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Infrared Extinction Performance of Biological Materials |
LI Le, HU Yi-hua*, GU You-lin,ZHAO Yi-zheng, YU Lei, HUANG Bao-kun |
1. State Key Laboratory of Pulsed Power Laser, Electronic Engineering Institute, Hefei 230037, China
2. Key Laboratory of Electronic Restriction,Hefei 230037, China |
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Abstract It has been a hotspot to looking for high performance electromagnetic attenuation material. At present, the conventional inorganic materials, such as aluminum foil, copper, graphite, have been widely used in electromagnetic attenuation field. However, there are certain restrictions on the use of inorganic materials, such as high cost of raw material, low generating efficiency, and environment unfriendly. Recently, considerable attention has been paid to microbial materials, which has the potential to solve the problems above. In this study, three biological materials, fungi An0429 spores, fungi Bb0919 spores and fungi Cx0507 spores were used to measure infrared extinction performance. They were subjected to specular reflection spectra measurements in the range of 4 000~400 cm-1 (2.5~25 μm) by squash method. The real (n) and imaginary (k) parts of the complex refractive index of biological materials were calculated by using Kramers-Kroning relation based on the measured data. The complex refractive index with real part n and imaginary part k in the infrared band satisfies the following conditions n≥1 and k≥0. The static mass extinction coefficient was calculated based on Mie theory. Compared with common inorganic materials, biological materials possess a good extinction performance. In the smoke box test, the transmittances of fungi An0429, fungi Bb0919 spores and fungi Cx0507 spores were 5.1%, 8.2% and 7.4%, the mass extinction coefficients were 1.257, 1.065 and 1.009 m2·g-1. These results showed that have higher extinction characteristics. In addition, biological microbial materials have other advantages, such as short growth cycle, low production cost, absence of toxic in the casting process, and environmental friendliness. Therefore, microbial materials have great potential in extinction applications.
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Received: 2016-07-05
Accepted: 2016-12-20
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Corresponding Authors:
HU Yi-hua
E-mail: skl_hyh@163.com
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[1] Thomas A W, Henson Z B, Du J, et al. Journal of the American Chemical Society, 2014, 136(10): 3736.
[2] Jacques S L. Physics in Medicine and Biology, 2013, 58(11): R37.
[3] D’Esposito L, Koenig J L. Fourier Transform Infrared Spectroscopy, Applications to Chemical Systems, 2012, 1: 61.
[4] SUN Du-juan, HU Yi-hua, GU You-lin, et al(孙杜娟,胡以华,顾有林,等). Acta Phys. Sin.(物理学报),2013, 62(9): 94218.
[5] Gurton K P, Ligon D A, Kvavilashvili R. Applied Optics, 2001, 40(25): 4444.
[6] Baldauf N A, Rodriguez-Romo L A, Yousef A E, et al. Applied Spectroscopy,2006, 60(6): 592.
[7] GUO Wei-liang, WANG Dan, SONG Jia, et al(郭伟良, 王 丹, 宋 佳, 等). Acta Optica Sinica(光学学报),2011, 31(2): 0230002.
[8] SUN Du-juan, HU Yi-hua, GU You-lin, et al(孙杜娟,胡以华,顾有林, 等). Acta Photonica Sinica(光子学报), 2013, 42(5): 555.
[9] Mishchenko M I, Travis L D, Lacis A A. Scattering, Absorption, and Emission of Light by Small Particles. UK: Cambridge University Press, 2002.
[10] Guo Z, Zhou K, Zhang A, et al. Journal of Nonlinear Optical Physics & Materials, 2014, 23(04): 1450049.
[11] DOU Zheng-wei, LI Xiao-xia, ZHAO Ji-jin(豆正伟, 李晓霞, 赵纪金). Acta Armamentarii(兵工学报),2011, 32(4): 498.
[12] Wang P, Liu H, Zhao Y, et al. Applied Spectroscopy, 2016: 0003702816662599. |
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