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Nature: Smallest vibration sensor in the quantum world

03.15.13 | Helmholtz Association

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The Spin of a Molecule Changes and Deforms the Nanotube Mounted between 2 Electrodes
The spin of a molecule (orange) changes and deforms the nanotube (black) mounted between two electrodes (gold). Credit: Figure: C. Grupe/KIT

This press release is available in German .

In their experiment the researchers used a carbon nanotube that was mounted between two metal electrodes, spanned a distance of about 1 µm, and could vibrate mechanically. Then, they applied an organic molecule with a magnetic spin due to an incorporated metal atom. This spin was oriented in an external magnetic field.

"In this setup, we demonstrated that the vibrations of the tube are influenced directly when the spin flips parallel or antiparallel to the magnetic field," explains Mario Ruben, head of the working group at KIT. When the spin changes, the resulting recoil is transferred to the carbon nanotube and the latter starts to vibrate. Vibration changes the atomic distances of the tube and, hence, its conductance that is used as a measure of motion.

The strong interaction between a magnetic spin and mechanical vibration opens up interesting applications apart from determining the states of motion of the carbon nanotube. It is proposed to determine the masses of individual molecules and to measure magnetic forces within the nano-regime. Use as a quantum bit in a quantum computer might also be feasible.

According to the supplementary information published in the same issue of nature nanotechnology such interactions are of high importance in the quantum world, i.e. in the range of discrete energies and tunnel effects, for the future use of nanoscopic effects in macroscopic applications. Combination of spin, vibration, and rotation on the nanoscale in particular may result in entirely new applications and technologies.

Videoanimation shows wave on Carbon nanotube.

The online version of the print paper:

http://www.nature.com/nnano/journal/v8/n3/full/nnano.2012.258.html

The supplementary information:

The homepage of the research group at KIT can be found at:

http://www.ruben-group.de/

Karlsruhe Institute of Technology (KIT) is a public corporation according to the legislation of the state of Baden-Württemberg. It fulfills the mission of a university and the mission of a national research center of the Helmholtz Association. KIT focuses on a knowledge triangle that links the tasks of research, teaching, and innovation.

This press release is available on the internet at http://www.kit.edu .

The photo of printing quality may be downloaded under http://www.kit.edu or requested by mail to presse@kit.edu or phone +49 721 608-4 7414. The photo may be used in the context given above exclusively.

Nature Nanotechnology

Keywords

Magnetic Fields Quantum Tunneling Vibration

Article Information

Journal
Nature Nanotechnology

Contact Information

Monika Landgraf
presse@kit.edu

Source

Original Source
http://www.kit.edu/visit/pi_2013_12574.php

How to Cite This Article

APA:
Helmholtz Association. (2013, March 15). Nature: Smallest vibration sensor in the quantum world. Brightsurf News. https://www.brightsurf.com/news/19V7PX58/nature-smallest-vibration-sensor-in-the-quantum-world.html
MLA:
"Nature: Smallest vibration sensor in the quantum world." Brightsurf News, Mar. 15 2013, https://www.brightsurf.com/news/19V7PX58/nature-smallest-vibration-sensor-in-the-quantum-world.html.