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| Laser-Induced Plant Fluorescence Lifetime Correction Technique and Its Properties Analysis |
| WAN Wen-bo, SU Jun-hong* |
| School of Optoelectronic Engineering, Xi’an Technological University, Xi’an 710021, China |
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Abstract Laser-induced chlorophyll fluorescence lifetime measurement is a novel technique for evaluating plant growth status and environmental monitoring. This method is developed on the basis of plant fluorescence spectrum analysis technique. According to the physical properties of chlorophyll fluorescence signal and information simulation technology, a laser-induced chlorophyll fluorescence lifetime correction technique for improving the chlorophyll fluorescence lifetime measurement accuracy is presented in this paper. Laser-induced plant fluorescence lifetime measurement system was used to collect the chlorophyll fluorescence and its background signal. Then, the chlorophyll fluorescence decay function can be separated from the plant fluorescence signal in deconvolution algorithm, and fluorescence lifetime estimation can be obtained. Finally, the chlorophyll fluorescence lifetime correction technique was used to retrieve the precision values of fluorescence lifetime. The results of simulation and experiment show that real-time monitoring of high-precision chlorophyll fluorescence lifetime can be achieved in this method. Based on this, a large number of different concentrations chlorophyll solution were measured, and the relationship model of chlorophyll content and the fluorescence lifetime was built. In the future, this method can be used for remote sensing to monitor the algae biomass in the ocean, lake or river.
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Received: 2017-11-27
Accepted: 2018-03-08
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Corresponding Authors:
SU Jun-hong
E-mail: sujunhong@xatu.edu.cn
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[1] Janusauskaite D, Feiziene D. Acta Agriculturae Scandinavica Section B-Soil and Plant Science, 2012, 62(1): 7.
[2] Harilal S S, LaHaye N L, Phillips M C. Optics Letters, 2016, 41(15): 3547.
[3] Rodrigues C E D, da Silva R P M, Nunes R A. Measurement, 2011, 44(1): 11.
[4] Salgado-Salazar C. Phytopathology, 2016, 106(12): 114.
[5] HAN Xiao-shuang, LIU De-qing, LUAN Xiao-ning, et al(韩晓爽,刘德庆,栾晓宁,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2016, 36(2): 445.
[6] Granum E, Perez-Bueno M L, Calderon C E, et al. European Journal of Plant Pathology, 2015, 142(3): 625.
[7] Wicaksono B, Kong H, Markova L V, Han H G. Measurement, 2013, 46(10): 4161.
[8] Biswal R, Mishra G K, Agrawal P K, et al. Applied Optics, 2013, 52(14): 3269.
[9] Fiserova E, Kubala M. Journal of Luminescence, 2012, 132(8): 2059.
[10] Henning P E, Geissinger P. Measurement Science & Technology, 2012, 23(4): 045104.
[11] Bisby R H, Botchway S W, Greetham G M, et al. Measurement Science & Technology, 2012, 23(8): 084001.
[12] Kiefer J. Optics Letters, 2016, 2016, 41(24): 5684.
[13] Kumar R, Mujumdar S. Applied Optics, 2015, 54(27): 8170.
[14] Lynch K, Scarano F. Measurement Science & Technology, 2013, 24(3): 035305.
[15] Najafi M, Zazubovich V. Journal of Physical Chemistry B, 2015, 119(25): 7911.
[16] Son S, Moon S J, Park J Y. Optics Letters, 2013, 38(22): 4578.
[17] Spiro A, Lowe M. Optics Letters, 2014, 39(18): 5362.
[18] Perez C E A, Rodrigues F A, Moreira W R, et al. Phytopathology, 2014, 104(2): 143.
[19] Torres L A, Fleck B A, Wilson D J, Nobes D S. Measurement, 2013, 46(8): 2597.
[20] Greer D H. Plant Physiology and Biochemistry, 2015, 97: 139.
[21] Correia T, Arridge S. Physics in Medicine and Biology, 2015, 61(4): 1439.
[22] Agishev R, Comeron A, Rodriguez A, et al. Applied Optics, 2014, 53(15): 3164.
[23] Bharathi S, Ratnam M M, Choong K K. Measurement, 2013, 46(2): 855.
[24] Salvatori E, Fusaro L, Gottardini E, et al. Plant Physiology and Biochemistry, 2014, 85: 105.
[25] Saito Y, Takano K, Kobayashi F, et al. Applied Optics, 2014, 53(30): 7030.
[26] Sipka G, Maroti P. Photosynthesis Research, 2016, 127(1): 61. |
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