Difference between revisions of "Excitation emission matrix (EEM)"
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− | [[File: | + | [[File:MFA EEM.jpg|thumb|EEM analysis of colorants using an Agilent Cary Eclipse Spectrometer with a fiber optic probe at the MFA lab (MFA.org)]] |
== Description == | == Description == | ||
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The Excitation Emission Matrix (EEM) is a specific measurement that is becoming more widely used within the field of fluorescence spectroscopy. In a typical fluorescence (emission) measurement, the excitation wavelength is fixed and the detection wavelength varies, while in a fluorescence excitation measurement the detection wavelength is fixed and the excitation wavelength is varied across a region of interest. An emission map is measured by recording the emission spectra resulting from a range of excitation wavelengths and combining them all together. This compilation is a three dimensional scan that results can best be represented as a contour plot of excitation wavelength vs. emission wavelength vs. fluorescence intensity. | The Excitation Emission Matrix (EEM) is a specific measurement that is becoming more widely used within the field of fluorescence spectroscopy. In a typical fluorescence (emission) measurement, the excitation wavelength is fixed and the detection wavelength varies, while in a fluorescence excitation measurement the detection wavelength is fixed and the excitation wavelength is varied across a region of interest. An emission map is measured by recording the emission spectra resulting from a range of excitation wavelengths and combining them all together. This compilation is a three dimensional scan that results can best be represented as a contour plot of excitation wavelength vs. emission wavelength vs. fluorescence intensity. | ||
+ | [[File:Derrick Fluorescence reds max.jpg|thumb|Fluorescence excitation and emission maxima for some organic reds (MFA)]] | ||
+ | [[File:MFA EEM reds on print.jpg|thumb|3-dimensional EEM spectra of pink and red colorants on a Japanese print by Harunobu ([https://collections.mfa.org/objects/481262/yoshiwara-bijin-awase-the-beautiful-women-of-the-yoshiwara?ctx=6b7a658d-e4f5-4260-bc54-d720a1d30e0d&idx=4 MFA # 2006.1537.2)]]] | ||
− | + | Excitation can occur at many wavelengths. When we set the instrument to scan through several excitation wavelengths, we can determine which wavelength excites the most molecules to fluoresce. This is called the Excitation maxima. Exposing the compound to this maximum excitation wavelength we can measure the emission curve The point with the highest emission is called the Emission max. For these three reds shown in the plot, their Excitation and Emission maxima are distinctly different. Additionally, the maxima that the emission for safflower is in the yellow region, madder is in the orange region, and sappanwood is in the red region. | |
− | Excitation can occur at many wavelengths. When we set the instrument to scan through several excitation wavelengths, we can determine which wavelength excites the most molecules to fluoresce. This is called the Excitation maxima. | ||
− | Exposing the compound to this maximum excitation wavelength we can measure the emission curve | ||
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− | + | THE MFA Scientific lab EEM instrument is set to step through the excitation wavelengths every 10 nm and collects a full emission curve at each excitation wavelength. So Instead of looking at the single line plots, we usually plot a contour map that provides the full data in the form of a three dimensional plot were the excitation wavelength is given on the vertical axis and the emission wavelength on the horizontal access. The intensity of the absorption or emission is given by the color with dark red being the most intense. The angled bar on the plot is where the excitation and emission wavelengths are identical, thus the detector is saturated at these points. | |
− | the full data in the form of a three dimensional plot were the excitation wavelength is given on the vertical axis and the emission wavelength on the horizontal access. The intensity of the absorption or emission is given by the color with dark red being the most intense. The angled bar on the plot is where the excitation and emission wavelengths are identical, thus the detector is saturated at these points. | ||
== Synonyms and Related Terms == | == Synonyms and Related Terms == | ||
EEM; Excitation-emission matrix spectroscopy; Fluorescence spectroscopy; Fluorimetry; Spectrofluorimetry | EEM; Excitation-emission matrix spectroscopy; Fluorescence spectroscopy; Fluorimetry; Spectrofluorimetry | ||
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+ | ==Additional Images== | ||
+ | <gallery> | ||
+ | File:Excitation Emission Matrix Horiba.jpg|Excitation Emission Matrix plot from Horiba: [https://www.horiba.com/int/scientific/technologies/fluorescence-spectroscopy/what-is-an-excitation-emission-matrix-eem/ EEM] | ||
+ | File:Derrick Fluorescence red comparison.jpg|3-dimensional contour plots for some organic reds; (MFA) | ||
+ | File:MFA EEM yellow 3D.jpg|thumb|3-D EEM spectra for some common yellow colorants; (MFA) | ||
+ | </gallery> | ||
==Resources and Citations== | ==Resources and Citations== |
Latest revision as of 07:35, 17 November 2023
Description
The Excitation Emission Matrix (EEM) is a specific measurement that is becoming more widely used within the field of fluorescence spectroscopy. In a typical fluorescence (emission) measurement, the excitation wavelength is fixed and the detection wavelength varies, while in a fluorescence excitation measurement the detection wavelength is fixed and the excitation wavelength is varied across a region of interest. An emission map is measured by recording the emission spectra resulting from a range of excitation wavelengths and combining them all together. This compilation is a three dimensional scan that results can best be represented as a contour plot of excitation wavelength vs. emission wavelength vs. fluorescence intensity.
Excitation can occur at many wavelengths. When we set the instrument to scan through several excitation wavelengths, we can determine which wavelength excites the most molecules to fluoresce. This is called the Excitation maxima. Exposing the compound to this maximum excitation wavelength we can measure the emission curve The point with the highest emission is called the Emission max. For these three reds shown in the plot, their Excitation and Emission maxima are distinctly different. Additionally, the maxima that the emission for safflower is in the yellow region, madder is in the orange region, and sappanwood is in the red region.
THE MFA Scientific lab EEM instrument is set to step through the excitation wavelengths every 10 nm and collects a full emission curve at each excitation wavelength. So Instead of looking at the single line plots, we usually plot a contour map that provides the full data in the form of a three dimensional plot were the excitation wavelength is given on the vertical axis and the emission wavelength on the horizontal access. The intensity of the absorption or emission is given by the color with dark red being the most intense. The angled bar on the plot is where the excitation and emission wavelengths are identical, thus the detector is saturated at these points.
Synonyms and Related Terms
EEM; Excitation-emission matrix spectroscopy; Fluorescence spectroscopy; Fluorimetry; Spectrofluorimetry
Additional Images
Excitation Emission Matrix plot from Horiba: EEM
Resources and Citations
- Wikipedia: Fluorescence spectroscopy
- Horiba: EEM