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Microkinetic Modeling of the Water Gas Shift Reaction on Copper and Iron Catalysts

Microkinetic Modeling of the Water Gas Shift Reaction on Copper and Iron Catalysts. Caitlin Callaghan, Ilie Fishtik & Ravindra Datta Fuel Cell Center Chemical Engineering Department Worcester Polytechnic Institute Worcester, MA November 8, 2002. Research Objectives .

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Microkinetic Modeling of the Water Gas Shift Reaction on Copper and Iron Catalysts

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  1. Microkinetic Modeling of the Water Gas Shift Reaction on Copper and Iron Catalysts Caitlin Callaghan, Ilie Fishtik & Ravindra Datta Fuel Cell Center Chemical Engineering Department Worcester Polytechnic Institute Worcester, MA November 8, 2002

  2. Research Objectives • Develop a predictive microkinetic model for LTS and HTS water gas shift catalysts • Identify the rate determining steps • Develop reduced model • Simulate the reaction for different catalysts (e.g. Cu, Fe, etc.) • Eventual goal is a priori design of catalysts for the water-gas-shift-reaction in fuel reformers for fuel cells

  3. Model Theory • Mechanism assumed to proceed via a set of ERs involving the active sites (S), surface intermediates (Ii), and terminal species (Ti). • The generic rate expressionfor each reaction is given by: Ref. Fishtik & Datta

  4. Developing the Model Identify (q) surface intermediates: H2OS, COS, CO2S, H2S, HS, OHS, OS, HCOOS Pre-exponential factors fromtransition state theory • 101 Pa-1s-1 – adsorption/desorption reactions • 1013 s-1 – surface reactions UBI-QEP methodused to generate ERs and calculate the energetic characteristics (H, Ea) of each ER based on three types of reactions: • 1. AB(g) + S  ABS • 2. AB(g) +S  AS + BS • 3. AS + BCS  ABS + CS

  5. Adsorption and Desorption Reactions Elementary Reactions s1 : H2O + S  H2OS s2 : CO + S  COS s3 : CO2S CO2 + S s4 : HS + HS H2S + S s5 : H2S H2 + S s6 : H2OS +S OHS + HS s7 : COS + OSCO2S + S s8 : COS + OHSHCOOS + S s9 : OHS + S OS + HS s10 : COS + OHS CO2S + HS s11 : HCOOS + S CO2S + HS s12 : HCOOS + OS CO2S + OHS s13 : H2OS + OS 2 OHS s14 : H2OS + HS OHS + H2S s15 : OHS + HS OH + H2S s16 : HCOOS + OHS  CO2S + H2OS s17: HCOOS + HS  CO2S + H2S

  6. Reaction Energetics • Pre-exponential factors • Pa-1s-1 (adsorption/ desorption steps) • s-1 (surface reaction) • Activation energies (kcal/mol)

  7. Simulation of Microkinetic Model for Cu(111), 13-step Ref. Fishtik & Datta, Surf. Sci. 512 (2002). Expt. Conditions Space time = 0.09 s FEED: COinlet = 0.15 H2Oinlet = 0.20 CO2 inlet = 0.05 H2 inlet = 0.05 Ref. Xue et al. Catal. Today, 30, 107 (1996).

  8. Simulation of Microkinetic Model for Cu(111), 15-step Expt. Conditions Space time = 1.80 s FEED: COinlet = 0.10 H2Oinlet = 0.10 CO2 inlet = 0.00 H2 inlet = 0.00

  9. Simulation of Microkinetic Model for Fe(111), 15-step Expt. Conditions Space time = 1.17 s FEED: COinlet = 0.10 H2Oinlet = 0.10 CO2 inlet = 0.00 H2 inlet = 0.00

  10. Reaction Route Analysis • A Reaction Route is the result of a linear combination of q+1 ERs that produces the desired overall reaction. • 450 Possible Reaction Routes were found including • Empty Roots The net reaction is zero. • Non-Empty Roots The net reaction is the WGSR. • 70 Unique Reaction Routes remain • 17 Routes previously examined (Fishtik & Datta, Surf. Sci. 512 (2002).) • 53 New Roots based on s14,s15,s16 & s17 contribution

  11. Unique Reaction Routes formate reaction route RR1 = s1 + s2 + s3 + s4 + s5 + s6 + s8 + s11 redox reaction route RR2 = s1 + s2 + s3 + s4 + s5 + s6 + s7 + s9 associative reaction route RR3 = s1 + s2 + s3 + s4 + s5 + s6 + s10 modified redox reaction route RR18 = s1 + s2 + s3 + s5 + s6 + s7 + s15

  12. Energy Diagram Analysis

  13. RR Contributions on Cu(111) Equilibrium RR1 & RR3 RR2 Total Mechanism

  14. RR Contributions on Fe(111) Equilibrium RR1, RR3, RR18 & RR19 Total Mechanism

  15. Reaction Route Combination • The ERs of each dominant RR are combined to generate a “net” RR • Simplified Model involving only 13 ERs

  16. Quasi-Equilibrium Reactions • Identified by affinity calculations • s1,s2,s3,s4,s5,s7,s11 • All intermediates represented except OHS Reducing the Model Rate Determining Steps • Copper: s6,s8,s10,s15 • Iron: s6,s8,s10,s12,s15 Quasi-Steady State Species • OHS

  17. 12-Step, 4-Route, 4-RDS Model s1: H2O + S  H2OS EQ s2: CO + S  COS EQ s6: H2OS + S  OHS + HS RDS s8: COS + OHS  HCOOS + S RDS s10:COS + OHS  CO2S + HS RDS s12: CO2S + OHS  OS + HCOOS RDS s15: OHS + HS  OS + H2S RDS s2 + s3 + s7: CO + OS  CO2 + S EQ s3: CO2S  CO2 + S EQ 1/2(s4 + s5): HS  1/2H2 + S EQ s3+1/2s4+1/2s5 + s11: HCOOS  CO2 + 1/2H2 + S EQ

  18. Rate Expressions RR1 RR3 RR19 RR18

  19. WGSR Mechanism r6 A6 r8 r10 r12 r15 A8 = A9 = A10 = A12 = A15 r

  20. Overall Rate Expression • IRRs and ERs combine to indicate the dominant rates of each RR • Cu(111):r12 neglected • Fe(111):r12 included • Overall Rate Expression r = r8 + r9 + r10 + r12 + r15

  21. Simplified Model

  22. Conclusions • A reliable predictive microkinetic model for the WGS reaction on Cu(111) and Fe(111) is developed. • Only a limited number of RRs dominate the kinetics of the process (RR1,RR3,RR18,RR19). • Prediction of simplified models compare extremely well with the complete microkinetic model. • The addition of s14 and s15 dramatically affected the model for WGS on copper; the model for iron remained unaffected. RR18 requires further investigation.

  23. Questions…

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