Laser-induced stress wave propagation through smooth and rough substrates

We investigate laser-induced acoustic wave propagation through smooth and roughened titanium-coated glass substrates. Acoustic waves are generated in a controlled manner via the laser spallation technique. Surface displacements are measured during stress wave loading by alignment of a Michelson-type interferometer. A reflective coverslip panel facilitates capture of surface displacements during loading of as-received smooth and roughened specimens. Through interferometric experiments we extract the substrate stress profile at each laser fluence (energy per area). The shape and amplitude of the substrate stress profile is analyzed at each laser fluence. Peak substrate stress is averaged and compared between smooth specimens with reflective panel and rough specimens with reflective panel. The reflective panel is necessary because the surface roughness of the rough specimens precludes in situ interferometry. Through these experiments we determine that the surface roughness employed has no significant effect on substrate stress propagation and smooth substrates are an appropriate surrogate to determine stress wave loading amplitude of roughened surfaces less than 1.2 {\mu}m average roughness (Ra). No significant difference was observed when comparing the average peak amplitude and loading slope in the stress wave profile for the smooth and rough configurations at each fluence.

[1]  Martha E. Grady,et al.  Biofilm and Cell Adhesion Strength on Dental Implant Surfaces via the Laser Spallation Technique , 2019, bioRxiv.

[2]  Kyle Chard,et al.  A data ecosystem to support machine learning in materials science , 2019, MRS Communications.

[3]  Martha E. Grady,et al.  Adhesion of Biofilms on Titanium Measured by Laser-Induced Spallation , 2018, Experimental Mechanics.

[4]  I. Foster,et al.  The Materials Data Facility: Data Services to Advance Materials Science Research , 2016, JOM.

[5]  R. Kitey,et al.  Adhesion strength of lead zirconate titanate sol-gel thin films , 2016 .

[6]  P. Lv,et al.  Adhesion Strength of Thermal Barrier Coatings with Thermal-Sprayed Bondcoat Treated by Compound Method of High-Current Pulsed Electron Beam and Grit Blasting , 2015, Journal of Thermal Spray Technology.

[7]  N. Sottos,et al.  Molecular tailoring of interfacial failure. , 2014, Langmuir : the ACS journal of surfaces and colloids.

[8]  Nancy R. Sottos,et al.  Interfacial adhesion of photodefinable polyimide films on passivated silicon , 2014 .

[9]  F. Lepoutre,et al.  Laser Shock Adhesion Test (LASAT) of EB-PVD TBCs: Towards an industrial application , 2013 .

[10]  N. Sottos,et al.  Dynamic delamination of patterned thin films , 2008 .

[11]  N. Sottos,et al.  Adhesion strength measurement of polymer dielectric interfaces using laser spallation technique , 2008 .

[12]  M. Ozkan,et al.  Cell adhesion measurement by laser-induced stress waves , 2006 .

[13]  J. Jansen,et al.  Implant Surface Roughness and Bone Healing: a Systematic Review , 2006, Journal of dental research.

[14]  V. Gupta,et al.  Effect of Substrate Orientation, Roughness, and Film Deposition Mode on the Tensile Strength and Toughness of Niobium–Sapphire Interfaces , 2005 .

[15]  N. Sottos,et al.  Tensile and mixed-mode strength of a thin film-substrate interface under laser induced pulse loading , 2004 .

[16]  V. Gupta,et al.  Study on the interface strength of zirconia coatings by a laser spallation technique , 2004 .

[17]  N. Sottos,et al.  A parametric study of laser induced thin film spallation , 2002 .

[18]  Liu Bl,et al.  Improvement of osseointegration of titanium dental implants by a modified sandblasting surface treatment: an in vivo interfacial biomechanics study. , 1999 .

[19]  D. Li,et al.  Improvement of osseointegration of titanium dental implants by a modified sandblasting surface treatment: an in vivo interfacial biomechanics study. , 1999, Implant dentistry.

[20]  B D Boyan,et al.  Effect of titanium surface roughness on proliferation, differentiation, and protein synthesis of human osteoblast-like cells (MG63). , 1995, Journal of biomedical materials research.

[21]  D. Devaux,et al.  GENERATION OF SHOCK WAVES BY LASER-MATTER INTERACTION IN CONFINED GEOMETRIES , 1991 .

[22]  V. Gupta,et al.  Measurement Of Interface Strength By Laser Pulse Induced Spallation , 1990 .