Researchers at Purdue University have achieved a groundbreaking breakthrough in quantum physics by using a quantum computer to simulate how energy can be teleported and stored in a qubit. This achievement marks a significant milestone in the field of quantum computing, as it demonstrates the potential for harnessing and storing energy from empty spaces.
The idea of teleporting energy was first proposed over a decade ago by Masahiro Hotta, a researcher at Tohoku University in Japan. However, previous attempts to implement this concept were hindered by the loss of teleported energy into the environment.
Sabre Kais, a professor of chemistry, electrical, and computer engineering at Purdue University, led a research team that successfully solved the energy storage problem using quantum computing. The team used qubits in their lowest energy state and entangled them to simulate the teleportation process.
The experiment demonstrated that when measurements were made on the first qubit’s energy state, it would increase its energy slightly, which would be reflected in the entangled qubit as well. This change could then be extracted from the entangled qubit and stored in another qubit for future use.
While this achievement is still largely theoretical, it has significant implications for the development of quantum computing and its potential applications in fields such as chemistry and materials science.
Source: https://interestingengineering.com/science/energy-teleport-quantum-computers