[ad_1]
Baby it’s cold INSIDE! Scientists create coldest temperature EVER recorded in a lab – reaching 38 trillion degrees above absolute zero
- Scientists researched the wave properties of atoms in the laboratory
- They managed to manipulate the atoms to the point where they were practically static
- The slower the particles in atoms move, the cooler the temperature
- Bring them to a virtual stop authorized for conditions close to absolute zero
- For a few seconds, these particles were so still that the temperature dropped to 38 picokelvins (pK), or 38 trillionth of a degree above absolute zero.
Scientists created the coldest conditions on record, reaching just 38 trillion degrees above absolute zero.
By researching the wave properties of atoms, experts from the University of Bremen produced one of the “coldest places in the universe” for a few seconds in the lab.
Absolute zero – zero Kelvin, or -459.67 ° F – is the point at which atoms have no energy and do not move, and it is the coldest temperature that is theoretically possible to to reach.
To get as close to that point as possible, the team manipulated a cloud of atoms to a point where it was at a “virtual stop”.
For a few seconds, these particles were so still that the temperature dropped to 38 picokelvins (pK), or 38 trillionth of a degree above absolute zero.
The team says this could have important ramifications for our understanding of quantum mechanics, because the cooler the temperature, the more particular matter acts.
Absolute zero is the coldest temperature that it is theoretically possible to reach, based on the laws of thermodynamics. It is zero Kelvin, or -459.67 degrees Fahrenheit
To achieve the remarkably low temperature, the German team developed a process that lowers the temperature of a system by slowing the particles down until they almost come to a stop.
This is such a low temperature that no thermometer can detect it, so they base the measurement on the absence of kinetic motion of the observed particles.
The mechanism used to detect temperature is known as “Matter-wave lens system in the time domain” and can see matter behaving like a wave.
To study these waves, the team used a magnetic lens that allowed them to shape a quantum gas and use it to create a focused wave of matter that they could control and make sure it behaves. a specific way.
Unlike regular gas, which is a loose arrangement of particles, quantum gas is much less predictable, also known as Bose-Einstein condensate.
“By combining an excitation of a Bose-Einstein condensate (BEC) with a magnetic lens, we form a material wave lens system in the time domain,” the researchers wrote.
“Focus is regulated by the strength of the lens potential. By placing the focus at infinity, we lower the total internal kinetic energy of a BEC to 38 pK. ‘
The BEC is generated in a magnetic trap, after which the trap is turned off, and the gas initially expands in all three spatial directions.
A magnetic lens may have slowed this expansion and collimated the wave of matter in the past, but it only worked in two directions.
Scientists have created the coldest conditions on record, reaching just 38,000 billionths of a degree warmer than absolute zero, which is the coldest possible temperature
However, this is the first time that researchers have also managed to stop the expansion in the third direction.
The researchers say future experiments could make the particles even slower and last up to 17 seconds at this point, allowing for more detailed study.
The results were published in the journal Physical Review Letters.
[ad_2]
Source link