Researchershave discovered that E. coli bacteria can synchronize their movements, creating order in seemingly random biological systems. By trapping individual bacteria in micro-engineered circular ...

New studies from Arizona State University reveal surprising ways bacteria can move without their flagella - the slender, whip-like propellers that usually drive them forward. Movement lets bacteria ...

Researchers have discovered that bacterial swarms transition from stable vortices to chaotic turbulence through distinct intermediate states. Combining experiments with bacterial swarms, computer ...

New studies from Arizona State University reveal surprising ways bacteria can move without their flagella—the slender, whip-like propellers that usually drive them forward. Movement lets bacteria form ...

An audience clapping in rhythm, fireflies flashing in unison, or flocks of starlings moving as one – synchronisation is a natural phenomenon observed across diverse systems and scales. First described ...

An audience clapping in rhythm, fireflies flashing in unison, or flocks of starlings moving as one – synchronisation is a natural phenomenon observed across diverse systems and scales. First described ...

This study contributes to the development of control theories for the collective motion of self-propelled microorganisms, particles, or microdevices. The collective motion of bacteria—from stable ...

The collective motion of bacteria—from stable swirling patterns to chaotic turbulent flows—has intrigued scientists for ...