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Static Equilibrium - I01:05

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A rigid body is said to be in dynamic equilibrium when both its linear and angular acceleration are zero, relative to an inertial frame of reference. This means that a body in equilibrium can be moving, but only when its linear and angular velocities are constant. A rigid body is said to be in static equilibrium when it is at rest in the selected frame of reference. The distinction between static equilibrium (e.g., a state of rest) and dynamic equilibrium (e.g, a state of uniform motion) is...
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Static Equilibrium - II01:07

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Static equilibrium is a special case in mechanics that is very important in everyday life. It occurs when the net force and the net torque on an object or system are both zero. This means that both the linear and angular accelerations are zero. Thus, the object is at rest, or its center of mass is moving at a constant velocity. However, this does not mean that no forces are acting on the object within the system. In fact, there are very few scenarios on Earth in which no forces are acting upon...
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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.
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Plastic deformation represents a fundamental concept in materials science, which explains the irreversible change in the shape of a material when it experiences stress beyond its elastic capability. This phenomenon is important in structural engineering, especially in designing and analyzing cantilever beams—structures that are securely fixed at one end and bear loads at the opposite end. When these beams are subjected to loads within their elastic range, they will return to their...
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Plastic Deformations01:14

Plastic Deformations

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It is essential to understand how structural members behave under plastic deformation when the bending stress exceeds the material's yield strength. This state of deformation permanently alters the shape of the member, in contrast to the linear elastic behavior observed before yielding. The strain at any point in the member is expressed in terms of maximum strain. Notably, the neutral axis, which coincides with the centroid during elastic bending, shifts away from the centroid under plastic...
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Problem Solving in Statics01:28

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Problem-solving in statics is a crucial aspect of engineering and physics that involves resolving issues associated with bodies in a state of equilibrium. In most cases, problem-solving requires several steps to achieve an accurate result. These steps are crucial to ensuring that the solution is accurate and practical.
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Updated: Feb 3, 2026

Fabricating Metamaterials Using the Fiber Drawing Method
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Reprogramming Static Deformation Patterns in Mechanical Metamaterials.

Larry A Danso1, Eduard G Karpov2

  • 1Department of Civil & Materials Engineering, University of Illinois, Chicago, IL 60607, USA. lappia2@uic.edu.

Materials (Basel, Switzerland)
|October 24, 2018
PubMed
Summary
This summary is machine-generated.

This study introduces an x-braced metamaterial lattice capable of reprogramming deformation patterns by utilizing bandgaps. Researchers can tune lattice properties to block or filter static deformations, enabling novel material functionalities.

Keywords:
Saint Venant’s effect reversaldeformation reprogramminglattice materialsmechanical metamaterialsstatic Raleigh wavestransformation mechanics

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Area of Science:

  • Metamaterials
  • Lattice Mechanics
  • Solid Mechanics

Background:

  • Metamaterial lattices offer tunable mechanical properties.
  • Understanding deformation decay is crucial for material design.
  • Non-local effects in lattices can lead to unique wave phenomena.

Purpose of the Study:

  • To investigate an x-braced metamaterial lattice with bandgaps in its deformation decay spectrum.
  • To develop a method for reprogramming deformation patterns in lattices.
  • To explore the design of polarizing non-local lattices.

Main Methods:

  • Development of a single mode fundamental solution using static Raleigh waves.
  • Construction of analytical displacement solutions based on polarization vectors of bandgaps.
  • Analysis of bandgap design for predicting deformation behavior.

Main Results:

  • The x-braced lattice exhibits bandgaps in its deformation decay spectrum.
  • Static boundary deformations can be completely blocked or filtered by tuning stiffness and unit-cell aspect ratio.
  • The reverse Saint Venant's edge effect (RSV) was observed, reversing deformation decay dependence on Raleigh wavenumber.

Conclusions:

  • The x-braced metamaterial lattice provides a platform for controlling deformation patterns.
  • Tunable bandgaps enable functionalities like load pattern recognition and stress alleviation.
  • Findings guide the engineering of smart materials with advanced mechanical responses.