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Gamma rays will reach beyond the limits of light

Date:
October 20, 2017
Source:
Chalmers University of Technology
Summary:
Researchers have discovered a new way to produce high energy photon beams. The new method makes it possible to produce these gamma rays in a highly efficient way, compared with today's technique. The obtained energy is a billion times higher than the energy of photons in visible light. These high intensity gamma rays significantly exceed all known limits, and pave the way towards new fundamental studies.
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Researchers have discovered a new way to produce high energy photon beams. The new method makes it possible to produce these gamma rays in a highly efficient way, compared with today's technique. The obtained energy is a billion times higher than the energy of photons in visible light. These high intensity gamma rays significantly exceed all known limits, and pave the way towards new fundamental studies.

"When we exceed the limit of what is currently possible, we can see deeper into the basic elements of nature. We can dive into the deepest part of the atomic nuclei," says Arkady Gonoskov, researcher at the Department of Physics at Chalmers University of Technology.

The results were recently published in the high impact journal Physical Review X. The new method is an outcome of a collaboration between Chalmers University of Technology in Sweden, Institute of Applied Physics and Lobachevsky University in Russia and University of Plymouth in the UK. Physicists in different fields, as well as computer scientists, have managed to work out the numerical models and analytic estimates for simulating these ultra-strong gamma rays in a new and somehow unexpected way.

In normal cases, if you shoot a laser pulse at an object, all the particles scatter. But if the laser light is intense enough and all parameters are right, the researchers have found that the particles are instead trapped. They form a cloud where particles of matter and antimatter are created and start to behave in a very special, unusual way.

"The cloud of trapped particles efficiently converts the laser energy into cascades of high energy photons -- a phenomena that is very fortunate. It's an amazing thing that the photons from this source can be of such high energy," says Mattias Marklund, professor at the Department of Physics at Chalmers.

The discovery is highly relevant for the future large scale laser facilities that are under development right now. The most intense light sources on earth will be produced at such research facilities -- as big as football fields.

"Our concept is already part of the experimental program proposed for one such facility: Exawatt Center for Extreme Light Studies in Russia. We still don't know where these studies will lead us, but we know that there are yet things to be discovered within nuclear physics, for example new sources of energy. With fundamental studies, you can aim at something and end up discovering something completely different -- which is more interesting and important," says Arkady Gonoskov.


Story Source:

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


Journal Reference:

  1. A. Gonoskov, A. Bashinov, S. Bastrakov, E. Efimenko, A. Ilderton, A. Kim, M. Marklund, I. Meyerov, A. Muraviev, A. Sergeev. Ultrabright GeV Photon Source via Controlled Electromagnetic Cascades in Laser-Dipole Waves. Physical Review X, 2017; 7 (4) DOI: 10.1103/PhysRevX.7.041003

Cite This Page:

Chalmers University of Technology. "Gamma rays will reach beyond the limits of light." ScienceDaily. ScienceDaily, 20 October 2017. <www.sciencedaily.com/releases/2017/10/171020101634.htm>.
Chalmers University of Technology. (2017, October 20). Gamma rays will reach beyond the limits of light. ScienceDaily. Retrieved October 3, 2024 from www.sciencedaily.com/releases/2017/10/171020101634.htm
Chalmers University of Technology. "Gamma rays will reach beyond the limits of light." ScienceDaily. www.sciencedaily.com/releases/2017/10/171020101634.htm (accessed October 3, 2024).

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