摘要
Precise control over light-matter interactions is critical for many optical manipulation and material characterization methodologies,further playing a paramount role in a host of nanotechnology applications.Nonetheless,the fundamental aspects of interactions between electromagnetic fields and matter have yet to be established unequivocally in terms of an electromagnetic momentum density.Here,we use tightly focused pulsed laser beams to detect bulk and boundary optical forces in a dielectric fluid.From the optical convoluted signal,we decouple thermal and nonlinear optical effects from the radiation forces using a theoretical interpretation based on the Microscopic Ampère force density.It is shown,for the first time,that the time-dependent pressure distribution within the fluid chiefly originates from the electrostriction effects.Our results shed light on the contribution of optical forces to the surface displacements observed at the dielectric air-water interfaces,thus shedding light on the long-standing controversy surrounding the basic definition of electromagnetic momentum density in matter.
基金
funding from CNPq(409403/2018-0,304738/2019-0)
CAPES(Finance Code 001),Fundação Araucária,and FINEP
Companhia Paranaense de Energia(COPEL)and Agência Nacional de Energia Elétrica(Aneel)
the financial support through the contract P&D 2866-0466/2017
the financial support from the Slovenian Research Agency(research core funding No.P2-0231)
European Union’s Horizon 2020 Marie Skłodowska-Curie Actions(MSCA)individual fellowship under Contract No.846218.
