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Related Concept Videos

Raman Spectroscopy: Overview01:20

Raman Spectroscopy: Overview

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The underlying principle of Raman spectroscopy is based on the interaction between light and matter, specifically molecules' inelastic scattering of photons. When a monochromatic beam of light, typically from a laser source, interacts with a sample, most scattered light has the same frequency as the incident light. This is known as Rayleigh scattering.
However, a small fraction of the scattered light exhibits a frequency shift due to the exchange of energy between the incident photons and...
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Raman Spectroscopy Instrumentation: Overview01:26

Raman Spectroscopy Instrumentation: Overview

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A conventional Raman spectrophotometer includes a laser source, a sample holding system, a wavelength selector, and a detector.
The monochromatic laser source, typically using visible or near-infrared radiation, generates a highly focused beam of light. This light interacts with the molecules of the sample, scattering some of the light. Liquid and gaseous samples are usually tested in ordinary glass capillaries, while solids can be analyzed as powders packed in capillaries or as potassium...
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Atomic Absorption Spectroscopy: Atomization Methods01:25

Atomic Absorption Spectroscopy: Atomization Methods

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Atomic Absorption Spectroscopy (AAS) atomizes samples through flame atomization or electrothermal atomization. Flame atomization typically involves a nebulizer and spray chamber assembly to combine the sample with a fuel–oxidant mixture, creating a fine aerosol mist that enters a burner. Typically, the fuel and oxidant are combined in an approximately stoichiometric ratio. However, for atoms that are easily oxidized, a fuel-rich mixture may be more advantageous. Only about 5% of the...
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IR Spectroscopy: Hooke's Law Approximation of Molecular Vibration01:16

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A covalently bonded heteronuclear diatomic molecule can be modeled as two vibrating masses connected by a spring. The vibrational frequency of the bond can be expressed using an equation derived from Hooke's law, which describes how the force applied to stretch or compress a spring is proportional to the displacement of the spring. In this case, the atoms behave like masses, and the bond acts like a spring.
According to Hooke's law, the vibrational frequency is directly proportional to...
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Atomic Absorption Spectroscopy: Lab01:21

Atomic Absorption Spectroscopy: Lab

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For AAS measurements, samples must be introduced as clear solutions, often requiring extensive preliminary treatment to dissolve materials like soils, animal tissues, and minerals. Common methods for sample preparation include treatment with hot mineral acids, wet ashing, combustion in closed containers, high-temperature ashing, or fusion with reagents.
 Solutions containing organic solvents, such as low-molecular-mass alcohols, esters, or ketones, enhance absorbances by increasing...
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Atomic Absorption Spectroscopy: Instrumentation01:22

Atomic Absorption Spectroscopy: Instrumentation

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An atomic absorption spectrophotometer (AAS) comprises several components: a radiation source, an atomizer, a monochromator, and a detector. The radiation source can be a hollow-cathode lamp (HCL) or an electrodeless-discharge lamp (EDL), both of which provide a narrow emission line of the required wavelength. However, some instruments use continuum sources and high-resolution monochromators to achieve a narrow range of radiation.
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A Novel Technique for Raman Analysis of Highly Radioactive Samples Using Any Standard Micro-Raman Spectrometer
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Revisiting spontaneous Raman scattering for direct oxygen atom quantification.

A W van de Steeg, L Vialetto, A F Silva

    Optics Letters
    |April 30, 2021
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    This summary is machine-generated.

    This study reveals oxygen atom Raman activity can measure absolute gas densities. Researchers used carbon dioxide microwave plasma to determine accurate cross sections for oxygen atom transitions.

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    Area of Science:

    • Atomic Physics
    • Plasma Science
    • Spectroscopy

    Background:

    • The Raman activity of oxygen atoms is largely unexplored for quantitative measurements.
    • Accurate methods are needed to determine absolute densities in gases with oxygen atoms.

    Purpose of the Study:

    • To evaluate the potential of oxygen atom Raman activity for determining absolute gas densities.
    • To establish accurate cross sections for specific oxygen atom transitions ($^3P_2 o ^3P_1$ and $^3P_2 o ^3P_0$).

    Main Methods:

    • Utilized carbon dioxide microwave plasma to create a self-calibrating gas mixture.
    • Employed Raman spectroscopy to measure cross sections for oxygen atom transitions.
    • Validated stoichiometric conservation using a 1D fluid model.

    Main Results:

    • Measured cross sections: $\sigma_{J=2\to1} = 5.27 \pm _{sys:0.53}^{rand:0.17} \times 10^{-31}\;cm^2/sr$ and $\sigma_{J=2\to0} = 2.11 \pm _{sys:0.21}^{rand:0.06} \times 10^{-31}\;cm^2/sr$.
    • Achieved a detection limit of $1 \times 10^{15}\;cm^{-3}$ in systems without other scattering species.

    Conclusions:

    • Oxygen atom Raman activity is a viable method for determining absolute densities in oxygen-containing gases.
    • The established cross sections provide a foundation for future quantitative Raman spectroscopy of oxygen atoms.