Quantum computers counting on carbon nanotubes
Like a guitar string nanotubes (black) can be clamped and excited to vibrate. An electric field (electrodes: blue) ensures that two of the many possible states can be selectively addressed.
Credit: M.J. Hartmann, TUM
Carbon nanotubes can be used as quantum bits for quantum computers. A study by physicists at the Technische Universitaet Muenchen (TUM) has shown how nanotubes can store information in the form of vibrations. Up to now, researchers have experimented primarily with electrically charged particles. Because nanomechanical devices are not charged, they are much less sensitive to electrical interference.
Using quantum mechanical phenomena, computers could be much more powerful than their classical digital predecessors. Scientists all over the world are working to explore the basis for quantum computing. To date most systems are based on electrically charged particles that are held in an “electromagnetic trap.” A disadvantage of these systems is that they are very sensitive to electromagnetic interference and therefore need extensive shielding. Physicists at the Technische Universitaet Muenchen have now found a way for information to be stored and quantum mechanically processed in mechanical vibrations.
Playing a nano-guitar
A carbon nanotube that is clamped at both ends can be excited to oscillate. Like a guitar string, it vibrates for an amazingly long time. “One would expect that such a system would be strongly damped, and that the vibration would subside quickly,” says Simon Rips, first author of the publication. “In fact, the string vibrates more than a million times. The information is thus retained up to one second. That is long enough to work with.”
Since such a string oscillates among many physically equivalent states, the physicists resorted to a trick: an electric field in the vicinity of the nanotube ensures that two of these states can be selectively addressed. The information can then be written and read optoelectronically. “Our concept is based on available technology,” says Michael Hartmann, head of the Emmy Noether research group Quantum Optics and Quantum Dynamics at the TU Muenchen. “It could take us a step closer to the realization of a quantum computer.”
The research was supported by the German Research Council (DFG) within the Emmy-Noether program and SFB 631.
Story Source:
The above post is reprinted from materials provided by Technische Universitaet Muenchen. Note: Materials may be edited for content and length.
Journal Reference:
- Simon Rips and Michael J. Hartmann,. Quantum Information Processing with Nanomechanical Qubits. Physical Review Letters, 110, 1205034 (2013) DOI: 10.1103/PhysRevLett.110.120503
Related Posts
Like this post? Share it!
0 Comments
Categories
- Biology (3 posts)
- Chemistry (72 posts)
- Environtment (3 posts)
- et cetera (5 posts)
- Health (20 posts)
- Nanomaterial (312 posts)
- Physics (33 posts)
Comments
- No comments yet.
Be the first to comment!
Recent Posts
- Using robots, scientists assemble promising antimicrobial compounds
- Light-powered healing of a wearable electrical conductor
- Graphene oxide biodegrades with help of human enzymes
- New tool measures distance between phonon collisions
- Umbrella-shaped diamond nanostructures make efficient photon collectors: Tiny, luminescent nanostructures may prove to be useful in highly sensitive magnetic sensors or within the realm of quantum computing
- First steps to create biodegradable displays for electronics
- Patterning oxide nanopillars at the atomic scale by phase transformation
- Microscopic view of coughed-up mucus may be new biomarker for cystic fibrosis progression
- New research could revolutionize flexible electronics, solar cells
- Nanocircuitry grown with semiconducting graphene nanoribbons
