Results 211 to 220 of about 3,732 (262)

Thermal runaway in germanium laser windows

Applied Optics, 1982
A 1-D model of thermal runaway in germanium induced by IR laser radiation is presented. The model examines the influence of the temperature dependent thermal conductivity.
K, Wilner, E, Klinger, W J, Wild
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Thermal runaway and thermal runaway propagation in batteries: What do we talk about?

Journal of Energy Storage, 2019
Abstract Investigations describing incidents with electrochemical cells, in which the cell heats up and is either destroyed or severely damaged, causing damage to the immediate environment of the cell, are frequently referred to as “thermal runaway“. However, the term is used in most papers without a clear definition of what is meant.
Alexander Börger, Jan Mertens, Heinz Wenzl   +2 more
openaire   +1 more source

Plane structures in thermal runaway

Israel Journal of Mathematics, 1993
zbMATH Open Web Interface contents unavailable due to conflicting licenses.
Herrero, M. A., Velázquez, J. J. L.
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Thermal Runaway in Integrated Circuits

IEEE Transactions on Device and Materials Reliability, 2006
In deep submicrometer technologies, increased standby leakage current in high-performance processors results in increased junction temperature. Elevated junction temperature causes further increase on the standby leakage current. The standby leakage current is expected to increase even more under the burn-in environment leading to still higher junction
A. Vassighi, M. Sachdev
openaire   +1 more source

Thermal Runaway in Germanium Laser Windows

Applied Optics, 1971
The absorption coefficient of 50-Omega cm germanium was measured over the 400-2000 cm(-1) wavenumber region for temperatures from 300 K to 450 K. Lattice absorption is negligible for wavenumbers greater than 900 cm(-1); at a wavelength of 10.6 microm the absorption is due entirely to free carrier effects.
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Thermal runaways: Problems with agitation

Plant/Operations Progress, 1986
AbstractHeat flow calorimetry‐an analytical technique to identify agitation hazards.
E. D. Weir, G. W. Gravenstine, T. F. Hoppe   +2 more
openaire   +1 more source

Thermal Runaway in the Earth's Mantle

Studies in Applied Mathematics, 1986
We examine the possibility that thermal runaway may occur locally in the earth's asthenosphere, due to a coupling between the velocity and temperature fields due to a strongly temperature‐dependent viscosity. The analysis is based on a partial description of convection in the earth, in which the boundary‐layer nature of the motion is taken into account.
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Transition from Thermal Runaway to Propagating Flames

SIAM Journal on Applied Mathematics, 1991
Summary: In analysing thermal runaway in reactive-diffusive systems, it can be seen that diffusion and conduction become significantly reduced in importance towards the final stages. As a result, these diffusive effects play a negligible role in the early structure of the reaction waves that finally emerge from an ignition kernel.
Henderson, KL, Dold, JW
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Control of thermal runaway—some mathematical insights

International Journal of Heat and Mass Transfer, 1998
zbMATH Open Web Interface contents unavailable due to conflicting licenses.
Geer, James, Fillo, John
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Thermal runaway of IMPATT diodes

IEEE Transactions on Electron Devices, 1975
A simple one-dimensional computer model of the dc-thermal behavior of a Schottky-barrier GaAs IMPATT diode has been formulated to compute the conditions for thermal runaway in IMPATT diodes of various designs. The model has been used to determine the thermal stability conditions for three designs of GaAs IMPATT's.
openaire   +1 more source