Author
Listed:
- Junsuke Yamanishi
(Osaka University
Institute for Molecular Science, National Institutes of Natural Sciences)
- Hidemasa Yamane
(Osaka Prefecture University
Kitasato University)
- Yoshitaka Naitoh
(Osaka University)
- Yan Jun Li
(Osaka University)
- Nobuhiko Yokoshi
(Osaka Prefecture University)
- Tatsuya Kameyama
(Graduate School of Engineering, Nagoya University)
- Seiya Koyama
(Graduate School of Engineering, Nagoya University)
- Tsukasa Torimoto
(Graduate School of Engineering, Nagoya University)
- Hajime Ishihara
(Osaka Prefecture University
Osaka University
Osaka University)
- Yasuhiro Sugawara
(Osaka University)
Abstract
Three-dimensional (3D) information of the optical response in the nanometre scale is important in the field of nanophotonics science. Using photoinduced force microscopy (PiFM), we can visualize the nano-scale optical field using the optical gradient force between the tip and sample. Here, we demonstrate 3D photoinduced force field visualization around a quantum dot in the single-nanometre spatial resolution with heterodyne frequency modulation technique, using which, the effect of the photothermal expansion of the tip and sample in the ultra-high vacuum condition can be avoided. The obtained 3D mapping shows the spatially localized photoinduced interaction potential and force field vectors in the single nano-scale for composite quantum dots with photocatalytic activity. Furthermore, the spatial resolution of PiFM imaging achieved is ~0.7 nm. The single-nanometer scale photoinduced field visualization is crucial for applications such as photo catalysts, optical functional devices, and optical manipulation.
Suggested Citation
Junsuke Yamanishi & Hidemasa Yamane & Yoshitaka Naitoh & Yan Jun Li & Nobuhiko Yokoshi & Tatsuya Kameyama & Seiya Koyama & Tsukasa Torimoto & Hajime Ishihara & Yasuhiro Sugawara, 2021.
"Optical force mapping at the single-nanometre scale,"
Nature Communications, Nature, vol. 12(1), pages 1-7, December.
Handle:
RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-24136-2
DOI: 10.1038/s41467-021-24136-2
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