What did TU Wien researchers discover about transport?

TU Wien researchers discovered a physical system, an ultracold quantum gas, where transport of energy and mass occurs with complete efficiency, showing no degradation.

How does the quantum gas's transport differ from normal matter?

Unlike normal matter where friction causes resistance, this quantum gas exhibits perfect flow without dissipation, similar to a frictionless conductor.

Why doesn't the atomic cloud in the experiment reach thermal balance?

The atomic cloud does not thermalize because energy and momentum are conserved and passed on indefinitely, rather than dispersing as heat, due to its unique one-dimensional, collision-based momentum exchange.

Home / Science / Perfect Flow: Atoms Defy Friction in Quantum Gas

Perfect Flow: Atoms Defy Friction in Quantum Gas

8 Jan

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Summary

Scientists observed a physical system with no transport degradation.
An ultracold quantum gas exhibited perfect energy and mass flow.
Atomic flow behavior defies typical diffusion, acting like a perfect conductor.

Perfect Flow: Atoms Defy Friction in Quantum Gas

In a groundbreaking experiment, scientists at TU Wien have observed a physical system exhibiting transport without any degradation, a rare phenomenon that defies everyday physics. By confining thousands of rubidium atoms to move along a single line using magnetic and optical fields, they created an ultracold quantum gas.

This meticulously controlled environment allowed energy and mass to flow with complete efficiency. Published in the journal Science, the results show that the flow remains steady and unchanged even after countless atomic collisions, behaving more like a perfect conductor than typical matter where friction and collisions cause resistance.

The team explained this behavior using an analogy to Newton's cradle, where momentum is conserved and passed on without loss. This unique quantum transport means the atomic cloud does not thermalize according to standard thermodynamic laws, offering new insights into the emergence and disappearance of resistance at the quantum level.