Simulation and experimental investigation of turbid medium in frequency-domain photoacoustic response induced by modulated laser

•Phase of photoacoustic signal is introduced to detect depth of optical absorber inside turbid medium.•Photoacoustic pressure induced by modulated laser in turbid medium is studied in frequency-domain.•Relation between relative phase of photoacoustic signal and relative position of absorber is obtai...

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Bibliographic Details
Published in:Infrared physics & technology 2018-08, Vol.92, p.109-114
Main Authors: Liu, Yang, Meng, Xiang-Lin, Liu, Jun-Yan, Wang, Yong-Hui, Xu, Hong-Tu, Wang, Yang
Format: Article
Language:English
Subjects:
Amplitude
Frequency-domain photoacoustic
Phase
Turbid medium
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Summary:•Phase of photoacoustic signal is introduced to detect depth of optical absorber inside turbid medium.•Photoacoustic pressure induced by modulated laser in turbid medium is studied in frequency-domain.•Relation between relative phase of photoacoustic signal and relative position of absorber is obtained.•Depth of optical absorber inside the turbid medium is quantitatively detected. In this work, a one-dimensional (1D) photoacoustic mathematic model of turbid medium in frequency domain is presented, and it is derived from the theories of optical absorption and radiation transfer, thermal-wave diffusion and mechanical fluctuant effect. The theoretical simulations are carried out to analyze the effects of absorption coefficient, the relative position of the absorber on the amplitude and phase of the photoacoustic signal. A frequency – domain photoacoustic imaging system is developed to carry out the position scanning inspection experiments. At the fixed laser modulation frequency, the absorption property of the medium is detected according to the positive correlation between the amplitude of the photoacoustic signal and the absorption coefficient. Based on the relationship between the relative phase of the photoacoustic signal and the relative position of the medium, the depth of the optical absorber inside the turbid medium is quantitatively detected. The experiment results indicate that the amplitude and phase of the photoacoustic signal have high sensitivity to the optical absorption coefficient and structural characteristic parameters of the turbid medium.
ISSN:1350-4495
1879-0275
DOI:10.1016/j.infrared.2018.05.016