural Science at Stanford University, explored how water spray generated electrical charges capable of forming carbon-nitrogen bonds—essential for life. Postdoctoral scholars Yifan Meng and Yu Xia, along with graduate student Jinheng Xu, contributed to the study, which challenges the idea that lightning strikes were necessary to initiate the chemical reactions leading to life.

Microlightning and Chemical Reactions in Water Droplets

The research team discovered that water droplets of varying sizes developed opposite electrical charges when dispersed. Larger droplets typically carried a positive charge, while smaller ones were negatively charged. When these oppositely charged droplets came into proximity, tiny electrical sparks—termed “microlightning” by Zare—were observed. These discharges were captured using high-speed cameras, revealing flashes of energy powerful enough to drive chemical reactions.

When room-temperature water was sprayed into a gas mixture containing nitrogen, methane, carbon dioxide, and ammonia—compounds believed to be abundant on early Earth—organic molecules such as hydrogen cyanide, glycine, and uracil were produced. These findings suggest that microlightning from water droplets may have contributed significantly to the formation of life’s building blocks, without the need for large-scale lightning strikes.

A New Perspective on Life’s Origins

Zare stated in Tech Explore that water droplets in constant motion—whether crashing into rocks or dispersing into the air—could have repeatedly generated these microelectric discharges. This mechanism, he explained, may resolve challenges associated with the Miller-Urey hypothesis, which has been criticised for its reliance on infrequent lightning events over vast oceans.

Beyond its implications for the origins of life, the study also aligns with previous research from Zare’s team on the reactivity of water droplets. Prior investigations have demonstrated how divided water can spontaneously generate hydrogen peroxide and contribute to ammonia production. He emphasised that while water is often perceived as chemically passive, when broken into tiny droplets, it becomes highly reactive, capable of driving significant chemical transformations.

Related Topics:
Continue Reading

Science

Virginia Tech Engineers Craft Durable, Self‑Repairing, and Recyclable PCBs

Published

11 hours ago

on

July 2, 2025

By

Virginia Tech Engineers Craft Durable, Self‑Repairing, and Recyclable PCBs

A team of scientists has developed a new kind of self-healing circuit board that stays functional even after severe mechanical damage and can be reshaped or recycled entirely using heat. Infused with liquid metal and built using a polymer known as vitrimer, the new circuit boards could dramatically cut electronic waste and transform the durability of consumer electronics. Vitrimer retains the strength of traditional thermoset materials while allowing flexibility and repair, making it possible to reconfigure damaged boards without compromising electrical performance.

As per a study published in Advanced Materials on June 1, the boards were created by blending vitrimer with just 5% by volume of liquid metal droplets. This combination nearly doubled the material’s strain-at-break, or stretchability, compared to vitrimer alone. The embedded droplets are flexible as well, serving as flexible conductors in place of metal wiring used in traditional boards. Using a rheometer, tests showed the material was able to return to its original shape after heat-induced deformation ranging from 170°C to 200°C, which conventional epoxy-based thermosets cannot achieve.

Engineers also demonstrated that the material remains highly conductive and can recover its electrical function after being damaged. “Modern circuit boards simply cannot do this,” said Josh Worch, co-lead author of the study. His team designed the dynamic composite with the aim of building a circular economy around electronics. The design addresses a major environmental concern: most circuit boards today use thermosets that cannot be recycled and end up in landfills.

Electronic waste has more than doubled in 12 years, from 34 to 62 billion kilograms, as noted in a 2024 UN report. Despite containing valuable metals like gold, current boards are difficult to break down and reclaim due to the permanent nature of thermosetting plastics. The new vitrimer-based design, by contrast, allows for easy separation and reuse of materials. “Even if the board is damaged,” said Michael Bartlett, another co-lead author, “electrical performance will not suffer.”

More work needs to be done to improve the recovery of some elements, but the advance is a big step toward greener electronics, the researchers say. The technology could one day be in many different types of devices, from phones and laptops to wearables and TVs, changing the way devices are made, operated, and recycled.

For the latest tech news and reviews, follow Gadgets 360 on X, Facebook, WhatsApp, Threads and Google News. For the latest videos on gadgets and tech, subscribe to our YouTube channel. If you want to know everything about top influencers, follow our in-house Who’sThat360 on Instagram and YouTube.


Meta CEO Mark Zuckerberg Reportedly Restructures AI Division, Creates Meta Superintelligence Labs



Nothing Phone 3 First Impressions

Continue Reading

Science

Newly Detected Seaborgium-257 Offers Critical Data on Fission and Quantum Shell Effects

Published

14 hours ago

on

July 2, 2025

By

Newly Detected Seaborgium-257 Offers Critical Data on Fission and Quantum Shell Effects

German Scientists at GSI Helmholtzzentrum für Schwerionenforschung found a new superheavy isotope, 257Sg, named Seaborgium, which reveals unexpected details about the stability and nuclear fission. This study was published in Physical Review Letters and describes how this isotope, made by fusing chromium-52 with lead-206, survived for 12.6 milliseconds, longer than usual. The rare longevity and decay into 253Rf provide new indications of how K-quantum numbers or angular momentum impact the fission resistance. The findings fill in the gaps and give us an understanding of the effects of quantum shells in superheavy nuclei, which is crucial for preventing immediate disintegration.

Challenging Traditional Views on K-Quantum Numbers and Fission

As per the study by GSI, it challenges conservative views on how K-quantum numbers impact fission. Previously, it was found that the higher K values lead to greater fission hindrance, but after getting the findings from the GSI team, a more complex dynamic emerged. They found that K-quantum numbers offer hindrance to fission, but it is still ot known that it is how much, said Dr. Pavol Mosat, the study’s co-author.

Discovery of First K-Isomeric State in Seaborgium

An important milestone is the identification of the first K-isomeric state in seaborgium. In 259Sg, the scientists found that the conversion of the electron signal occurs 40 microseconds after the nuclear formation. This is clear evidence of the high angular momentum K-isomer. These states have longer lifetimes and friction in fission in a more effective way than their ground-state counterparts.

Implications for the Theorised Island of Stability

This discovery by the scientists provides key implications for the Island of stability, which has long been theorised. It is a region where superheavy elements could have comparatively long half-lives. If K-isomers are present in the still undiscovered elements such as 120, they can enable scientists in the detection of nuclei that would otherwise decay in just under one microsecond.

Synthesising 256Sg with Ultra-Fast Detection Systems

This team of German Scientists under GSI is now aiming to synthesise 256Sg, which might decay quicker than observed or predicted. Their success is dependent on the ultra-fast detection systems created by GSI, which are capable of capturing events within 100 nanoseconds. This continued research by the team may help in reshaping the search and studying the heaviest elements in the periodic table.

For the latest tech news and reviews, follow Gadgets 360 on X, Facebook, WhatsApp, Threads and Google News. For the latest videos on gadgets and tech, subscribe to our YouTube channel. If you want to know everything about top influencers, follow our in-house Who’sThat360 on Instagram and YouTube.

Further reading:
257Sg, seaborgium, K-isomer, superheavy, elements, nuclear stability, fission, GSI, TASCA, Physical Review Letters, element 120, island of stability

OpenAI Says It Has No Plan to Use Google’s In-House Chip



Apple Loses Bid to Dismiss US Smartphone Monopoly Case

Continue Reading

Science

NASA CODEX Telescope on ISS Reveals Hidden Secrets of the Sun’s Corona

Published

15 hours ago

on

July 2, 2025

By

NASA CODEX Telescope on ISS Reveals Hidden Secrets of the Sun’s Corona

A mini solar telescope aboard the International Space Station caught the first-ever images, which reveal the subtle and never-seen changes in the outer atmosphere of the Sun. It is known as the Coronal Diagnostic Experiment (CODEX) and has been designed to understand the solar corona, the outer layer of the Sun, in depth. This mini telescope functions like a coronagraph, which blocks the Sun’s disk to imitate the total solar eclipse. CODEX was delivered through SpaceX Dragon on November 5, 2024. It was mounted on the ISS using the Canadarm2 robotic arm on November 9, 2025.

Revolutionising Solar Observation

According to the report by NASA, the unique design of CODEX consists of an occulting disk the size of a tennis ball held by three arms made up of metal. It allows it to block the intense sunlight when imaging the faint corona. The first images were revealed on June 10, 2025, at the time of the American Astronomical Society’s meeting in Alaska. These comprised pictures of coronal streamers and footage of the temperature fluctuations in the outer corona over many days. This offers a fresh perspective on solar dynamics.

Measuring Solar Wind Like Never Before

CODEX is unlike the previous coronagraphs as it is the first to measure both the speed and temperature of the solar wind. There is a constant flow of superhot particles from the Sun. With the help of four narrowband filters, in which two are used for determining the temperature and two for speed, astronomers compare brightness to decode these properties, which helps in solving the mystery of how the solar wind reaches 1.8 million degrees Fahrenheit.

Tackling the Solar Weather Challenge

To know the solar wind, it is crucial to predict the geomagnetic storms triggered by the coronal holes. Shortly, the storms observed on June 13, 2025 and June 25, 2025, caused auroras because of these events. After refining the analysis of solar wind, CODEX can help in mitigating and forecasting such kind of disturbances.

A Timely Launch Amid Solar Peak

NASA’s CODEX started operations at a suitable moment, just as the current solar maximum comes to its end. As the magnetic field of the Sun shifts during the solar battle zone, CODEX is ready to catch the critical data that can change our understanding of the weather in space.

Continue Reading

Trending