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Related Concept Videos

Sound as Pressure Waves01:17

Sound as Pressure Waves

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Sound waves, which are longitudinal waves, can be modeled as the displacement amplitude varying as a function of the spatial and temporal coordinates. As a column of the medium is displaced, its successive columns are also displaced. As the successive displacements differ relatively, a pressure difference with the surrounding pressure is created. The gauge pressure varies across the medium.
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Intensity and Pressure of Sound Waves01:05

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The intensity of sound waves can be related to displacement and pressure amplitudes by using their wave expressions and the definition of intensity. The critical step to achieve this is to write the power delivered by the particles on the wave as the product of force and velocity and simplify the force per unit area as the pressure. The velocity of the medium's particles can be derived from the displacement.
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Kinetic and Potential Energy of a Wave01:10

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All forms of waves carry energy; this is directly visualized in nature. For instance, the waves of earthquakes are so intense that they can shake huge concrete buildings, causing them to fall. Loud sounds can damage nerve cells in the inner ear, causing permanent hearing loss. The waves of the oceans can erode beaches. 
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Force and Potential Energy in One Dimension01:13

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Force can be calculated from the expression for potential energy, which is a function of position. The component of a conservative force, in a particular direction, equals the negative of the derivative of the corresponding potential energy with respect to the displacement in that direction. For regions where potential energy changes rapidly with displacement, the work done and force is maximum. Also, when force is applied along the positive coordinate axis, the potential energy decreases with...
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Electrostatic Boundary Conditions01:16

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Consider an external electric field propagating through a homogeneous medium. When the electric field crosses the surface boundary of the medium, it undergoes a discontinuity. The electric field can be resolved into normal and tangential components. The amount by which the field changes at any boundary is given by the difference between the field components above and below the surface boundary.
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Consider the wave equation for a sinusoidal wave moving in the positive x-direction. The wave equation is a function of both position and time. From the wave equation, two different graphs can be plotted.
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Updated: May 30, 2025

Multiscale Sampling of a Heterogeneous Water/Metal Catalyst Interface using Density Functional Theory and Force-Field Molecular Dynamics
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Noise-Tolerant Force Calculations in Density Functional Theory: A Surface Integral Approach for Wavelet-Based

Moritz Gubler1, Jonas A Finkler1,2, Stig Rune Jensen3

  • 1Department of Physics, University of Basel, Klingelbergstrasse 82, CH-4056 Basel, Switzerland.

The Journal of Physical Chemistry. A
|January 27, 2025
PubMed
Summary
This summary is machine-generated.

We present a novel method for calculating quantum mechanical forces using surface integrals of the stress tensor. This approach improves accuracy for density functional theory (DFT) calculations, especially with wavelet methods, and enhances machine-learned potentials.

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Area of Science:

  • Computational Physics
  • Quantum Chemistry
  • Materials Science

Background:

  • Traditional force calculations in Density Functional Theory (DFT) using the Hellmann-Feynman theorem can suffer from inaccuracies, particularly with advanced basis set representations like wavelets.
  • Accurate computation of forces is crucial for molecular dynamics simulations and predicting material properties.

Purpose of the Study:

  • To introduce and validate a new method for computing quantum mechanical forces in DFT.
  • To address the limitations of the Hellmann-Feynman theorem in specific computational contexts.
  • To provide accurate force data for training machine-learned potentials.

Main Methods:

  • Developed a method for calculating forces via surface integrals of the quantum mechanical stress tensor.
  • Applied the method to systems utilizing multiresolution wavelet representations of orbitals.
  • Integrated the force calculation method with machine learning techniques for potential training.

Main Results:

  • The surface integral method yields highly accurate forces, showing superior consistency with the potential energy surface compared to the Hellmann-Feynman theorem.
  • The approach demonstrates robustness and reliability, particularly for DFT with discontinuous basis sets and wavelet methods.
  • Forces computed using surface integrals are accurate enough for training machine-learned potentials, unlike those from the Hellmann-Feynman theorem.

Conclusions:

  • Surface integrals over the stress tensor provide a more accurate and reliable alternative for force computations in DFT, especially with wavelet-based methods.
  • This method overcomes key limitations of the Hellmann-Feynman theorem for specific basis sets.
  • The high accuracy of forces from surface integrals enables their effective use in developing advanced machine-learned potentials.