Physicists Just Confirmed The Upper Limit For The Speed of Sound in The Universe - Science world

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Tuesday, August 10, 2021

Physicists Just Confirmed The Upper Limit For The Speed of Sound in The Universe

 Einstein's theory of special relativity theory gave us the ordinance of the Universe - that of sunshine in a very vacuum. But absolutely the top speed of sound, through any medium, has been somewhat trickier to constrain.


It's impossible to live the speed of sound in every single material living, but scientists have now managed to pin down an upper limit supported fundamental constants, the universal parameters by which we understand the physics of the Universe.

That ordinance, in line with the new calculations, is 36 kilometres per second (22 miles per second). That's about twice the speed of sound travelling through a diamond.

Both sound and lightweight travel as waves, but they behave slightly differently. actinic radiation may be a sort of radiation, so-named because light waves encompass oscillating electric and magnetic fields. These fields generate self-perpetuating electromagnetic radiation which will travel in an exceedingly vacuum - and its top speed is around 300,000 kilometres per second. Travelling through a medium, like water or an environment, slows it down.

The sound may be a mechanical wave, which is caused by a vibration in a very medium. because the wave travels through the medium, that medium's molecules hit one another, transferring energy as they're going.

Hence, the more rigid the medium - the tougher it's to compress - the faster sound travels. for instance, water has more tightly packed particles than air, and that is partially why whales can communicate across such vast distances within the ocean.

In a rigid solid, sort of a diamond, sound can travel even faster. We leverage this property to check the within of Earth when sound waves from earthquakes travel through it. we are able to even use it to know the interiors of stars.

"Soundwaves in solids are already hugely important across many scientific fields," said materials scientist Chris Pickard of the University of Cambridge within the UK.

"For example, seismologists use sound waves initiated by earthquakes deep within the Earth interior to grasp the character of seismic events and therefore the properties of Earth composition. They're also of interest to materials scientists because sound waves are associated with important elastic properties including the power to resist stress."

By now, you'll be able to probably see the matter with constraining the speed of sound. How can we account for all the possible materials within the Universe so as to work out an absolute upper limit on the speed of sound?

This is where fundamental constants are useful. To calculate the regulation of sound, a team of scientists from the Queen Mary University of London, the University of Cambridge within the UK, and therefore the Institute for prime Pressure Physics in Russia found the regulation depends on two fundamental constants.

These are the spectrum line constant, which characterises the strength of electromagnetic interactions between elementary charged particles; and therefore the proton-to-electron mass ratio, which is that the mass of the proton divided by the remaining mass of the electron.

"The finely tuned values of the spectrum line constant and also the proton-to-electron mass ratio, and also the balance between them, govern nuclear reactions like proton decay and nuclear synthesis in stars, resulting in the creation of the essential biochemical elements, including carbon. This balance provides a narrow 'habitable zone' within the space where stars and planets can form and life-supporting molecular structures can emerge," the researchers wrote in their paper.

"We show that an easy combination of the spectrum line constant and also the proton-to-electron mass ratio ends up in another dimensionless quantity that has an unexpected and specific implication for a key property of condensed phases - the speed at which waves travel in solids and liquids, or the speed of sound."

To confirm their equation, the team experimentally measured the speed of sound during a sizable amount of elemental solids and liquids and returned results per their predictions.

One specific prediction of the team's theory is that the speed of sound should decrease with the mass of the atom. in keeping with this prediction, the sound should move fastest through solid atomic hydrogen - which may only exist at extremely high pressures, above around 1 million times Earth's gas pressure baffled level (100 gigapascals).

Obtaining a sample to verify this prediction experimentally would be extremely difficult, therefore the team relied on calculations supported the properties of solid atomic hydrogen between 250 and 1,000 gigapascals. and that they found that, again, the results agreed with their predictions.

If the results of applying the team's equation remain consistent, it could influence be a valuable tool, not only for understanding individual materials but the broader Universe.

"We believe the findings of this study," said physicist Kostya Trachenko of Queen Mary University of London, "could have further scientific applications by helping us to search out and understand limits of various properties like viscosity and thermal conductivity relevant for high-temperature superconductivity, quark-gluon plasma and even part physics."

 Einstein's theory of special relativity theory gave us the ordinance of the Universe - that of sunshine in a very vacuum. But absolutely the top speed of sound, through any medium, has been somewhat trickier to constrain.


It's impossible to live the speed of sound in every single material living, but scientists have now managed to pin down an upper limit supported fundamental constants, the universal parameters by which we understand the physics of the Universe.

That ordinance, in line with the new calculations, is 36 kilometres per second (22 miles per second). That's about twice the speed of sound travelling through a diamond.

Both sound and lightweight travel as waves, but they behave slightly differently. actinic radiation may be a sort of radiation, so-named because light waves encompass oscillating electric and magnetic fields. These fields generate self-perpetuating electromagnetic radiation which will travel in an exceedingly vacuum - and its top speed is around 300,000 kilometres per second. Travelling through a medium, like water or an environment, slows it down.

The sound may be a mechanical wave, which is caused by a vibration in a very medium. because the wave travels through the medium, that medium's molecules hit one another, transferring energy as they're going.

Hence, the more rigid the medium - the tougher it's to compress - the faster sound travels. for instance, water has more tightly packed particles than air, and that is partially why whales can communicate across such vast distances within the ocean.

In a rigid solid, sort of a diamond, sound can travel even faster. We leverage this property to check the within of Earth when sound waves from earthquakes travel through it. we are able to even use it to know the interiors of stars.

"Soundwaves in solids are already hugely important across many scientific fields," said materials scientist Chris Pickard of the University of Cambridge within the UK.

"For example, seismologists use sound waves initiated by earthquakes deep within the Earth interior to grasp the character of seismic events and therefore the properties of Earth composition. They're also of interest to materials scientists because sound waves are associated with important elastic properties including the power to resist stress."

By now, you'll be able to probably see the matter with constraining the speed of sound. How can we account for all the possible materials within the Universe so as to work out an absolute upper limit on the speed of sound?

This is where fundamental constants are useful. To calculate the regulation of sound, a team of scientists from the Queen Mary University of London, the University of Cambridge within the UK, and therefore the Institute for prime Pressure Physics in Russia found the regulation depends on two fundamental constants.

These are the spectrum line constant, which characterises the strength of electromagnetic interactions between elementary charged particles; and therefore the proton-to-electron mass ratio, which is that the mass of the proton divided by the remaining mass of the electron.

"The finely tuned values of the spectrum line constant and also the proton-to-electron mass ratio, and also the balance between them, govern nuclear reactions like proton decay and nuclear synthesis in stars, resulting in the creation of the essential biochemical elements, including carbon. This balance provides a narrow 'habitable zone' within the space where stars and planets can form and life-supporting molecular structures can emerge," the researchers wrote in their paper.

"We show that an easy combination of the spectrum line constant and also the proton-to-electron mass ratio ends up in another dimensionless quantity that has an unexpected and specific implication for a key property of condensed phases - the speed at which waves travel in solids and liquids, or the speed of sound."

To confirm their equation, the team experimentally measured the speed of sound during a sizable amount of elemental solids and liquids and returned results per their predictions.

One specific prediction of the team's theory is that the speed of sound should decrease with the mass of the atom. in keeping with this prediction, the sound should move fastest through solid atomic hydrogen - which may only exist at extremely high pressures, above around 1 million times Earth's gas pressure baffled level (100 gigapascals).

Obtaining a sample to verify this prediction experimentally would be extremely difficult, therefore the team relied on calculations supported the properties of solid atomic hydrogen between 250 and 1,000 gigapascals. and that they found that, again, the results agreed with their predictions.

If the results of applying the team's equation remain consistent, it could influence be a valuable tool, not only for understanding individual materials but the broader Universe.

"We believe the findings of this study," said physicist Kostya Trachenko of Queen Mary University of London, "could have further scientific applications by helping us to search out and understand limits of various properties like viscosity and thermal conductivity relevant for high-temperature superconductivity, quark-gluon plasma and even part physics."

1 comment:

  1. who is writing this stuff? Certainly doesn't have English as a first language. Or is it a (poor) computer translation program? Unreadable.


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    ReplyDelete