Numerical Treatment Of Laser Interaction With Solid In One Dimension
Abstract
The laser radiation has great important in many applications. In this paper we have studied
the influence of laser radiation on solid material. We use a (800 μs) pulsed laser ND: YAG
with (1.06 μ m) wave length, (3 J) energy and power density of (7.6 X 106 W/cm2) . We have
deduced a mathematical function for laser energy with time, then deducing a function for laser
power density with time because practically assumed to be constant.
A lead material used in this paper for study, we have deduced mathematical functions for
thermal properties (conductivity, specific heat, density, diffusivity) with temperature, and
solve the partial differential equation (P.D.E) which represent the heat transfer of laser
radiation to the material in one dimension, presumes variable and constant laser density ( I=I0
and I=I(t)) , also the thermal properties conductivity , specific heat ,density and diffusivity (
K=K0 and K=K(T),C=C0 and C=C(T), ( ) 0 and T ,du=du0 and du=du(T))
respectively .
The results reveal that the time of evaporation increase when the laser density is taken as
variable with time , also it increase when the thermal properties were vary with temperature .
We used (Matlab 7.0) to perform all programs which related with this paper
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Copyright (c) 2009 Hameed H Hameed, Hayder M Abaas
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