A 3D printed acoustic levitator developed at Bristol University takes the technology out of the lab and into the homes and schools of students and researchers.
According to the university, the technology, published in Review of Scientific Instruments, could be applied to a range of applications including blood tests.
Acoustic levitation uses powerful acoustic waves to push particles from all directions and trap them in mid-air. By using ultrasound it is possible to use powerful vibrations without causing any harm to humans.
Magnetic levitation uses magnetic fields to suspend objects in mid-air. Whilst not as strong as magnetic levitation, acoustic levitation can act on a range of materials, from liquids to living animals.
Using parking sensors, a motor driver, an Arduino single board microcontroller and a 3D-printed part, the Bristol team has developed an instruction pack for those wanting to assemble their own levitator at home or school.
The instructions will enable any researcher to put together a levitator and conduct experiments in acoustic levitation. This levitator is said to be safe to use, robust against temperature or humidity changes, and can operate for extensive periods of time, enabling experiments that were not possible before.
The levitator operates at 40kHz in air and can trap objects above 2.2g/cm3 density and 4mm in diameter whilst consuming 10W of input power.
Dr Asier Marzo from the university’s Department of Mechanical Engineering, said: “Levitating samples in mid-air can improve diagnosis from blood samples and detection of the structure of molecules.
“Usually a sample on a microscope slide is illuminated with x-rays, lasers or another type of radiation so the reflected radiation can be analysed. However, no matter how transparent the microscope slide is, it will always interfere with the test. On the contrary, if the sample is levitated, all the reflections are going to be from the sample.
“Acoustic levitation has been explored in hundreds of studies for applications in pharmaceuticals, biology or biomaterials. It holds the promise of supporting innovative and ground-breaking processes.
“However, historically levitators have been restricted to a small number of research labs because they needed to be custom-made, carefully tuned and required high-voltage. Now, not only scientists but also students can build their own levitator at home or school to experiment and try new applications of acoustic levitation.”