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Researchers put single molecules in super-fridge

Date:
November 10, 2016
Source:
University of Leicester
Summary:
For the first time, a team of researchers has observed how a single two-atom-large molecule rotates in the coldest liquid known in nature. These findings could help to trigger new applications of drugs for diagnostics and develop new materials.
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Image of a micro discharge cell mounted on a low temperature fridge.
Credit: Image courtesy of University of Leicester

An international team of researchers led by the University of Leicester has for the first time observed how a single two-atom-large molecule rotates in the coldest liquid known in nature.

The team consists of researchers from the Department of Physics and Astronomy at the University of Leicester, the Centre National de la Recherche Scientifique (CNRS), Grenoble, France and the Department of Physics in Kerbala, Iraq.

The interactions of molecules in liquids determines chemical reactions and biological processes.

In ordinary liquids the interactions between the molecules is too strong and overshadows the subtle features of rotations.

By choosing a very special liquid composed of helium atoms the researchers reduced the strength of the molecular interactions so that they had the chance to see single molecules rotating.

Lead author Dr Klaus von Haeften from the University of Leicester Department of Physics and Astronomy said: "To introduce molecules into the liquid helium we had to excite the helium using a discharge.

"This was necessary because ordinary molecules would freeze once they are introduced into liquid helium. By exciting helium in the discharge tiny gas bubbles were formed."

The researchers observed that by applying pressure the molecules within these bubbles would collide with the ultra-cold liquid and begin to cool and slow down their rotations.

This happened at a rate of more than 100 billion degrees Kelvin (centigrade) per second. At pressures of several atmospheres the molecules reached the slowest possible rotational speed.

The researchers believe that with these molecules they can investigate liquid helium at even lower temperatures.

At these temperatures friction disappears, and the team expects to be able to measure with great precision how molecules respond to this 'superfluid' state.

Dr von Haeften added: "The results of these studies in liquid helium will also be important to understand ordinary liquids, where such observations are impossible to make.

"This may trigger new applications of drugs for diagnostics and therapy and the development of new materials."

Two of the international researchers involved in the project have conducted their PhD studies at the University of Leicester.

Mrs Nagham Shiltagh (Iraq) is currently investigating how the technology developed in this project could be applied in other areas and Luis Guillermo Mendoza-Luna (Mexico) was involved in setting up the experiment and recording the data and has now assumed an academic position in Mexico.

The paper 'Excimers in the Lowest Rotational Quantum State in Liquid Helium' is published in the Journal of Physical Chemistry Letters.


Story Source:

Materials provided by University of Leicester. Note: Content may be edited for style and length.


Journal Reference:

  1. Luis Guillermo Mendoza-Luna, Nagham M. K. Shiltagh, Mark J. Watkins, Nelly Bonifaci, Frédéric Aitken, Klaus von Haeften. Excimers in the Lowest Rotational Quantum State in Liquid Helium. The Journal of Physical Chemistry Letters, 2016; 4666 DOI: 10.1021/acs.jpclett.6b02081

Cite This Page:

University of Leicester. "Researchers put single molecules in super-fridge." ScienceDaily. ScienceDaily, 10 November 2016. <www.sciencedaily.com/releases/2016/11/161110084650.htm>.
University of Leicester. (2016, November 10). Researchers put single molecules in super-fridge. ScienceDaily. Retrieved May 29, 2017 from www.sciencedaily.com/releases/2016/11/161110084650.htm
University of Leicester. "Researchers put single molecules in super-fridge." ScienceDaily. www.sciencedaily.com/releases/2016/11/161110084650.htm (accessed May 29, 2017).

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