Machine learning reveals complex behaviours in optically trapped particles

Since their invention in the 1980s [1], optical tweezers have found a wide range of applications, from biophotonics and mechanobiology to microscopy and optomechanics [2, 3, 4, 5]. Simulations of the motion of microscopic particles held by optical tweezers are often required to explore complex phenomena and to interpret experimental data [6, 7, 8, 9]. For the sake of computational efficiency, these simulations usually model the optical tweezers as an harmonic potential [10, 11]. However, more physically-accurate optical-scattering models [12, 13, 14, 15] are required to accurately model more onerous systems; this is especially true for optical traps generated with complex fields [16, 17, 18, 19]. Although accurate, these models tend to be prohibitively slow for problems with more than one or two degrees of freedom (DoF) [20], which has limited their broad adoption. Here, we demonstrate that machine learning permits one to combine the speed of the harmonic model with the accuracy of optical-scattering models. Specifically, we show that a neural network can be trained to rapidly and accurately predict the optical forces acting on a microscopic particle. We demonstrate the utility of this approach on two phenomena that are prohibitively slow to accurately simulate otherwise: the escape dynamics of swelling microparticles in an optical trap, and the rotation rates of particles in a superposition of beams with opposite orbital angular momenta. Thanks to its high speed and accuracy, this method can greatly enhance the range of phenomena that can be efficiently simulated and studied.

[1]  E. Lutz,et al.  Experimental verification of Landauer’s principle linking information and thermodynamics , 2012, Nature.

[2]  A Dogariu,et al.  Negative nonconservative forces: optical "tractor beams" for arbitrary objects. , 2011, Physical review letters.

[3]  D. Hanstorp,et al.  Juggling with Light. , 2018, Physical review letters.

[4]  S. Chu,et al.  Observation of a single-beam gradient force optical trap for dielectric particles. , 1986, Optics letters.

[5]  Jürgen Schmidhuber,et al.  Deep learning in neural networks: An overview , 2014, Neural Networks.

[6]  Simon Hanna,et al.  Shape-induced force fields in optical trapping , 2014, Nature Photonics.

[7]  H. Rubinsztein-Dunlop,et al.  High-speed transverse and axial optical force measurements using amplitude filter masks. , 2019, Optics express.

[8]  Christoph F. Schmidt,et al.  Direct observation of kinesin stepping by optical trapping interferometry , 1993, Nature.

[9]  Yibo Zhang,et al.  Deep Learning Microscopy , 2017, ArXiv.

[10]  Rosalba Saija,et al.  Scattering from Model Nonspherical Particles , 2003 .

[11]  J. P. Woerdman,et al.  Orbital angular momentum of light and the transformation of Laguerre-Gaussian laser modes. , 1992, Physical review. A, Atomic, molecular, and optical physics.

[12]  José A Rodrigo,et al.  Shaping of light beams along curves in three dimensions. , 2013, Optics express.

[13]  G. Volpe,et al.  Simulation of a Brownian particle in an optical trap , 2013 .

[14]  R. Metzler,et al.  Manipulation and Motion of Organelles and Single Molecules in Living Cells. , 2017, Chemical reviews.

[15]  Ivo D. Dinov,et al.  Deep learning for neural networks , 2018 .

[16]  Kishan Dholakia,et al.  Optical micromanipulation. , 2008, Chemical Society reviews.

[17]  W. Bowen,et al.  Enhanced optical trapping via structured scattering , 2015, 2105.09539.

[18]  Jie Lin,et al.  Multiparameter Controllable Chiral Optical Patterns , 2020 .

[19]  M J Padgett,et al.  Optical ferris wheel for ultracold atoms. , 2007, Optics express.

[20]  Kuo-Kang Liu,et al.  Optical tweezers for single cells , 2008, Journal of The Royal Society Interface.

[21]  Giovanni Volpe,et al.  Optical Tweezers: Principles and Applications , 2016 .

[22]  Alexander Jesacher,et al.  Size selective trapping with optical "cogwheel" tweezers. , 2004, Optics express.

[23]  Yi Yang,et al.  Nanophotonic particle simulation and inverse design using artificial neural networks , 2018, Science Advances.

[24]  Norman R. Heckenberg,et al.  Optical tweezers computational toolbox , 2007 .

[25]  M. Berns,et al.  Escape forces and trajectories in optical tweezers and their effect on calibration. , 2015, Optics Express.

[26]  Halina Rubinsztein-Dunlop,et al.  Calibration of nonspherical particles in optical tweezers using only position measurement. , 2013, Optics letters.

[27]  Rosalba Saija,et al.  Scattering from Model Nonspherical Particles: Theory and Applications to Environmental Physics , 2003 .

[28]  Jonathan M. Taylor,et al.  Indirect optical trapping using light driven micro-rotors for reconfigurable hydrodynamic manipulation , 2019, Nature Communications.

[29]  K. Dholakia,et al.  Bessel beams: Diffraction in a new light , 2005 .

[30]  Reza Pourabolghasem,et al.  Knowledge Discovery in Nanophotonics Using Geometric Deep Learning , 2019, Adv. Intell. Syst..

[31]  H. Rubinsztein-Dunlop,et al.  Phase-transition-like properties of double-beam optical tweezers. , 2011, Physical review letters.

[32]  A. Ashkin Forces of a single-beam gradient laser trap on a dielectric sphere in the ray optics regime. , 1992, Methods in cell biology.

[33]  Giovanni Volpe,et al.  Digital video microscopy enhanced by deep learning , 2018, Optica.

[34]  Geoffrey E. Hinton,et al.  Deep Learning , 2015, Nature.

[35]  S. Dattagupta Stochastic Thermodynamics , 2021, Resonance.

[36]  Isaac C. D. Lenton,et al.  Theory and practice of simulation of optical tweezers , 2017, Journal of Quantitative Spectroscopy and Radiative Transfer.

[37]  Halina Rubinsztein-Dunlop,et al.  Machine learning wall effects of eccentric spheres for convenient computation. , 2019, Physical review. E.

[38]  A. Ashkin,et al.  Optical trapping and manipulation of viruses and bacteria. , 1987, Science.

[39]  Ali Adibi,et al.  Deep learning approach based on dimensionality reduction for designing electromagnetic nanostructures , 2019, npj Computational Materials.

[40]  Tsuyoshi Murata,et al.  {m , 1934, ACML.

[41]  Halina Rubinsztein-Dunlop,et al.  Optical tweezers: Theory and modelling , 2014 .

[42]  Mark D Hannel,et al.  Machine-learning techniques for fast and accurate feature localization in holograms of colloidal particles. , 2018, Optics express.

[43]  Alexander Rohrbach,et al.  Stiffness of optical traps: quantitative agreement between experiment and electromagnetic theory. , 2005, Physical review letters.

[44]  Jan Gieseler,et al.  Levitated Nanoparticles for Microscopic Thermodynamics—A Review , 2018, Entropy.

[45]  Halina Rubinsztein-Dunlop,et al.  Orientation of swimming cells with annular beam optical tweezers , 2019, Optics Communications.

[46]  M. Padgett,et al.  Optical trapping and binding , 2013, Reports on progress in physics. Physical Society.

[47]  Miles J. Padgett,et al.  Tweezers with a twist , 2011 .

[48]  F. Ritort,et al.  The nonequilibrium thermodynamics of small systems , 2005 .

[49]  U. Seifert Stochastic thermodynamics, fluctuation theorems and molecular machines , 2012, Reports on progress in physics. Physical Society.

[50]  William H. Press,et al.  Numerical Recipes 3rd Edition: The Art of Scientific Computing , 2007 .

[51]  Simon Hanna,et al.  Optical angular momentum transfer by Laguerre-Gaussian beams. , 2009, Journal of the Optical Society of America. A, Optics, image science, and vision.

[52]  Naoya Matsumoto,et al.  Mode purities of Laguerre-Gaussian beams generated via complex-amplitude modulation using phase-only spatial light modulators. , 2009, Optics letters.