A surprising experiment opens the path to new particle manipulation methods
Researchers at Aalto University have discovered a surprising phenomenon that changes how we think about how sound can move particles. Their experiment is based on a famous experiment recognisable from high school science classrooms worldwide 鈥 the Chlandni Plate experiment, where particles move on a vibrating surface. The experiment was first performed in from 1787 by Ernst Chladni, who is now known as the father of acoustics. Chladni鈥檚 experiment showed that when a plate is vibrating at a frequency, heavy particles move towards the regions with less vibration, called nodal lines. This experiment has been extensively repeated during the centuries since, and shaped the common understanding of how heavy particles move on a vibrating plate. But researchers at Aalto University have now shown a case where heavy particles move towards the regions with more vibrations, or antinodes. 鈥淭his is a surprising result, almost a contradiction to common beliefs,鈥 says Professor Quan Zhou.
The researchers installed a silicon plate on a piezoelectric transducer and submerged it into water. They spread sub-mm glass spheres on the plate, and vibrated the plate with signals of different frequencies, creating waves on the plate. The researchers were then surprised to observe that the particles move towards the antinodes, forming what they have dubbed 鈥渋nverse Chladni patterns鈥.
An interesting aspect is that the system can create predictable motion at a wide range of frequencies. 鈥淲e can move particles at almost any frequency, and we do not rely on the resonance of the plate鈥, says Zhou. 鈥淭his gives us a lot of freedom in motion control鈥.
Using the newly discovered phenomenon, the researchers were able to precisely control the motion of single particles and a swarm of particles on the submerged plate. In one example, they moved a particle in a maze on the plate, wrote words consisting of separate letters, and merged, transported and separated a swarm of particles by playing different musical notes.
鈥淢any procedures in pharmaceutical research and microsystem assembly require the ability to move and manipulate small particles easily. Using just a single actuator to do all these different things, we are opening a path to new particle handling techniques鈥, says Zhou. 鈥淎dditionally, the method can inspire the future factory-on-a-chip systems.鈥
Contact:
Professor Quan Zhou
quan.zhou@aalto.fi
Read more news
Design at the start of the supply chain 鈥 Aalto University leads a major EU project to transform textile colouration practices
The EU Horizon-funded MELANGE project brings together design, technology and business to rethink colouration practices in the textile industry and accelerate the transition towards circular and sustainable textile systems.
Arsi Ik盲heimonen鈥檚 doctoral research: Smartphone data could reveal early signs of depression
A phone in your pocket, a smart ring on your finger, and an activity tracker on your wrist: everyday devices collect information about their users almost continuously. This data can help monitor and predict symptoms of depression.
Professor Hironori Yoshida: 鈥淢achines should adapt to materials, not the other way around鈥
Professor of Formgiving believes the future of design lies in embracing irregularity rather than eliminating it. His research combines design, AI and robotics.