BTEC Thermal Model

BTEC Thermal Model

AFRL/RHDO has developed a configurable, laser-tissue interaction model that includes components from various areas of Biophysics. The model predicts heat transfer in biological tissue, in either one-dimension or two-dimensional cylindrical coordinates, and is coupled to an Arrhenius damage model. A...

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Bibliographische Detailangaben
Hauptverfasser: Irvin, Lance J, Maseberg, P D, Buffington, Gavin D, Clark, III , Clifton D, Thomas, Robert J, Edwards, Michael L, Stolarski, Jacob
Format: Report
Sprache:eng
Schlagworte:
ACCURACY
APPROXIMATION(MATHEMATICS)
ARREHIUS INTEGRAL
Biology
BIOPHYSICS
BOUNDARY CONDITIONS
COHERENT OPTICAL RADIATION
EMITTERS
FINITE DIFFERENCE THEORY
GAUSSIAN BEAM PROPAGATION
HEAT TRANSFER
HELMHOLTZ WAVE EQUATION
INTERACTIONS
Lasers and Masers
MONTE CARLO METHOD
ONE DIMENSIONAL
PE62202F
PERFUSION EFFECTS
STABILITY
THERMAL MODELS
Thermodynamics
TISSUES(BIOLOGY)
TWO DIMENSIONAL
VERIFICATION
WUAFRL7757B226
Z-SCAN SIMULATION
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Beschreibung
Zusammenfassung:AFRL/RHDO has developed a configurable, laser-tissue interaction model that includes components from various areas of Biophysics. The model predicts heat transfer in biological tissue, in either one-dimension or two-dimensional cylindrical coordinates, and is coupled to an Arrhenius damage model. A simulation can be configured as a single run, or a damage-threshold search. Multiple models for describing the laser-tissue interaction are available, including linear absorption (1D, 2D), Monte Carlo scattering (2D) and Beam Propagation Methods using Finite Difference approximations or Hankel Transform methods (2D). The original document contains color images.