Abstract
A plasmon state formed at the boundary of photonic crystal and metal is experimentally testified [1]. In analogy with the electronic Tamm states formed at the boundaries of a crystal, the plasmon state is named Tamm plasmon (TP). Different from the well-known surface plasmon, the propagation constant dispersion of TP lies within the light corn. No coupling system, like prism, is required to excite the plasmon mode. In addition, both TE and TM polarized light can be employed to excited TP. Studies of TP based application and its tunability was intensively discussed [2]. However, the mechanism behind resonance wavelength (λTP) shifting and variation of energy coupling efficiency to resonance modes has been less studied. In this work, a novel approach based on admittance loci is proposed to analyze the TP resonance modes and further design the layer structure for shifting resonance wavelength and tuning the coupling efficiency [3]. Figure 1 shows the schematic diagram of TP structure, and the electric field excited by incident light at resonance wavelength. In this presentation, the advanced design of Tamm plasmon device will be demonstrated for its tunability and sensor application.
© 2015 Japan Society of Applied Physics, Optical Society of America
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