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What is Spectroscopy? Spectroscopy is a method of understanding molecular properties by measuring the interaction of light and matter
.
By analyzing the amount of light a sample absorbs or emits, we can determine the composition, properties and volume of the sample
.
We use spectrometers for spectral analysis in basic research
.
But they are also used in applied sciences, including industrial, chemical, petrochemical, environmental, food and agriculture, metals and mining, among others
.
We use spectroscopy to study life on Earth and distant planets
.
In our daily life, we can also see spectrometers
.
Designers at home improvement stores use a simple spectrometer to analyze and match paint colors to redecorate your bedroom
.
Researchers use it to develop cancer treatments
.
Spectrometers can also help monitor oil spills and atmospheric conditions
.
Why is it so important? The benefits of spectroscopic technology are wide-ranging, from improving food quality to hunting down criminals, and it can play a role in a range of unexpected things
.
We can apply a variety of different spectroscopic techniques in almost every field of scientific research, from environmental analysis, biomedical science to space exploration
.
We'll take a deep dive into this technique, including discussions of Raman spectroscopy, molecular vibrational studies of matter, fluorescence, and excitation-emission matrices
.
The science of spectroscopy has come a long way
.
Engineers have made continuous improvements to detectors, software, and overall design, increasing measurement speed, enabling the miniaturization of spectrometers, lowering the price of the instrument, and increasing the reliability of the equipment
.
.
By analyzing the amount of light a sample absorbs or emits, we can determine the composition, properties and volume of the sample
.
We use spectrometers for spectral analysis in basic research
.
But they are also used in applied sciences, including industrial, chemical, petrochemical, environmental, food and agriculture, metals and mining, among others
.
We use spectroscopy to study life on Earth and distant planets
.
In our daily life, we can also see spectrometers
.
Designers at home improvement stores use a simple spectrometer to analyze and match paint colors to redecorate your bedroom
.
Researchers use it to develop cancer treatments
.
Spectrometers can also help monitor oil spills and atmospheric conditions
.
Why is it so important? The benefits of spectroscopic technology are wide-ranging, from improving food quality to hunting down criminals, and it can play a role in a range of unexpected things
.
We can apply a variety of different spectroscopic techniques in almost every field of scientific research, from environmental analysis, biomedical science to space exploration
.
We'll take a deep dive into this technique, including discussions of Raman spectroscopy, molecular vibrational studies of matter, fluorescence, and excitation-emission matrices
.
The science of spectroscopy has come a long way
.
Engineers have made continuous improvements to detectors, software, and overall design, increasing measurement speed, enabling the miniaturization of spectrometers, lowering the price of the instrument, and increasing the reliability of the equipment
.
