Tiny motors show it takes a ’tilt’ to swim upstream

Swimming upstream isn't easy, but a specific head tilt motion can make it easier, new research with nano-sized motors shows.

James Devitt-NYU • futurity
Oct. 29, 2019 4 minSource

A salmon swims in a shallow river

Swimming upstream, and against a current, involves a front-first downward tilt and then moving along a surface, new research shows.

Researchers created “nano-motors” to uncover this effective means of locomotion under such conditions.

The findings and creation of the tiny motors offer new insights into the nature of movement in fluids and have implications for engineering, the researchers say.

“These nano-motors not only helped us better understand the nature of moving against flows at the tiny scales we can’t easily see, but also could be the first step in developing smart material and robotic systems in the microscopic world,” says Jun Zhang, a professor of physics and mathematics at New York University and a coauthor of the paper, which appears in the journal Physical Review Letters.

Small nano-motors move against a current, swimming upstream
Nano-motors of micron-meter size, made of platinum and gold, propel themselves against a flow (big arrows on channel walls) that contains hydrogen peroxide. Random thermal jiggling from the fluid molecules disturbs the motors’ motion, but the long-gold motors (pullers) still maintains a relatively straight trajectory because its steeper tilt helps it align more easily against the flow and hence move upstream. (Credit: Yan-Peng Liu)

“While this effect of movement has long been known, our work offers a comprehensive explanation for it, which enhances our understanding of this widespread dynamic,” adds coauthor Michael Shelley, a professor at the Courant Institute of Mathematical Sciences.

The researchers, including first author Quentin Brosseau, a postdoctoral fellow at the Courant Institute, focused on a previously discovered phenomenon, rheotaxis—movement involving a change of direction to head upstream or into a current.

However, detailed explanations for rheotaxis had been lacking. To fully understand this process, the scientists created nano-motors composed of two metals—platinum and gold (Pt/Au). Shelley, Zhang, and their colleagues had previously created a more basic version of these nano-motors, which are less than the width of a human hair.

The motors described in the Physical Review Letters paper were more advanced; the researchers varied the proportions of these metals in order to vary their movement—in some models, the composition was evenly split while others had a 3:1 gold-to-platinum ratio or a 3:1 platinum-to-gold make-up.

Fueled chemically by a hydrogen peroxide dilution when placed in water, the nano-motors could swim—with the platinum end always serving as the head. However, these motors had different “tilts,” depending on their make-up. Those composed primarily of gold were labeled “pullers” while those largely made up of platinum were called “pushers.” The pullers tended to move with their tails up (a pronounced tilt) while the pushers remained relatively flat.

This difference was significant when it came to moving against currents.

When the tilt is large (pullers), the tail is more exposed to an oncoming flow, which catches the tail and turns the motor around—similar to the way wind turns a weather vane. Consequently, the motor’s front faces the flow, after which the motor continues forward, now moving against the current. By contrast, if the motor is not tilted (pushers), a current cannot catch its tail and spin it around to move against this flow—and, as a result, it is unlikely to respond to an oncoming flow.

“This synthetic system mimics natural micro-organisms, such as E. coli in flow, and offers a means for predicting their pathways through the human body,” says Brosseau. “It is key to understand contamination processes and engineer smart material for targeted drug delivery.”

Additional coauthors are from NYU, the Flatiron Institute, and the New Jersey Institute of Technology. Support for the work came from the MRSEC Program of the National Science Foundation and also through additional NSF grants.

Source: New York University

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