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New neutron holography technique opens a window for obtaining clear 3-D atomic images

Date:
August 28, 2017
Source:
Nagoya Institute of Technology
Summary:
New work at particle accelerator facilities shows that neutron holograms can reveal the precise atomic structure of doped materials, offering a new characterization technique for materials scientists.
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People usually associate holograms with futuristic 3D display technologies, but in reality, holographic technologies are now being used to help study materials at the atomic level. X-rays, a high energy form of light, are often used to study atomic structure. However, X-rays are only sensitive to the number of electrons associated with an atom. This limits the use of X-rays for studying materials made up of lighter elements. Neutron measurements can often fill in the gaps in structures when X-ray measurements fail, but neutron beams are harder to make and have lower intensities than X-ray beams, which limits their versatility.

Now, a collaboration among Japanese researchers working at national particle accelerator facilities across Japan has developed a new multiple-wavelength neutron holography technique that can give insights into previously unknown structures. They demonstrated a new neutron holographic method using a Eu-doped CaF2 single crystal and obtained clear three-dimensional atomic images around trivalent Eu substituted divalent Ca, revealing never-before-seen intensity features of the local structure that allows it to maintain charge neutrality.

"We knew that neutron holography might be able to tell us more about the structure of a europium-doped calcium fluoride crystal," says lead author Kouichi Hayashi. "Europium ions add extra positive charge to the crystal structure, and our neutron holograms showed how fluorine atoms arranged in the lattice to balance this excess charge. These kinds of structural problems are often encountered by materials scientists developing new electronic materials, and our method offers an exciting new tool for these researchers."

The new holographic method works by firing neutrons with controlled speed at a sample, which in this case is the europium-doped calcium fluoride crystals. Neutrons are normally thought of as particles, but also have wave-like properties similar to light, depending on their speed. When the neutrons hit europium atoms, gamma rays are produced in a pattern controlled by the local structure. The gamma ray patterns, or holograms, measured from neutrons travelling at different speeds are combined to produce a three-dimensional representation of the europium atoms in the crystal.

Hayashi says, "Neutron sources are less intense than X-ray sources, but it is essential that we work around this issue to develop more effective methods for exploring structures with light elements. Our work here represents a step towards a full toolbox of commentary X-ray and neutron techniques for materials research."


Story Source:

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


Journal Reference:

  1. Kouichi Hayashi, Kenji Ohoyama, Naohisa Happo, Tomohiro Matsushita, Shinya Hosokawa, Masahide Harada, Yasuhiro Inamura, Hiroaki Nitani, Toetsu Shishido, Kunio Yubuta. Multiple-wavelength neutron holography with pulsed neutrons. Science Advances, 2017; 3 (8): e1700294 DOI: 10.1126/sciadv.1700294

Cite This Page:

Nagoya Institute of Technology. "New neutron holography technique opens a window for obtaining clear 3-D atomic images." ScienceDaily. ScienceDaily, 28 August 2017. <www.sciencedaily.com/releases/2017/08/170828102716.htm>.
Nagoya Institute of Technology. (2017, August 28). New neutron holography technique opens a window for obtaining clear 3-D atomic images. ScienceDaily. Retrieved December 21, 2024 from www.sciencedaily.com/releases/2017/08/170828102716.htm
Nagoya Institute of Technology. "New neutron holography technique opens a window for obtaining clear 3-D atomic images." ScienceDaily. www.sciencedaily.com/releases/2017/08/170828102716.htm (accessed December 21, 2024).

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