Measurement of High Temperature Elastic Moduli of Infrared Transparent Materials
Abstract
Insight into a material s high temperature mechanical and microstructural properties can be gained from knowledge of its elastic moduli. For a single-crystal material, the elastic modulus, C(sub ijkl), provides information on the strain (Epsilon sub kl) - stress (sigma sub ij) relationship given by sigma sub ij = C(sub ijkl) dot Epsilon sub kl. This relationship shows that, for a given strain, a large elastic modulus will induce a large stress in the material. In regards to mechanical properties, the crystallographic axis with the largest elastic modulus is the most likely for failure to occur. Before any IR transparent material can be considered for application in a high stress environment, such as IR dome applications, the elastic moduli must be known. Laser-based ultrasonics provides a non-contact, non-destructive means of measuring the elastic moduli of IR transparent materials in an elevated temperature environment. In this paper, the application of laser ultrasonics to IR materials characterization is reviewed. Specific calculations for determining the elastic moduli for isotropic and trigonal crystal symmetries, as exhibited by single-crystal sapphire, are presented. Measurements of the elastic moduli as a function of temperature for borosilicate glass and fused silica, elastically isotropic materials, are presented. In addition, a room-temperature ultrasonic measurement of germanium (Ge), an elastically anisotropic material, is shown.
Document Details
- Document Type
- Technical Report
- Publication Date
- Aug 01, 1998
- Accession Number
- ADA400218
Entities
People
- D. W. Blodgett
- James B. Spicer
- K. C. Baldwin
Organizations
- Johns Hopkins University