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'Quantum Material' Has Shark-Like Ability to Detect Small Electrical Signals

Date: 
Tuesday, December 19, 2017

A “quantum material” that mimics a shark’s ability to detect the minute electric fields of small prey has been shown to perform well in ocean-like conditions, with potential applications from defence to marine biology.

From left, Purdue University doctoral student Derek Schwanz, professor Shriram Ramanathan and postdoctoral research associate Zhen Zhang, have led work to develop a sensor that mimics a shark’s “sixth sense.” (Purdue University image/Marshall Farthing)

The material maintains its functional stability and does not corrode after being immersed in saltwater, a prerequisite for ocean sensing. Surprisingly, it also functions well in the cold, ambient temperatures typical of seawater, said Shriram Ramanathan, a professor of materials engineering at Purdue University in West Lafayette, Ind.

Such a technology might be used to study ocean organisms and ecosystems and to monitor the movement of ships for military and commercial maritime applications.

“So, it has potentially very broad interest in many disciplines,” said Ramanathan, who led research to develop the sensor.

Findings are detailed in a research paper published today in the journal Nature. Scientists from the Canadian Light Source at the University of Saskatchewan contributed to the research along with those at Argonne National Laboratory, Rutgers University, the National Institute of Standards and Technology, the Massachusetts Institute of Technology, Columbia University, and the University of Massachusetts.

The new sensor was inspired by an organ near a shark’s mouth called the ampullae of Lorenzini, which is capable of detecting small electric fields from prey animals.

“This organ is able to interact with its environment by exchanging ions from seawater, imparting the so-called sixth sense to sharks,” said Purdue postdoctoral research associate Zhen Zhang, one of the paper’s lead authors.

The organ contains a jelly that conducts ions from seawater to a specialized membrane located at the bottom of the ampulla. Sensing cells in the membrane allow the shark to detect bioelectric fields emitted by prey fish.

The new sensor is made of a material called samarium nickelate, which is a quantum material, meaning its performance taps into quantum mechanical interactions. Samarium nickelate is in a class of quantum materials called strongly correlated electron systems, which have exotic electronic and magnetic properties.

Because this material can conduct protons very fast, the researchers wondered whether they might develop a sensor that mimics the shark’s organ.

“We have been working on this for a few years,” said Ramanathan.

The sensor is made from a “quantum material” that, surprisingly, functions well in the cold, ambient temperatures typical of seawater (Purdue University image/Marshall Farthing)

“We show that these sensors can detect electrical potentials well below one volt, on the order of millivolts, which is comparable to electric potentials emanated by marine organisms. The material is very sensitive. We calculated the detection distance of our device and find a similar length scale to what has been reported for electroreceptors in sharks.”

The quantum effect causes the material to undergo a dramatic “phase change” from a conductor to an insulator, which allows it to act as a sensitive detector. The material also exchanges mass with the environment, as protons from the water move into the material and then return to the water, going back and forth.

“Having a material like that is very powerful,” said Purdue graduate student Derek Schwanz, another lead author of the paper.

Metals such as aluminum, for example, immediately form an oxide coating when placed in seawater. The reaction protects against corrosion but prevents further interaction with the environment.

“Here, we start with the oxide material and we are able to maintain its functionality, which is very rare,” Ramanathan said.

The material also changes optical properties, becoming more transparent as it becomes more insulating.

“If the material transmits light differently, then you can use light as a probe to study the property of the material and that is very powerful. Now you have multiple ways to study a material, electrically and optically.”

The material was tested by immersing it in simulated ocean water environments designed to cover the wide ranges of temperature and pH found across earth’s oceans. In future work, researchers plan to test the devices in real oceans instead and may team with biologists to apply the technology to broader studies.

At the Canadian Light Source, scientists Ronny Sutarto and Feizhou He analyzed the quantum material using the REIXS beamline, one of the top X-ray scattering beamlines in the world in quantum materials research. The CLS data showed strong evidence that the ‘phase change’ occurred in this quantum material.

Zhang, Zhen, Derek Schwanz, Badri Narayanan, Michele Kotiuga, Joseph A. Dura, Mathew Cherukara, Hua Zhou, John W. Freeland, Jiarui Li, Ronny Sutarto, Feizhou He, Chongzhao Wu, Jiaxin Zhu, Yifei Sun, Koushik Ramadoss, Stephen S. Nonnenmann, Nanfang Yu, Riccardo Comin, Karin M. Rabe, Subramanian K. R. S. Sankaranarayanan & Shriram Ramanathan. “Perovskite nickelates as electric-field sensors in salt water.” Nature (published online Dec. 18, 2017) DOI: 10.1038/nature25008

This release was written by Emil Venere, Purdue News Service, with additional information provided by the Lana Haight, Canadian Light Source.

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