SOEST Earth Sciences professor Bridget Smith-Konter and graduate student Lauren Ward co-authored a study published recently in Science that revealed unusual surface deformation associated with the 2019 Ridgecrest earthquake in the San Andreas Fault area of California.

Watch the video below.

The research team, led by scientists at the Scripps Institution of Oceanography, analyzed satellite data and discovered hundreds of previously unmapped fractures surrounding the 2019 Ridgecrest earthquake sequence.

Most deformation associated with an earthquake is, not surprisingly, in the same direction as the fault rupture. However, the researchers found areas of deformation associated with the 2019 event that moved in the opposite direction.

Superconductivity is a phenomenon where an electric circuit loses its resistance and becomes extremely efficient under certain conditions. There are different ways in which this can happen which were thought to be incompatible. For the first time researchers discover a bridge between two of these methods to achieve superconductivity. This new knowledge could lead to a more general understanding of the phenomena, and one day to applications.

If you're like most people, there are three states of matter in your everyday life: solid, liquid and gas. You might be familiar with a fourth state of matter called plasma, which is like a gas that got so hot all its constituent atoms came apart, leaving behind a super hot mess of subatomic particles. But did you know about a so-called fifth state of matter at the complete opposite end of the thermometer? It's known as a Bose-Einstein condensate (BEC).

"A BEC is a unique state of matter as it is not made from particles, but rather waves," said Associate Professor Kozo Okazaki from the Institute for Solid State Physics at the University of Tokyo. "As they cool down to near absolute zero, the atoms of certain materials become smeared out over space. This smearing increases until the atoms — now more like waves than particles — overlap, becoming indistinguishable from one another. The resulting matter behaves like it's one single entity with new properties the preceding solid, liquid or gas states lacked, such as superconduction. Until recently superconducting BECs were purely theoretical, but we have now demonstrated this in the lab with a novel material based on iron and selenium (a nonmetallic element)."

Astronomers say they'll have to keep an eye on the near-Earth asteroid Apophis to see how much of a danger the space rock poses to our planet during a close pass in 2068. But don't panic: The chances of an impact still seem very low.

Under certain circumstances, the sun can heat an asteroid unevenly, causing the space rock to radiate away heat energy asymmetrically. The result can be a tiny push in a certain direction — an effect called Yarkovsky acceleration, which can change the path of an asteroid through space.

Since astronomers hadn't measured this solar push on Apophis before, they didn't take it into consideration when calculating the threat the asteroid poses to us in 2068. Those previous calculations showed a tiny impact probability — around 1 in 150,000.

Now, a new study shows the asteroid is drifting away from its previously predicted orbit by about 557 feet (170 meters) a year due to the Yarkovsky effect, lead author and University of Hawaii at Manoa astronomer David Tholen said during a press conference on Oct. 26.

"Basically, the heat that an asteroid radiates gives it a very tiny push," he explained during a virtual meeting of the American Astronomical Society's Division for Planetary Sciences. You can find the press conference on YouTube here. It begins at the 22-minute mark.

Scientists have used gene therapy to regenerate damaged nerve fibres in the eye, in a discovery that could aid the development of new treatments for glaucoma, one of the leading causes of blindness worldwide.
Axons - nerve fibres - in the adult central nervous system (CNS) do not normally regenerate after injury and disease, meaning that damage is often irreversible. However, over the past decade there have been a number of discoveries that suggest it may be possible to stimulate regeneration.

In a study published today in Nature Communications, scientists tested whether the gene responsible for the production of a protein known as Protrudin could stimulate the regeneration of nerve cells and protect them from cell death after an injury.

The team, led by Dr Richard Eva, Professor Keith Martin and Professor James Fawcett from the John van Geest Centre for Brain Repair at the University of Cambridge, used a cell culture system to grow brain cells in a dish. They then injured their axons using a laser and analysed the response to this injury using live-cell microscopy. The researchers found that increasing the amount or activity of Protrudin in these nerve cells vastly increased their ability to regenerate.

Nerve cells in the retina, known as retinal ganglion cells, extend their axons from the eye to the brain through the optic nerve in order to relay and process visual information. To investigate whether Protrudin might stimulate repair in the injured CNS in an intact organism, the researchers used a gene therapy technique to increase the amount and activity of Protrudin in the eye and optic nerve. When they measured the amount of regeneration a few weeks after a crush injury to the optic nerve, the team found that Protrudin had enabled the axons to regenerate over large distances. They also found that the retinal ganglion cells were protected from cell death.

The researchers showed that this technique may help protect against glaucoma, a common eye condition. In glaucoma, the optic nerve that connects the eye to the brain is progressively damaged, often in association with elevated pressure inside the eye. If not diagnosed early enough, glaucoma can lead to loss of vision. In the UK, round one in 50 people over the age of 40, and one in ten people over the age of 75 is affected by glaucoma.

For the first time, we have tracked a strange blast of radio waves - called a fast radio burst - back to its source, solving a major cosmic mystery. The burst came from a magnetar, which is a neutron star with a strong magnetic field.

Fast radio bursts, or FRBs, are incredibly powerful flashes of radio waves that mostly come from distant galaxies. Since the first one was discovered in 2007, many explanations for them have been put forward. However, because they tend to come from so far away, there was never enough evidence to determine what exactly was making them. Some FRBs have been tracked back to their host galaxies, but their source hasn't been pinpointed.

In April, astronomers found an FRB coming from within our own galaxy for the first time, allowing them to take a closer look. Several teams of researchers examined the area where it arose and found that the burst originated from a magnetar called SGR 1935+2154. While magnetars have been a favoured contender to explain FRBs, this is the first evidence that they can produce radio waves at high enough energies to account for the signals.

Inspired by a parasitic worm that digs its sharp teeth into its host's intestines, Johns Hopkins researchers have designed tiny, star-shaped microdevices that can latch onto intestinal mucosa and release drugs into the body.

David Gracias, Ph.D., a professor in the Johns Hopkins University Whiting School of Engineering, and Johns Hopkins gastroenterologist Florin M. Selaru, M.D., director of the Johns Hopkins Inflammatory Bowel Disease Center, led a team of researchers and biomedical engineers that designed and tested shape-changing microdevices that mimic the way the parasitic hookworm affixes itself to an organism's intestines.

Made of metal and thin, shape-changing film and coated in a heat-sensitive paraffin wax, "theragrippers," each roughly the size of a dust speck, potentially can carry any drug and release it gradually into the body.

The team published results of an animal study this week as the cover article in the journal Science Advances.

Gradual or extended release of a drug is a long-sought goal in medicine. Selaru explains that a problem with extended-release drugs is they often make their way entirely through the gastrointestinal tract before they've finished dispensing their medication.

Scientists are seeing the Australian platypus in a whole new light. Under an ultraviolet lamp, this bizarre-looking creature appears even more peculiar than normal, glowing a soft, greenish-blue hue instead of the typical brown we're used to seeing.

The recent discovery has not been found in any other monotreme species, and it has scientists wondering: Have we been overlooking an ancient world of fluorescent fur?

"Biofluorescence has now been observed in placental New World flying squirrels, marsupial New World opossums, and the monotreme platypus of Australia and Tasmania," the authors write.

"These taxa, inhabiting three continents and a diverse array of ecosystems, represent the major lineages of Mammalia."

Asthma impacts millions of children already at a young age. Children growing up on a farm have a lower risk of developing asthma than children not living on a farm. The mechanisms behind this protective farm effect on childhood asthma are largely unknown. A group of researchers from Helmholtz Zentrum München and the Dr. von Hauner Children's Hospital of Ludwig Maximilians University Munich (LMU) clarified how the children's gut microbiome is involved in the protection process.

We are born into an environment full of small organisms called microbiota. Within the first minutes and hours of our lives, they start challenging but also educating our immune system. The largest immune organ is our gut, where maturation of the immune system and maturation of the colonizing bacteria, the gut microbiome, go hand in hand. After profound perturbations in the first year of life, the maturation process, the composition of the gut microbiome gradually stabilizes and accompanies us for our lives. Previous research of the Munich scientists showed an asthma-protective effect by a diverse environmental microbiome, which was particularly pronounced in farm children. The question now was whether this effect could be attributed to the maturation process of the early gut microbiome.

Scannable barcodes, QR codes and RFID tags may soon be surpassed by DNA-based tagging technology.

Researchers from the University of Washington and Microsoft Research in the US say they have developed a fast, reliable and inexpensive system of molecular tagging that uses DNA sequences as identification.

Smaller and lighter than conventional tags, this method can be used to track objects that are too small or too numerous to be tagged with existing technology.

The system, dubbed "Porcupine", is described in a paper in the journal Nature Communications.

"Molecular tagging is not a new idea, but existing methods are still complicated and require access to a lab, which rules out many real-world scenarios," explains Washington's Kathryn Doroschak, the lead author.

"We designed the first portable, end-to-end molecular tagging system that enables rapid, on-demand encoding and decoding at scale, and which is more accessible than existing molecular tagging methods."

While more conventional tagging systems rely on radio waves (RFID) or printed lines (barcodes), Porcupine's tags are composed of predefined sequences of synthetic DNA strands called molecular bits, or "molbits".

In the initial prototype system, there are 96 molbits, which can then be combined to create billions of unique combinations.

US researchers have developed a way to control and measure atoms that are so close together they are impossible to distinguish by optical means.

When atoms get cosy - that is, within a few billionths of a metre of each other - they exhibit interesting quantum mechanical behaviour. At this scale, their spins begin to exert an influence on each other, and two or more atoms can become entangled: a strange quantum phenomenon where the atoms will thereafter mirror each other's properties instantly, even if they are kilometres or light-years apart.

Entanglement is key for future technologies like quantum computing - but first, scientists must observe and understand these tightly-packed atoms. Conventional microscopes are unable to distinguish between atoms that are just nanometers apart, just as our eyes are often unable to spatially resolves two distant stars that are close together in the night sky.

Researchers from Princeton University have now demonstrated a technique to resolve such atoms. In a paper published in the journal Science, they describe using a finely tuned laser to excite closely spaced erbium atoms in a crystal.

Each atom responds slightly differently to different wavelengths, re-emitting the light at unique frequencies that subtly change according to an atom's spin state.