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Related Concept Videos

Potential Energy00:52

Potential Energy

42.7K
The energy stored by a structure and location of matter in space is called potential energy. For instance, raising a kettlebell changes its spatial location and increases its potential energy. Similarly, a stretched rubber band contains potential energy which, under certain conditions, can be converted into other forms of energy, such as kinetic energy.
Chemical bonds that form attractive forces between atoms also contain potential energy, called chemical energy. When a chemical reaction...
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Potential Energy01:09

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A conservative force, such as a gravitational or elastic force, gives the body the capacity to do work. This capacity, measured as the potential energy, depends on the body's location or “position” relative to a fixed reference position or datum. The gravitational potential energy is considered zero at the reference point. Suppose a body is located at some vertical distance above a fixed horizontal reference or datum. In that case, the weight of the body has positive gravitational potential...
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On comparing the reactivity of silver and lead, it is observed that the two ionic species, Ag+ (aq) and Pb2+ (aq), show a difference in their redox reactivity towards copper: the silver ion undergoes spontaneous reduction, while the lead ion does not. This relative redox activity can be easily quantified in electrochemical cells by a property called cell potential. This property is commonly known as cell voltage in electrochemistry, and it is a measure of the energy which accompanies the charge...
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Thermodynamics of a Redox Reaction
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Suppose a positive test charge moves away from a positive static charge, then the Coulomb force does positive work, and its electric potential energy decreases. The potential energy per unit charge is defined as the electric potential. The electric potential is independent of the test charge.
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Improving Robustness and Training Efficiency of Machine-Learned Potentials by Incorporating Short-Range Empirical

Zihan Yan1,2, Zheyong Fan3, Yizhou Zhu2,4

  • 1School of Materials Science and Engineering, Zhejiang University, Hangzhou, Zhejiang 310058, China.

Journal of Chemical Information and Modeling
|January 29, 2026
PubMed
Summary
This summary is machine-generated.

This study introduces a hybrid machine learning force field (MLFF) approach that improves the robustness and efficiency of materials modeling. By integrating short-range repulsion, it prevents unphysical atom clustering in simulations, enabling accurate analysis of materials like LLZO.

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Area of Science:

  • Materials Science
  • Computational Chemistry
  • Condensed Matter Physics

Background:

  • Machine learning force fields (MLFFs) are crucial for molecular dynamics simulations.
  • Current MLFFs struggle with accuracy and robustness due to limited training data, especially for rare events.
  • This deficiency hinders reliable, long-timescale simulations of complex materials.

Purpose of the Study:

  • To develop a more robust and training-efficient MLFF framework.
  • To address the limitations of purely data-driven MLFFs in capturing essential short-range interactions.
  • To enable stable, long-timescale simulations for materials like solid electrolytes.

Main Methods:

  • Implemented a hybrid MLFF by integrating an empirical short-range repulsive potential.
  • Utilized lithium lanthanum zirconium oxide (Li$_{7}$La$_{3}$Zr$_{2}$O$_{12}$ or LLZO) as a model system.
  • Compared the performance of the hybrid MLFF against purely data-driven MLFFs in extended simulations.

Main Results:

  • Purely data-driven MLFFs exhibited unphysical atom clustering in LLZO simulations due to insufficient short-range repulsion.
  • The hybrid MLFF successfully prevented these artifacts, enabling stable, long-time molecular dynamics simulations.
  • The hybrid approach demonstrated high performance with minimal training data (25 configurations) and reduced active learning needs.

Conclusions:

  • The hybrid MLFF framework offers a universal paradigm for developing robust and efficient force fields for complex materials.
  • Integrating physics-driven constraints with data-driven flexibility enhances MLFF reliability.
  • This approach is compatible with existing MLFF architectures and critical for accurate materials modeling.