Hitoki Yoneda and co-workers at the University of Electro-Communications, Tokyo, together with scientists across Japan, have built an atomic X-ray laser with the shortest wavelength yet, producing a stable beam with a wavelength of 1.5 ångström, or 0.15 nanometers. This tiny wavelength is nearly ten times shorter than that of previously-reported atomic lasers.
TOKYO, Japan, Sept. 13, 2015 (GLOBE NEWSWIRE) -- via PRWEB - An atomic laser capable of operating at the shortest wavelengths achieved to date has been developed by researchers based at the University of Electro-Communications, Toyko.
The creation of lasers that can generate a coherent stream of X-ray radiation at short wavelengths has long been a goal for scientists. The primary aim of such 'X-ray lasers' is to produce high quality, high resolution images of tiny targets, such as molecules. However, the wavelengths of lasers developed to date are still too large to result in clear, detailed images of such targets.
Now, Hitoki Yoneda and co-workers at the University of Electro-Communications in Tokyo, together with scientists across Japan, have built an atomic X-ray laser with the shortest wavelength yet, producing a stable beam with a wavelength of 1.5 ångström, or 0.15 nanometers. This tiny wavelength is nearly ten times shorter than that of previously-reported atomic lasers.
Lasers work by using an energy source to excite a laser medium, which then releases a concentrated stream of photons. This stimulated emission process can increase the coherence of laser light under proper conditions. This work demonstrated that this is true, even in the X-ray region.
The team built their atomic laser based on copper atoms. The researchers exposed the foil to two X-ray pulses of different energies, generated by an X-ray free-electron laser; one pulse was tuned as a pump source and the other as a seed for the main laser beam. Yoneda and his team found that using the pumped copper medium in combination with the X-ray pulse acting as a seed for the main laser beam, greatly enhanced the coherence and energy extraction efficiency of the short-wavelength beam.
The researchers hope their 'hard X-ray inner-shell atomic laser' will eventually produce ultrastable, high quality X-ray images, and could feasibly transform the fields of medicine, quantum optics and particle physics.
Background:
The advances in laser technology
The ability to harness X-rays in an ultra-short, coherent and highly focused way will allow X-ray scientists to image tiny objects – as small as an individual molecule – clearly and precisely. Until now, X-ray lasers have been limited to larger wavelengths on the margins between UV and X-ray radiation in the electromagnetic spectrum. These larger wavelengths mean the laser beam can bypass smaller molecules without bouncing off them. Existing lasers also produce less detailed images of the target objects as a result.
Now, the long-standing goal of X-ray science appears to be edging ever closer, with the new 'hard X-ray inner-shell atomic laser' developed by Yoneda and his team. The researchers conducted initial tests on a design incorporating a copper foil medium bombarded by one laser pulse from an X-ray free-electron laser acting as a pump for the main laser.
However, the team was aware of the need to generate an extraction with the highest levels of coherency and efficiency as possible, and so decided to incorporate both pumping and seeding X-ray pulses from the X-ray free-electron laser into their design. The resulting X-ray beam is far superior to that of the free-electron laser on its own, with a significantly reduced wavelength of just 1.5 ångström.
Future work:
The new laser represents a significant step forward in the future of ultrafast X-ray spectroscopy and X-ray quantum optics. The team hopes it will soon be possible to commercialise the product as an highly coherent X-ray laser capable of producing high resolution and highly detailed images.
Using copper foil as a medium bombarded by two X-ray pulses of different energies produced by an X-ray free-electron laser, researchers at the University of Electro-Communications in Tokyo have successfully created a powerful and highly coherent atomic X-ray laser with the shortest wavelength to date.
Reference
H. Yoneda, Y. Inubushi, K. Nagamine, Y. Michine, H. Ohashi, H. Yumoto, K. Yamauchi, H. Mimura, H. Kitamura, T. Katayama, T. Ishikawa & M. Yabashi. Atomic inner-shell laser at 1.5-ångström wavelength pumped by an X-ray free-electron laser, Nature 524 (2015).
Further information:
International Public Relations, University of Electro-Communications , Tokyo.
1-5-1 Chofugaoka, Chofu, Tokyo 182-8585
E-mail: ru-info-ml(at)uec(dot)ac(dot)jp
Website: http://www.uec.ac.jp/
About The University of Electro-Communications
The University of Electro-Communications (UEC) in Tokyo is a small, luminous university at the forefront of applied sciences, engineering, and technology research. Its roots go back to the Technical Institute for Wireless Commutations, which was established in 1918 by the Wireless Association to train so-called wireless engineers in maritime communications in response to the Titanic disaster in 1912. In 1949, the UEC was established as a national university by the Japanese Ministry of Education, and moved in 1957 from Meguro to its current Chofu campus in Tokyo.
With approximately 4,000 students and 350 faculty, UEC is regarded as a small university, but with particular expertise in wireless communications, laser science, robotics, informatics, and material science, to name just a few areas of research.
The UEC was selected for the Ministry of Education, Culture, Sports, Science and Technology (MEXT) Program for Promoting the Enhancement of Research Universities as a result of its strengths in three main areas: optics and photonics research, where we are number one for the number of joint publications with foreign researchers; wireless communications, which reflects our roots; and materials-based research, particularly on fuel cells.
Website: http://www.uec.ac.jp/
This article was originally distributed on PRWeb. For the original version including any supplementary images or video, visit http://uk.prweb.com/releases/2015/09/prweb12946526.htm