There are examples of art imitating nature all around us—whether it’s Monet’s pastel Water Lilies or Chihuly’s glassblown Seaforms, the human conception of natural phenomena dazzles but does not often surprise.
Yet when associate professor of physics Latika Menon peered under the electron microscope last fall, she discovered the exact opposite. Instead of art imitating nature, she found nature imitating art.
Menon grew up in the eastern region of India and was vaguely familiar with a cultural dance from the western state of Rajasthan known as the Bhavai pot dance. Nimble dancers sway their hips as a tall stack of wide-bellied pots balances gingerly atop their heads. Back in the lab at Northeastern, Menon’s team recently created gallium nitride nanowires, which bore a striking resemblance to that stack of pots.
What’s more, a postdoctoral research associate in Menon’s lab, Eugen Panaitescu, jumped on the bandwagon with a cultural art reference of his own. Panaitescu, who hails from Romania, also saw his country’s famous Endless Column reflected in the nanowires. Dedicated to the fallen Romanian heroes of World War I, Constantin Brancusi’s 96-foot-tall monolith is constructed of 17 three-dimensional rhombuses, periodically wavering from a wider circumference to a narrower one.
But the Northeastern researchers’ nanowires aren’t just notable for their aesthetic appeal. Gallium nitride is used across a range of technologies, including most ubiquitously in light emitting diodes. The material also holds great potential for solar cell arrays, magnetic semiconductors, high-frequency communication devices, and many other things. But these advanced applications are restricted by our limited ability to control the material’s growth on the nanoscale.
The very thing that makes Menon’s nanowires beautiful represents a breakthrough in her ability to process them for these novel uses. She deposited onto a silicon substrate small droplets of liquid gold metal, which act as catalysts to grab gaseous gallium nitride from the atmosphere of the experimental system. The net forces between the tiny gold droplet, the solid substrate, and the gas cause the nanowire to grow in a particular direction, she explained. Depending on the size of the gold catalyst, she can create wires that exhibit periodic serrations.