Measurement of the optical absorption coefficient of a liquid by use of a time-resolved photoacoustic technique

Yaochun Shen; Zuhong Lu; Stephen Spiers; Hugh A. MacKenzie; Helen S. Ashton; John Hannigan; Scott S. Freeborn; John Lindberg

Measurement of the optical absorption coefficient of a liquid by use of a time-resolved photoacoustic technique

Yaochun Shen, Zuhong Lu, Stephen Spiers, Hugh A. MacKenzie, Helen S. Ashton, John Hannigan, Scott S. Freeborn, John Lindberg

Research output: Contribution to journal › Article › peer-review

40 Citations (Scopus)

Abstract

A time-resolved photoacoustic technique has been applied to the study of dissolved and dispersed absorbers in aqueous systems. The temporal pressure profiles generated from colloidal graphite and glucose solutions were measured, and it was found that the amplitude of the photoacoustic signal of both the glucose and the colloidal graphite solutions increase linearly with concentration and that acoustic signal time delay yields the acoustic velocity. The logarithm of the photoacoustic signal amplitude changes linearly with the time delay, with a slope that is proportional to the product of the acoustic velocity and the optical absorption that can thus be determined. © 2000 Optical Society of America.

Original language	English
Pages (from-to)	4007-4010
Number of pages	4
Journal	Applied Optics
Volume	39
Issue number	22
Publication status	Published - 1 Aug 2000

Cite this

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title = "Measurement of the optical absorption coefficient of a liquid by use of a time-resolved photoacoustic technique",

abstract = "A time-resolved photoacoustic technique has been applied to the study of dissolved and dispersed absorbers in aqueous systems. The temporal pressure profiles generated from colloidal graphite and glucose solutions were measured, and it was found that the amplitude of the photoacoustic signal of both the glucose and the colloidal graphite solutions increase linearly with concentration and that acoustic signal time delay yields the acoustic velocity. The logarithm of the photoacoustic signal amplitude changes linearly with the time delay, with a slope that is proportional to the product of the acoustic velocity and the optical absorption that can thus be determined. {\textcopyright} 2000 Optical Society of America.",

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T1 - Measurement of the optical absorption coefficient of a liquid by use of a time-resolved photoacoustic technique

AU - Shen, Yaochun

AU - Lu, Zuhong

AU - Spiers, Stephen

AU - MacKenzie, Hugh A.

AU - Ashton, Helen S.

AU - Hannigan, John

AU - Freeborn, Scott S.

AU - Lindberg, John

PY - 2000/8/1

Y1 - 2000/8/1

N2 - A time-resolved photoacoustic technique has been applied to the study of dissolved and dispersed absorbers in aqueous systems. The temporal pressure profiles generated from colloidal graphite and glucose solutions were measured, and it was found that the amplitude of the photoacoustic signal of both the glucose and the colloidal graphite solutions increase linearly with concentration and that acoustic signal time delay yields the acoustic velocity. The logarithm of the photoacoustic signal amplitude changes linearly with the time delay, with a slope that is proportional to the product of the acoustic velocity and the optical absorption that can thus be determined. © 2000 Optical Society of America.

AB - A time-resolved photoacoustic technique has been applied to the study of dissolved and dispersed absorbers in aqueous systems. The temporal pressure profiles generated from colloidal graphite and glucose solutions were measured, and it was found that the amplitude of the photoacoustic signal of both the glucose and the colloidal graphite solutions increase linearly with concentration and that acoustic signal time delay yields the acoustic velocity. The logarithm of the photoacoustic signal amplitude changes linearly with the time delay, with a slope that is proportional to the product of the acoustic velocity and the optical absorption that can thus be determined. © 2000 Optical Society of America.

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M3 - Article

SN - 1559-128X

VL - 39

SP - 4007

EP - 4010

JO - Applied Optics

JF - Applied Optics

IS - 22

ER -

Measurement of the optical absorption coefficient of a liquid by use of a time-resolved photoacoustic technique

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