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Magnetic pollen replicas offer multimodal adhesion

By R&D Editors | November 22, 2013

These scanning electron microscope images show a pollen particle (left) that has been coated with iron oxide and a replica of the same particle (right) after firing at 600 C to remove the organic material and crystallize the iron oxide. Arrows point to features that were preserved by the process. Imagest: Brandon Goodwin and Ken Sandhage Researchers have created magnetic replicas of sunflower pollen grains using a wet chemical, layer-by-layer process that applies highly conformal iron oxide coatings. The replicas possess natural adhesion properties inherited from the spiky pollen particles while gaining magnetic behavior, allowing for tailored adhesion to surfaces.

By taking advantage of the native pollen grain shape and a non-natural oxide chemistry, this work provides a unique demonstration of tunable, bio-enabled multimodal adhesion. The spikes inherited from the sunflower pollen provide short range adhesion—over nanoscale distances—while the oxide chemistry provides an adhesion mode that operates over much longer distances—up to one millimeter.

The work was supported by the Air Force Office of Scientific Research, and has been accepted for publication in the journal Chemistry of Materials.

“Pollen grains are inexpensive and sustainable templates that are readily available in large quantities,” said Ken Sandhage, a prof. in the School of Materials Science and Engineering at the Georgia Institute of Technology. “Because pollen grains are already designed by nature for adhesion, we thought that it would be interesting to try to augment such natural behavior with an additional, non-natural mode of adhesion.”

Sandhage and graduate student Brandon Goodwin began by examining the microscopic shapes of several types of pollen before choosing particles from the sunflower (Helianthus annuus). The sunflower pollen grains are nearly spherical, but covered with spikes that can entangle with the hairs on bees’ legs, or adhere to surfaces via van der Waals forces at nanometer-scale distances, Sandhage explained.

The researchers washed the burr-like pollen particles with chloroform, methanol, hydrochloric acid and water to clean the surfaces and expose hydroxyl groups for chemically attaching their coating. They then applied iron oxide using an automated, layer-by-layer surface sol-gel process they had developed earlier for coating diatom shells made of silica. Reaction of the iron oxide precursor with the hydroxyl groups on the surface of the pollen particles resulted in a highly-conformal coatings.

The sol-gel process used alternating cycles of exposure to an iron (III) isopropoxide precursor solution and water to apply 30 thin layers of hematite onto the pollen. Heating the particles to 600 C then burned out the organic material from the original pollen grains and crystallized the iron oxide, leaving hollow 3-D particles. The shells were then heated again in a controlled oxygen atmosphere to convert the hematite into magnetite, which is more strongly magnetic.

“We examined individual pollen grains before and after firing, and we could see that the shape and surface features were well preserved,” said Sandhage, who is the B. Mifflin Hood Prof. in the School of Materials Science and Engineering. “The conformal nature of the coating process allowed us to generate ceramic replicas that retained even tiny surface features on the starting pollen grains.”

The adhesion properties of the magnetic pollen-shaped particles were then analyzed by graduate student Ismael Gomez and prof. Carson Meredith, both from Georgia Tech’s School of Chemical and Biomolecular Engineering. Gomez and Meredith used an atomic force microscope (AFM) tip to press the replicas onto a variety of surfaces, then measured the force required to remove them from the surfaces. They studied replica pollen adhesion to polyvinyl alcohol, polyvinyl acetate, polystyrene, silicon, nickel and neodymium-iron-boron—and compared the adhesion properties to those of the original sunflower pollen grains.

“We found that we achieved multimodal adhesion by retaining short-range van der Waals attraction, as exhibited by the native pollen, and gaining magnetic adhesion,” Sandhage said.

The layer-by-layer nature of the coating process allowed for control of the amount of magnetic material, and the magnetic properties of the pollen replicas. The researchers chose to apply 30 layers to achieve sufficient long-range magnetic behavior while retaining high-aspect-ratio, sharp spikes that provide for short-range van der Waals forces.

“Reproducibly generating large quantities of such cheap microparticles possessing high-aspect surface features over their entire particle surfaces would be quite challenging using synthetic top-down methods,” Sandhage said.

The Air Force Multidisciplinary University Research Initiative (MURI) that funded the work is aimed at both understanding adhesion in natural systems and controllably tailoring such adhesion. In future research supported by the MURI, Sandhage and Meredith plan to study other oxide materials and explore the variety of shapes available in pollen particles.

View Abstract

Source: Georgia Institute of Technology

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