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Before any business can take place at meetings, whether it be the local borough or a committee at work, a certain number of members need to be in attendance. This is called reaching quorum.

It turns out, the same thing also happens on a microscopic level. For instance, bacteria exhibit a behavior called quorum sensing.

“When there are one or two bacteria, they behave in a certain way,” said Anna Balazs, Distinguished professor of Chemical Engineering and the John A. Swanson Chair of Engineering at the 51��Ʒ��Ƶ’s . “But suddenly, when there is a critical threshold of bacteria, the bacteria can sense this increase in population and they dramatically change their behavior.”

In other words, the bacteria have reached a quorum.

Other examples of quorum sensing in living beings include how honey bees select locations for new hives or bioluminescence in deep-sea squid.

Now imagine that type of behavior in machines. That’s what Balazs and collaborator Henry Shum at the University of Waterloo in Canada have been researching. The duo has mimicked quorum sensing behavior in synthetic — nonliving — materials, which could lead to mechanical devices with the ability for self-recognition and self-regulation.

in the Proceedings of the National Academy of Sciences.

The findings build off of a the pair published in 2015, where three microscopic synthetic capsules reacted and moved toward each other using chemical signaling.

“They have a bioinspired behavior that enables them to come together and form small groups,” Shum said.

This most recent study, however, modeled a large number of microcapsules and found that, once quorum was met, synthetic particles reacted autonomously to produce distinct oscillations in chemical signals. The oscillations indicate to the other particles that there is a quorum.

“I don’t want to say the particles are self-aware, but they can perform this simple, elementary lifelike function,” Balazs said.

Balazs added that these particles’ ability to “count” shows potential blurred lines between what is living and nonliving.

Balazs and Shum said their findings could lead to advancements in soft robotics, a sub-field dealing with the construction of robots from highly flexible materials, similar to those found in living organisms.

Their findings could also inspire new “mechano-responsive” materials, such as polymer gels with embedded quorum sensing elements that would activate a certain chemical behavior when compressed, and then switch off when stretched or when a specific temperature is reached. 

For example: “You could have a robotic skin that solidifies to protect itself at a certain temperature, and then becomes ‘squishy’ again when the temperature drops to a nominal level,” Balazs said.

In the future, Balazs and Shum will combine aspects of their work by studying how larger microscopic systems react and move toward each other to build different structures.