Ab initio Calculations of Interfacial Structure and Dynamics in Fuel Cell Membranes
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Ab initio Calculations of Interfacial Structure and Dynamics in Fuel Cell Membranes
Ata Roudgar, Sudha P. Narasimachary and Michael EikerlingDepartment of Chemistry Simon Fraser University, Burnaby, BC Canada
2. Model of Hydrated Interfaces inside PEMs
1. Introduction
Effective properties (proton conductivity, water transport, stability)
hydrophobic phase
hydrophilic phase
Primary chemical structure• backbones• side chains • acid groups
Molecular interactions (polymer/ion/solvent), persistence length
Self-organizationinto aggregatesand dissociation
Secondary structure• aggregates • array of side chains• water structure
“Rescaled” interactions (fluctuating sidechains,mobile protons, water)
Heterogeneous PEM• random phase separation• connectivity• swelling
Focus on Interfacial Mechanisms of PT
Insight in view of fundamental understanding and design:
Objectives Correlations and mechanisms of proton transport in interfacial layer Is good proton conductivity possible with minimal hydration?
Assumptions: decoupling of aggregate and side chain dynamics map random array of surface groups onto 2D array terminating C-atoms fixed at lattice positions remove supporting aggregate from simulation
Feasible model of hydrated interfacial layer
3. Stable Structural Conformation
Side view
fixed carbon positions
__
3 3 23 x CF SO H + H OUnit cell:
Ab initio calculations based on DFT (VASP) formation energy as a function of dCC
effect of side chain modification binding energy of extra water molecule energy for creating water defect
2D hexagonal array of surface groups
dCC
Upon increasing sidechain there is a transition from “upright” to “tilted” structure occurs at dCC = 6.5Å
independent highly correlated
Formation energy as a function of sidechain separation for regular array of Triflic acid, CF3-SO3-H
Collective Coordinates and Minimum Reaction Path
Regular 10x10x10 grid of points is generated. Each point represents one configuration of the these three CCs.
At each of these positions a geometry optimization including all remaining degrees of freedom is performed.
The path which contains the minimum configuration energy is identified (as shown).
1 2 3
Three collective coordinates: hydronium motion r, surface group rotation and surface group tilting .
r
Correlations in interfacial layer are strong function of sidechain density.
Transition between upright (“stiff”) and tilted (“flexible”) configurations at dCC = 6.5Å involves
hydronium motion, sidechain rotation, and sidechain tilting.
Reducing interfacial dynamics to the evolution of 3 collective coordinates enabled
determination of transition path (activation energy 0.55 eV).
The binding energy of second shell becomes weak at small dcc No proton transfer from
interface to bulk is expected.
• A. Roudgar, S. Narasimachary and M. Eikerling, J. Phys. Chem. B 110, 20469 (2006).• A. Roudgar, S.P. Narasimachary, M. Eikerling .Chem. Phys. Lett. 457, 337 (2008)• M. Eikerling and A.A. Kornyshev, J. Electroanal. Chem. 502, 1-14 (2001). K.D. Kreuer, J. Membrane Sci. 185, 29- 39 (2001).• C. Chuy, J. Ding, E. Swanson, S. Holdcroft, J. Horsfall, and K.V. Lovell, J. Electrochem. Soc. 150, E271-E279 (2003).• E. Spohr, P. Commer, and A.A. Kornyshev, J. Phys.Chem. B 106, 10560-10569 (2002).• M. Eikerling, A.A. Kornyshev, and U. Stimming, J. Phys.Chem.B 101, 10807-10820 (1997).
References
6. Conclusions
The tilted structure can be found in 3 different states: - fully dissociated - partially dissociated - non-dissociated
The largest formation energy E = -2.78 eV at dCC = 6.2 Å corresponds to the upright structure.
DE= 0.55eV
4. Proton Transform Mechanism at Interface
Computational details
Understanding the effect of chemical architecture, phase separation, and random morphology on transport properties and stability of polymer electrolyte membranes (PEM) is vital for the design of advanced proton conductors for polymer electrolyte fuel cells.
Low temperature (T<100˚C), high degree of hydration, proton transfer in bulk, high conductivity
High temperature (T>100˚C), low degree of hydration, proton transfer at interface, conductivity?
Evolution of PEM Morphology and Properties
Car-Parrinello Molecular Dynamics (CPMD) using functional BLYP
Upright Tilted
Side view Top view
5. Proton Transform from Interface to Bulk
The optimum density for one layer of water is calculated by varying the density of water layer. The average hydrogen bond length, <dO…O> = 2.92 Å
Initialization of the second hydration shell
The hydrogen bonds form in between water layer and oxygen
atoms of Triflic acid
We calculated the binding energy between first and second hydration shells:
Ebin = ESG+wl – ESG – Ewl
The binding energy between first and second hydration shells as a function of dCC shows that for small dCC the second shell do not interact with minimally hydration Hydrophobic?
For large dCC the interaction between first and second shell binding energy is increased proton transform is more probable
Upright conformation
With this density we could make the second hydration shell consist of 14 water molecules. The surface group separation correspond to optimum density of water layer is dCC=7.07Å
Optimize geometry of minimally hydration and second hydration shell
Frequency spectrum using AIMD Simulation Car-Parrinello NVT simulation at T = 300K for upright
conformation Simulation time = 60ps The frequency spectrum is calculated as a Fourier transform
of velocity correlation function: 0 01
1( ) ( ) , ,N
i i ii
C t v t v t t vN
• The fluctuations of sidechain rotation and sidechain tilting are responsible for proton transfer.• Low frequencies ≈ 100cm-1 are responsible for proton transfer.