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Non-Hermitian acoustic metamaterial for the complete control of sound by accessing the exceptional points

Non-Hermitian systems always play a negative role in wave manipulations due to inherent non-conservation of energy as well as loss of information. Recently, however, there has been a paradigm shift on utilizing non-Hermitian systems to implement varied miraculous wave controlling. For example, parity-time symmetric media with well-designed loss and gain are presented to create a nontrivial effect of unidirectional diffraction, which is observed near the exceptional points (EPs) in the non-Hermitian systems. Here, we report the design and realization of non-Hermitian acoustic metamaterial (NHAM) and show that by judiciously tailoring the inherent loss, the phase and amplitude of reflection can possibly be tuned in a decoupled manner. Such decoupled tuning of phase and amplitude is closely related to the EPs. As a demonstration of functionality, we experimentally generate a high-quality acoustic hologram via NHAM. Our work may open a new degree of freedom for realizing the complete control of sound.

preprint2016arXivOpen access
Yi-Fan ZhuXue-Feng ZhuXu-Dong FanBin LiangXin-ye ZouJing YangJian-chun Cheng
physics.class-ph
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Yi-Fan ZhuXue-Feng ZhuXu-Dong FanBin LiangXin-ye ZouJing YangJian-chun Cheng

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