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Akustische Hologramme für "Fast Forward Science 2017"

28 July 2017

03:30

Teilnahme am Wettbewerb Fast Forward Science http://www.fastforwardscience.de Holographic techniques are fundamental to applications such as volumetric displays1, high density data storage and tweezing that require spatial control of intricate optical2 or acoustic fields3,4 within a 3D volume. The basis of holography is spatial storage of the phase and/or amplitude profile of the desired wavefront5,6 in a manner that allows that wavefront to be reconstructed by interference when the hologram is illuminated with a suitable coherent source. Modern computer generated holography7 skips the process of recording a hologram from a physical scene, and instead calculates the required phase profile before rendering it for reconstruction. In ultrasound applications, the phase profile is typically generated by discrete and independently driven ultrasound sources3,4,8-12, whose small number limits the complexity or degrees of freedom that can be attained in the wavefront. Here we introduce monolithic acoustic holograms, which can reconstruct diffraction-limited acoustic pressure fields and thus truly arbitrary ultrasound beams. We use rapid fabrication to craft the holograms and achieve two orders of magnitude higher degrees of freedom than commercial phased array sources. The technique is inexpensive, appropriate for both transmission and reflection elements, and scales well to higher information content, larger aperture size, and higher power. The complex 3D pressure and phase distributions produced by these acoustic holograms allow us to demonstrate new approaches to controlled ultrasonic manipulation of both solids in water, and liquids and solids in air. We expect that acoustic holograms will enable new capabilities in beam-steering and the contactless transfer of power, improve medical imaging, and drive new applications of ultrasound. "Holograms for Acoustics" Nature (2016) doi:10.1038/nature19755 Kai Melde, Dr. Andrew G. Mark, Dr. Tian Qiu, Prof. Peer Fischer Micro Nano and Molecular Systems Lab Max Planck Institute for Intelligent Systems, Stuttgart

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