Effects of drop height and surface instability on neuromuscular activation during drop jumps

Holography is a powerful tool for three-dimensional imaging. However, in explosive, supersonic, hypersonic, cavitating, or ionizing environments, shock-waves and density gradients impart phase distortions that obscure objects in the field-of-view. Capturing time-resolved information in these environments also requires ultra-high-speed acquisition. To reduce phase distortions and increase imaging rates, we introduce an ultra-high-speed phase conjugate digital in-line holography (PCDIH) technique. In this concept, a coherent beam passes through the shock-wave distortion, reflects off a phase conjugate mirror, and propagates back through the shock-wave, thereby minimizing imaging distortions from phase delays. By implementing the method using a pulse-burst laser setup at up to 5 million-frames-persecond, time-resolved holograms of ultra-fast events are now possible. This technique is applied for holographic imaging through laser-spark plasma-generated shock-waves and to enable three-dimensional tracking of explosively generated hypersonic fragments. Simulations further advance our understanding of physical processes and experiments demonstrate ultra-high-speed PCDIH techniques for capturing dynamics.

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Time-resolved digital in-line holography and pyrometry for aluminized solid rocket propellants

Chen

Heyborne

Guildenbecher

2018

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Laser Diagnostics for Solid Rocket Propellants and Explosives

Mazumdar

Heyborne

Guildenbecher

2019

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Solid Propellant Scaling Analysis Using Simultaneous Holography and Imaging Pyrometry

Marsh

Zheng

Heyborne

et al. 2021

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Jeffery D. Heyborne

Time-resolved size, velocity, and temperature statistics of aluminum combustion in solid rocket propellants

Megahertz-rate shock-wave distortion cancellation via phase conjugate digital in-line holography

Time-resolved digital in-line holography and pyrometry for aluminized solid rocket propellants

Laser Diagnostics for Solid Rocket Propellants and Explosives

Solid Propellant Scaling Analysis Using Simultaneous Holography and Imaging Pyrometry

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