Transparent, thin and tough – why don’t insect wings break?

Posted on: 29 August 2012

Researchers from Trinity College Dublin have shown that the wings of insects are not as fragile as they might look. A study just published in the scientific journal PLOS ONE now shows that the characteristic network of veins found in the wings of grasshoppers helps to capture cracks, similar to watertight compartments in a ship.

“The desert locusts are the marathon-flyers of the insect world,” says Dr Jan-Henning Dirks, who studied the properties of the wings together with Professor David Taylor at the Department of Mechanical and Manufacturing Engineering. “These grasshoppers can fly for days across deserts and oceans with wings ten times thinner than a human hair”.

During these long journeys the wings of the grasshoppers have to withstand hundreds of thousands of wing beats without failure. What is their secret? 

Like all insect body parts, the wings are made from cuticle, which is the second most common natural material in the world.

“We recently showed that the cuticle of the grasshopper legs is one of the toughest natural materials in the world,” says Taylor. “Now we wanted to know whether this is true for the locust wings, too.” To measure the toughness of the wings, the team  cut small notches into the wing’s membrane and measured the force needed to drive the crack through the wing.

“We were quite surprised when our first experiments showed that the membrane of the wings alone was not very tough.” said Dirks. “We were expecting the membrane to be at least as tough as the legs.” 

However, when Dirks and Taylor then looked at the videos they recorded, they found that most cracks were effectively stopped once they ran into a cross vein. These minute crack barriers increased the wing’s toughness by 50%.  So if these veins are so good in stopping cracks, why not have more of them?

 “Compared to the thin wing membrane, the wing veins are relatively heavy. Therefore you want as few veins as possible to keep the weight of the wing low,” said Dirks. However, as the videos demonstrate, with fewer veins in the wing there’s less protection against cracks. “It’s like the watertight compartments in a ship. With too many compartments, the ship gets too heavy. With too few, a single hole can sink the entire ship.” 

To answer the question What is the optimum ratio of the membrane and the veins? The researchers studied the characteristic pattern of the wings in detail and measured the size and shape of the almost 1000 vein “cells” found in each wing. Using fracture mechanics, Dirks and Taylor then showed that the spacing of most wing veins matches the membrane’s so called “critical crack length”. At a given stress, cracks smaller than this material constant do not grow.

“Thanks to this precise spacing of the cross veins, the cracks are always stopped before they can reach this critical length and start growing themselves. ” says Taylor “Nature has found a mechanically ‘optimal’ solution for the locust wings, with a high toughness and a low weight.”

The researchers believe that the vein pattern found in insect wings thus might inspire the design of more durable and lightweight artificial ‘venous’ wings for micro-air-vehicles. And by “reversing” their analysis, one could possibly even use the vein spacing of fossil insects to study the wing properties of extinct insect species.

The manuscript “Veins improve fracture toughness of insect wings” by Dirks and Taylor is published in PLOS ONE and freely available under the open access policy at  http://dx.plos.org/10.1371/journal.pone.0043411