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Journal of Analytical & Bioanalytical Techniques | ISSN: 2155-9872 | Volume 9

World HPLC, Separation Techniques & Pharmacovigilance

World Analytical Chemistry & Mass Spectrometry

18

th

International Conference on

August 29-30, 2018 | Toronto, Canada

&

Photoacoustics spectroscopy: The less explored non-destructive spectroscopy for multicharacterization

Michael Anjello Jothi Rajan

Tamil Nadu State Council for Science & Technology, India

O

ptical spectroscopy remains a widely used and most important tool for investigating and characterizing the properties of

matter. The energy used in optical spectroscopy exists in the form of optical photons or quanta, with a wavelength ranging

from less than 1A˚ in the x-ray region to more than 10 6A˚ in the far-infrared. It is highly versatile, widely ranged and non-

destructive in nature. Optical Spectroscopy has been a scientific tool for over a century and a half and it has proven invaluable

in studies on reasonably clear media, such as solutions and crystals and on specularly reflective surfaces. There are, however,

several instances where conventional transmission spectroscopy is inadequate even for the case of clear, transparent materials.

Such a situation arises when one is attempting to measure a very weak absorption, which in turn involves the measurement of

a very small change in the intensity of a strong, essentially unattenuated, transmitted signal. Although this problem occurs for

all forms of matters, it has received particular attention in the case of transparent gas mixtures containing minute quantities

of an absorbing species or pollutant. Various techniques develop to overcome this difficulty, such as derivative spectroscopic,

have proven to generally inadequate. In addition to weakly absorbing materials, there are a great many nongaseous substances,

both organic and inorganic, that are not readily amenable to the conventional transmission or reflection modes of optical

spectroscopy. These are usually highly light-scattering materials, such as powders, amorphous solids, gels, smears and

suspensions. Other difficult materials are those that are optically opaque and have dimensions that far exceed the penetration

depth of the photons. Over the years, several techniques have been developed to permit optical investigation of highly light

– scattering and opaque substances. The most common of these are diffuse reflectance, attenuated total reflection (ATR) and

internal reflection spectroscopy and Raman scattering. All these techniques have proven to be very useful, yet each suffers from

serious limitations. In particular, each method is applicable to only a relatively small category of materials, each is useful over a

small wavelength range and the data obtained are often difficult to interpret. The modern scanning and tunneling microscopic

techniques in spite of their versatility are having inherent inadequacies and economically very costly. The photoacoustic

spectroscopy strikes a balance between the optical spectroscopy and the modern microscopic techniques in that it is relatively

cheaper, highly efficient over a wide range of wavelengths, applicable for any type of material. The newly developed electronics

technology is highly assisting the versatility of the photoacoustic spectroscopy (PAS), Ultrasonic photoacoustic microscopy

and Piezoelectric Photoacoustic microscopy (PPAM) to study the thermal and optical characteristics of any type of materials

in the micro and nanoscales. In this work, we present the thermal diffusivity measurement of Poly (methyl methacrylate)

(PMMA) - montmorillonite (MMT) clay nanocomposite by PPAM and compare it with the X-ray diffraction studies.

anjellojothi@gmail.com

J Anal Bioanal Tech 2018, Volume 9

DOI: 10.4172/2155-9872-C1-028