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| == Example simulation == | | == Example simulation == |
− | Below, a simple example simulation for the methanation reaction is shown. The simulation is based on the input file as shown within the grey box. In the input file, you specify the compounds, the elementary reaction steps and the boundary conditions of the reaction. The microkinetic network is automatically constructed on the basis of the elementary reaction steps and the corresponding ordinary differential equations are solved over time. The results can be found in a series of data files as well as in ready-to-use graphs (see example graphs).
| + | [[Example simulation]] |
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− | [[Image:Derivative_methane_simulation.png|frame|Example graph of the Turn-over-frequency for the methanation reaction as a function of temperature.]]
| + | == Contact == |
− | | |
− | <pre>
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− | # Example input for methanation
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− | #
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− | # This is an example of a comment. Comments should have a # as the first character on a line.
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− | #
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− | ##############################################
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− | # the line below tells the program to start indexing all compounds
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− | &compounds
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− | settings)
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− | CO; 0; 1.0
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− | H2; 0; 3.0
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− | CH4; 0; 0.0
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− | H2O; 0; 0.0
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− | CO*; 1; 0.0
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− | H*; 1; 0.0
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− | C*; 1; 0.0
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− | CH*; 1; 0.0
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− | CH2*; 1; 0.0
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− | CH3*; 1; 0.0
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− | O*; 1; 0.0
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− | OH*; 1; 0.0
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− | H2O*; 1; 0.0
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− | *; 1; 1.0
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− | #################################
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− | # the line below tells the program to start indexing all reactions
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− | &reactions
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− | #
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− | # adsorptions / desorptions - Note that adsorptions and desorption can also be done with Arhenius (AR) equations
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− | # m^2 amu K sigma sticking J/mol
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− | HK; {CO} + {*} => {CO*}; 1e-19; 28; 2.73; 1; 1; 120e3
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− | HK; {H2} + 2{*} => 2{H*}; 1e-19; 2; 88; 2; 1; 80e3
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− | HK; {H2O} + {*} => {H2O*}; 1e-19; 18; 2; 2; 1; 63e3
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− | # Surface reactions
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− | # vf vb Eaf Eab
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− | AR; {CO*} + {*} => {C*} + {O*}; 6e11; 4e12; 65e3; 90e3
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− | AR; {C*} + {H*} => {CH*} + {*}; 1e13; 2e13; 40e3; 39e3
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− | AR; {CH*} + {H*} => {CH2*} + {*}; 2e12; 2e11; 75e3; 37e3
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− | AR; {CH2*} + {H*} => {CH3*} + {*}; 2e15; 4e13; 57e3; 47e3
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− | AR; {CH3*} + {H*} => {CH4} + 2{*}; 1e15; 3e9; 130e3; 57e3
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− | AR; 2{OH*} => {H2O*} + {O*}; 5e12; 5e13; 54e3; 28e3
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− | AR; {O*} + {H*} => {OH*} + {*}; 4e14; 5e14; 100e3; 67e3
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− | AR; {OH*} + {H*} => {H2O*} + {*}; 2e15; 4e13; 92e3; 30e3
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− | #################################
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− | # the lines below tell the program which settings we want to use
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− | &settings
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− | TYPE = SEQUENCERUN
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− | PRESSURE = 10
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− | #REAGENTS = {CO},{H2}
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− | #KEYCOMPONENTS = {CH4}
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− | #################################
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− | # the lines below tell the program which runs we want to perform
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− | &runs
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− | # Temp; Time; AbsTol; RelTol
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− | 400; 1e8; 1e-12; 1e-12
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− | 450; 1e6; 1e-12; 1e-12
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− | 500; 1e4; 1e-12; 1e-12
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− | 550; 1e2; 1e-12; 1e-12
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− | 600; 1e1; 1e-12; 1e-12
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− | 650; 1e1; 1e-12; 1e-12
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− | 700; 1e1; 1e-12; 1e-12
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− | 750; 1e1; 1e-12; 1e-12
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− | 800; 1e1; 1e-12; 1e-12
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− | 850; 1e1; 1e-12; 1e-12
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− | 900; 1e1; 1e-12; 1e-12
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− | 950; 1e1; 1e-12; 1e-12
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− | 1000; 1e1; 1e-12; 1e-12
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− | 1050; 1e1; 1e-12; 1e-12
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− | 1100; 1e1; 1e-12; 1e-12
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− | 1150; 1e1; 1e-12; 1e-12
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− | 1200; 1e1; 1e-12; 1e-12
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− | 1250; 1e1; 1e-12; 1e-12
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− | 1300; 1e1; 1e-12; 1e-12
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− | 1350; 1e1; 1e-12; 1e-12
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− | 1400; 1e1; 1e-12; 1e-12
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− | </pre>
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MKMCXX is a software suite for constructing and performing microkinetics simulations. MKMCXX allows you to perform complex microkinetic simulations with a large number of compounds and elementary reaction steps in a short amount of time. The core engine of MKMCXX is C++-based and hence very fast. On the basis of a single input file, you are able to perform a detailed microkinetic study on any reaction of interest. Besides these simulations, also various analytical tools are integrated. For instance, a degree of rate control analysis can be performed to identify rate-controlling steps. All this functionality can be controlled on the basis of single, simple to write, input file. Maybe the best of all, MKMCXX is completely free (as in beer) and may be used for educational, academic or commercial purposes. Please read the license for more details.