Study on mechanical model of Nafion membrane

Similar documents
hydrated Nafion-117 for fuel cell application

Effect of Relative Humidity and Temperature on the Mechanical Properties of PFSA Nafion -cation-exchanged membranes for Electrochemical Applications

Electrolytic membranes : Ion conduction in nanometric channels

Hydrocarbon Fuel Cell Membranes Containing Perfluorosulfonic Acid Group

Structuring of hydrophobic and hydrophilic polymers at interfaces Stephen Donaldson ChE 210D Final Project Abstract

Morphology of Supported Polymer Electrolyte. Ultra-thin Films: a Numerical Study. Supporting Information

Van der Waals Fluid Deriving the Fundamental Relation. How do we integrate the differential above to get the fundamental relation?

Mechanical Properties of Tetra-Polyethylene and Tetra-Polyethylene Oxide Diamond Networks via Molecular Dynamics Simulations

Synthesis of Highly Ion-Conductive Polymers for Fuel Cells (for H + and OH )

Experimental Study of Nafion- and Flemion-based Ionic Polymermetal Composites (IPMCs) with Ethylene Glycol as Solvent

Leveraging Simulations to Gain Insights into Polymer Electrolyte Membrane

Improved Fuel Transport Selectivity in Polymer Electrolyte Membranes. Kyle Tyler Clark. A dissertation submitted in partial satisfaction of the

Mechanical Engineering Ph.D. Preliminary Qualifying Examination Solid Mechanics February 25, 2002

Proton channels FUEL CELLS

Nanophase Segregation and Water Dynamics in the Dendrion Diblock Copolymer Formed from the Fréchet Polyaryl Ethereal Dendrimer and Linear PTFE

Aggregation States and Proton Conductivity of Nafion in Thin Films

produce water. Figure 1. Basic Diagram of a PEMFC. [1]

Chapter 7. Highlights:

An Atomistic-based Cohesive Zone Model for Quasi-continua

Constitutive Response and Mechanical Properties of PFSA Membranes in Liquid Water

Stress-Strain Curves of Nafion Membranes in Acid and Salt Forms

Electrolytes for Fuel Cells

Advanced Analytical Chemistry Lecture 12. Chem 4631

Deformation of Elastomeric Networks: Relation between Molecular Level Deformation and Classical Statistical Mechanics Models of Rubber Elasticity

Hyeyoung Shin a, Tod A. Pascal ab, William A. Goddard III abc*, and Hyungjun Kim a* Korea

CE 530 Molecular Simulation

The Molecular Dynamics Method

Molecular Dynamics Simulations. Dr. Noelia Faginas Lago Dipartimento di Chimica,Biologia e Biotecnologie Università di Perugia

Mechanics-Based Model for Non-Affine Swelling in Perfluorosulfonic Acid (PFSA) Membranes

CHARACTERIZING MECHANICAL PROPERTIES OF GRAPHITE USING MOLECULAR DYNAMICS SIMULATION

FACTORS INFLUENCING ELECTROCHEMICAL PROPERTIES AND PERFORMANCE OF HYDROCARBON BASED IONOMER PEMFC CATALYST LAYERS

Current and Temperature Distributions in Proton Exchange Membrane Fuel Cell

Supplementary Information for: Controlling Cellular Uptake of Nanoparticles with ph-sensitive Polymers

Ugur Pasaogullari, Chao-Yang Wang Electrochemical Engine Center The Pennsylvania State University University Park, PA, 16802

Modeling the Behaviour of a Polymer Electrolyte Membrane within a Fuel Cell Using COMSOL

Structure, molecular dynamics, and stress in a linear polymer under dynamic strain

Supplementary Information for Atomistic Simulation of Spinodal Phase Separation Preceding Polymer Crystallization

Fuel-Cell Performance of Multiply-Crosslinked Polymer Electrolyte Membranes Prepared by Two-Step Radiation Technique

MATERIALS SCIENCE POLYMERS

For an imposed stress history consisting of a rapidly applied step-function jump in

Stalled phase transition model of high-elastic polymer

Research Interests. Seung Soon Jang, Ph. D. School of Materials Science and Engineering Georgia Institute of Technology Atlanta, GA

NORMAL STRESS. The simplest form of stress is normal stress/direct stress, which is the stress perpendicular to the surface on which it acts.

Supporting Information

Structural Bioinformatics (C3210) Molecular Mechanics

Introduction to Engineering Materials ENGR2000. Dr. Coates

Chapter 1 Introduction

Coarse-Grained Models!

Shear Properties and Wrinkling Behaviors of Finite Sized Graphene

Proton-Conducting Nanocomposites and Hybrid Polymers

Module-4. Mechanical Properties of Metals

Controlled actuation of Nafion-based Ionic Polymer-metal Composites (IPMCs) with Ethylene Glycol as Solvent

General-purpose Coarse-grained. Molecular Dynamics Program COGNAC

Direct Energy Conversion: Fuel Cells

Weight and contact forces: Young's modulus, Hooke's law and material properties

Nanoscale Mechanics: A Quantum-Continuum Approach

Development of Bifunctional Electrodes for Closed-loop Fuel Cell Applications. Pfaffenwaldring 6, Stuttgart, Germany

, to obtain a way to calculate stress from the energy function U(r).

NanoStructured Polymer Membrane for Fuel Cell Application: Computational NanoTechnology Approach

Mechanical properties 1 Elastic behaviour of materials

A Molecular Modeling Approach to Predicting Thermo-Mechanical Properties of Thermosetting Polymers

Experiment Two (2) Torsional testing of Circular Shafts

CURRENT SENSING ATOMIC FORCE MICROSCOPY STUDY OF AGING MECHANISM OF NAFION MEMBRANES DUE TO THERMAL ANNEALING

Thermodynamic considerations on the stability of water in Nafion

Fuel Cells Jong Hak Kim Chemical Engineering Yonsei University

Two-step multiscale homogenization of polymer nanocomposites for large size RVEs embodying many nanoparticles

Modeling, simulation and characterization of atomic force microscopy measurements for ionic transport and impedance in PEM fuel cells

Nonlinear Viscoelastic Behaviour of Rubber Composites

DAMAGE MECHANICS MODEL FOR OFF-AXIS FATIGUE BEHAVIOR OF UNIDIRECTIONAL CARBON FIBER-REINFORCED COMPOSITES AT ROOM AND HIGH TEMPERATURES

Basic 8 Micro-Nano Materials Science. and engineering

The Effect of Network Solvation on the Viscoelastic Response of Polymer Hydrogels

Dissipative Particle Dynamics: Foundation, Evolution and Applications

Tailoring actuation of ionic polymer-metal composites through cation combination

ME 2570 MECHANICS OF MATERIALS

Molecular Driving Forces

Introduction Fuel Cells Repetition

STATIC LOADING TESTS AND A COMPUTATIONAL MODEL OF A FLEXIBLE NET

Diffusion and Interfacial Transport of Water in Nafion

Frequently Asked Questions

A Study of Methanol Vapor Sorption Dynamics by Nafion Membranes

Diffusion of Water and Diatomic Oxygen in Poly(3-hexylthiophene) Melt: A Molecular Dynamics Simulation Study

Oxygen reduction and transport characteristics at a platinum and alternative proton conducting membrane interface

An Analytical Model for Long Tube Hydroforming in a Square Cross-Section Die Considering Anisotropic Effects of the Material

Table of Contents. Preface...xvii. Part 1. Level

Self-Oscillating Nano-Gel Particles

PERFLUORINATED POLYMER GRAFTING: INFLUENCE OF PRE- IRRADIATION CONDITIONS

Prediction of Young s Modulus of Graphene Sheets by the Finite Element Method

File ISM02. Dynamics of Soft Matter

Scalable Elastomeric Membranes for Alkaline Water Electrolysis. Author Name: Yu Seung Kim Date: November 13, 2017 Venue: NREL

Outline. Tensile-Test Specimen and Machine. Stress-Strain Curve. Review of Mechanical Properties. Mechanical Behaviour

On the visco-elastic properties of open-cell polyurethane foams in uniaxial compression

Inhomogeneous elastic response of amorphous solids

Molecular Dynamics Simulation of Polymer Metal Bonds

TRANSIENTS IN POLYMER ELECTROLYTE MEMBRANE (PEM) FUEL CELLS

Constitutive Modeling of Nanotube-Reinforced Polymer Composite Systems. G. M. Odegard, V. M. Harik, K. E. Wise, and T. S. Gates

Oxygen permeation studies on alternative proton exchange membranes designed for elevated temperature operation

Kobe-Brown Simulation Summer School 2015 Project: DPD Simulation of a Membrane

Mechanical Properties of Phagraphene Membranes: A Fully Atomistic Molecular Dynamics Investigation

Introduction to molecular dynamics

Citation Holzforschung (2010), 64(4): Right Walter de Gruyter GmbH

Transcription:

ICCM4 8-3 th July, Cambridge, England Abstract Study on mechanical model of Nafion membrane *I. Riku, K. Marui and K. Mimura Graduate School of Engineering, Osaka Prefecture niversity, -, Gakuen-cho, Naka-ku, Sakai City 599-83, Japan *Corresponding author: riku@me.osakafu-u.ac.jp To clarify the effect of density of entanglement points of molecular chains on mechanical behavior of Nafion membrane, we at first employ molecular dynamic (MD) method to constitute the computational models for Nafion membranes with different density of entanglement points of molecular chains. And then, MD simulation for Nafion membrane under simple tension is performed. The results show that relatively high deformation resistance together with a distinct yield point appears in the Nafion membrane, which has a high density of entanglement points of molecular chains. Keywords: Nafion membrane, Mechanical behavior, Entanglement point, Molecular chain, MD Introduction Because of the high power density, high efficiency, fast start-up, and zero emission at the point of use, proton exchange membrane fuel cells (PEMFCs) are the most promising candidates for replacing internal combustion engines in automobiles, and are also being developed for portable and distributed stationary power generation applications. However, the life of PEMFCs is currently limited by the mechanical endurance of polymer electrolyte membranes (PEMs) []. The failure of PEM is believed to be the result of a combined chemical and mechanical effect acting together []. While chemical degradation of the membrane has been investigated and reported extensively in literature, there is little work published on mechanical degradation of the membrane. Recently, it is found that cyclic hydration of the membrane during the operation cycles (start/shut down) of the fuel cell may cause mechanical degradation of the membrane [3]. To investigating such mechanical degradation of the membrane subjected to fuel cell cycles, some microstructure analyses have been done for the membrane made from the sulfonated tetrafluoroethylene copolymer with the trade name Nafion [4]. Nafion consists of a hydrophobic polytetrafluoroethylene (PTFE)-like backbone and pendent chains with sulfonated (SO3 ) end groups. nder humidified conditions, the hydrophilic end groups segregate into nano-sized clusters, which imbibe water and cause the swelling of the ionomer [5]. To account for the effect of such change of the microstructure of the membrane on the mechanical response, Benziger et al. [6] proposed that membrane swelling and relaxation processes work as an interfacial contact switch between the membrane and the catalyst layer. Moreover, a viscoelastic model has been developed by Lai et al. and the mechanical response predictions upon implementing the model using the data for Nafion NR have been validated with stress measurements from a relaxation test performed at small initial strain (3%) in the linear elastic region [3]. However, in these studies, the computational models are just phenomenological ones and the change in the entanglement situation for the physical linkages of the molecular chain has not been accounted for explicitly. Therefore, in this paper, to clarify the effect of density of entanglement points of molecular chains on mechanical behavior of Nafion membrane, we at first employ molecular dynamic (MD) method to constitute the computational models for Nafion membranes with different density of

entanglement points of molecular chains. And then, MD simulation for Nafion membrane under simple tension is performed and the relationship between the macroscopic yield behaviour and the movement of molecular chains is discussed. MD Simulation Model Figure shows the structure formula of Nafion. In this paper, polymer chains of Nafion membrane are represented by coarse-grained model, in which each bead corresponds to a group of atoms such as CF, CF, CF 3. The total potential function of the molecular chain of Nafion membrane are given by ( r) + ( θ ) + ( ) + ( r ) ( r ) total = bond angle torsion φ nonbond + where bond ( r), ( θ ), ( φ), nonbond ( r ) and ( r ) angle torsion coulomb coulomb represents bond stretching energy, bending energy of successive bonds, torsion energy, van der Waals potential and Coulomb potential, respectively. These potential functions are defined as below: torsion nonbond bond angle ( r) = k ( r r ) b ( θ ) = k ( θ θ ) θ 4 n ( φ) = Vn ( ) cos( nφ) ( r ) n= σ = D r coulomb [ ] q q 4πε r i j ( r ) = σ r where k b, k, θ V, n D are constants, r is equilibrium bond length, σ is Lennard-Jones diameter, θ is equilibrium angle, q i, q are the electric charge held by j i th and j th bead, and ε is the vacuum conductivity. The number of the group of monomers shown in Figure is prescribed as m = 4, x =. The number of the beads of Nafion membrane is, and the number of molecular chains is. To clarify the effect of the density of entanglement points of molecular chains, two different models of membrane are constituted. One is a point-poor model, in which the number of entanglement point is poor, and the other is a point-rich model, in which 5 entanglement points have been added to the point-poor model equally. Figure shows the configuration of molecular chains of the point-rich model. The equation of motion is solved using the velocity Verlet algorithm with time step fs. The simulation is performed using a periodic boundary condition for the x and y axial directed walls of the simulation model. All the simulations are done using the coarse-grained molecular dynamics program OCTA/COGNAC [7]. Relaxation of the simulation model is carried out for 5, time steps under constant-temperature of 3K and density conditions (NVT-Nose Hoover ensemble). Simulation Result Figure 3 shows the macroscopic stress-strain relation of Nafion membrane. The point-poor model shows an elastic-like response whereas the point-rich model shows an elastoplastic-like response. 6

To clarify the effect of the density of entanglement points on such macroscopic response, the microscopic movement of certain molecular chains has been investigated. Figure 4 shows the difference between the position of several beads of one molecular chain of point-rich model and its corresponding position when the molecular chain moves as a rigid solid. It can be understood that there are two different patterns of the movement of the molecular chain. One pattern is shown in Figure 4(a) that the difference of the position of all the investigated beads increases gradually. The other pattern is shown in Figure 4(b) that the difference of the position of several beads once increases dramatically at the deformation stage, marked as A, and decreases quickly at the subsequent deformation stage whereas the difference of the position of the other beads is negligible. As a result, the molecular chains that behave in the pattern shown in Figure 4(a) attribute to the elongation of Nafion membrane whereas the molecular chains behave in the pattern shown in Figure 4(b) have no attribution to the deformation of Nafion membrane but have considerable relation with the macroscopic yield behavior of Nafion membrane. Table shows the number of the corresponding molecular chains of each pattern for the point-poor and the point-rich model. The fraction of the molecular chains that behaves in the pattern shown in Figure 4(b) increases from 7% to 47% when the number of entanglement points of the molecular chain increases. Based on the results shown above, we imply that the increase of the number of entanglement points of molecular chain leads to the tendency of the network of molecular chains to deform more locally at the microscopic region and consequently much more deformation of molecular chains behaving in pattern shown in Figure 4(a) and much more possibility of movement of molecular chains behaving in pattern shown in Figure 4(b), i.e. macroscopic yield behavior of Nafion membrane. Figure. Structure formula of Nafion Figure. Configuration of molecular chains of the point-rich model of Nafion membrane 3

Figure 3. Macroscopic stress-strain relation of Nafion membrane (a) (b) Figure 4. Movement of the beads inside the molecular chain of point-rich model of Nafion membrane Table. Number of molecular chains Pattern shown in Figure 4(a) Pattern shown in Figure 4(b) Point-poor model 73 7 Point-rich model 53 47 4

Conclusions In this paper, we constituted the MD computational models for Nafion membranes with different density of entanglement points of molecular chains and employed such models to clarify the relationship between the macroscopic yield behaviour and the movement of molecular chains. We found that the increase of the density of entanglement points of molecular chain leads to the tendency of the network of molecular chains to deform more locally at the microscopic region and consequently high deformation resistance together with a distinct macroscopic yield point of Nafion membrane. References. Huang, X. Y., Solasi, R., Zou, Y., Feshler, M., Reifsnider, K., Condit, D., Burlatsky, S., Madden, T., Mechanical endurance of polymer electrolyte membrane and PEM fuel cell durability, J. Polym. Sci., B44, 346-357, (6).. Liu, W., Ruth, K., Rusch, G., The membrane durability in PEM fuel cells, J. New Mater. Electrochem. Syst., 4, 7-3, (). 3. Lai, Y. H., Gittleman, C. S., Mittelsteadt, C. K., Dillard, D. A., Viscoelastic stress model and mechanical characterization of perfluorosulfonic acid (PFSA) polymer electrolyte membranes, Proceedings of the Third International Conference on Fuel Cell Science, Engineering and Technology, 53-59, Ypsilanti, Michigan, SA, May 3-5 (5). 4. Gebel, G., Aldebert, P., Pineri, M., Swelling study of perfluorosulphonated ionomer membranes, Polymer, 34, 333-339, (993). 5. Liu, D., Kyriakides, S., Case, S. W., Lesco, J. J., Li, Y. X., Mcgrath, J. E., Tensile behavior of Nafion and sulfonated poly(arylene ether sulfone) copolymer membranes and its morphological correlations, J. Polym. Sci., B44, 453-465, (6). 6. Benziger, J., Chia, E., Moxley, J. F., Kevrekidis, I. G., The dynamic response of PEM fuel cells to changes in load, Chem. Eng. Sci., 6, 743-759, (5). 7. Information on http://octa.jp/ 5

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback