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Volume 3, Issue 2

ISSN: 2470-9905

Crystallography 2017

October 16-17, 2017

2

nd

International Conference on

October 16-17, 2017 | Chicago, USA

Applied Crystallography

Yoshinori Ohmasa et al., Struct Chem Crystallogr Commun, 3:2

DOI: 10.21767/2470-9905-C1-002

Double bragg scattering from highly oriented pyrolytic graphite in small-angle X-ray scattering region

Yoshinori Ohmasa

1

, Ayano Chiba

2

1

Kansai University, Japan

2

Keio University, Japan

H

ighly oriented pyrolytic graphite (HOPG) is a form of carbon, which is composed of many crystallites arranged uniaxially.

The c-axes of the crystallites are aligned along a single direction, while the a- and b-axes are distributed randomly in the plane

perpendicular to the c-axis. HOPG is used in a wide range of scientific and technological areas, for example as a monochromator of

X-ray and neutron beams. We measured small-angle X-ray scattering from HOPG and observed radial streak patterns. When the

sample is rotated, the number and the direction of the streaks change. The streaks are divided into two categories: (i) A pair of streaks

which forms X-shaped pattern. The angle between the two streaks changes with sample rotation, and they appear and disappear in

pairs. (ii) A single streak which appears only in a narrow range of the sample rotation angle. Examples of the streak patterns of the type

(i) and (ii) are shown in Fig.1 and 2, respectively. We found that the appearance of the streaks is explained by double Bragg scattering.

They appear in the small-angle region because the first scattered X-ray is scattered back to the small-angle region. The streaks of the

type (i) is caused by the successive Bragg reflections

hkl

and

hkl

with

(h,k)

≠ (0,0), and (ii) is by

00l

and

00l

. The dependence of the

streak directions on the sample rotation angle is in good agreement with theoretical prediction. The double Bragg scattering observed

in the present work is an obstacle to obtaining the ‘true’ small-angle scattering. On the other hand, the intensity profile of the double

Bragg scattering pattern itself is interesting because it contains various pieces of information on the sample structure. For example,

the width and length of the streaks are related to the distribution of crystallites.

¯

Biography

Yoshinori Ohmasa studied physics at Kyoto University and received PhD from Kyoto University. His doctoral thesis is about the phase transitions and the structure of chal-

cogen mixed crystals under high pressure. He worked at Kyoto University from 1996 to 2008, and moved to Hiroshima Institute of Technology, and then to Kansai University.

His research interest covers the field of structurally disordered materials, such as liquid, glass, alloys and disordered crystals. Especially, he has been studying phenomena

related to liquid surface, such as wetting and capillary waves.

y_ohmasa@kansaiu.ac.jp

Fig.1(left) Fig.2(right) : Examples of observed streak patterns of the type (i) and (ii), respectively. The

scattering in Fig.1 is caused by the successive Bragg scatterings and , and Fig.2 is by and