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Related Concept Videos

IR Spectroscopy: Hooke's Law Approximation of Molecular Vibration01:16

IR Spectroscopy: Hooke's Law Approximation of Molecular Vibration

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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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IR Spectroscopy: Molecular Vibration Overview01:24

IR Spectroscopy: Molecular Vibration Overview

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When Infrared (IR) radiation passes through a covalently bonded molecule, the bonds transition from lower to higher vibrational levels. The fundamental vibrational motions that result in infrared absorption can be classified as stretching or bending vibrations.
Stretching vibrations are vibrational motions that occur along the bond line, changing the bond length or distance between two bonded atoms. They are further distinguished as symmetric or asymmetric. In symmetric stretching, the...
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Infrared (IR) Spectroscopy: Overview01:09

Infrared (IR) Spectroscopy: Overview

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When electromagnetic radiation passes through a material, atoms or molecules transition from a lower to a higher energy state by absorbing radiation corresponding to the energy difference between the two states. The absorption of infrared (IR) radiation causes transitions between vibrational energy levels in a molecule. Therefore, IR spectroscopy is a useful analytical tool for determining the molecular structure of molecules.
Different compounds display unique properties due to their...
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Applications of IR Spectroscopy: Overview01:11

Applications of IR Spectroscopy: Overview

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The non-destructive nature and ability to provide valuable chemical information make IR spectroscopy a versatile technique with broad applications in various scientific and industrial fields. IR spectroscopy is commonly used to identify and characterize organic and inorganic compounds. It provides information about the functional groups present in a molecule and the bonding between atoms. This helps in the structural elucidation of compounds during organic synthesis, pharmaceutical research,...
1.9K
IR Frequency Region: Fingerprint Region01:03

IR Frequency Region: Fingerprint Region

1.8K
IR spectra are divided into two main regions: the diagnostic region and the fingerprint region. The diagnostic region of the spectrum lies above 1500 cm−1. The absorptions resulting from single-bond vibrations of the N–H, C–H, and O–H stretch at higher wavenumbers and appear on the left side of the spectrum. The stretching absorptions of the C≡C and C≡N occur between 2100–2300 cm−1. In contrast, those arising from stretching absorptions of the...
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Molecular Spectroscopy: Absorption and Emission01:14

Molecular Spectroscopy: Absorption and Emission

4.3K
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.
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Related Experiment Video

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O-cresol Concentration Online Measurement Based On Near Infrared Spectroscopy Via Partial Least Square Regression
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Toward Complete Molecular Structure Prediction from Infrared Spectroscopy Using Deep Learning.

Colin Zhang1,2, Yang Ha2

  • 1Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, United States.

Journal of Chemical Information and Modeling
|December 17, 2025
PubMed
Summary
This summary is machine-generated.

We developed a deep learning model to predict molecular structures from Infrared (IR) spectra. This AI approach aids in solving complex chemical structures, improving upon traditional methods in analytical chemistry.

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Area of Science:

  • Analytical Chemistry
  • Computational Chemistry
  • Machine Learning

Background:

  • Infrared (IR) spectroscopy is vital for determining molecular structures.
  • Interpreting complex spectra with overlapping peaks is challenging, even for experts.
  • Previous machine learning efforts focused on functional groups, not complete structures, due to data limitations.

Purpose of the Study:

  • To develop a deep learning model for predicting complete molecular structures from IR spectra.
  • To address the challenge of spectral ambiguity in complex organic compounds.
  • To automate molecular structure elucidation using only spectral data.

Main Methods:

  • A dual-loss deep learning architecture, inspired by image-captioning models, was proposed.
  • A dataset of over 17,000 IR spectra was generated using quantum mechanical density functional theory calculations.
  • The model predicts molecular structures as Simplified Molecular Input Line Entry System (SMILES) strings.

Main Results:

  • The best model achieved 16.26% accuracy in predicting complete molecular structures in a single attempt on an unseen test set.
  • The model demonstrated up to 88% accuracy in regenerating individual functional groups.
  • The dual loss function effectively learned chemical properties from both spectral data and SMILES strings.

Conclusions:

  • Deep learning offers a promising approach to enhance IR spectroscopy for molecular structure determination.
  • This AI-driven method has potential applications in analytical chemistry, medicine, and other scientific fields.
  • The study highlights the capability of AI to overcome limitations in spectral interpretation.