- Normally formation happens in attoseconds and an attosecond is to a second what a second is to about 31.71 billion years.
- Further study of the particle could lead to quantum processors and ultra-fast electronics.
A quasiparticle is a concept of a state or phenomena that occurs in many-body systems or solid-state materials — like when an electron moves through a solid and polarizes its environment, generating a “polarization cloud” that moves together with the electron. This “dressed electron” is a quasiparticle also known as a polaron.
Scientists have been struggling to actually observe and measure quasiparticles. “The nonequilibrium dynamics of many-body quantum systems are tricky to study experimentally or theoretically,” according to a study published in Science by a team of theoretical physicists led by Rudolf Grimm.
“These processes last only attoseconds, which makes a time-resolved observation of their formation extremely difficult,” Grimm explains. An attosecond is one-quintillionth of a second — that’s very fast.
The researchers were able to create an environment that slowed the process down a bit, enabling them to observe the birth of an actual quasiparticle called a Fermi polaron (essentially, potassium atoms embedded in a lithium cloud).
To do so, they created an ultracold quantum gas, made up of lithium atoms and a small sample of potassium atoms in the middle, using laser trapping techniques inside a vacuum chamber. Then, they applied magnetic fields to tune particle interactions that formed the Fermi polaron.
THE FUTURE OF ELECTRONICS
Now that a quasiparticle has been observed in real time, the next step is to actually measure it. That remains to be a challenge. However, this development is a step towards making actual quantum processors, a feat that continues to elude many quantum computation researchers.
“We developed a new method for observing the ‘birth’ of a polaron virtually in real time,” says Grimm. Looking into the future, he says: “This may turn out to be a very interesting approach to better understand the quantum physical properties of ultrafast electronic devices.”
This major breakthrough in physics could lead to huge leaps in quantum computing and ultra-fast electronics.