Abstract
Intense light traps and binds small particles, offering unique control to the microscopic world. With incoming illumination and radiative losses, optical forces are inherently nonconservative, thus non-Hermitian. Contrary to conventional systems, the operator governing time evolution is real and asymmetric (i.e., non-Hermitian), which inevitably yield complex eigenvalues when driven beyond the exceptional points, where light pumps in energy that eventually “melts” the light-bound structures. Surprisingly, unstable complex eigenvalues are prevalent for clusters with ~10 or more particles, and in the many-particle limit, their presence is inevitable. As such, optical forces alone fail to bind a large cluster. Our conclusion does not contradict with the observation of large optically-bound cluster in a fluid, where the ambient damping can take away the excess energy and restore the stability. The non-Hermitian theory overturns the understanding of optical trapping and binding, and unveils the critical role played by non-Hermiticity and exceptional points, paving the way for large-scale manipulation.
Highlights
Intense light traps and binds small particles, offering unique control to the microscopic world
This paper aims to demonstrate that when the number of particles increases in an optically bound cluster, the system will always pass through exceptional point (EP) to yield unstable conjugate pairs of complex eigenvalues, irrespective of details such as particle size, shape, composition, and the illuminating light
The “run-away” phenomenon associated with the EP can be suppressed to a certain extent by viscous dissipation[8,9,10,11,41,42,43,44]
Summary
Intense light traps and binds small particles, offering unique control to the microscopic world. The force matrices governing OB stability are non-Hermitian because we are dealing with open systems with incoming light and radiative loss[26,27,28,29,30,31]. They are different from the usual non-Hermitian matrices studied in the exceptional point (EP) literature[32,33,34,35], which typically involve symmetric matrices with complex diagonal terms[36,37,38,39,40]. The “run-away” phenomenon associated with the EP (exponentially growing trajectory when perturbed from the equilibrium) can be suppressed to a certain extent by viscous dissipation[8,9,10,11,41,42,43,44]
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