Gecko

Single Hair from a Gecko's Foot

Single Hair from a Gecko's Foot
The feet of the gecko cling to virtually any surface. This scanning electron microscope image shows one of the branching hairs, or setae, on the sole of a gecko's foot. These hairs nestle into nanoscale niches on the contact surface. The gecko's amazing ability to cling to vertical or inverted surfaces is due to the interaction between nanoscale structures on its feet and tiny crevices on the wall or ceiling. The soles of gecko feet are made up of overlapping adhesive lamellae covered with millions of superfine hairs, or setae, each of which branches out at the end into hundreds of spatula-shaped structures. These flexible pads—each measuring only a few nanometers across—curve to fit inside unseen cracks and divots on the surface. The combined adhesion of these millions of pads holds the gecko in place.

Minimum credit: 

Autumn Kellar, Lewis & Clark College

Size: 

Each seta measures about 200 nm.

Pixels: Width: 

2048

Pixels: Height: 

2048

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

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Nanotubes Mimicking Gecko Feet

Nanotubes Mimicking Gecko Feet
The nanoscale structures on a gecko's foot enable it to cling to most surfaces. This scanning electron microscope image shows multiwalled carbon nanotubes attached to a polymer backing, an experiment designed to replicate the gecko foot's adhesive properties. The gecko's amazing ability to cling to vertical or inverted surfaces is due to the interaction between nanoscale structures on its feet and tiny crevices on the wall or ceiling. The soles of gecko feet are made up of overlapping adhesive lamellae covered with millions of superfine hairs, or setae, each of which branches out at the end into hundreds of spatula-shaped structures. These flexible pads—each measuring only a few nanometers across—curve to fit inside unseen cracks and divots on the surface. The combined adhesion of these millions of pads holds the gecko in place.

Minimum credit: 

Ali Dhinojwala, University of Akron

This is a NISE Network product: 

no

Size: 

Each bundle of carbon nanotubes measures about 70-80 µm in width.

Pixels: Width: 

1181

Pixels: Height: 

1181

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

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Gecko Foot (8700X)

Gecko Foot (8700X)
The gecko's amazing ability to cling to vertical or inverted surfaces is due to the interaction between nanoscale structures on its feet and tiny crevices on the wall or ceiling. The soles of gecko feet are made up of overlapping adhesive lamellae covered with millions of superfine hairs, or setae, each of which branches out at the end into hundreds of spatula-shaped structures. These flexible pads—each measuring only a few nanometers across—curve to fit inside unseen cracks and divots on the surface. The combined adhesion of these millions of pads holds the gecko in place. This striking property is being studied for use in the creation of new kinds of adhesive tapes, self-dissolving bandages, and high friction materials that can support loads on smooth surfaces.

Minimum credit: 

Cliff Mathisen, FEI Company

Pixels: Width: 

493

Pixels: Height: 

522

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

Return to gallery

Gecko Foot (1660X)

Gecko Foot (1660X)
The gecko's amazing ability to cling to vertical or inverted surfaces is due to the interaction between nanoscale structures on its feet and tiny crevices on the wall or ceiling. The soles of gecko feet are made up of overlapping adhesive lamellae covered with millions of superfine hairs, or setae, each of which branches out at the end into hundreds of spatula-shaped structures. These flexible pads—each measuring only a few nanometers across—curve to fit inside unseen cracks and divots on the surface. The combined adhesion of these millions of pads holds the gecko in place. This striking property is being studied for use in the creation of new kinds of adhesive tapes, self-dissolving bandages, and high friction materials that can support loads on smooth surfaces.

Minimum credit: 

Cliff Mathisen, FEI Company

Pixels: Width: 

379

Pixels: Height: 

401

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

Return to gallery

Gecko Toe

Gecko Toe
The gecko's amazing ability to cling to vertical or inverted surfaces is due to the interaction between nanoscale structures on its feet and tiny crevices on the wall or ceiling. The soles of gecko feet are made up of overlapping adhesive lamellae covered with millions of superfine hairs, or setae, each of which branches out at the end into hundreds of spatula-shaped structures. These flexible pads—each measuring only a few nanometers across—curve to fit inside unseen cracks and divots on the surface. The combined adhesion of these millions of pads holds the gecko in place. This striking property is being studied for use in the creation of new kinds of adhesive tapes, self-dissolving bandages, and high friction materials that can support loads on smooth surfaces.

Minimum credit: 

Cliff Mathisen, FEI Company

Pixels: Width: 

1024

Pixels: Height: 

1084

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

Return to gallery

Gecko Foot

Gecko Foot
The gecko's amazing ability to cling to vertical or inverted surfaces is due to the interaction between nanoscale structures on its feet and tiny crevices on the wall or ceiling. The soles of gecko feet are made up of overlapping adhesive lamellae covered with millions of superfine hairs, or setae, each of which branches out at the end into hundreds of spatula-shaped structures. These flexible pads—each measuring only a few nanometers across—curve to fit inside unseen cracks and divots on the surface. The combined adhesion of these millions of pads holds the gecko in place. This striking property is being studied for use in the creation of new kinds of adhesive tapes, self-dissolving bandages, and high friction materials that can support loads on smooth surfaces.

Minimum credit: 

A.Dhinojwala, University of Akron

Pixels: Width: 

574

Pixels: Height: 

574

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

Return to gallery