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Related Concept Videos

Hydrogen Bonds01:04

Hydrogen Bonds

A hydrogen bond is formed when a weakly positive hydrogen atom already bonded to one electronegative atom (for example, the oxygen in the water molecule) is attracted to another electronegative atom from another polar molecule, such as water (H2O), hydrogen fluoride (HF), or ammonia (NH3). The huge electronegativity difference between the H atom (2.1) and the atom to which it is bonded (4.0 for an F atom, 3.5 for an O atom, or 3.0 for an N atom), combined with the very small size of an H atom...
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Hydrogen BondsHydrogen bonds are weak attractions between atoms that have formed other chemical bonds. One of these atoms is electronegative, like oxygen, and has a partial negative charge. The other is a hydrogen atom that has bonded with another electronegative atom and has a partial positive charge.Hydrogen Bonds Control the World!Because hydrogen has very weak electronegativity when it binds with a strongly electronegative atom, such as oxygen or nitrogen, electrons in the bond are...
Hess's Law03:40

Hess's Law

There are two ways to determine the amount of heat involved in a chemical change: measure it experimentally, or calculate it from other experimentally determined enthalpy changes. Some reactions are difficult, if not impossible, to investigate and make accurate measurements for experimentally. And even when a reaction is not hard to perform or measure, it is convenient to be able to determine the heat involved in a reaction without having to perform an experiment.
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The electrons of the outermost energy level determine the energetic stability of the atom and its tendency to form chemical bonds with other atoms. The innermost electron shell has a maximum capacity of two electrons, but the next two electron shells can each have a maximum of eight electrons. This is known as the octet rule, which states that, with the exception of the innermost shell, atoms are most stable energetically when they have eight electrons in their valence shell, the...
Van der Waals Interactions01:24

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Atoms and molecules interact with each other through intermolecular forces. These electrostatic forces arise from attractive or repulsive interactions between particles with permanent, partial, or temporary charges. The intermolecular forces between neutral atoms and molecules are ion–dipole, dipole–dipole, and dispersion forces, collectively known as van der Waals forces.Polar molecules have a partial positive charge on one end and a partial negative charge on the other end of the molecule,...

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Quantification of Hydrogen Concentrations in Surface and Interface Layers and Bulk Materials through Depth Profiling with Nuclear Reaction Analysis
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Quantification of Hydrogen Concentrations in Surface and Interface Layers and Bulk Materials through Depth Profiling with Nuclear Reaction Analysis

Published on: March 29, 2016

Potential energy surface for interactions between two hydrogen molecules.

Konrad Patkowski1, Wojciech Cencek, Piotr Jankowski

  • 1Department of Physics and Astronomy, University of Delaware, Newark, Delaware 19716, USA. patkowsk@udel.edu

The Journal of Chemical Physics
|December 3, 2008
PubMed
Summary
This summary is machine-generated.

We accurately calculated the interaction energy between two hydrogen molecules using advanced computational methods. This precise potential energy surface improves predictions of molecular behavior, like the second virial coefficient.

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Area of Science:

  • * Physical Chemistry
  • * Quantum Chemistry
  • * Computational Molecular Science

Background:

  • * Accurate potential energy surfaces are crucial for understanding intermolecular interactions.
  • * Previous calculations for hydrogen molecule interactions lacked the desired precision.

Purpose of the Study:

  • * To compute highly accurate nonrelativistic interaction energies for two ground-state hydrogen molecules.
  • * To develop a precise four-dimensional potential energy surface for H2-H2 interactions.
  • * To improve the calculation of the second virial coefficient for hydrogen.

Main Methods:

  • * Employed the supermolecular coupled-cluster method with single, double, and noniterative triple excitations [CCSD(T)].
  • * Utilized very large augmented quintuple zeta basis sets, supplemented with bond functions.
  • * Performed symmetry-adapted perturbation theory and explicitly correlated Gaussian (ECG) calculations for validation and uncertainty estimation.

Main Results:

  • * Achieved an accuracy of approximately 0.15 K (0.3%) at the potential well minimum.
  • * Calculated interaction energies with an estimated uncertainty an order of magnitude better than previous studies.
  • * The fitted potential's global minimum is -57.12 K for a T-shaped configuration at R=6.34 bohrs.

Conclusions:

  • * The developed potential energy surface is highly accurate, significantly improving upon prior work.
  • * Calculations of the second virial coefficient using this potential show substantially better agreement with experimental data.
  • * This study sets a new benchmark for the accuracy of intermolecular potential calculations for small molecules.