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Related Concept Videos

UV–Vis Spectrometers01:14

UV–Vis Spectrometers

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The absorbance of UV and visible (UV–visible) radiations is measured using a UV–visible spectrophotometer. Deuterium lamps, which emit UV radiation, and tungsten lamps, which produce radiation in the visible region, are used as light sources in UV–visible spectrophotometers. A monochromator or prism is used for diffraction grating, i.e., to split the incoming radiation into different wavelengths. A system of slits is used to focus the desired wavelength on the sample cell.
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IR Spectrum01:19

IR Spectrum

1.3K
When infrared (IR) radiation passes through a molecule, the bonds stretch or bend by absorbing the radiation. This absorption creates the molecule's absorption spectrum, which is the plot of its percentage transmittance versus wavenumber.
Transmittance is defined as the ratio of the radiant power passing through a sample to that from the radiation's source. Multiplying the transmittance by 100 gives the percent transmittance (%T), which varies between 100% (no absorption) and 0%...
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UV–Vis Spectrum01:30

UV–Vis Spectrum

1.3K
When light passes through a substance, a portion of the light is absorbed while the remaining light is reflected or transmitted. If the molecule absorbs light between the wavelengths of 180–400 nm range, the UV spectrum is obtained, and if it absorbs light in the 400–780 nm wavelength range, the visible spectrum is obtained.     
The UV–Vis spectrum of a molecule is the plot of its absorbance versus wavelength. The plot is drawn by taking molar...
1.3K
Molecular Spectroscopy: Absorption and Emission01:14

Molecular Spectroscopy: Absorption and Emission

3.4K
Molecules possess discrete energy levels called quantum states. Unlike atoms, which have simpler energy levels, molecules possess additional rotational and vibrational energy levels.  Each energy level is separated by an energy gap, with the gaps between adjacent electronic, vibrational, and rotational levels varying significantly. The three types of energy levels in a diatomic molecule are shown in Figure 1.
3.4K
¹³C NMR: ¹H–¹³C Decoupling01:04

¹³C NMR: ¹H–¹³C Decoupling

1.2K
The probability of having two carbon-13 atoms next to each other is negligible because of the low natural abundance of carbon-13. Consequently, peak splitting due to carbon-carbon spin-spin coupling is not observed in spectra. However, protons up to three sigma bonds away split the carbon signal according to the n+1 rule, resulting in complicated spectra.
A broadband decoupling technique is used to simplify these complex, sometimes overlapping, signals. Broadband decoupling relies on a...
1.2K
UV–Vis Spectroscopy of Conjugated Systems01:32

UV–Vis Spectroscopy of Conjugated Systems

7.3K
Organic compounds with conjugated double bonds show strong absorption features in the UV–visible region of the electromagnetic spectrum attributed to π → π* electronic excitations. Generally, a UV–vis absorption spectrum is recorded as a plot of absorbance vs wavelength. The wavelength of maximum absorbance, which manifests as a peak in the absorption spectrum, is denoted as λmax.
One of the factors influencing λmax is the extent...
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Broadband absorption spectrum processing method based on end-to-end deep learning networks.

Haoyong Li, Hai Zhong, Dahua Gao

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    |August 12, 2025
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    Summary
    This summary is machine-generated.

    This study introduces a fast neural network method for analyzing absorption spectra, significantly reducing processing time. The novel approach enhances real-time applications in engine temperature measurement and material design.

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    Area of Science:

    • Spectroscopy
    • Artificial Intelligence
    • Chemical Engineering

    Background:

    • Absorption spectrum analysis is crucial for applications like engine temperature measurement and material design.
    • Current methods for processing absorption spectra are slow and complex, hindering real-time applications.
    • Existing techniques involve multiple steps including filtering, denoising, baseline correction, and database comparison.

    Purpose of the Study:

    • To develop a rapid and accurate method for processing absorption spectra.
    • To overcome the limitations of traditional, time-consuming spectral analysis techniques.
    • To enable real-time online processing of absorption spectrum data.

    Main Methods:

    • A novel neural network architecture combining Long Short-Term Memory (LSTM) and Fully Convolutional Network (FCN) was designed.
    • The neural network directly processes unprocessed absorption spectra without requiring pre-processing steps.
    • The method was tested for temperature processing of H2O and CO2 absorption spectra.

    Main Results:

    • The proposed neural network method achieved a 98.4% accuracy rate for H2O and CO2 temperature processing.
    • The average processing time per absorption spectrum was 0.00036 seconds, representing a significant speed improvement.
    • The method demonstrated high accuracy and unprecedented processing speed for absorption spectra.

    Conclusions:

    • The developed neural network method offers a highly accurate and extremely fast solution for absorption spectrum analysis.
    • This approach has significant potential for real-time online applications in various scientific and engineering fields.
    • The combination of LSTM and FCN networks effectively addresses challenges in spectral feature extraction and processing accuracy.