Buendía Álvaro, Sánchez-Gil Jose A, Giannini Vincenzo
Instituto de Estructura de la Materia, Consejo Superior de Investigaciones Científicas, Serrano 121, 28006Madrid, Spain.
Centre of Excellence ENSEMBLE3 sp. z o.o., Wolczynska 133, Warsaw, 01-919, Poland.
ACS Photonics. 2023 Jan 11;10(2):464-474. doi: 10.1021/acsphotonics.2c01526. eCollection 2023 Feb 15.
In the last years there have been multiple proposals in nanophotonics to mimic topological condensed matter systems. However, nanoparticles have degrees of freedom that atoms lack of, like dimensions or shape, which can be exploited to explore topology beyond electronics. Elongated nanoparticles can act like projectors of the electric field in the direction of the major axis. Then, by orienting them in an array the coupling between them can be tuned, allowing to open a gap in an otherwise gapless system. As a proof of the potential of the use of orientation of nanoparticles for topology, we study 1D chains of prolate spheroidal silver nanoparticles. We show that in these arrays spatial modulation of the polarization allows to open gaps, engineer hidden crystalline symmetries and to switch on/off or left/right edge states depending on the polarization of the incident electric field. This opens a path toward exploiting features of nanoparticles for topology to go beyond analogues of condensed matter systems.
在过去几年里,纳米光子学领域提出了多种模拟拓扑凝聚态物质系统的方案。然而,纳米粒子具有原子所没有的自由度,如尺寸或形状,可利用这些自由度探索超越电子学范畴的拓扑结构。细长的纳米粒子在主轴方向上可充当电场的投影仪。然后,通过将它们排列成阵列,可以调节它们之间的耦合,从而在原本无带隙的系统中打开一个带隙。作为利用纳米粒子取向实现拓扑结构潜力的一个证明,我们研究了长椭球形银纳米粒子的一维链。我们表明,在这些阵列中,极化的空间调制能够打开带隙、设计隐藏的晶体对称性,并根据入射电场的极化情况开启/关闭或切换左右边缘态。这为利用纳米粒子的特性实现拓扑结构开辟了一条道路,使其超越凝聚态物质系统的类似物。