Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Static and Kinetic Frictional Force01:05

Static and Kinetic Frictional Force

16.2K
One of the simpler characteristics of sliding friction is that it is parallel to the contact surfaces between systems, and is always in a direction that opposes the motion or attempted motion of the systems relative to each other. If two systems are in contact and moving relative to one another, then the friction between them is called kinetic friction. For example, kinetic friction slows a hockey puck sliding on ice.
However, if two systems are in contact and are stationary relative to one...
16.2K
Friction: Problem Solving01:21

Friction: Problem Solving

280
Friction is an essential force that influences the motion of objects in daily life. Depending on the situation, it can be either beneficial or problematic. Consider a bus with a mass of three megagrams and its center of mass at a specific point, moving along a banked road at a constant speed. The coefficient of static friction between the tires and the road is 0.5. Find the maximum angle of the banked road at which the bus would not slip or tip.
Initially, a visual representation of the...
280
Types of Friction Problems01:27

Types of Friction Problems

642
Friction is an essential concept in physics, engineering, and everyday life. It is the force that opposes the relative motion or tendency of such motion between two surfaces in contact. One of the most common types of friction encountered in various applications is dry friction. Dry friction problems can be broadly categorized into three types, each with unique characteristics and challenges.
The first type of dry friction problem involves situations where there is no apparent impending motion....
642
Frictional Force01:07

Frictional Force

8.4K
When a body is in motion, it encounters resistance because the body interacts with its surroundings. This resistance is known as friction, a common yet complex force whose behavior is still not completely understood. Friction opposes relative motion between systems in contact, but also allows us to move. Friction arises in part due to the roughness of surfaces in contact. For one object to move along a surface, it must rise to where the peaks of the surface can skip along the bottom of the...
8.4K
Dry Friction01:30

Dry Friction

469
Dry friction occurs between two solid surfaces in contact as they attempt to move relative to one another. In daily life, dry friction is encountered in various forms, such as when walking on the ground, sliding an object across a table, or rubbing hands together. Despite its ubiquity, the underlying mechanisms behind dry friction are not readily visible.
To illustrate this concept, imagine a wooden crate resting on a rough, non-uniform horizontal surface. When an external force is applied to...
469
Static Friction01:18

Static Friction

902
Static friction is a force that opposes the relative motion or tendency of motion between two surfaces in contact. It plays a crucial role in our daily lives, from walking on the ground to driving a car.
For example, consider a scenario where a truck is connected to a car by a rope, ready to tow it along a road. When no external force is applied by the truck, the car remains stationary and is said to be in static equilibrium. In this case, the forces acting on the car, such as gravity and the...
902

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Charge accumulation and solvation in β-NiOOH: Surface chemistry of an OER catalyst from ML-aided simulations.

The Journal of chemical physics·2026
Same author

Frictional Unlocking and Energy-Controlled Constrained Densification in Nanoparticle Networks.

ACS nano·2025
Same author

Quantum paraelectricity in the H-bonded ferroelectrics KH2PO4 and KD2PO4 under pressure.

The Journal of chemical physics·2025
Same author

Thermally Activated Sliding of C<sub>60</sub> on Gold.

ACS omega·2025
Same author

The effects of disordered edge and vanishing friction in microscale structural superlubric graphite contact.

Nature communications·2024
Same author

Universal moiré buckling of freestanding 2D bilayers.

Proceedings of the National Academy of Sciences of the United States of America·2024
Same journal

Polarization-State-Dependent Charge Screening in Metal-Ferroelectric-Metal Memcapacitors Enabled by an IGZO Oxygen Reservoir Layer.

ACS applied materials & interfaces·2026
Same journal

Enabling Closed-Loop Recycling of Carbon Fiber-Reinforced Composites: A Dynamic Network Strategy Based on Cardanol-Derived Amines and Lignin-Derived Carbonates.

ACS applied materials & interfaces·2026
Same journal

Unconventional Phase Shift in Spin Hall Magnetoresistance of Antiferromagnetic Insulators.

ACS applied materials & interfaces·2026
Same journal

The Evolving Landscape of Terahertz Biosensing: From Sensitivity to Precision.

ACS applied materials & interfaces·2026
Same journal

π-π Stacking Enhanced Generation of Reactive Species in Donor-Acceptor Heterojunctions for High-Efficiency Photocatalytic Degradation of Endocrine-Disrupting Compounds under Solar Light.

ACS applied materials & interfaces·2026
Same journal

Interfacial Engineering of Frustrated Lewis Pairs for Promoting Cellulose-to-Sorbitol Cascade Conversion.

ACS applied materials & interfaces·2026
See all related articles

Related Experiment Video

Updated: Sep 16, 2025

Studying the Neural Basis of Adaptive Locomotor Behavior in Insects
10:19

Studying the Neural Basis of Adaptive Locomotor Behavior in Insects

Published on: April 13, 2011

13.0K

Can Neural Networks Learn Atomic Stick-Slip Friction?

Mahboubeh Shabani1,2, Andrea Silva3,4, Franco Pellegrini4

  • 1Department of Physics, Shahid Beheshti University, 1983969411 Tehran, Iran.

ACS Applied Materials & Interfaces
|July 9, 2025
PubMed
Summary
This summary is machine-generated.

Machine learning (ML) now interprets nanofriction force traces, automatically extracting Prandtl-Tomlinson (PT) model parameters. This approach, trained on simulations, successfully analyzes experimental data, advancing stick-slip nanofriction studies.

Keywords:
atomic stick−slipmachine learningnano tribologyneural networknonlinear friction

More Related Videos

Kinematic History of a Salient-recess Junction Explored through a Combined Approach of Field Data and Analog Sandbox Modeling
06:55

Kinematic History of a Salient-recess Junction Explored through a Combined Approach of Field Data and Analog Sandbox Modeling

Published on: August 5, 2016

8.3K
Preparation and Friction Force Microscopy Measurements of Immiscible, Opposing Polymer Brushes
13:57

Preparation and Friction Force Microscopy Measurements of Immiscible, Opposing Polymer Brushes

Published on: December 24, 2014

14.1K

Related Experiment Videos

Last Updated: Sep 16, 2025

Studying the Neural Basis of Adaptive Locomotor Behavior in Insects
10:19

Studying the Neural Basis of Adaptive Locomotor Behavior in Insects

Published on: April 13, 2011

13.0K
Kinematic History of a Salient-recess Junction Explored through a Combined Approach of Field Data and Analog Sandbox Modeling
06:55

Kinematic History of a Salient-recess Junction Explored through a Combined Approach of Field Data and Analog Sandbox Modeling

Published on: August 5, 2016

8.3K
Preparation and Friction Force Microscopy Measurements of Immiscible, Opposing Polymer Brushes
13:57

Preparation and Friction Force Microscopy Measurements of Immiscible, Opposing Polymer Brushes

Published on: December 24, 2014

14.1K

Area of Science:

  • Surface Science
  • Tribology
  • Computational Physics

Background:

  • Nanofriction experiments generate force traces with atomic stick-slip oscillations.
  • Traditional analysis relies on ad hoc algorithms, lacking standardization.

Purpose of the Study:

  • To explore machine learning (ML) for interpreting nanofriction force traces.
  • To automatically extract Prandtl-Tomlinson (PT) model parameters using ML.
  • To demonstrate the transferability of ML models from simulation to experimental data.

Main Methods:

  • A neural network (NN) perceptron was trained on synthetic force traces from simulations.
  • Physics-based descriptors were incorporated into synthetic data to improve model transferability.
  • The trained NN was applied to analyze experimental nanofriction data.

Main Results:

  • The ML model successfully analyzed experimental nanofriction force traces.
  • The NN extracted Prandtl-Tomlinson (PT) model parameters automatically.
  • Incorporating physics-based descriptors resolved transferability issues between synthetic and experimental data.

Conclusions:

  • Machine learning offers a powerful, automated approach to analyze stick-slip nanofriction.
  • Physics-informed machine learning enhances model robustness and applicability to real-world data.
  • This study provides a proof-of-concept for advanced ML applications in nanofriction research.