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Cantera
2.3.0
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| ▼Global Data | |
| Physical Constants | |
| Error Handling | These classes and related functions are used to handle errors and unknown events within Cantera |
| Input File Handling | |
| ▼Diagnostic Output | |
| Writing messages to the screen | |
| Templated Utility Functions | These are templates to perform various simple operations on arrays |
| Chemical Equilibrium | |
| Equilfunctions | |
| ▼Chemical Kinetics | |
| Falloff Parameterizations This section describes the | Parameterizations used to describe the fall-off in reaction rate constants due to intermolecular energy transfer |
| Kinetics Managers | |
| Surface Problem Solver Methods | |
| Surface Problem Bulk Phase Mode | Functionality expected from the bulk phase |
| Stoichiometry | Note: these classes are designed for internal use in class ReactionStoichManager |
| Numerical Utilities within Cantera | Cantera contains some capabilities for solving nonlinear equations and integrating both ODE and DAE equation systems in time |
| ODE Integrators | |
| Solvers for Equation Systems | |
| One-Dimensional Reacting Flows | |
| ▼Models of Phases of Matter | These classes are used to represent the composition and state of a single phase of matter |
| Electric Properties of Phases | Treatment of the Phase Potential and the electrochemical potential ofa species |
| Transport Properties for Species in Phases | These classes provide transport properties |
| ▼Thermodynamic Properties | These classes are used to compute the thermodynamic properties of phases of matter |
| Species Standard-State Thermodynamic Properties | In this module we describe Cantera's treatment of pressure dependent standard states (PDSS) objects |
| Species Reference-State Thermodynamic Properties | To compute the thermodynamic properties of multicomponent solutions, it is necessary to know something about the thermodynamic properties of the individual species present in the solution |
| Managers for Calculating Standard-State | Thermodynamics |
1.8.14