Visualizing ultrafast photothermal dynamics with decoupled optical force nanoscopy

• Published in: Nature communications Vol. 14; no. 1; p. 7267
• Main Authors: Wang, Hanwei, Meyer, Sean M., Murphy, Catherine J., Chen, Yun-Sheng, Zhao, Yang
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 10.11.2023; Nature Publishing Group; Nature Portfolio
• Subjects: 147/136; 147/3; 639/624/400/1021; 639/925/357/354; 639/925/930/2735; 639/925/930/328/1262; Cancer therapies; Chemical synthesis; Drug delivery; Electromagnetic absorption; Electron microscopy; Humanities and Social Sciences; Inactivation; Microscopy; Modulation; multidisciplinary; Nanomaterials; Nanoparticles; Nanorods; Nanotechnology; Scanning probe microscopy; Science; Science (multidisciplinary); Speed limits; Thermal diffusion
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-023-42666-9

The photothermal effect in nanomaterials, resulting from resonant optical absorption, finds wide applications in biomedicine, cancer therapy, and microscopy. Despite its prevalence, the photothermal effect in light-absorbing nanoparticles has typically been assessed using bulk measurements, neglecting near-field effects. Beyond standard imaging and therapeutic uses, nanosecond-transient photothermal effects have been harnessed for bacterial inactivation, neural stimulation, drug delivery, and chemical synthesis. While scanning probe microscopy and electron microscopy offer single-particle imaging of photothermal fields, their slow speed limits observations to milliseconds or seconds, preventing nanoscale dynamic investigations. Here, we introduce decoupled optical force nanoscopy (Dofn), enabling nanometer-scale mapping of photothermal forces by exploiting unique phase responses to temporal modulation. We employ the photothermal effect’s back-action to distinguish various time frames within a modulation period. This allows us to capture the dynamic photothermal process of a single gold nanorod in the nanosecond range, providing insights into non-stationary thermal diffusion at the nanoscale. Diving deep into material insights, the authors introduce the ‘Decoupled Optical Force Nanoscopy’. This innovation uncovers the physical origins of light induced forces and captures dynamic thermal details with unparalleled nanometer precision.