The Hydrogenation of N Molecules on a Stepped Ru(0001 ... - hi
Transcript of The Hydrogenation of N Molecules on a Stepped Ru(0001 ... - hi
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface
Conversion of DFT into Gibbs Free Energyvalues and Approximate Effects of
Electrodes Potential Difference
Egill SkulasonUniversity of Iceland
Department of [email protected]
14th of April 2004
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Contents• Background
– The ammonia synthesis in nature vs. industrial– Theoretical resource of ammonia synthesis
• The Methodology– Conversion of DFT into Gibbs Free Energy values– Approximate Effects of Electrodes Potential Difference
• The hydrogenation of N2 molecules and N atoms on astepped Ru(0001) surface
• Conclusions
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Background
• The conversion of atmospheric N2 into abiologically accessible form of nitrogen such asammonia (NH3), is termed nitrogen fixation.
• Since the element N is present in manybiomolecules, such as amino acids, nitrogenfixation is a prerequisite for life.
• In spite of the vast quantities of atmospheric N2,the sources of biologically accessible nitrogen arefew.
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• Oxidation of N2 to nitrogenoxides by lightning andcombustion.
• The commercial Haber-Boschprocess where N2 reacts withhydrogen on a Fe or Ru basedcatalyst to form ammonia.
• The enzyme catalyzedammonia synthesis where N2reacts with electrons andprotons to form ammonia.
L. Stryer, Biochemistry, 4. Ed. (W.H. Freeman and Company, New York, 1995), p. 714.
The Ammonia Synthesis inNature vs. Industrial
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Theoretical Resource ofAmmonia Synthesis
• Hydrogenation of N atoms on the– Ru(0001) surface– Stepped Ru(0001) surface
• Hydrogenation of N2 molecules on the– FeMoco Model– Ru(0001) surface– Stepped Ru(0001) surface
Stepped Surface
Surface
FeMoco Model
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Hydrogenation ofN atoms on the
Ru(0001) Surfacewith and without a Step
T.H. Rod, A. Logadottir & J.K. Norskov, J.Chem.Phys.,Vol 112, No. 12, 2000, p. 5343
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
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Hydrogenation ofN2 Molecules in
Gas Phase and onthe FeMoco Model
T.H. Rod, A. Logadottir & J.K. Norskov, J.Chem.Phys.,Vol 112, No. 12, 2000, p. 5343
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
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Hydrogenation ofN2 Molecules on
the Ru(0001)Surface and on the
FeMoco Model
T.H. Rod, A. Logadottir & J.K. Norskov, J.Chem.Phys.,Vol 112, No. 12, 2000, p. 5343
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
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The Methodology
• Conversion of DFT into Gibbs Free Energy values :ΔH = ΔEDFT + ZPEΔG = ΔH - TΔS
• Approximate Effects of Electrodes PotentialDifference:
Over all reaction: N2 + 3H2 ↔ 2NH3The anode reaction: H2 ↔ 2H+ + 2e-
The cathode reaction: N2 + 6H+ + 6e- ↔ 2NH3
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The Methodology
• The Gibbs free energy is calculated from the DFTand Zero Point Energy values (which are at 0 V).
• Than the number of electrons (with the elementarycharge e), multiplied with the cell potential (U), isadded to ΔG(0):
ΔG(U) = ΔG(0) + eU• All states involving an electron in the electrode, will
simply be shifted in energy by eU.
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1. Ru + N2 + 6(H+ + e-) shifted by 6U2. Ru-N2 + 6(H+ + e-) shifted by 6U3. Ru-N2H + 5(H+ + e-) shifted by 5U4. Ru-N2H2 + 4(H+ + e-) shifted by 4U5. Ru-N2H3 + 3(H+ + e-) shifted by 3U6. Ru-N2H4 + 2(H+ + e-) shifted by 2U7. Ru-NH2 +NH3 + (H+ + e-) shifted by 1U8. Ru-NH3 +NH3 not shifted9. Ru + 2NH3 not shifted
The Hydrogenation of theN2 Molecules and the
Shifted Steps in the Reaction
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface.
- ΔE values at 0 V -
1.85
1.23
1.90
1.37
1.02 0.95
-0.73-0.93
0.00
-2.00
-1.00
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0 1 2 3 4 5 6 7 8 9 10
En
erg
y [
eV
]
DE at 0 V
1 Ru + N2 + 3H22 Ru-N2 + 3H23 Ru-N2H + 5/2 H24 Ru-N2H2 + 2 H25 Ru-N2H3 + 3/2 H26 Ru-N2H4 + H27 Ru-NH2 +NH3 + 1/2H28 Ru-NH3 +NH39 Ru + 2NH3
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface.
- ΔG values at 0 V -
0.71 0.68
1.72 1.70 1.712.01
-0.15 -0.05 0.00
1.85
1.23
1.90
1.37
1.02 0.95
-0.73-0.93
0.00
-2.00
-1.00
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0 1 2 3 4 5 6 7 8 9 10
En
erg
y [
eV
]
DG at 0 VDE at 0 V
1 Ru + N2 + 3H22 Ru-N2 + 3H23 Ru-N2H + 5/2 H24 Ru-N2H2 + 2 H25 Ru-N2H3 + 3/2 H26 Ru-N2H4 + H27 Ru-NH2 +NH3 + 1/2H28 Ru-NH3 +NH39 Ru + 2NH3
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface.
- ΔG values at -0.3 V -
0.71 0.68
1.72 1.70 1.712.01
-0.15 -0.05 0.00
2.51 2.48
3.22
2.902.61 2.61
0.15-0.05 0.00
1.85
1.23
1.90
1.37
1.02 0.95
-0.73-0.93
0.00
-2.00
-1.00
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0 1 2 3 4 5 6 7 8 9 10
En
erg
y [
eV
]
DG at 0 V
DG at -0.3 VDE at 0 V
1 Ru + N2 + 3H22 Ru-N2 + 3H23 Ru-N2H + 5/2 H24 Ru-N2H2 + 2 H25 Ru-N2H3 + 3/2 H26 Ru-N2H4 + H27 Ru-NH2 +NH3 + 1/2H28 Ru-NH3 +NH39 Ru + 2NH3
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface.
- ΔG values at -0.6 V -
0.71 0.68
1.72 1.70 1.712.01
-0.15 -0.05 0.00
2.51 2.48
3.22
2.902.61 2.61
0.15-0.05 0.00
4.31 4.28
4.72
4.10
3.513.21
0.45
-0.05 0.00
1.85
1.23
1.90
1.37
1.02 0.95
-0.73-0.93
0.00
-2.00
-1.00
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0 1 2 3 4 5 6 7 8 9 10
En
erg
y [
eV
]
DG at 0 V
DG at -0.3 VDG at -0.6 VDE at 0 V
1 Ru + N2 + 3H22 Ru-N2 + 3H23 Ru-N2H + 5/2 H24 Ru-N2H2 + 2 H25 Ru-N2H3 + 3/2 H26 Ru-N2H4 + H27 Ru-NH2 +NH3 + 1/2H28 Ru-NH3 +NH39 Ru + 2NH3
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface.
- ΔG values at -0.9 V -
0.71 0.68
1.72 1.70 1.712.01
-0.15 -0.05 0.00
2.51 2.48
3.22
2.902.61 2.61
0.15-0.05 0.00
4.31 4.28
4.72
4.10
3.513.21
0.45
-0.05 0.00
6.11 6.086.22
5.30
4.41
3.81
0.75
-0.05 0.00
1.85
1.23
1.90
1.37
1.02 0.95
-0.73-0.93
0.00
-2.00
-1.00
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0 1 2 3 4 5 6 7 8 9 10
En
erg
y [
eV
] DG at 0 VDG at -0.3 V
DG at -0.6 VDG at -0.9 V
DE at 0 V
1 Ru + N2 + 3H22 Ru-N2 + 3H23 Ru-N2H + 5/2 H24 Ru-N2H2 + 2 H25 Ru-N2H3 + 3/2 H26 Ru-N2H4 + H27 Ru-NH2 +NH3 + 1/2H28 Ru-NH3 +NH39 Ru + 2NH3
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
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The Hydrogenation of N2 Moleculeson a Stepped Ru(0001) Surface.
- ΔG values at -1.04 V -
0.71 0.68
1.72 1.70 1.712.01
-0.15 -0.05 0.00
2.51 2.48
3.22
2.902.61 2.61
0.15-0.05 0.00
4.31 4.28
4.72
4.10
3.513.21
0.45
-0.05 0.00
6.11 6.086.22
5.30
4.41
3.81
0.75
-0.05 0.00
6.95 6.92 6.92
5.86
4.83
4.09
0.89
-0.05 0.00
1.85
1.23
1.90
1.37
1.02 0.95
-0.73-0.93
0.00
-2.00
-1.00
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0 1 2 3 4 5 6 7 8 9 10
En
erg
y [
eV
] DG at 0 VDG at -0.3 V
DG at -0.6 VDG at -0.9 VDG at -1.04 V
DE at 0 V
1 Ru + N2 + 3H22 Ru-N2 + 3H23 Ru-N2H + 5/2 H24 Ru-N2H2 + 2 H25 Ru-N2H3 + 3/2 H26 Ru-N2H4 + H27 Ru-NH2 +NH3 + 1/2H28 Ru-NH3 +NH39 Ru + 2NH3
E. Skulason, T. Bligaard, H. Jonsson & J.K. Norskov, unpublished
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
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The Hydrogenation of Nitrogen Atomson a Stepped Ru(0001) Surface.
- ΔG values at -0.2 V -
A. Logadottir & J.K. Norskov, unpublished
Calculational detailsDFT program: DACAPOPlane-wavesGGAPseudopotentialsRPBE functional
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Conclusions• The second hydrogen atom adsorbs on the outer nitrogen
atom on the stepped Ru(0001) surface while it adsorbs onthe inner nitrogen atom on the Ru(0001) surface and theFeMoco Model.
• The hydrogenation of the N atoms is more feasible than ofthe N2 molecules on the stepped Ru(0001).
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Table with the CalculationsSpecies Energy [eV] ZPE [eV] S [J/(K*mol)] - TS [eV] H [eV] G [eV]
Ru -13650.28 0 0 -13650.28 -13650.28
Ru-N2 -14193.85 0.2 -0.05 -14193.65 -14193.70
Ru-N2H -14209.19 0.5 -0.05 -14208.69 -14208.74
Ru-N2H2 -14225.73 0.94 -0.05 -14224.79 -14224.84
Ru-N2H3 -14242.09 1.23 -0.05 -14240.86 -14240.91
Ru-N2H4 -14258.17 1.53 -0.05 -14256.64 -14256.69
Ru-NH2 -13955.43 0.8320 -0.0367 -13954.60 -13954.64
Ru-NH3 -13971.64 1.1245 -0.0984 -13970.51 -13970.61
H2 g -32.02 0.2730 130.6840 -0.4064 -31.75 -32.16
N2 g -542.94 0.1460 191.6100 -0.5959 -542.79 -543.39
NH3 g -320.43 0.8900 238.9700 -0.7432 -319.54 -320.28