Abstract
Aquatic insects living in fast-flowing streams have developed various types of attachment systems to resist being carried away by strong currents. Combinations of various attachment devices offer aquatic insects advantages in underwater adhesion on substrates with different surface properties. In this study, the net-winged midge (Blepharicera sp.) larvae were investigated to understand micro-/nano-structural attachment mechanisms. The hierarchical structure of insect adhesive surfaces was characterized using Optical Microscopy (OM), Scanning Electron Microscopy (SEM) and Transmission Electron Microscopy (TEM). Centrifugal measurements were also conducted to measure the critical rotational velocity at which the larvae of Blepharicera sp. can adhere to substrates with varying roughness. Commercial suckers require smooth substrate surface to maintain a pressure that is lower than the surrounding pressure for adhesion under the sucker cup while the suckers of net-winged midge larvae possess hierarchical micro-/nano-structures, which attach closely to rough surfaces underwater. Furthermore, the functions of microstructures observed on the sucker, including wrinkled surface, inward setae, outer fibers, and nick were explored and may contribute to underwater adhesion. The aligned C-shaped suckers can attach and detach effectively by closing or opening the gap. The unique microstructure and adhesion capability of such suckers could shed light on the design and synthesis of novel bio-inspired devices for reversible underwater adhesion.
Highlights
Aquatic insects living in fast-flowing streams have developed various types of attachment systems to resist being carried away by strong currents
We investigated the relationship between micro-/ nanostructures and attachment mechanisms of the Blepharicera sp. larva
Supplementary Video S1 shows that the larva of Blepharicera can move forward with one of the suckers detaching and the other five suckers attaching to the surface
Summary
Aquatic insects living in fast-flowing streams have developed various types of attachment systems to resist being carried away by strong currents. The net-winged midge (Blepharicera sp.) larvae were investigated to understand micro-/ nano-structural attachment mechanisms. Commercial suckers require smooth substrate surface to maintain a pressure that is lower than the surrounding pressure for adhesion under the sucker cup while the suckers of net-winged midge larvae possess hierarchical micro-/nano-structures, which attach closely to rough surfaces underwater. Blephariceridae (or net-winged midges) larvae from the nematocerous family are known for their sucker attachment They live in fast-flowing streams, attaching to stones by using six suction discs located on the ventral side of the body[4,5,6,7]. The net-winged midge larvae adhesion capability on varying surface roughness and the capillary force contribution have not been studied. We hope this study can provide further understanding in biological underwater adhesion and offer inspirations for novel bio-mimetic underwater attachment devices and systems
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