Topological insulator particles as optically induced oscillators: Towards dynamical force measurements and optical rheology

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Topological insulator particles as optically induced oscillators: Towards dynamical force measurements and optical rheology Warlley Hudson Campos warlley.campos@ufv.

1 Topological insulator particles as optically induced oscillators: Towards dynamical force measurements and optical rheology Warlley Hudson Campos Departamento de Física - Universidade Federal de Viçosa TOPOLOGICAL STATES OF MATTER - IIP/NATAL/BRAZIL Collaborators: J.M. Fonseca, J.B.S. Mendes, M.S. Rocha, W.A. Moura-Melo - DPF/UFV V.E. Carvalho - DPF/UFMG Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

2 Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

Departamento de Física, Universidade Federal de Viçosa, 36570-900, Viçosa, Minas Gerais, Brazil.

3 Departamento de Física, Universidade Federal de Viçosa, , Viçosa, Minas Gerais, Brazil. Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

4 3D Topological Insulators Theoretically predicted in 2007 Experimentally observed in 2008 Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

Science 329.5992, (2010): 659. Hasan, M. Z. and Kane, C. L. Rev. Mod. Phys. 82, (2010): 3045. Qi, X.-L. and Zhang, S.-C.

5 Topological insulators properties Strong spin-orbit coupling Gapped bulk band structure; metallic surface states protected by time reversal symmetry Spin-momentum locking Dissipationless propagation of electrons Chen, Y. L., et al. Science , (2010): 659. Hasan, M. Z. and Kane, C. L. Rev. Mod. Phys. 82, (2010): Qi, X.-L. and Zhang, S.-C. Rev. Mod. Phys. 83, (2011): Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

Application prospects Topological quantum computing

Mellnik, A. R. et al. Nature 511, (2014): 449. Jamali, M.

Rev. Let., 117, (2016): 076601. Warlley H.

6 Application prospects Topological quantum computing Electronic devices with low dissipation Spintronics Mellnik, A. R. et al. Nature 511, (2014): 449. Jamali, M. et al. Nano Lett., 15, (2015): Wang, H. et al. Phys. Rev. Let., 117, (2016): Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

7 Optical tweezers technique λ 1064 nm ytterbium-doped fiber laser Laser power 25 mw Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

8 Optical tweezers technique Ray optics regime (radius >> λ) Highly focused Gaussian light beam: I = I 0 e Ar 2 Conservation of linear momentum Snell law: n p sin θ p = n med sin θ med n particle > n medium Refraction in the bulk leads to gradient force: F g I Rocha, M. S. Am. J. Phys. 77, (2009): 704. Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

9 Optical tweezers technique Absorption and reflection leads to radiation pressure: F rp I Radiation pressure deflects the particle from the focus There is also a viscous (Stokes) force exerted by the surrounding medium: F s v Dielectric particle gradient force dominates stable trap Metallic particle radiation pressure dominates deflection Rocha, M. S. Am. J. Phys. 77, (2009): 704. Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

1, (2016): 5. Alemany, A. et al. Biophys. J. 110.1, (2016): 63. Naufer, M. et al. Protein Science, (2017): Early View.

10 Some applications of optical tweezers Membrane elastic properties Micro-rheology DNA studies Pontes, B. et al. PLoS One 8.7, (2013): e Murugesapillai, D. et al. Biophys. Rev. 9, (2016): 17. Ayala, Y. A. et al. BMC biophysics 9.1, (2016): 5. Alemany, A. et al. Biophys. J , (2016): 63. Naufer, M. et al. Protein Science, (2017): Early View. Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

11 Topological insulator bead in optical tweezers Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

B 90 (2014): 075105 Amendola, V. and Meneghetti, M Phys. Chem. Chem. Phys. 15 (2013): 3027.

12 Syntesis of TI-particles ARPES measurements for Bi 2 Te 3 : Laser ablation technique in liquid solution: Michiardi, M. et al. Phys. Rev. B 90 (2014): Amendola, V. and Meneghetti, M Phys. Chem. Chem. Phys. 15 (2013): Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

13 Oscillatory motion Particles diameter between 3µm and 7µm Oscillation parallel to the focal plane For a particle with diameter 4.2µm: Amplitudes vary between 7µm 9µm Closest approximation 3.2µm Well-defined period: T = (3.52 ± 0.32)s Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

Topological Insulators Optical tweezers Material Model and Results Applications Conclusions and Prospects Theoretical model IN = exp 2r 2 ω(z)2! v u u ω(z) = ω0 t1 + zr = Warlley H.

14 Topological Insulators Optical tweezers Material Model and Results Applications Conclusions and Prospects Theoretical model IN = exp 2r 2 ω(z)2! v u u ω(z) = ω0 t1 + zr = Warlley H. Campos πω02 λ z zr!2 2r 2 ω(z)2 2r Fg exp(1/2) 2r 2 exp Fg = ω(z) ω(z)2 2r Fg exp(1/2) 2r 2 F = Frp exp ω(z) 2 ω(z) Frp = Frp exp Topological Insulator particles as optically induced oscillators 03/24/ / 19

15 Optical force Physical parameters: ω(z) = (5.55 ± 0.15)µm F rp = (4.1 ± 0.6)pN F g = (2.1 ± 0.2)pN ω(z) cicles = (5.7±0.3)µm ω 0exp = (0.45 ± 0.02)µm ω 0pred = 2λ πn.a. 0.36µm Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

16 Averages: Dependence with diameter In the range analysed (diameter µm) : Optical forces increase with the particle size Frequency increases with particle size F g Aa 3 F rp Ba 2 F S Ca Harmonic description: T = 2π m k a 3 Aa 3 +Ba 2 +Ca A 1.81s 2 B 3.89µms 2 C 46.50µm 2 s 2 Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

al. J. Opt. 13, (2011): 044022 Warlley H.

17 Some potential applications Dynamic force measurements Wang, M.D. et al. Biophys. Journal 72, (1997): Microrheology Preece, D. et. al. J. Opt. 13, (2011): Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

18 Conclusions and Prospects Microsized TI Bi 2 Te 3 particles oscillate perpendicularly to the optical axis when subject to a highly focused light beam Frequency remains practically constant during a number of cycles For practical purposes, frequency can be controlled by changing the power of the light beam and diameter of the particles Regular spherical shape is crucial for highly precise applications Other TI composites may have more intense manifestation of these properties Functionalize the TI particles Work available in arxiv: Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

19 Topological Insulators Optical tweezers Material Model and Results Applications Conclusions and Prospects Acknowledgements Thank you! Warlley H. Campos Topological Insulator particles as optically induced oscillators 03/24/ / 19

Chapter 2 Physical Principle of Optical Tweezers

Chapter 2 Physical Principle of Optical Tweezers The radiation pressure of light was first deduced theoretically by James C. Maxwell in 1873 based on his electromagnetic theory [1, 2], and measured experimentally