# Laser-Controlled Propulsion of a Microbubble Rolling on a Carbon Nanocoil Rail

**Authors:** Yuli Liu, Si Li, Yanming Sun, Jinlu Li, Yuanyong Dai, Mengmeng Zhang, Jian Shen, Lujun Pan

PMC · DOI: 10.3390/nano16010005 · Nanomaterials · 2025-12-19

## TL;DR

Researchers developed a method to control microbubble movement in microfluidic chips using laser-energized carbon nanocoils, enabling precise and repeatable manipulation.

## Contribution

A novel laser-based propulsion system using carbon nanocoils for controllable microbubble transport in microchannels is introduced.

## Key findings

- Laser-controlled microbubbles can be generated, transported, stopped, and re-mobilized repeatedly on a microchannel.
- Rolling microbubble motion is achieved via a dynamic thermal gradient at the liquid-CNC interface.
- The approach enables accurate and reconfigurable manipulation of microbubbles for microfluidic applications.

## Abstract

Controllably propelling microbubbles in microchannels within a microfluidic chip is of great scientific significance yet remains challenging. In this work, we employ carbon nanocoils (CNCs) as a laser-energized rail for propelling microbubbles to the desired position on the inner sidewall of microchannels by laser irradiation at the liquid-CNC interface. Laser-controlled microbubbles can be generated, transported to a desired location, stopped, and re-mobilized repeatedly without a significant change in volume on the microchannel within a microfluidic chip by controlling the laser spot. The microbubbles exhibit a rolling motion at the liquid-CNC interface due to stronger convectional flow induced by a dynamic, mobile thermal gradient generated by a scanning laser spot. The photothermal conversion properties and hydrophobic surface of the CNCs enable the CNCs to function as a laser-energized rail for microbubble propulsion. These results demonstrate that laser-controlled microbubbles rolling on CNC rails have good mobility and can be accurately manipulated in a microchannel chip. This approach leverages a dynamic thermal gradient, departing from static control methods to enable on-demand, reconfigurable manipulation of microbubbles, which opens up new possibilities for lab-on-a-chip and microfluidic applications.

## Full-text entities

- **Chemicals:** Carbon Nanocoil Rail (-), carbon (MESH:D002244)

## Full text

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## Figures

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## References

59 references — full list in the complete paper: https://tomesphere.com/paper/PMC12787769/full.md

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Source: https://tomesphere.com/paper/PMC12787769