2.7 Raman spectroscopy Principle: Raman spectroscopy is based on the use of a laser light to induce oscillation and rotation in human fluids containing glucose. Because the emission of scattered light is influenced by molecular vibration‚ it is possible to estimate glucose concentration in human fluids [24]. This effect depends on the concentration of the glucose molecules. This technique can measure very weak signals‚ even in human fluids. The wavelength range of Raman spectrum is considered to
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Micro-Raman Spectroscopy Raman spectroscopy is a micro-analytical method that showed many advantages in analysis of cultural heritage materials. It is a form of vibrational spectroscopy that allows the identification of particles in homogeneous materials in the micron order. The identification is employed on the basis of the molecular vibrational spectra of samples‚ obtained by excitation with visible laser light. In micro-Raman spectroscopy‚ the laser beam is focused by means of a microscope
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Raman Effect : Raman scattering or the Raman effect ( /ˈrɑːmən/) is the inelastic scattering of a photon. It was discovered by Sir Chandrasekhara Venkata Raman and Kariamanickam Srinivasa Krishnan in liquids‚[1] and by Grigory Landsberg and Leonid Mandelstam in crystals.[2][3] When light is scattered from an atom or molecule‚ most photons are elastically scattered (Rayleigh scattering)‚ such that the scattered photons have the same energy (frequency) and wavelength as the incident photons. However
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Raman Amplifier Introduction Basic Raman Concept High Power Raman Fiber Lasers Raman Fiber Amplifier Combining EDFA and Raman Amplifier Conclusion January 8‚ 2008 Y. Lin: Raman Amplifier 1 Introduction Raman Amplifier was demonstrated in the 1980s Unavailability of high-power diode laser pump source Why do you need it : amplify signals from 1270 to 1670 nm any optical fiber can serve as the amplifying medium Raman process itself provides high-power laser Disadvantage:
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2 UV-Vis Spectroscopy 1.3 Fluorescence Spectroscopy 1.4 Atomic Spectrometric Methods CHAPTER 2 Methodology 14 2.1 UV-Vis Spectroscopy 2.2 Fluorescence Spectroscopy 2.3 Atomic Spectrometric Methods CHAPTER 3 Results and Data Analysis 18 3.1 UV-Vis Spectroscopy 3.2 Fluorescence Spectroscopy 3.3 Atomic Spectrometric Methods CHAPTER 4 Discussions and Problem Solving 33 4.1 UV-Vis Spectroscopy 4.2 Fluorescence Spectroscopy 4.3 Atomic
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Infrared Spectroscopy Organic Chemistry Lab 301A B. The purpose of this lab is to study Infrared Spectroscopy‚ which focuses on the study of the electromagnetic spectrum. The area to be studied is the infrared region‚ which is made up of gamma‚ X‚ and UV rays. We want to be able to identify spectra’s to their complementary structures. The background of this experiment particularly deals with the study of compound structure determination‚ and traits. We must be aware of the functional groups
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Infrared Spectroscopy: Fundamentals and Applications 2.3.6 Advantages 2.3.7 Computers 2.3.8 Spectra 2.4 Transmission Methods 2.4.1 Liquids and Solutions 2.4.2 Solids 2.4.3 Gases 2.4.4 Pathlength Calibration 2.5 Reflectance Methods 2.5.1 Attenuated Total Reflectance Spectroscopy 2.5.2 Specular Reflectance Spectroscopy 2.5.3 Diffuse Reflectance Spectroscopy 2.5.4 Photoacoustic Spectroscopy 2.6 Microsampling Methods 2.7 Chromatography–Infrared Spectroscopy 2.8 Thermal Analysis–Infrared Spectroscopy 2.9 Other
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Dr. C.V. Raman was born on November 7‚ 1888 in an orthodox South Indian Brahmin family in tirchurappalli‚ Tamilnadu. His father’s name was Chandra Shekhar Aiyer who had special interest in science and mathematics. His mother Parvati was a pious lady. Raman was a very brilliant student since his early childhood He passed his matriculation at the age of 11 and at 15 graduated from the Presidency College‚ Chennai. He was the only student to get a first class. He completed his Master’s degree in Physics
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Spectrophotometry. Spectroscopy‚ and the Spectrometer Spectroscopy is the branch of science concerned with the investigation and measurement spectra produced when mater interacts with or emits electromagnetic radiation Meanwhile‚ spectrophotometry is the measurement of color in a solution by determining the amount of light absorbed in the ultraviolet‚ infrared‚ or visible spectrum. A spectrophotometer is an instrument often used to compare the intensity of light from a regulated or standard
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BEER’S LAW EXPERIMENT 3 Amanda Buchanan – September 20‚ 2015 Chemistry 1212 – Section 50 OBJECTIVES: The objectives of this experiment are to understand why and how spectroscopy is used to determine the components and concentrations of a solution‚ describe various types of spectroscopy‚ describe the visible and ultraviolet regions of the electromagnetic spectrum‚ define Beer’s law and define the relationship between absorbance and transmittance. Other learning objectives are to create a Beer’s
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