Day: January 4, 2022

In a Swiss valley, an unusual multi-armed crane lifts two 35-ton concrete blocks high into the air. The blocks delicately inch their way up the blue steel frame of the crane, where they hang suspended from either side of a 66-meter-wide horizontal arm. There are three arms in total, each one housing the cables, winches, and grabbing hooks needed to hoist another pair of blocks into the sky, giving the apparatus the appearance of a giant metallic insect lifting and stacking bricks with steel webs. Although the tower is 75 meters tall, it is easily dwarfed by the forested flanks of southern Switzerland’s Lepontine Alps, which rise from the valley floor in all directions.

Thirty meters. Thirty-five. Forty. The concrete blocks are slowly hoisted upwards by motors powered with electricity from the Swiss power grid. For a few seconds they hang in the warm September air, then the steel cables holding the blocks start to unspool and they begin their slow descent to join the few dozen similar blocks stacked at the foot of the tower. This is the moment that this elaborate dance of steel and concrete has been designed for. As each block descends, the motors that lift the blocks start spinning in reverse, generating electricity that courses through the thick cables running down the side of the crane and onto the power grid. In the 30 seconds during which the blocks are descending, each one generates about one megawatt of electricity: enough to power roughly 1,000 homes.

This tower is a prototype from Switzerland-based Energy Vault, one of a number of startups finding new ways to use gravity to generate electricity. A fully-sized version of the tower might contain 7,000 bricks and provide enough electricity to power several thousand homes for eight hours. Storing energy in this way could help solve the biggest problem facing the transition to renewable electricity: finding a zero-carbon way to keep the lights on when the wind isn’t blowing and the sun isn’t shining. “The greatest hurdle we have is getting low-cost storage,” says Robert Piconi, CEO and cofounder of Energy Vault.

Without a way to decarbonize the world’s electricity supply, we’ll never hit net zero greenhouse gas emissions by 2050. Electricity production and heat add up to a quarter of all global emissions and, since almost every activity you can imagine requires electricity, cleaning up power grids has huge knock-on effects. If our electricity gets greener, so do our homes, industries, and transport systems. This will become even more critical as more parts of our lives become electrified— particularly heating and transport, which will be difficult to decarbonize in any other way. All of this electrification is expected to double electricity production by 2050 according to the International Atomic Energy Agency. But without an easy way to store large amounts of energy and then release it when we need it, we may never undo our reliance on dirty, polluting, fossil-fuel-fired power stations.

This is where gravity energy storage comes in. Proponents of the technology argue that gravity provides a neat solution to the storage problem. Rather than relying on lithium-ion batteries, which degrade over time and require rare-earth metals that must be dug out of the ground, Piconi and his colleagues say that gravity systems could provide a cheap, plentiful, and long-lasting store of energy that we’re currently overlooking. But to prove it, they’ll need to build an entirely new way of storing electricity, and then convince an industry already going all-in on lithium-ion batteries that the future of storage involves extremely heavy weights falling from great heights.

A dense, magnetic star violently erupted and spat out as much energy as a billion suns — and it happened in a fraction of a second, scientists recently reported.

This type of star, known as a magnetar, is a neutron star with an exceptionally strong magnetic field, and magnetars often flare spectacularly and without warning. But even though magnetars can be thousands of times brighter than our sun, their eruptions are so brief and unpredictable that they’re challenging for astrophysicists to find and study.

However, researchers recently managed to catch one of these flares and calculate oscillations in the brightness of a magnetar as it erupted. The scientists found that the distant magnetar released as much energy as our sun produces in 100,000 years, and it did so in just 1/10 of a second, according to a statement translated from Spanish.

Related: The 12 strangest objects in the universe

A neutron star forms when a massive star collapses at the end of its life. As the star dies in a supernova, protons and electrons in its core are crushed into a compressed solar mass that combines intense gravity with high-speed rotation and powerful magnetic forces, according to NASA. The result, a neutron star, is approximately 1.3 to 2.5 solar masses — one solar mass is the mass of our sun, or about 330,000 Earths — crammed into a sphere measuring just 12 miles (20 kilometers) in diameter. 

Matter in neutron stars is so densely packed that an amount the size of a sugar cube would weigh more than 1 billion tons (900 million metric tons), and a neutron star’s gravitational pull is so intense that a passing marshmallow would hit the star’s surface with the force of 1,000 hydrogen bombs, according to NASA.

Magnetars are neutron stars with magnetic fields that are 1,000 times stronger than those of other neutron stars, and they are more powerful than any other magnetic object in the universe. Our sun pales in comparison to these bright, dense stars even when they aren’t erupting, study lead author Alberto J. Castro-Tirado, a research professor with the Institute for Astrophysics of Andalucía at the Spanish Research Council, said in the statement.

“Even in an inactive state, magnetars can be 100,000 times more luminous than our sun,” Castro-Tirado said. “But in the case of the flash that we have studied — GRB2001415 — the energy that was released is equivalent to that which our sun radiates in 100,000 years.”

A “giant flare”

The magnetar that produced the brief eruption is located in the Sculptor Galaxy, a spiral galaxy about 13 million light-years from Earth, and is “a true cosmic monster,” study co-author Victor Reglero, director of UV’s Image Processing Laboratory, said in the statement. The giant flare was detected on April 15, 2020 by the Atmosphere–Space Interactions Monitor (ASIM) instrument on the International Space Station, researchers reported Dec. 22 in the journal Nature.

Artificial intelligence (AI) in the ASIM pipeline detected the flare, enabling the researchers to analyze that brief, violent energy surge; the flare lasted just 0.16 seconds and then the signal decayed so rapidly that it was nearly indistinguishable from background noise in the data. The study authors spent more than a year analyzing ASIM’s two seconds of data collection, dividing the event into four phases based on the magnetar’s energy output, and then measuring variations in the star’s magnetic field caused by the energy pulse when it was at its peak. 

It’s almost as if the magnetar decided to broadcast its existence “from its cosmic solitude” by shouting into the void of space with the force “of a billion suns,” Reglero said.

Only about 30 magnetars have been identified from approximately 3,000 known neutron stars, and this is the most distant magnetar flare detected to date. Scientists suspect that eruptions such as this one may be caused by so-called starquakes that disrupt magnetars’ elastic outer layers, and this rare observation could help researchers unravel the stresses that produce magnetars’ energy burps, according to the study.

Originally published on Live Science.

A dense, magnetic star violently erupted and spat out as much energy as a billion suns — and it happened in a fraction of a second, scientists recently reported.

This type of star, known as a magnetar, is a neutron star with an exceptionally strong magnetic field, and magnetars often flare spectacularly and without warning. But even though magnetars can be thousands of times brighter than our sun, their eruptions are so brief and unpredictable that they’re challenging for astrophysicists to find and study.

However, researchers recently managed to catch one of these flares and calculate oscillations in the brightness of a magnetar as it erupted. The scientists found that the distant magnetar released as much energy as our sun produces in 100,000 years, and it did so in just 1/10 of a second, according to a statement translated from Spanish.

Related: The 12 strangest objects in the universe

A neutron star forms when a massive star collapses at the end of its life. As the star dies in a supernova, protons and electrons in its core are crushed into a compressed solar mass that combines intense gravity with high-speed rotation and powerful magnetic forces, according to NASA. The result, a neutron star, is approximately 1.3 to 2.5 solar masses — one solar mass is the mass of our sun, or about 330,000 Earths — crammed into a sphere measuring just 12 miles (20 kilometers) in diameter. 

Matter in neutron stars is so densely packed that an amount the size of a sugar cube would weigh more than 1 billion tons (900 million metric tons), and a neutron star’s gravitational pull is so intense that a passing marshmallow would hit the star’s surface with the force of 1,000 hydrogen bombs, according to NASA.

Magnetars are neutron stars with magnetic fields that are 1,000 times stronger than those of other neutron stars, and they are more powerful than any other magnetic object in the universe. Our sun pales in comparison to these bright, dense stars even when they aren’t erupting, study lead author Alberto J. Castro-Tirado, a research professor with the Institute for Astrophysics of Andalucía at the Spanish Research Council, said in the statement.

“Even in an inactive state, magnetars can be 100,000 times more luminous than our sun,” Castro-Tirado said. “But in the case of the flash that we have studied — GRB2001415 — the energy that was released is equivalent to that which our sun radiates in 100,000 years.”

A “giant flare”

The magnetar that produced the brief eruption is located in the Sculptor Galaxy, a spiral galaxy about 13 million light-years from Earth, and is “a true cosmic monster,” study co-author Victor Reglero, director of UV’s Image Processing Laboratory, said in the statement. The giant flare was detected on April 15, 2020 by the Atmosphere–Space Interactions Monitor (ASIM) instrument on the International Space Station, researchers reported Dec. 22 in the journal Nature.

Artificial intelligence (AI) in the ASIM pipeline detected the flare, enabling the researchers to analyze that brief, violent energy surge; the flare lasted just 0.16 seconds and then the signal decayed so rapidly that it was nearly indistinguishable from background noise in the data. The study authors spent more than a year analyzing ASIM’s two seconds of data collection, dividing the event into four phases based on the magnetar’s energy output, and then measuring variations in the star’s magnetic field caused by the energy pulse when it was at its peak. 

It’s almost as if the magnetar decided to broadcast its existence “from its cosmic solitude” by shouting into the void of space with the force “of a billion suns,” Reglero said.

Only about 30 magnetars have been identified from approximately 3,000 known neutron stars, and this is the most distant magnetar flare detected to date. Scientists suspect that eruptions such as this one may be caused by so-called starquakes that disrupt magnetars’ elastic outer layers, and this rare observation could help researchers unravel the stresses that produce magnetars’ energy burps, according to the study.

Originally published on Live Science.

A dense, magnetic star violently erupted and spat out as much energy as a billion suns — and it happened in a fraction of a second, scientists recently reported.

This type of star, known as a magnetar, is a neutron star with an exceptionally strong magnetic field, and magnetars often flare spectacularly and without warning. But even though magnetars can be thousands of times brighter than our sun, their eruptions are so brief and unpredictable that they’re challenging for astrophysicists to find and study.

However, researchers recently managed to catch one of these flares and calculate oscillations in the brightness of a magnetar as it erupted. The scientists found that the distant magnetar released as much energy as our sun produces in 100,000 years, and it did so in just 1/10 of a second, according to a statement translated from Spanish.

Related: The 12 strangest objects in the universe

A neutron star forms when a massive star collapses at the end of its life. As the star dies in a supernova, protons and electrons in its core are crushed into a compressed solar mass that combines intense gravity with high-speed rotation and powerful magnetic forces, according to NASA. The result, a neutron star, is approximately 1.3 to 2.5 solar masses — one solar mass is the mass of our sun, or about 330,000 Earths — crammed into a sphere measuring just 12 miles (20 kilometers) in diameter. 

Matter in neutron stars is so densely packed that an amount the size of a sugar cube would weigh more than 1 billion tons (900 million metric tons), and a neutron star’s gravitational pull is so intense that a passing marshmallow would hit the star’s surface with the force of 1,000 hydrogen bombs, according to NASA.

Magnetars are neutron stars with magnetic fields that are 1,000 times stronger than those of other neutron stars, and they are more powerful than any other magnetic object in the universe. Our sun pales in comparison to these bright, dense stars even when they aren’t erupting, study lead author Alberto J. Castro-Tirado, a research professor with the Institute for Astrophysics of Andalucía at the Spanish Research Council, said in the statement.

“Even in an inactive state, magnetars can be 100,000 times more luminous than our sun,” Castro-Tirado said. “But in the case of the flash that we have studied — GRB2001415 — the energy that was released is equivalent to that which our sun radiates in 100,000 years.”

A “giant flare”

The magnetar that produced the brief eruption is located in the Sculptor Galaxy, a spiral galaxy about 13 million light-years from Earth, and is “a true cosmic monster,” study co-author Victor Reglero, director of UV’s Image Processing Laboratory, said in the statement. The giant flare was detected on April 15, 2020 by the Atmosphere–Space Interactions Monitor (ASIM) instrument on the International Space Station, researchers reported Dec. 22 in the journal Nature.

Artificial intelligence (AI) in the ASIM pipeline detected the flare, enabling the researchers to analyze that brief, violent energy surge; the flare lasted just 0.16 seconds and then the signal decayed so rapidly that it was nearly indistinguishable from background noise in the data. The study authors spent more than a year analyzing ASIM’s two seconds of data collection, dividing the event into four phases based on the magnetar’s energy output, and then measuring variations in the star’s magnetic field caused by the energy pulse when it was at its peak. 

It’s almost as if the magnetar decided to broadcast its existence “from its cosmic solitude” by shouting into the void of space with the force “of a billion suns,” Reglero said.

Only about 30 magnetars have been identified from approximately 3,000 known neutron stars, and this is the most distant magnetar flare detected to date. Scientists suspect that eruptions such as this one may be caused by so-called starquakes that disrupt magnetars’ elastic outer layers, and this rare observation could help researchers unravel the stresses that produce magnetars’ energy burps, according to the study.

Originally published on Live Science.

A dense, magnetic star violently erupted and spat out as much energy as a billion suns — and it happened in a fraction of a second, scientists recently reported.

This type of star, known as a magnetar, is a neutron star with an exceptionally strong magnetic field, and magnetars often flare spectacularly and without warning. But even though magnetars can be thousands of times brighter than our sun, their eruptions are so brief and unpredictable that they’re challenging for astrophysicists to find and study.

However, researchers recently managed to catch one of these flares and calculate oscillations in the brightness of a magnetar as it erupted. The scientists found that the distant magnetar released as much energy as our sun produces in 100,000 years, and it did so in just 1/10 of a second, according to a statement translated from Spanish.

Related: The 12 strangest objects in the universe

A neutron star forms when a massive star collapses at the end of its life. As the star dies in a supernova, protons and electrons in its core are crushed into a compressed solar mass that combines intense gravity with high-speed rotation and powerful magnetic forces, according to NASA. The result, a neutron star, is approximately 1.3 to 2.5 solar masses — one solar mass is the mass of our sun, or about 330,000 Earths — crammed into a sphere measuring just 12 miles (20 kilometers) in diameter. 

Matter in neutron stars is so densely packed that an amount the size of a sugar cube would weigh more than 1 billion tons (900 million metric tons), and a neutron star’s gravitational pull is so intense that a passing marshmallow would hit the star’s surface with the force of 1,000 hydrogen bombs, according to NASA.

Magnetars are neutron stars with magnetic fields that are 1,000 times stronger than those of other neutron stars, and they are more powerful than any other magnetic object in the universe. Our sun pales in comparison to these bright, dense stars even when they aren’t erupting, study lead author Alberto J. Castro-Tirado, a research professor with the Institute for Astrophysics of Andalucía at the Spanish Research Council, said in the statement.

“Even in an inactive state, magnetars can be 100,000 times more luminous than our sun,” Castro-Tirado said. “But in the case of the flash that we have studied — GRB2001415 — the energy that was released is equivalent to that which our sun radiates in 100,000 years.”

A “giant flare”

The magnetar that produced the brief eruption is located in the Sculptor Galaxy, a spiral galaxy about 13 million light-years from Earth, and is “a true cosmic monster,” study co-author Victor Reglero, director of UV’s Image Processing Laboratory, said in the statement. The giant flare was detected on April 15, 2020 by the Atmosphere–Space Interactions Monitor (ASIM) instrument on the International Space Station, researchers reported Dec. 22 in the journal Nature.

Artificial intelligence (AI) in the ASIM pipeline detected the flare, enabling the researchers to analyze that brief, violent energy surge; the flare lasted just 0.16 seconds and then the signal decayed so rapidly that it was nearly indistinguishable from background noise in the data. The study authors spent more than a year analyzing ASIM’s two seconds of data collection, dividing the event into four phases based on the magnetar’s energy output, and then measuring variations in the star’s magnetic field caused by the energy pulse when it was at its peak. 

It’s almost as if the magnetar decided to broadcast its existence “from its cosmic solitude” by shouting into the void of space with the force “of a billion suns,” Reglero said.

Only about 30 magnetars have been identified from approximately 3,000 known neutron stars, and this is the most distant magnetar flare detected to date. Scientists suspect that eruptions such as this one may be caused by so-called starquakes that disrupt magnetars’ elastic outer layers, and this rare observation could help researchers unravel the stresses that produce magnetars’ energy burps, according to the study.

Originally published on Live Science.

China’s freeze on video game licenses continues. South China Morning Post notes that the National Press and Publication Administration (NPPA) has not released a list of newly approved titles since July 2021. Because of this, state-run newspaper Securities Daily reports that approximately 14,000 small game studios and video game connection companies, including those involved in merchandising or publishing, have gone under.

Typically, the NPPA approves around 80 to 100 games a month, so the lack of an approved list has ground part of the industry to a halt. China is such a massive market, and the hiatus has caused uncertainty that has led to layoffs at game companies and conglomerates, with game divisions. However, it sounds like the smaller outfits have been hit the hardest.

In comparison, companies like tech giant Tencent have continued to expand internationally as a way to balance the regulatory situation at home. SCMP points out that Tencent also plans to open a new studio in Singapore under the TiMi Studio Group, which is responsible for Tencent’s mega-hit Honor of Kings. TiMI also has international studios in Montreal, Seattle, and Los Angeles.

No reason has been given for the hiatus, and the NPPA hasn’t stated as to when approvals will restart. Prior to this latest freeze, the longest period that new game licenses were not released was a nine-month window in 2018.

SCMP points out that the approval freeze happened a few months after March 2021 when President Xi Jinping mentioned his concerns about gaming’s psychological impact on young people. Later, that August, state-run media referred to video games as “spiritual opium” and “electronic drugs.” Then, on September 1, restrictions limiting the online gaming of the nation’s youth went into effect. While these restrictions were not law (and were soon circumvented), the combined impact of all this, the lack of new game approvals, and general uncertainty is impacting the industry—and not in a good way.