Torsional instability is a mechanical phenomenon where a structural element subjected to twisting (

torsional In the field of solid mechanics, torsion is the twisting of an object due to an applied torque. Torsion could be defined as strain or angular deformation, and is measured by the angle a chosen section is rotated from its equilibrium position. Th ...

) forces undergoes sudden deformation or failure beyond a critical

torque In physics and mechanics, torque is the rotational analogue of linear force. It is also referred to as the moment of force (also abbreviated to moment). The symbol for torque is typically \boldsymbol\tau, the lowercase Greek letter ''tau''. Wh ...

threshold. This instability is characterized by a rapid transition from stable twisting to helical

buckling In structural engineering, buckling is the sudden change in shape (Deformation (engineering), deformation) of a structural component under Structural load, load, such as the bowing of a column under Compression (physics), compression or the wrin ...

, kinking, or collapse, often observed in slender rods, beams, and architectural structures.

Examples

The Dee Bridge collapsed in 1847 after adding extra weight to the bridge in the form of rocks and gravel to reduce track vibration, but lead to a critical point of torsional instability. The Tacoma Narrows Bridge collapsed in 1940 due to specific wind conditions that were exacerbated by torsional oscillations, transitioning from vertical to destructive twisting modes. In the 1970s, occupants of the top floors of the

John Hancock Tower The John Hancock Tower, colloquially known as the Hancock, is a 60-story, skyscraper in the Back Bay neighborhood of downtown Boston, Massachusetts. The pinnacle height (including antennas) is . Designed by Henry N. Cobb of the firm I. M. Pe ...

reported feeling

motion sickness Motion sickness occurs due to a difference between actual and expected motion. Symptoms commonly include nausea, vomiting, cold sweat, headache, dizziness, tiredness, loss of appetite, and increased salivation. Complications may rarely include ...

, which was later revealed to be due to torsional instability of the building. This phenomenon is also known to happen to drill strings and pipelines, buckling under rotational loads in oil/gas extraction, as well as aircraft wings, experiencing torsional flutter under aerodynamic forces.

Mitigation strategies

A way to reduce the chance of torsional instability is by making cross-sections stiffer. This can be done by choosing shapes that naturally resist twisting, like hollow tubes or cross-shaped sections, instead of shapes like flat plates, which twist more easily. Stiffer cross-sections provide more resistance to the twisting force and help the structure remain stable. Another way is by implementing braces, which are structural components that provide extra stability and strength to a building or structure. For example, twisting a

scaffold Scaffolding, also called scaffold or staging, is a temporary structure used to support a work crew and materials to aid in the construction, maintenance and repair of buildings, bridges and all other human-made structures. Scaffolds are widely u ...

is harder than twisting a ladder because the scaffold has braces that resist twisting, making it much stiffer and more stable than the ladder. Similarly, bracing systems in a building distribute forces and provide resistance against torsion. In addition to modifying the shape and bracing, engineers can use materials to make structures stronger and lighter at the same time. These materials include composites like carbon fiber or hybrid materials that are better at resisting twisting forces than traditional steel or concrete. For example, bridges or buildings made with these materials can carry heavy loads and resist twisting without becoming overly bulky or heavy. Engineers also rely on mathematical models and computer simulations to predict how a structure will respond to torsional forces under different conditions, such as strong winds, earthquakes, or heavy traffic. These digital tools allow engineers to analyze and optimize their designs before construction begins, ensuring the structure can handle these forces while still being safe, functional, and cost-efficient.

Examples

Mitigation strategies

See also

References

Further reading