SCIENTIFIC INSTRUMENT FOR COLLOIDAL SYSTEMS EXPERIMENTAL STUDYING IN MICROGRAVITY-Reference-Cited by-同舟云学术

SCIENTIFIC INSTRUMENT FOR COLLOIDAL SYSTEMS EXPERIMENTAL STUDYING IN MICROGRAVITY

Published:2019-06-21 Issue:6 Volume: Page:83-90
ISSN:2218-5453
Container-title:Issues of radio electronics
language:
Short-container-title:Voprosy radioèlektroniki

Author:

Boreysho A. S.¹,Bakhanov I. S.²,Kiselev I. A.³,Rabchinskii M. K.⁴,Chugreev A. V.⁵

Affiliation:

1. Ustinov Baltic State Technical University «VOENMEH»; Laser Systems JSC,  Neudorf  SEZ

2. Laser Systems JSC,  Neudorf  SEZ

3. Ustinov Baltic State Technical University «VOENMEH»; Laser Systems JSC,  Neudorf  SEZ

4. Laser Systems JSC,  Neudorf  SEZ

5. Ustinov Baltic State Technical University «VOENMEH»; Laser Systems JSC,  Neudorf  SEZ

Abstract

Dispersia scientific instrument is designed to carry out series of experiments for the study of colloidal systems in microgravity conditions on the board of Russian Segment of the International Space Station. There are strong requirements on the reliability,  safety, mass and overall dimensions for spaceborn scientific instruments. The design and distinctive characteristics of the scientific instrument for study of processes of colloidal crystallization, aggregation, spinodal decomposition are discussed. The  experimental results of first ground tests are presented. The originally designed optic scheme for the analysis of static light scattering is described. Technical solutions developed to allow forming external stimuli to the studied sample are reviewed as  well. Finally, the experimental results on the study of colloidal system with the use of the developed scientific instrument during the first ground tests are presented.

Publisher

CRI Electronics

Subject

General Medicine

Reference12 articles.

1. Noda S., Kitamura K., Okino T., et al. Photonic-crystal surface-emitting lasers: review and introduction of modulated-photonic crystals. IEEE Journal of Selected Topics in Quantum Electronics, 2017, vol. 23, 4900107.

2. Hussein H. M. E., Ali T. A., Rafat N. H. A review on the techniques for building all-optical photonic crystal logic gates. Optics & Laser Technology, 2018, vol. 106, pp. 385–397.

3. Bunkin N. F., Lobeev A. V., Lyakhov G. A. Studies of spinodal decomposition in stratified solutions using laser methods. Uspekhi fizicheskikh nauk, 1997, vol. 40, pp. 1019–1034. (In Russian).

4. Dinsmore A. D., Crocker J. C., Yodh A. G. Self-assembly of colloidal crystals. Current Opinion in Colloid & Interface Science, 1998, vol. 3, pp. 5–11.

5. Cheng Z., Zhu J., Russel W. B., et al. Colloidal hard-sphere crystallization kinetics in microgravity and normal gravity. Applied Optics, 2011, vol. 40, pp. 4146–4151.