Imaging of Shock-Induced Deformation in Condensed Matter

Ultrasensitive ICCD Camera Enables the Study of Rapidly Evolving Material Deformation in Extreme Environments


Introduction

Understanding the response of materials under the rapidly evolving extreme conditions induced by shock-compression is of great relevance to many industries whose work involves high-strain-rate phenomena, such as aerospace design, advanced materials processing and mining, renewable energy research, and defense technology.

"The study of dynamic material deformation via synchrotron x-ray radiography promises to reveal new details on fundamental damage
processes in condensed matter..."

In extreme environments like these, where loading conditions typically last for only a few microseconds, the bulk mechanical behavior of materials is governed by the interplay of numerous mesoscopic damage processes. However, the evolution of these fundamental deformation processes (e.g., local phase changes, strain localization, and crack pattern growth) is inaccessible via commonly employed diagnostics based on visible radiation, such as photonic Doppler velocimetry and high-speed imaging. Therefore, to better understand the performance of current materials and assist in the intelligent design of materials with predefined properties, new techniques capable of providing an unobstructed view of in-material damage are required.


In-house x-ray radiography has long been employed in extreme environments to image subsurface deformation in materials. In recent years, third-generation synchrotron light sources and free electron lasers have extended the capabilities of dynamic x-ray imaging to the submicron and sub-nanosecond scales in macroscopic samples. These increased capabilities not only allow finer insight into material deformation but also place higher demands on detector technology.

In this application note, the use of high-energy synchrotron x-ray radiography to study shock-induced deformation in high-Z materials is discussed. Key to this research is the Princeton Instruments PI-MAX4:1024i intensified CCD (ICCD) camera with a Gen III filmless intensifier, which permits fast imaging in low-photon scenarios.


X-ray Imaging of Shock-Compression Experiments

High-energy, high-resolution x-ray imaging experiments were performed at Beamline I12 at the Diamond Light Source synchrotron. Well-defined, reproducible shock waves were driven into targets by projectiles (cylindrical steel or copper flyer plates: 2 mm thick, 12.5 mm diameter) launched from a purpose-designed portable gas gun1. Impact velocities ranged from 250-850 ms-1, generating shock pressures and material motion on the order of 5-20 GPa and many hundreds ms-1, respectively. Following impact, target damage was examined via high-energy (50-250 keV) x-ray radiography and complementary velocimetry diagnostics. Figure 1 illustrates the experimental setup, showing how radiographs are captured using a single-crystal scintillator, optical relay, and the PI-MAX4:1024i ICCD camera.

Imaging of Shock-Induced Deformation in Condensed Matter-images-1.png

Figure 1. Typical experimental setup for shock-compression experiments at the Diamond
Light Source. Following flyer plate impact, synchrotron x-ray radiography and velocimetry
probe material deformation in real-time.

Figures 2 and 3 show a photograph of the experimental apparatus assembled at Beamline I12 and a photograph of the PI-MAX4 ICCD camera's optical relay, respectively. The large size (11 x 7 x 4 m) of the second experimental hutch at Beamline I12 facilitates large-scale experiments, allowing several diagnostics to be fielded simultaneously. To protect against damage from Compton-scattered x-rays, the optical relay and camera are shielded with 2 mm of lead.

Imaging of Shock-Induced Deformation in Condensed Matter-images-2.png

Figure 2. Annotated photograph of the shockcompression imaging apparatus in the second e
xperimental hutch (EH2), Beamline I12 at the Diamond Light Source. Inset: a typical projectile,
consisting of a polycarbonate sabot and copper flyer plate.

Imaging of Shock-Induced Deformation in Condensed Matter-images-3.png

Figure 3. Annotated photograph of the x-ray imaging system. The x-rays are converted
to visible radiation by a single-crystal scintillator. Radiographs are then recorded by rapidly
gating the PI-MAX4 ICCD camera's Gen III filmless intensifier.

Periodic 3D-printed Structures for Energy Absorption

Periodic structures with well-defined, customizable porosity are of great interest to safety applications where impact or blast stresses may be dissipated by the process of successive pore collapse. To examine the intricacies of the blast mitigation process in more detail, well-defined stainless steel lattice structures were produced by selective laser melting (SLM) and subject to dynamic radiography testing. Figure 4(a) shows a photograph of a typical SLM lattice structure and Figure 4(b) presents an illustration of the impact experiment.

Imaging of Shock-Induced Deformation in Condensed Matter-images-4.png

Figure 4. (a) Photograph of the SLM steel lattice discussed in this application note,
measuring 8 x 8 x 8 mm in size. The insets show schematics of the lattice from two
different perspectives. (b) Illustration of the impact experiment. Gas-gun-driven,
cylindrical steel flyer plates impact the cubic steel lattice at 500 ms-1.

Although visible radiation methods such as high-speed imaging in-silhouette may reveal the kinetics of the pore collapse process in open structures, penetrating x-ray radiation is required to resolve density changes throughout the system. These measurements may then be fed back into material models to guide the design of better-performing systems. Figure 5 shows a series of in-situ radiographs captured before and during the impact experiments. One radiograph was captured per shot with a 12.5 x 12.5 mm field of view and 500 ns exposure. In each dynamic image, the cylindrical projectile enters from the left. Repeat experiments were performed to stroboscopically step through the deformation process.

Imaging of Shock-Induced Deformation in Condensed Matter-images-5.png

Figure 5. (a) Static, in-situ radiograph of the SLM steel lattice aligned prior to impact.
(b-d) Dynamic in-situ radiographs captured 2.4 μs, 6.1 μs, and 8.4 μs after impact,
respectively. Radiographs are shown in false color to emphasize d
ensity contrast. In each dynamic radiograph, the development of a buried interfacial
structure, flyer densification, and the pore collapse process is highlighted by white
arrows.

The dynamic radiographs reveal the localized propagation of damage throughout the lattice structures. Future work will continue to compare deformation observed in the radiographs to the predictions of 3D hydrocode simulations, providing novel data to evaluate material strength and design models.


Important New ICCD Technologies

The highly advanced PI-MAX4:1024i scientific camera (see Figure 6) used in the experiments discussed above features an exclusive picosecond gating technology from Princeton Instruments. By employing state-of-the-art electronics and fiberoptically bonding the intensifier to the CCD sensor, this technology enables new PI-MAX4:1024i cameras to gate conventional image intensifiers (which normally achieve ~2 to 3 ns gating) at <500 ps without sacrificing quantum efficiency. An integrated programmable timing generator, SuperSynchro, built into the PI-MAX4:1024i further enhances the camera's utility for high-precision, time-resolved applications.

Imaging of Shock-Induced Deformation in Condensed Matter-images-6.png

Figure 6. PI-MAX4:1024i ICCD cameras, which utilize one of several
en II or Gen III filmless intensifiers fiberoptically bonded to an interline-
transfer CCD, run at near video rates (26 frames per second).

It should be noted that another new addition to the PI-MAX®4 series, the PI-MAX4:2048f, now provides four times the imaging area and resolution of any other scientific ICCD camera currently available. This large-format camera, which employs a 2k x 2k CCD fiberoptically coupled to one of several 25 mm diameter Gen II or Gen III filmless intensifiers, offers SuperSynchro, high frame rates (6 MHz / 16-bit digitization), and a 1 MHz sustained gating repetition rate.

Complete control over all PI-MAX4:1024i and PI-MAX4:2048f hardware features is simple with the latest version of Princeton Instruments' LightField® data acquisition software (available as an option). Precision intensifier gating control and gate delays, as well as a host of novel functions for easy capture and export of imaging data, are provided via the exceptionally intuitive LightField user interface.


Summary

The study of dynamic material deformation via synchrotron x-ray radiography promises to reveal new details on fundamental damage processes in condensed matter, which may be used to evaluate the results of leading numerical models. This interplay between novel experimental data and advanced modeling can assist in the design of better-performing materials for the advanced materials processing, aerospace, defense, and renewable energy industries.

The PI-MAX4:1024i ICCD camera from Princeton Instruments allows researchers to probe material behavior on ultrafast timescales with resolution sufficient to evaluate leading predictive models. Using Princeton Instruments' SuperSynchro technology in combination with a Gen III filmless intensifier offers unparalleled flexibility in gating and sensitivity, thereby facilitating imaging in low signal-to-noise scenarios.


Resources


To learn about research being conducted by the Institute of Shock Physics, Imperial College London, please visit: https://www.imperial.ac.uk/shock-physics


Reference

D.E. Eakins and D.J. Chapman, Review of Scientific Instruments 85, in press, 2014.


Authors

Mr. Michael E. Rutherforda, Dr. David J.
Chapmana, Dr. Daniel E. Eakinsa
Dr. Michael Drakopoulosb
Mr. Manjul Shahc


a: Institute of Shock Physics, Imperial
College London, London, UK, SW7
2BW


b: Diamond Light Source, Beamline I12
JEEP, Didcot, Oxfordshire, UK, OX11
0DE


c: Princeton Instruments, 3660
Quakerbridge Road, Trenton, NJ 08619
USA


Acknowledgements

The authors would like to acknowledge the continued support of this project by Imperial College London, EPSRC, STFC, and AWE. Additionally, the authors would like to extend their gratitude to all who assisted in performing experiments at the Diamond Light Source: Steven Johnson and David Pittman (sample preparation); Mark Collison, David Jones, Jasmina Music, Sam Stafford, Gareth Tear, Thomas White, and John Winters (experimental assistance).

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