Model-based Analysis of PEFC Catalyst Degradation Mechanisms

Model-based Analysis of PEFC Catalyst Degradation Mechanisms
Thomas Kadyk, Steven G. Rinaldo, Michael Eikerling International Symposium on Electrocatalysis

Literature: In-Situ Degradation
Correlation between decay in cell voltage and ECSA loss P.J. Ferreira et al. J. Electrochem. Soc. 152(11):A2256 (2005) 10/28/2014 ECAT2014

Literature: Ex-Situ Degradation
Correlation between changes in particle radius distribution (PRD) and ECSA loss → theoretical link between PRD evolution and ECSA loss K.J.J. Mayrhofer et al. Electrochem. Comm. 10:1144 (2008) 10/28/2014 ECAT2014

Outline Catalyst Layer Degradation Model
Fitting Experimental Accelerated Stress Tests Model Based Analysis Conclusions and Summary 10/28/2014 ECAT2014

Degradation Mechanisms
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dissolution and redeposition [1,2]
Model Equations dissolution and redeposition [1,2] coagulation [3] detachment dimensionless, normalized particle radius distribution rate of particle radius change particle creation and extinction terms detachment rate, assumed radius independent [1] I. Lifshitz, V. Slyozov, J. Phys. Chem. Solids 19:35 (1961) [2]C. Wagner, Z. Elektrochem. 65:581 (1961) [3] V. Smoluchowski, Z. Phys. Chem. 92:129 (1917) [Steven G. Rinaldo, PhD Thesis, SFU, 2013) 10/28/2014 ECAT2014

Kinetics of Dissolution and Redeposition
Pt mass balance assumption: c(t=0) = 0 characteristic radius surface tension mass moment [1] D. Talapin, A. Rogach, M. Haase, H. Weller, J. Phys. Chem. B 105:12278 (2001) 10/28/2014 ECAT2014

Kinetics of Coagulation
particles formed: particles coagulating: radius of particle formed from merging of two particles with radii and coagulation rate kernel, assumed constant (random collisions) [1] V. Smoluchowski, Z. Phys. Chem. 92:129 (1917) 10/28/2014 ECAT2014

Fitting Experimental Data
Accelerated Stress Tests: potential cycling V or V vs. RHE triangular or square wave form 10/28/2014 ECAT2014

Starting Point for Fit: fitting of single mechanisms separately dissolution and redeposition: 𝑅 0 0 , 𝑘 𝑑𝑖𝑠 0 , 𝑘 𝑟𝑑𝑝 0 coagulation: 𝑘 𝑐𝑔𝑙 0 detachment: 𝑘 𝑑𝑒𝑡 0 start point for single mechanism fit screened over 5-8 orders of magnitude Fit of 0.9V data converged into 2 parameter sets for dissolution/redeposition 2 start points for 0.9V fits 10/28/2014 ECAT2014

For 0.9V full model fits converged to 2 parameter sets low dissolution and high coagulation high dissolution and low coagulation Additional tests with varied start parameters 0.9 V dependency of the fit on start parameters ambiguity of dissolution/redeposition and coagulation detachment always negligible 1.2 V fit converge into approximately the same solution 10/28/2014 ECAT2014

Analyzing Individual Mechansism’s Contributions
PRD change of each mechanism ECSA loss from each mechanism 10/28/2014 ECAT2014

e.g. coagulation term cycle number↑ number of cycles r [m]
particles lost or gained ECSA loss 10/28/2014 ECAT2014

Square Wave 0.9V time (cycles) time (cycles) time (cycles)
deconvoluting individual mechanism’s contributions 45% ECSA loss due to dissolution/redeposition 2.5% ECSA loss due to coagulation negligible ECSA loss due to detachment time (cycles) 10/28/2014 ECAT2014

dynamic interplay between mechanisms rapid initial dissolution of small particles later regaining of ECSA due to redeposition caused by disturbance of the dissolution-redeposition equilibrium due to the other mechanisms time (cycles) 10/28/2014 ECAT2014

Summary and Conclusions
Degradation model linking PRD and ECSA loss dissolution and redeposition coagulation detachment Fitting experimental accelerated stress tests ambiguity of dissolution/redeposition and coagulation at low upper potential limit Model-based analysis deconvolute individual mechanism’s contribution to ECSA loss dynamic interaction of mechanisms 10/28/2014 ECAT2014

Model-based Analysis of PEFC Catalyst Degradation Mechanisms
Thank you for your attention! Model-based Analysis of PEFC Catalyst Degradation Mechanisms Thomas Kadyk, Michael Eikerling International Symposium on Electrocatalysis

coagulation term t↑ time (cycles) r [m] time (cycles) 10/28/2014
ECAT2014 time (cycles)

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Triangular Wave 1.2V time (cycles) time (cycles) time (cycles)
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Triangular Wave 0.9V time (cycles) time (cycles) time (cycles)
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Square Wave 0.9V – 2nd Start Point
time (cycles) time (cycles) time (cycles) time (cycles) 10/28/2014 ECAT2014

Triangular Wave 0.9V – 2nd Start Point
time (cycles) time (cycles) time (cycles) time (cycles) 10/28/2014 ECAT2014

Accelerated Stress Test: square or triangular waveform (SW,TW) cycling between 0.6–0.9 V or V vs. RHE 10/28/2014 ECAT2014

Particle Radius Distribution
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Solving Coupled Model: Numerical Issues
Convergence problems for SN → 0 ODE solver (variable-order solver based on numerical differentiation formulas [1]) Numerical mass loss for coagulation improved numerical integration Speed up code [1] L.F. Shampine et al. SIAM J. Sci. Comput. 18:1 (1997) 10/28/2014 ECAT2014

Fitting Strategy least-squares method
heuristic, derivative-free Nelder-Mead simplex algorithm [1] Starting Point: fitting of single mechanisms separately dissolution and redeposition: 𝑅 0 0 , 𝑘 𝑑𝑖𝑠 0 , 𝑘 𝑟𝑑𝑝 0 coagulation: 𝑘 𝑐𝑔𝑙 0 detachment: 𝑘 𝑑𝑒𝑡 0 using those parameters as starting point [1] J.C. Lagarias et al., SIAM J. Optim. 9(1):112 (1998) 10/28/2014 ECAT2014

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