Laser actuation of cantilevers for picometre amplitude dynamic force microscopy

Drew R. Evans; Ponlawat Tayati; Hongjie An; Ping Koy Lam; Vincent S.J. Craig; Tim J. Senden

doi:10.1038/srep05567

Laser actuation of cantilevers for picometre amplitude dynamic force microscopy

Drew R. Evans, Ponlawat Tayati, Hongjie An, Ping Koy Lam, Vincent S.J. Craig, Tim J. Senden^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

29 Citations (Scopus)

Abstract

As nanoscale and molecular devices become reality, the ability to probe materials on these scales is increasing in importance. To address this, we have developed a dynamic force microscopy technique where the flexure of the microcantilever is excited using an intensity modulated laser beam to achieve modulation on the picoscale. The flexure arises from thermally induced bending through differential expansion and the conservation of momentum when the photons are reflected and absorbed by the cantilever. In this study, we investigated the photothermal and photon pressure responses of monolithic and layered cantilevers using a modulated laser in air and immersed in water. The developed photon actuation technique is applied to the stretching of single polymer chains.

Original language	English
Article number	5567
Journal	Scientific Reports
Volume	4
DOIs	https://doi.org/10.1038/srep05567
Publication status	Published - 4 Jul 2014

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abstract = "As nanoscale and molecular devices become reality, the ability to probe materials on these scales is increasing in importance. To address this, we have developed a dynamic force microscopy technique where the flexure of the microcantilever is excited using an intensity modulated laser beam to achieve modulation on the picoscale. The flexure arises from thermally induced bending through differential expansion and the conservation of momentum when the photons are reflected and absorbed by the cantilever. In this study, we investigated the photothermal and photon pressure responses of monolithic and layered cantilevers using a modulated laser in air and immersed in water. The developed photon actuation technique is applied to the stretching of single polymer chains.",

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AU - Tayati, Ponlawat

AU - An, Hongjie

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AU - Craig, Vincent S.J.

AU - Senden, Tim J.

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AB - As nanoscale and molecular devices become reality, the ability to probe materials on these scales is increasing in importance. To address this, we have developed a dynamic force microscopy technique where the flexure of the microcantilever is excited using an intensity modulated laser beam to achieve modulation on the picoscale. The flexure arises from thermally induced bending through differential expansion and the conservation of momentum when the photons are reflected and absorbed by the cantilever. In this study, we investigated the photothermal and photon pressure responses of monolithic and layered cantilevers using a modulated laser in air and immersed in water. The developed photon actuation technique is applied to the stretching of single polymer chains.

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Laser actuation of cantilevers for picometre amplitude dynamic force microscopy

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