Optical properties of eukaryotic and prokaryotic microbial aerosols in the 0.25-15 μm band

Zhao Xinying; Hu Yihua; Gu Youlin; Chen Xi; Wang Xinyu; Wang Peng

doi:10.3788/IRLA201948.1017004

Volume 48 Issue 10

Oct. 2019

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Zhao Xinying, Hu Yihua, Gu Youlin, Chen Xi, Wang Xinyu, Wang Peng. Optical properties of eukaryotic and prokaryotic microbial aerosols in the 0.25-15 μm band[J]. Infrared and Laser Engineering, 2019, 48(10): 1017004-1017004(8). doi: 10.3788/IRLA201948.1017004

Citation:

Zhao Xinying, Hu Yihua, Gu Youlin, Chen Xi, Wang Xinyu, Wang Peng. Optical properties of eukaryotic and prokaryotic microbial aerosols in the 0.25-15 μm band[J]. Infrared and Laser Engineering, 2019, 48(10): 1017004-1017004(8). doi: 10.3788/IRLA201948.1017004

Optical properties of eukaryotic and prokaryotic microbial aerosols in the 0.25-15 μm band

doi: 10.3788/IRLA201948.1017004

Zhao Xinying^1,2,
Hu Yihua^1,2,
Gu Youlin^1,2,
Chen Xi^1,2,
Wang Xinyu^1,2,
Wang Peng³

1.
State Key Laboratory of Pulsed Power Laser Technology,National University of Defense Technology,Hefei 230037,China;
2.
Anhui Province Key Laboratory of Electronic Restriction,National University of Defense Technology,Hefei 230037,China;
3.
Key Laboratory of Ion Beam Bioengineering,Hefei Institute of Physical Science,Chinese Academy of Sciences,Hefei 230001,China

Received Date: 2019-05-05
Rev Recd Date: 2019-06-15
Publish Date: 2019-10-25

Abstract

Microbial aerosols, as an important component of atmospheric aerosols, can affect atmospheric radiation characteristics through absorption or scattering. At present, the research on the optical properties of microbial aerosols is mostly limited to single-band or single germplasm. It is impossible to generalize the generality and particularity of microscopic aerosol optical properties, which is not conducive to comprehensively analyze the effects of microbial aerosols on atmospheric radiation characteristics. Herein, the spectral reflectances of three eukaryotic microbe and three prokaryotic microbes in the waveband from 0.25 to 15 m were measured. Based on the Kramers-Kroning algorithm, the complex refractive index (CRI) m was calculated and the FTIR spectra of microbes were analysed. The similarities and differences between the optical properties of the 0.25-15 m band of eukaryotic and prokaryotic microorganisms were compared. The conclusion can help to comprehensively understand and quantitatively calculate atmospheric radiation characteristics, provide theoretical support for microbial aerosol remote sensing detection and type identification, and provide new ideas for the development of new functional materials.
- bioaerosol,
- complex refractive index,
- eukaryotic microorganism,
- prokaryotic microorganism

References

[1]	Li Chao, Yang Zijian, Du Yaohua, et al. Eye-safe LIDAR for short-range stand-off detection of bio-aerosols[J]. Optics and Precision Engineering, 2016, 24(7):1600-1606. (in Chinese)
[2]	Janine Frhlich-Nowoisky, Christopher J-Kampf, Bettina Weber. Bioaerosols in the Earth system:Climate, health, and ecosystem interactions[J]. Atmos Res, 2016, 182(3):346-376.
[3]	Clements R, Emerson J B, Wiedinmyer C. Seasonal variability in bacterial and fungal diversity of the near-surface atmosphere[J]. Environmental Science and Technology, 2013, 47(21):12097-12106.
[4]	Xiao Shaorong, Wang Kun, Liu Juan. Detection of atmospheric aerosol concentration and detection system design[J]. Chinese Optics, 2011, 43(6):633-638. (in Chinese)
[5]	Zhang Junqiang, Xue Chuang, Gao Zhiliang, et al. Optical remote sensor for cloud and aerosol from space:past,present and future[J]. Chinese Optics, 2015, 23(5):679-698. (in Chinese)
[6]	Tuminello P S, Arakawa E T, Khare B N. Optical properties of bacillus subtilis spores from 0.2 to 2.5 mm[J]. Applied Optics, 1997, 36(13):2818.
[7]	Gurton K P, Ligon D K, vavilashvili R. Measured infrared spectral extinction for aerosolized bacillus subtilis var. niger endospores from 3 to 13 mm[J]. Applied Optics, 2008, 40(25):4443-4448.
[8]	Zhao Xinying, Hu Yihua, Gu Youlin, et al. Transmittance of laser in the microorganism aggregated particle swarm[J]. Acta Optica Sinica, 2015, 42(6):222-228. (in Chinese)
[9]	Li Le, Hu Yihua, Gu Youlin. Infrared extinction performance of randomly oriented microbial-clustered agglomerate materials[J]. SAGE Publications, 2017, 71(11):2555-2562.
[10]	Li Le, Hu Yihua, Gu Youlin. Infrared extinction performance of aspergillus niger spores[J]. Infrared and Laser Engineering, 2014, 43(7):2175-2180. (in Chinese)
[11]	Gu Youlin, Wang Cheng, Yang Li, et al. Infrared extinction before and after aspergillus niger spores inactivation[J].Infrared and Laser Engineering, 2015, 44(1):36-41. (in Chinese)
[12]	Gu Youlin, Cao Guanghua, Yang Li, et al. Measurement of ultraviolet and infrared composite extinction performance of biological materials[J]. Infrared and Laser Engineering, 2018, 43(3):0321003. (in Chinese)
[13]	Segal-rosenheimer M, Linker R. Impact of the non-measured infrared spectral range of the imaginary refractive index on the derivation of the real refractive index using the Kramers-Kronig transform[J]. J Quant Spectrosc Radiat Transfer, 2009, 110(13):1147-1161.
[14]	Yurkin M A, Hoekstra A G. The discrete dipole approximation_An overview and recent developments[J]. Journal of Quantitative Spectroscopy and Radiative Transfer, 2007, 106(1):558-589.
[15]	Jacques Steven L. Modeling tissue optics-using Monte Carlo modeling a tutorial[C]//SPIE, 2008, 6854:68540T.
[16]	Zuo Chenze, Lu Qieni, Ge Baozhen, et al. Impact of refractive index of aerosol particles on particle diameter optical measurement[J]. Optics and Precision Engineering, 2017, 41(7):1777-1782. (in Chinese)
[17]	Ren Lin. Effect of water capacity on cell activity and storage stability of lactobacillus plantarum starter cultures[J]. Food Science, 2009, 30(23):388-390. (in Chinese)
[18]	Luca Quaroni, Theodora Zlateva. Infrared spectromicroscopy of biochemistry in functional single cells[J]. The Analyst, 2011, 136(16):3219.
[19]	Li Lei, Bai Huimin, Weng Shifu, et al. Laboratory study for analysis of intra-tumor heterogeneity of ovarian cancer by Fourier transform infrared spectroscopy[J]. Medical Journal of Peking Union Medical College Hospital, 2017, 8(4-5):268-273. (in Chinese)
[20]	Lisa M Miller, Paul Dumas. From structure to cellular mechanism with infrared microspectroscopy[J]. Current Opinion in Structural Biology, 2010, 20(5):649-656.

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通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

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Optical properties of eukaryotic and prokaryotic microbial aerosols in the 0.25-15 μm band

1. State Key Laboratory of Pulsed Power Laser Technology,National University of Defense Technology,Hefei 230037,China;

2. Anhui Province Key Laboratory of Electronic Restriction,National University of Defense Technology,Hefei 230037,China;

3. Key Laboratory of Ion Beam Bioengineering,Hefei Institute of Physical Science,Chinese Academy of Sciences,Hefei 230001,China

Received Date: 2019-05-05

Rev Recd Date: 2019-06-15

Publish Date: 2019-10-25

Key words:

Abstract: Microbial aerosols, as an important component of atmospheric aerosols, can affect atmospheric radiation characteristics through absorption or scattering. At present, the research on the optical properties of microbial aerosols is mostly limited to single-band or single germplasm. It is impossible to generalize the generality and particularity of microscopic aerosol optical properties, which is not conducive to comprehensively analyze the effects of microbial aerosols on atmospheric radiation characteristics. Herein, the spectral reflectances of three eukaryotic microbe and three prokaryotic microbes in the waveband from 0.25 to 15 m were measured. Based on the Kramers-Kroning algorithm, the complex refractive index (CRI) m was calculated and the FTIR spectra of microbes were analysed. The similarities and differences between the optical properties of the 0.25-15 m band of eukaryotic and prokaryotic microorganisms were compared. The conclusion can help to comprehensively understand and quantitatively calculate atmospheric radiation characteristics, provide theoretical support for microbial aerosol remote sensing detection and type identification, and provide new ideas for the development of new functional materials.

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Reference (20)

[1]	Li Chao, Yang Zijian, Du Yaohua, et al. Eye-safe LIDAR for short-range stand-off detection of bio-aerosols[J]. Optics and Precision Engineering, 2016, 24(7):1600-1606. (in Chinese)
[2]	Janine Frhlich-Nowoisky, Christopher J-Kampf, Bettina Weber. Bioaerosols in the Earth system:Climate, health, and ecosystem interactions[J]. Atmos Res, 2016, 182(3):346-376.
[3]	Clements R, Emerson J B, Wiedinmyer C. Seasonal variability in bacterial and fungal diversity of the near-surface atmosphere[J]. Environmental Science and Technology, 2013, 47(21):12097-12106.
[4]	Xiao Shaorong, Wang Kun, Liu Juan. Detection of atmospheric aerosol concentration and detection system design[J]. Chinese Optics, 2011, 43(6):633-638. (in Chinese)
[5]	Zhang Junqiang, Xue Chuang, Gao Zhiliang, et al. Optical remote sensor for cloud and aerosol from space:past,present and future[J]. Chinese Optics, 2015, 23(5):679-698. (in Chinese)
[6]	Tuminello P S, Arakawa E T, Khare B N. Optical properties of bacillus subtilis spores from 0.2 to 2.5 mm[J]. Applied Optics, 1997, 36(13):2818.
[7]	Gurton K P, Ligon D K, vavilashvili R. Measured infrared spectral extinction for aerosolized bacillus subtilis var. niger endospores from 3 to 13 mm[J]. Applied Optics, 2008, 40(25):4443-4448.
[8]	Zhao Xinying, Hu Yihua, Gu Youlin, et al. Transmittance of laser in the microorganism aggregated particle swarm[J]. Acta Optica Sinica, 2015, 42(6):222-228. (in Chinese)
[9]	Li Le, Hu Yihua, Gu Youlin. Infrared extinction performance of randomly oriented microbial-clustered agglomerate materials[J]. SAGE Publications, 2017, 71(11):2555-2562.
[10]	Li Le, Hu Yihua, Gu Youlin. Infrared extinction performance of aspergillus niger spores[J]. Infrared and Laser Engineering, 2014, 43(7):2175-2180. (in Chinese)
[11]	Gu Youlin, Wang Cheng, Yang Li, et al. Infrared extinction before and after aspergillus niger spores inactivation[J].Infrared and Laser Engineering, 2015, 44(1):36-41. (in Chinese)
[12]	Gu Youlin, Cao Guanghua, Yang Li, et al. Measurement of ultraviolet and infrared composite extinction performance of biological materials[J]. Infrared and Laser Engineering, 2018, 43(3):0321003. (in Chinese)
[13]	Segal-rosenheimer M, Linker R. Impact of the non-measured infrared spectral range of the imaginary refractive index on the derivation of the real refractive index using the Kramers-Kronig transform[J]. J Quant Spectrosc Radiat Transfer, 2009, 110(13):1147-1161.
[14]	Yurkin M A, Hoekstra A G. The discrete dipole approximation_An overview and recent developments[J]. Journal of Quantitative Spectroscopy and Radiative Transfer, 2007, 106(1):558-589.
[15]	Jacques Steven L. Modeling tissue optics-using Monte Carlo modeling a tutorial[C]//SPIE, 2008, 6854:68540T.
[16]	Zuo Chenze, Lu Qieni, Ge Baozhen, et al. Impact of refractive index of aerosol particles on particle diameter optical measurement[J]. Optics and Precision Engineering, 2017, 41(7):1777-1782. (in Chinese)
[17]	Ren Lin. Effect of water capacity on cell activity and storage stability of lactobacillus plantarum starter cultures[J]. Food Science, 2009, 30(23):388-390. (in Chinese)
[18]	Luca Quaroni, Theodora Zlateva. Infrared spectromicroscopy of biochemistry in functional single cells[J]. The Analyst, 2011, 136(16):3219.
[19]	Li Lei, Bai Huimin, Weng Shifu, et al. Laboratory study for analysis of intra-tumor heterogeneity of ovarian cancer by Fourier transform infrared spectroscopy[J]. Medical Journal of Peking Union Medical College Hospital, 2017, 8(4-5):268-273. (in Chinese)
[20]	Lisa M Miller, Paul Dumas. From structure to cellular mechanism with infrared microspectroscopy[J]. Current Opinion in Structural Biology, 2010, 20(5):649-656.

Optical properties of eukaryotic and prokaryotic microbial aerosols in the 0.25-15 μm band

doi: 10.3788/IRLA201948.1017004

Abstract

References

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通讯作者: 陈斌, bchen63@163.com

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