Catching the wave: researchers measure very short laser pulses
New study takes step forward in sub-atomic level research<em> - News Release</em>
Imperial College London news release
Strictly embargoed for
18.00 hours GMT
Sunday 3 December 2006
The study, published in Nature Physics, focused on extremely short laser pulses, less than 10 femtoseconds long – a femtosecond is one million-billionth of a second. These laser pulses can allow scientists to move and control the electrons in atoms and molecules, and to understand, for example, how molecules are formed. To achieve this reliably, the pulse of electromagnetic waves emitted from the laser must be controlled and measured with a precision which, until now, has been very hard to achieve.
Dr John Tisch , one of the Imperial research team, said: "This measurement technique is so accurate that we can determine the position of a peak in the pulse of electromagnetic waves from the laser with a precision of a mere 0.05 femtoseconds – in other words, 50 attoseconds. Also, the measurement can be made on individual pulses rather than by looking at the average properties of many pulses, so this is an important step forwards."
Dr Tisch explains that not only will this new technique lead to a greater ability to use short laser pulses for accurate sub-atomic level research, but it also sheds new light on the extremely short x-ray pulses emitted in response: "The x-ray pulses we used in the measurement process of our research are of great interest in their own right," he says. "They are on the attosecond timescale, which is even shorter than a femtosecond – just one billion-billionth of a second. They are a new tool for scientists to probe even faster motion than the femtosecond pulses that triggered them."
The research team have recently received a four-year GBP 2.5 million grant from the EPSRC to take this research to the next stage. Professor Jonathan Marangos explains: "Now we’ve perfected this technique, we are going to look into using our accurate measurements and control of these lasers to manipulate electrons and control quantum processes."
The research was funded by a Basic Technology Programme grant from RCUK.
-Ends-
For more information please contact:
Danielle Reeves, Imperial College London press office,
Tel: +44 (0)20 7594 2198
Mob: +44 (0)7803 886248
Email: Danielle.reeves@imperial.ac.uk
Notes to editors:
1. "Half-cycle cut-offs in harmonic spectra and robust carrier-envelope phase retrieval," Nature Physics, Sunday 3 December 2006.
C. A. Haworth, L. E. Chipperfield, J. S. Robinson, P. L. Knight, J. P. Marangos and J. W. Tisch – Department of Physics, the Blackett Laboratory, Imperial College London.
2. Consistently rated in the top three UK university institutions, Imperial College London is a world leading science-based university whose reputation for excellence in teaching and research attracts students (11,500) and staff (6,000) of the highest international quality. Innovative research at the College explores the interface between science, medicine, engineering and management and delivers practical solutions that enhance the quality of life and the environment - underpinned by a dynamic enterprise culture. Website: www.imperial.ac.uk
Article text (excluding photos or graphics) available under an Attribution-NonCommercial-ShareAlike Creative Commons license.
Photos and graphics subject to third party copyright used with permission or © Imperial College London.