Measurement, Characterization and Simulation of Laser Driven Shockwaves for Metal Surface Enhancement

Bovid, Stanley C.

January 2021

No description available.

Materials Science

Laser shock peening

laser driven flyer

photon doppler velocimetry

finite element analysis

shockwave

laser induced shock

residual stress

opaque overlays

High-Strain Rate Spall Strength Measurement of a CoCrFeMnNi High-Entropy Alloy

Andrew J Ehler (14052888)

03 November 2022

<p>  </p> <p>This work explored the dynamic behavior and failure mechanisms of an additively manufactured high-entropy alloy (HEA) when subjected to high-strain rate shock impacts. A laser-induced projectile impact testing (LIPIT) setup was used to study the dynamic behavior of the Cantor alloy CoCrFeMnNi samples manufactured using a directed-energy deposition technique. HEA flyers were accelerated by a pulse laser to velocities up to 1 km/s prior to impact with lithium fluoride glass windows. A photon Doppler velocimetry (PDV) system recorded the velocity of the flyer during the acceleration and subsequent impact. From this velocity profile, the Hugoniot coefficient and sound speed of the HEA samples were determined.</p> <p><br></p> <p>Upon determination of key shock parameters, spallation occurring due to shock was analyzed. Using the same LIPIT and PDV systems as the earlier testing, aluminum flyers of various thicknesses were accelerated into HEA samples. The back-surface velocity profiles of the HEA samples showed a characteristic “pullback” caused by the interaction of the tensile stress waves indicative of spall occurrence in the material. The magnitude of this pullback and the material properties determined in the first experiments allow for the measurement of spall strength at various strain-rates. This data is compared to previous data looking at similar HEAs manufactured using traditional methods. A comparison of this data showed that the spall strength of the HEA samples was equivalent to that of similar alloys but at significantly higher strain rates. As an increased strain-rate tends to result in increased spall strengths, further examination was needed to determine the reasons for this decreased spall strength in the AM samples.</p> <p><br></p> <p>Post-shock specimen recovery allowed for the failure mechanisms behind the spallation to be observed. Scanning electron microscope (SEM) images of the cross-section of the samples showed ductile fracture and void growth outside of the predicted spall region. Further imaging using energy dispersive spectroscopy (EDS) showed the presence of potentially chromium-oxide deposits in regions outside of the predicted spall plane. It is hypothesized that these regions created nucleation points about which spallation occurred. Thus, to achieve spall strength in AM HEAs equivalent to strengths in traditionally-casted alloys, the AM sample must be refined to reduce the occurrence of these deposits and voids.  </p>

Aerospace materials

Metals and alloy materials

high-entropy alloy

cantor alloy

equation of state

Hugoniot states

spall strength

laser induced projectile impact testing

photon Doppler velocimetry

Process Development and Capabilities of Chemically Augmented Laser Impact Welding

Lewis, Troy Brayden

09 August 2022

No description available.

Materials Science

Engineering

Metallurgy

Impact Welding

Laser Impact Welding

Photon Doppler Velocimetry

LIW

CALIW

PDV

Solid State Joining

Chemical Augment

MICRO-SCALE THERMO-MECHANICAL RESPONSE OF SHOCK COMPRESSED MOCK ENERGETIC MATERIAL AT NANO-SECOND TIME RESOLUTION

Abhijeet Dhiman (5930609)

11 March 2022

<p>Raman spectroscopy is a molecular spectroscopy technique that uses monochromatic light to provide a fingerprint to identify structural components and chemical composition. Depending on the changes in the unit-cell parameters and volume under the application of stress and temperature, the Raman spectrum undergoes changes in the wavenumber of Raman-active modes that allow identification of sample characteristics. Due to the various advantage of mechanical Raman spectroscopy (MRS), the use of this technique in the characterization and modeling of chemical changes under stress and temperature have gained popularity. </p> <p> Quantitative information regarding the local behavior of interfaces in an inhomogeneous material during shock loading is limited due to challenges associated with time and spatial resolution. Recently, we have extended the use of MRS to high-strain rate experiments to capture the local thermomechanical response of mock energetic material and obtain material properties during shock wave propagation. This was achieved by developing a novel method for <i>in‑situ</i> measurement of the thermo‑mechanical response from mock energetic materials in a time‑resolved manner with 5 ns resolution providing an estimation on local pressure, temperature, strain rate, and local shock viscosity. The results show the solid to liquid phase transition of sucrose under shock compression. The viscous behavior of the binder was also characterized through measurement of shock viscosity at strain rates higher than 10⁶/s using microsphere impact experiments.</p> <p> This technique was further extended to perform Raman spectral imaging over a microscale domain of the sample with a nano-second resolution. This was achieved by developing a laser-array Raman spectral imaging technique where simultaneous deconvolution of Raman spectra over the sample domain was achieved and Raman spectral image was reconstructed on post-processing. We developed a Raman spectral imaging system using a laser array and analysis was performed over the interface of sucrose crystals bonded using an epoxy binder. This study provides the Raman spectra over the microstructure domain which enabled the detection of localized melting under shock compression. The distribution of shock pressure and temperature over the microstructure was obtained using mechanical Raman analysis. The study shows the effects of an actual interface on the propagation of shock waves where a higher dissipation of shock energy was observed compared to an ideal interface. This increase in shock dissipation is accompanied by a decrease in both the maximum temperature, as well as the maximum pressure within the microstructure during shock wave propagation.</p>

Aerospace Engineering

Aerospace Materials

Aerospace Structures

Composite and Hybrid Materials

shock compression experiments

Raman spectra measurement

photon Doppler velocimetry

Energetic Materials Applications

Shock Waves

spectral method

Spectral imaging

mock energetic materials

high speed impacts

Developing the Axisymmetric Expanding Ring: A High Strain-Rate Materials Characterization Test

Johnson, Jason R.

02 June 2014

No description available.

Materials Science

Engineering

Mechanics

Metallurgy

Mechanical Engineering

Physics

Electromagnetics

Experiments

Ring expansion

axisymmetric expanding ring test

high rate testing

high strain rate

OFHC copper

FIRE system

photon doppler velocimetry

PDV