To enable the study of hydrocarbon reactions catalyzed by nickel surfaces and particles using reactive molecular dynamics on thousands of atoms as a function of temperature and pressure, we have developed the ReaxFF reactive force field to describe adsorption, decomposition, reformation and desorption of hydrocarbons as they interact with the nickel surface. The ReaxFF parameters were determined by fitting to the geometries and energy surfaces from quantum mechanics (QM) calculations for a large number of reaction pathways for hydrocarbon molecules chemisorbed onto nickel (111), (100) and (110) surfaces, supplemented with QM equations of state for nickel and nickel carbides. We demonstrate the validity and accuracy of ReaxFF by applying it to study the reaction dynamics of hydrocarbons as catalyzed by nickel particles and surfaces. For the dissociation of methyl on the (111), (100), and stepped (111) surfaces of nickel, we observe the formation of chemisorbed CH plus subsurface carbide. We observe that the (111) surface is the least reactive, the (100) surface has the fastest reaction rates, and the stepped (111) surface has an intermediate reaction rate. The importance of surface defects in accelerating reaction rates is highlighted by these results

Goddard, William A., III

Mueller, Jonathan E.

van Duin, Adri C. T.

English

Caltech Authors - Main

 1
Complete Parameters for ReaxFF Reactive Force Field for C/H/Ni 
Supporting Information for “Development and Validation of ReaxFF Reactive Force 
Field for Hydrocarbon Chemistry Catalyzed by Nickel.” 
Jonathan E. Mueller, Adri C. T. van Duin and William A. Goddard III 
 
This document contains the ReaxFF parameters in tabular form used for the Ni/C/H 
potential described above. Parameters in bold/italics were trained against the C/H/Ni 
training set presented in the above publication. 
 
 
General Parameters 
parameter unit value  parameter unit value  
1,bocp  - 50.0000  2,penp  - 6.9290  
2,bocp  - 9.5469 
 
3,penp  - 0.3842  
2,coap  - 26.5405 
 
4,penp  - 2.9294  
4,tripp  - 1.7224 
 
2,torp  - 5.7796  
3,tripp  - 6.8702 
 
3,torp  - 10.0000  
2kc  kcal/mol 60.4850 
 
4,torp  - 1.9487  
6,ovunp  - 1.0588 
 
2cot,p  - 2.1645  
2,tripp  - 4.6000 
 
1,vdWp  - 1.5591  
7,ovunp  - 12.1176 
 
CutoffOB ..  - 0.0010  
8,ovunp  - 13.3056 
 
4,coap  - 2.1365  
1,tripp  kcal/mol -70.5044 
 
4,ovunp  - 0.6991  
7,valp  - 33.8667 
 
3,ovunp  - 50.0000  
1,lpp  - 6.0891 
 
8,valp  - 1.8512  
9,valp  - 1.0563 
 
3,coap  - 2.6962  
10,valp  - 2.0384 
 
 
  
 
 
 2
Atom Parameters 
 σ
or  iVal  m  vdWr  ijD , γ  πor  eiVal  α  wγ  angleiVal
 
5ovunp  χ  
 Å - amu Å kcal/mol Å-1 Å - - Å-1 - kcal/mol eV 
C 1.3831 4.0000 12.0000 1.8814 0.1923 0.9000 1.1363 4.0000 9.7821 2.1317 4.0000 30.0000 5.9666 
H 0.8873 1.0000 1.0080 1.5420 0.0598 0.6883 -0.1000 1.0000 8.1910 30.9706 1.0000 0.0000 3.5768 
Ni 1.8201 2.0000 58.6900 1.9449 0.1880 0.8218 0.1000 2.0000 12.1594 3.8387 2.0000 0.0000 4.8038 
 
 
 η  ππ
or  2lpp , I  4bocp  3bocp  5bocp  2ovunp  3valp  
boc
iVal  5valp  
 eV Å kcal/mol kcal/mol - - - - - - - 
C 7.0000 1.2071 0.0000 186.1720 9.0068 34.9357 13.5366 -2.8983 2.5675 4.0000 2.9663 
H 10.5896 -0.1000 0.0000 54.0596 1.3986 2.1457 0.0003 -15.7683 2.1488 1.0000 2.8793 
Ni 7.3852 -1.0000 0.0000 95.6300 50.6786 0.6762 0.0981 -3.7733 3.6035 2.0000 2.5791 
 
 3
Bond Parameters 
 σ
eD   
π
eD  
ππ
eD  1,bep  5,bop  corr13
 
6,bop  1,ovunp  2,bep  3,bop  4,bop  1,bop  2,bop  
 kcal/mol kcal/mol kcal/mol - - - - - - - - - - 
C-C 143.3883 96.3926 76.4404 -0.7767 -0.4710 1.000 34.9900 0.5108 0.4271 -0.1116 9.0638 -0.0840 6.7452 
C-H 181.9084 0.0000 0.0000 -0.4768 0.0000 1.000 6.0000 0.7499 12.8085 1.0000 0.0000 -0.0608 6.9928 
H-H 168.2342 0.0000 0.0000 -0.2191 0.0000 1.000 6.0000 1.0062 6.1152 1.0000 0.0000 -0.0889 6.0000 
C-Ni 83.5810 9.0383 0.0000 0.2531 -0.200 1.000 16.0000 0.0529 1.4085 -0.1113 13.3900 -0.1436 4.5683 
H-Ni 114.7566 0.0000 0.0000 -0.8939 0.0000 1.000 6.0000 0.1256 0.1054 1.0000 0.0000 -0.1196 5.0815 
Ni-Ni 91.2220 0.0000 0.0000 -0.2538 -0.2000 0.000 16.0000 0.2688 1.4651 -0.2000 15.0000 -0.1435 4.3908 
 
Off Diagonal Terms 
 
ijD  vdWR  α  σor  πor  ππor  
 kcal/mol Å - Å Å Å 
C-H 0.1188 1.4017 9.8545 1.1203 -1.0000 -1.0000 
C-Ni 0.0800 1.7085 10.0895 1.5504 1.4005 -1.0000 
H-Ni 0.0366 1.7306 11.1019 1.2270 -1.0000 -1.0000 
 4
Angle Terms 
 
oΘ   1,valp  2,valp  1,coap  7,valp  1,penp  4,valp  
 degrees kcal/mol - kcal/mol - - - 
C-C-C 72.7917 38.5829 0.7209 0.0000 0.1409 17.4509 1.0670 
C-C-H 72.1533 14.2108 6.2512 0.0000 0.0100 0.0000 1.1022 
H-C-H 73.2608 24.9703 3.7807 0.0000 0.1335 0.0000 3.0461 
C-H-H 0.0000 0.0000 6.0000 0.0000 0.0000 0.0000 1.0400 
C-H-C 0.0000 7.5000 5.0000 0.0000 0.0000 0.0000 1.0400 
H-H-H 0.0000 27.9213 5.8635 0.0000 0.0000 0.0000 1.0400 
C-Ni-C 62.5000 16.6806 0.7981 0.0000 0.9630 0.0000 1.0711 
C-C-Ni 87.6241 12.6504 1.8145 0.0000 0.6154 0.0000 1.5298 
Ni-C-Ni 100.0000 40.4895 1.6455 0.0000 0.0100 0.0000 1.7667 
C-Ni-Ni 5.0994 3.1824 0.7016 0.0000 0.7465 0.0000 2.2665 
H-Ni-H 106.3969 30.0000 0.9614 0.0000 1.9664 0.0000 2.2693 
H-H-Ni 0.0000 26.3327 4.6867 0.0000 0.8177 0.0000 1.0404 
Ni-H-Ni 0.0000 60.0000 1.8471 0.0000 0.6331 0.0000 1.8931 
H-Ni-Ni 30.3748 1.0000 4.8528 0.0000 0.1019 0.0000 3.1660 
H-Ni-Ni 180.0000 -27.2489 8.3752 0.0000 0.8112 0.0000 1.0004 
C-Ni-H 97.5742 10.9373 2.5200 0.0000 1.8558 0.0000 1.0000 
C-H-Ni 0.0000 0.2811 1.1741 0.0000 0.9136 0.0000 3.8138 
H-C-Ni 84.0006 45.0000 0.6271 0.0000 3.0000 0.0000 1.0000 
 
 5
Torsion Terms 
 
 
1V   2V  3V  1,torp  1cot,p  
 kcal/mol kcal/mol kcal/mol - kcal/mol 
C-C-C-C -0.5000 53.0886 -0.1335 -6.2875 -1.9524 
C-C-C-H -0.4614   29.0459 0.2551 -4.8555 -2.7007 
H-C-C-H -0.2833 31.2867 0.2965 -4.8828 -2.4652 
X-C-H-X 0.0000 0.0000 0.0000 0.0000   0.0000 
X-H-H-X 0.0000 0.0000 0.0000 0.0000   0.0000 
X-C-C-X 0.0000 50.0000 0.3000 -4.0000 -2.0000 
C-C-C-Ni 0.0000 5.0000 0.4000 -6.0000 0.0000 
Ni-C-C-Ni 0.0000 44.3024 0.4000 -4.0000 0.0000 
H-C-C-Ni 0.0000 21.7038 0.0100 -4.0000 0.0000 
H-C-Ni-C 0.0000 5.2500 0.0100 -6.0000 0.0000 
C-C-Ni-C 0.0000 5.1676 0.0100 -5.9539 0.0000 
C-C-Ni-H 0.0000 5.1676 0.0100 -5.9539 0.0000 
 


Development and Validation of ReaxFF Reactive Force Field for Hydrocarbon Chemistry Catalyzed by Nickel

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A Theoretical Study of CH4 Dissociation on Pure and Gold-Alloyed Ni(111) Surfaces.

Ab initio Chemisorption Studies of CH3 on

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Ab Initio Simulation of Carbon Clustering on an Ni(111) Surface: A Model of the Poisoning of Nickel-Based Catalysts.

Activated Dissociative Chemisorption of CH4 on Ni(111): Observation of a Methyl Radical and Implication for the Pressure Gap in Catalysis.

Application of the ReaxFF Reactive Force Field to Reactive Dynamics of Hydrocarbon Chemisorption and Decomposition.

Atomistic-Scale Simulations of the Initial Chemical Events in the Thermal Initiation of Triacetonetriperoxide.

Binary Alloy Phase Diagrams.

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Cohesion in Metals; North-Holland:

Collision Induced Dissociative Chemisorption of CH4 on Ni(111) by Inert Gas Atoms: The Mechanism for Chemistry with a

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Dissociative Chemisorption: Dynamics and Mechanisms.

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Effect of d-Functions on MolecularOrbital Energies for Hydrocarbons.

Electronegativity Equalization Method for the Calculation of Atomic Charges in Molecules.

Embedded Diatomics-in-Molecules Potential Energy Function for Methyl Radical and Methane on Nickel Surfaces.

Empirical Interatomic Potential for Carbon, with Applications to Amorphous-Carbon.

Empirical Potential for Hydrocarbons for Use in Simulating the Chemical Vapor-Deposition of Diamond Films.

Energetics, and Reaction Barriers for CHx Bound to Ni(111) Surfaces.

Ethylene Hydrogenation on Ni(111) by Bulk Hydrogen.

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Finite Elastic Strain of Cubic Crystals.

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http://authors.library.caltech.edu/17896/1/Mueller2010p7421J_Phys_Chem_C.pdf

Development and Validation of ReaxFF Reactive Force Field for Hydrocarbon Chemistry Catalyzed by Nickel

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