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Related Concept Videos

Elastic Strain Energy for Shearing Stresses01:20

Elastic Strain Energy for Shearing Stresses

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As discussed in previous lessons, strain energy in a material is the energy stored when it is elastically deformed, a concept crucial in materials science and mechanical engineering. This energy results from the internal work done against the cohesive forces within the material. When a material undergoes shearing stress and corresponding shearing strain, the strain energy density, which is the energy stored per unit volume, is calculated. Within the elastic limit, where the stress is...
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Elastic Strain Energy for Normal Stresses01:22

Elastic Strain Energy for Normal Stresses

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Strain energy quantifies the energy stored within a material due to deformation under loading conditions, a fundamental concept in materials science and engineering. The strain energy can be modeled when a material is subjected to axial loading with uniformly distributed stress. In this scenario, the stress experienced by the material is the internal force divided by the cross-sectional area, and the strain induced is directly proportional to this stress through the modulus of elasticity.
If...
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Combustion Energy: A Measure of Stability in Alkanes and Cycloalkanes02:14

Combustion Energy: A Measure of Stability in Alkanes and Cycloalkanes

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The low reactivity in alkanes can be attributed to the non-polar nature of C–C and C–H σ bonds. Alkanes, therefore, were  initially termed as “paraffins,” derived from the Latin words: parum, meaning “too little,” and affinis, meaning “affinity.”
Alkanes undergo combustion in the presence of excess oxygen and high-temperature conditions to give carbon dioxide and water. A combustion reaction is the energy source in natural gas, liquified...
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Strain Energy01:13

Strain Energy

394
Strain energy is a fundamental concept in the field of materials science and structural engineering, describing the energy absorbed by a material or structure when it is deformed under load.
Consider a rod that is fixed at one end and subjected to an axial force at the free end. This axial force induces stress within the rod, leading to its elongation. As the axial force increases, so does the elongation of the rod, illustrating a direct relationship between the force applied and the resulting...
394
Strain-Energy Density01:20

Strain-Energy Density

389
Understanding the strain energy density in materials under axial load is crucial for evaluating their mechanical behavior and durability. When a rod is subjected to such a load, it elongates and stores energy, known as strain energy, as potential energy within the material. This energy is measured in terms of energy per unit volume.
In the elastic region of a material, the relationship between the stress and the strain is linear and follows Hooke's Law. The strain energy density in this...
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Conformations of Cycloalkanes02:29

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11.6K
Adolf von Baeyer attempted to explain the instabilities of small and large cycloalkane rings using the concept of angle strain — the strain caused by the deviation of bond angles from the ideal 109.5° tetrahedral value for sp3  hybridized carbons. However, while cyclopropane and cyclobutane are strained, as expected from their highly compressed bond angles, cyclopentane is more strained than predicted, and cyclohexane is virtually strain-free. Hence, Baeyer’s theory that...
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On-line Analysis of Nitrogen Containing Compounds in Complex Hydrocarbon Matrixes
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Predicting Hydrocarbon Strain Energy via a Group Equivalent Machine Learning Approach.

Jesse C Hearn1, Betsy M Rice2, Brian C Barnes2

  • 1Center for Engineering Concepts Development, Department of Mechanical Engineering, University of Maryland, College Park, Maryland 20742, United States.

The Journal of Physical Chemistry. A
|August 26, 2024
PubMed
Summary
This summary is machine-generated.

Machine learning predicts hydrocarbon strain energies using Benson group equivalents and molecular fingerprints. This approach estimates molecular properties without needing initial coordinates, aiding molecular design.

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Area of Science:

  • Computational chemistry
  • Organic chemistry
  • Machine learning

Background:

  • Strain energy quantifies molecular steric and configurational properties.
  • Estimating strain energy via quantum chemistry requires initial nuclear coordinates, often unknown in molecular design.
  • Predicting strain energy is crucial for screening and generating novel molecular candidates.

Purpose of the Study:

  • To develop a machine learning model for predicting hydrocarbon strain energies.
  • To utilize Benson group equivalents and molecular fingerprints for accurate strain energy estimation.
  • To provide a computational tool for molecular design that bypasses the need for initial structural data.

Main Methods:

  • A machine learning approach was developed using Benson group equivalents.
  • A featurization strategy combined group equivalent counts with molecular fingerprints.
  • Data were derived from electronic structure calculations on 166 synthesized strained hydrocarbons.

Main Results:

  • The study evaluated the predictive accuracy of various statistical learning methods for strain energy.
  • The developed model demonstrated effective prediction of hydrocarbon strain energies.
  • The performance merits and limitations of different machine learning models were discussed.

Conclusions:

  • Machine learning, utilizing Benson group equivalents and molecular fingerprints, offers an effective method for predicting hydrocarbon strain energies.
  • This approach facilitates molecular design by enabling strain energy estimation without requiring initial molecular coordinates.
  • The findings contribute to computational chemistry by providing a practical tool for assessing molecular properties.