S. C. Varshney and A. A. Gundjian, "Laser induced lattice strains and damage threshold limitation due to lattice defects in transparent optical materials," Appl. Opt. 19, 455-462 (1980)
The interaction of a high power laser beam with the lattice of transparent optical materials induces internal strains in the latter. Attention is focused on optical materials of zinc blende structure and excitation at the 10.6-μm wavelength of the laser. A lattice dynamical technique, which utilizes the imperfect lattice Green’s functions, is used to calculate the expected magnitude of the actual strains induced in real crystals taking into account the effect of lattice point defects. The information on the elastic strength of these materials then enables the quantitative evaluation of laser induced mechanical damage thresholds in very good agreement with the available state-of-the-art figures.
You do not have subscription access to this journal. Cited by links are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.
You do not have subscription access to this journal. Article tables are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.
You do not have subscription access to this journal. Equations are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.
Axial peak power density.
Estimated from a critical power = 48 MW and Gaussian radius = 0.5 mm.
Estimated from a breakdown electric field = 1.95 MV/cm.
As cited in Table 1 of Ref. 32. Eq. (8a) with data from Ref. 32.
Sufficient experimental data not available.
Ref. 34 polycrystalline value.
Ref. 35 hexagonal crystal value. Eq. (9a) with elastooptic data from Ref. 36.
Ref. 37.
Ref. 38.
Ref. 39.
Ref. 40. Eq. (9b) with r41 and d41 data from Ref. 36.
Ref. 41.
Ref. 42.
Table III
Calculated Threshold Electric Fields for Mechanical Damage In Zinc Blende Crystals at 10.6-μm Laser Radiation (Eth in 106 V/cm)
Axial peak power density.
Estimated from a critical power = 48 MW and Gaussian radius = 0.5 mm.
Estimated from a breakdown electric field = 1.95 MV/cm.
As cited in Table 1 of Ref. 32. Eq. (8a) with data from Ref. 32.
Sufficient experimental data not available.
Ref. 34 polycrystalline value.
Ref. 35 hexagonal crystal value. Eq. (9a) with elastooptic data from Ref. 36.
Ref. 37.
Ref. 38.
Ref. 39.
Ref. 40. Eq. (9b) with r41 and d41 data from Ref. 36.
Ref. 41.
Ref. 42.
Table III
Calculated Threshold Electric Fields for Mechanical Damage In Zinc Blende Crystals at 10.6-μm Laser Radiation (Eth in 106 V/cm)