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Sep 30, 2024

Quantum sensing approach captures nanoscale electrochemical evolution in battery

Posted by in categories: chemistry, evolution, nanotechnology, particle physics, quantum physics

Battery performance is heavily influenced by the non-uniformity and failure of individual electrode particles. Understanding the reaction mechanisms and failure modes at nanoscale level is key to advancing battery technologies and extending their lifespan. However, capturing real-time electrochemical evolution at this scale remains challenging due to the limitations of existing sensing methods, which lack the necessary spatial resolution and sensitivity.

Sep 30, 2024

Gene Therapy Is Developing Rapidly in the Asia Pacific

Posted by in category: biotech/medical

New deadlier viruses?


This article discusses the journeys of three gene therapy startups in South Korea, Japan, and China, and the products they are developing.

Sep 30, 2024

Travelling Salesman Problem

Posted by in category: futurism

An Exploration with Python.

Sep 30, 2024

Dynamical structure-function correlations provide robust and generalizable signatures of consciousness in humans

Posted by in category: neuroscience

Dynamical analysis of resting-state fMRI networks reveals a consistent increase in structure-function correlation and entropy decrease upon both general anesthesia-induced and deep sleep-induced loss of consciousness in humans.

Sep 30, 2024

Woman, 25, ‘cured’ of type 1 diabetes after stem cell transplant in world first

Posted by in category: biotech/medical

SCIENTISTS claim to have reversed a woman’s type 1 diabetes with a pioneering stem cell transplant.

The 25-year-old had suffered from the chronic condition for more than a decade.

Sep 30, 2024

NASA’s Hubble, MAVEN help Solve the Mystery of Mars’s Escaping Water

Posted by in categories: particle physics, space

Mars was once a very wet planet, as is evident in its surface geological features. Scientists know that over the last 3 billion years, at least some water went deep underground, but what happened to the rest? Now, NASA’s Hubble Space Telescope and MAVEN (Mars Atmosphere and Volatile Evolution) missions are helping unlock that mystery.

“There are only two places water can go. It can freeze into the ground, or the water molecule can break into atoms, and the atoms can escape from the top of the atmosphere into space,” explained study leader John Clarke of the Center for Space Physics at Boston University in Massachusetts. “To understand how much water there was and what happened to it, we need to understand how the atoms escape into space.”

Clarke and his team combined data from Hubble and MAVEN to measure the number and current escape rate of the hydrogen atoms escaping into space. This information allowed them to extrapolate the escape rate backwards through time to understand the history of water on the red planet.

Sep 30, 2024

Spinning artificial spider silk into next-generation medical materials

Posted by in categories: bioengineering, biotech/medical, education, genetics

Spider silk is one of the strongest materials on Earth, technically stronger than steel for a material of its size. However, it’s tough to obtain—spiders are too territorial (and cannibalistic) to breed them like silkworms, leading scientists to turn to artificial options.

Teaching microbes to produce the through is one such option, but this has proved challenging because the proteins tend to stick together, reducing the silk’s yield. So, Bingbing Gao and colleagues wanted to modify the natural protein sequence to design an easily spinnable, yet still stable, spider silk using microbes.

The team first used these microbes to produce the silk proteins, adding extra peptides as well. The new peptides, following a pattern found in the protein sequence of amyloid polypeptides, helped the artificial silk proteins form an orderly structure when folded and prevented them from sticking together in solution, increasing their yield.

Sep 30, 2024

New filtration material could remove long-lasting chemicals from water

Posted by in categories: biotech/medical, chemistry, engineering

Water contamination by the chemicals used in today’s technology is a rapidly growing problem globally. A recent study by the U.S. Centers for Disease Control found that 98 percent of people tested had detectable levels of PFAS, a family of particularly long-lasting compounds also known as “forever chemicals,” in their bloodstream.

A new filtration material developed by researchers at MIT might provide a nature-based solution to this stubborn contamination issue. The material, based on natural silk and cellulose, can remove a wide variety of these persistent chemicals as well as heavy metals. And, its antimicrobial properties can help keep the filters from fouling.

The findings are described in the journal ACS Nano, in a paper by MIT postdoc Yilin Zhang, professor of civil and environmental engineering Benedetto Marelli, and four others from MIT.

Sep 30, 2024

‘Squeezing’ increases accuracy out of quantum measurements

Posted by in category: quantum physics

Quantum squeezing is a concept in quantum physics where the uncertainty in one aspect of a system is reduced while the uncertainty in another related aspect is increased. Imagine squeezing a round balloon filled with air. In its normal state, the balloon is perfectly spherical. When you squeeze one side, it gets flattened and stretched out in the other direction. This represents what is happening in a squeezed quantum state: you are reducing the uncertainty (or noise) in one quantity, like position, but in doing so, you increase the uncertainty in another quantity, like momentum. However, the total uncertainty remains the same, since you are just redistributing it between the two. Even though the overall uncertainty remains the same, this ‘squeezing’ allows you to measure one of those variables with much greater precision than before.

This technique has already been used to improve the accuracy of measurements in situations where only one variable needs to be precisely measured, such as in improving the precision of atomic clocks. However, using squeezing in cases where multiple factors need to be measured simultaneously, such as an object’s position and momentum, is much more challenging.

In a research paper published in Physical Review Research (“Squeezing-induced quantum-enhanced multiphase estimation”), Tohoku University’s Dr. Le Bin Ho explores the effectiveness of the squeezing technique in enhancing the precision of measurements in quantum systems with multiple factors. The analysis provides theoretical and numerical insights, aiding in the identification of mechanisms for achieving maximum precision in these intricate measurements.

Sep 30, 2024

‘Superintelligent’ AI Is Only a Few Thousand Days Away: OpenAI CEO Sam Altman

Posted by in categories: futurism, robotics/AI

Altman predicts that with AI in the future, “We will be able to do things that would have seemed like magic to our grandparents.”

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