Aerosol ‘whipping jet’ technology is first of its kind

A multinational team of researchers, led in part by BSISB program director Hoi-Ying Holman, recently announced the discovery of a new type of aerosol-producing technology, dubbed the ‘whipping jet.’ Aerosol technology has the potential to impact many fields of science, from experimental studies of atmospheric aerosols to delivery of aerosolized medications.

The collaboration included Martin Trebbin of SUNY at Buffalo College of Arts and Sciences, Sankar Raju Narayanasamy of the Lawrence Livermore National Laboratory and an LBNL affiliate, and Ramakrishna Vasireddi of SOLEIL, the French synchrotron facility in Paris.

The technology delivers a highly reproducible 2D array of droplets of various sizes based on the whipping action of a fine-scale nozzle. This technology marks a third-generation advancement in the control of liquid jets, after cylindrical jets were developed in 1998 and flat liquid sheet jets, in 2018.

The team’s recent open-access publication in Cell Reports Physical Science earned further recognition as the journal’s cover art this past January (2023: Volume 4, Issue 1). The work was also highlighted in a press release by SUNY-Buffalo, in an article by Elements, the news and information source for the Berkeley Lab community, and in a story published by the American Association of Universities.

Observe the ‘whipping jet’ in action:

Funding acknowledgements

This work was supported by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Contract No. DEAC02-05CH11231.

References

  • Narayanasamy SR, Vasireddi R, Holman HYN, and Trebbin M. A sui generis whipping-instability-based self-sequencing multi-monodisperse 2D spray from an anisotropic microfluidic liquid jet device. Cell Reports Physical Science, 4(1): 101221. (2023; https://doi.org/10.1016/j.xcrp.2022.101221)
The ‘whipping jet’ was developed to improve the integration of sample introduction and sample environment for imaging control systems. (A) Internal view of the whipping jet nozzle during operation, and (B) an outside view of the gas focused self-sequencing whipping jet observed at 0.5 bar of applied gas pressure and a liquid flow rate of 66 µL/s. (C) A schematic representation of the whipping jet. (D) Nozzle design parameters, a scanning electron microscope image of the nozzle, made of polydimethylsiloxane (PDMS), and the high-aspect-ratio outlet of the nozzle (left to right). [Reprinted with permission from the authors of the original manuscript.]

By Liz Boatman