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Proceedings Paper

Algorithm for calculating nonisothermal diffusion-limited outgassing rates
Author(s): Timothy J. Girard; Richard M. Payton
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Paper Abstract

Formulas exist for prediction of diffusion limited outgassing rates under isothermal conditions. An algorithm has now been developed that predicts outgassing rates for material species that outgas via diffusion mechanisms for non-isothermal conditions. The algorithm uses initial species mass, diffusion coefficient, activation energy and a temperature history to determine outgassing rates at prescribed times. The algorithm accounts for bulk material temperature variations through time but does not account for thermal gradients through the material thickness. The non-isothermal mass loss equation is derived from a basic isothermal mass loss equation with the term that indicates species molecular propagation for the non-isothermal conditions. For isothermal conditions, the product of D(T) (where temperature T, is constant) and time is a measure of the species molecular propagation. This term in the isothermal mass loss equation is replaced with the term for non-isothermal molecular propagation, which is the integral over time of D(T) (where temperature, T, is time dependent). Temperature dependent outgassing rates are calculated by numerically differentiating the time and temperature dependent mass loss predictions. Mass loss rates for the non-isothermal conditions are compared to isothermal mass loss rates.

Paper Details

Date Published: 11 January 1993
PDF: 5 pages
Proc. SPIE 1761, Damage to Space Optics, and Properties and Characteristics of Optical Glass, (11 January 1993); doi: 10.1117/12.138919
Show Author Affiliations
Timothy J. Girard, Martin Marietta Astronautics Group (United States)
Richard M. Payton, Martin Marietta Astronautics Group (United States)


Published in SPIE Proceedings Vol. 1761:
Damage to Space Optics, and Properties and Characteristics of Optical Glass
James B. Breckinridge; Alexander J. Marker, Editor(s)

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