In the past, ecologists were forced to actually breed flowers which featured the shapes they required or to use paper maché to create the needed shape.
Eric Octavio Campos is a graduate student at the Department of Biology Daniel Lab within the University of Washington, who earned his Bachelor’s degree in Biology from UC Berkeley where he worked with Roy Caldwell on stomatopod locomotion. His work is now focused on the interactions between floral form and behavioral choice in Manduca sexta, or the hawkmoth, and he uses 3D printed artificial flowers to quantify his findings.
Campos says the team discovered that the moths were considerably more successful when attempting to feed from the curved, rather than the flat, 3D printed flowers. The result suggests that the nocturnal hawkmoth may use touch rather than visual input to find sources of nectar.
“With their long proboscis and nocturnal habits, finding a flower’s nectar source isn’t easy for the fist-sized hawkmoths we used in our study. Imagine being given a garden hose that’s almost twice your height in length. Now imagine trying to thread the other end through a hole that’s scarcely wider than the hose itself – at dusk as the sun is setting or at night during a full moon,” Campos says. “It may seem like a silly proposition, but it’s not too far off from what night-flying hawkmoths have to contend with to get a meal.”
Eric Octavio Campos
And he adds that 3D printing is critical to the work. Campos says the technology allows his team to study animal pollinators–and their evolutionary role–by exploring the interactions between floral form and pollinator performance. The ability to manipulate “mathematically-specified flower morphology” lets the researchers investigate the role of minute, but potentially important, differences in how floral form relates to pollinator foraging.
“The trouble is that, as a scientist, I would like a quantitative way in which to investigate flower shape and its supposed [effect] on pollinator foraging ability,” Campos says. “How can I describe flower shape using numbers instead of phrases such as, ‘funnel-like’ and ‘disk-like?’ The solution that my collaborators and I settle upon was to reduce the vast complexity of floral 3-dimensional shape into as few key ‘traits’ as possible and then describe those traits using a mathematical equation. If you can do that, then you essentially have an equation for numerically specifying any imaginable flower shape that you can think of. And the beauty of such an equation is that 3D printers can be used to make a real-life sculpture of any particular combination of shape ‘traits’ specified by the equation.”
Campos says 3D printing lets the team specify aspects of floral shape like length, width at the outer edge of the petals, width of the central nectar reservoir, and the degree of curvature of the petals. They then use that data to 3D print a plastic prototype of this ‘hypothetical’ flower.
“By carefully documenting the order in which these flowers are visited, and for how long, I can gain insights into how floral shape influences pollinator foraging ability!” Campos says. “Ultimately, I hope that my data can be used down the line to investigate how (if at all) animal visitation has influenced the evolution of flower shape diversity throughout the millions of years of flowering plant history…”
The authors of the paper, Shape matters: corolla curvature improves nectar discovery in the hawkmoth Manduca sexta, Campos, Harvey Bradshaw, and Daniel Thomas, published their work in the journal Functional Ecology.
Are you aware of any other scientific investigations which rely on 3D printing? Let us know in the 3D Printed Artificial Flowers forum thread on 3DPB.com.
