Equilibrium Electrochemistry

Equilibrium Electrochemistry Dr. David J. Fermín (S123) [email protected] Lecture notes at: www.chm.bris.ac.uk/pt/electrochemistry Aim of the course: This course provides the thermodynamic tools for understanding electrochemical reactions and devices. Starting from the concept of the electrochemical potential of charged species, this course will cover the thermodynamic relationships associated with electrochemical cells and various devices such as batteries and sensors. The potential distribution across electrified metal|electrolyte interfaces will also be discussed. 1

Global Picture – Energy Sources
Primary Energy Use


Electricity Production

toe: “tonnes of oil equivalent” = 42 GJ UNDP – World Energy Assessment 2004

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Unbalanced Energy Economy
Primary Energy Use

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Environmental Impact
Radiative Forcing: Impact in energy balance
RF > 0: Warming
CO2, CH4, NOx: Industrial development
Air pollution: 800 k deaths/year
Damages in Agriculture, forests, fishing, infrastructure

4 IPCC report – Executive summary Feb. 2007

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Sustainable Energy Worldwide 2007: 6.5 billion people – 13 TW energy consumption 2100: Energy demand up to 40 TW Carbon neutral energy sources – Global warming Reliable carbon sequestration: 25 billion Ton of CO2 a year with less than 1% loss Nuclear: 1GW plant / week for 50 years. Uranium source to deplete in 10 years Renewable: Hydroelectric - 0.5 TW Tidal – 2 TW

SOLAR: 120000 TW

Geothermal – 10 TW Wind – 2 TW

Target: Harvest – Transform – Store 6

Electrochemistry Electrons Ions Electrical potential Electrodes

Dissolution / Deposition Corrosion Electro-chromic Electro-luminescent systems

Nature 2001

http://p2library.nfesc.navy.mil/index.html

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Learning Objectives Electrochemical potential Chemical potential in condensed phases The activity of ions in solution The Galvani potential

Ecell and useful constants

Standard potential Calculating thermodynamic parameters, activity coefficient and solubility products

Thermodynamic of ions

Electroanalysis and devices

Standard Enthalpy, Entropy and Gibbs energy of formation Gibbs energy of solvation Debye-Hückel theory

Redox titration Ion selective electrodes Membrane electrodes (pH) Batteries

Electrochemical cells

Electrochemical double layer

The Galvani potential difference Conventional Electrochemical cells Cell reactions and electromotive force The Nernst Equation

The structure of the metal|electrolyte interface The Helmholtz layer The diffuse layer The potential distribution 8

Electrochemical Potential Chemical potential in gas phase

Chemical potential in liquid phase

The electrostatic potential of condensed phases

The electrochemical potential of charged species 9

1.1 Chemical potential
Fundamental Equation of Chemical Thermodynamics:

dG = Vdp − SdT + ∑ µidni

eqn. 1.1

i

 ∂G  µi =    ∂ni T ,P ,nj≠i eqn. 1.2

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1.2 Chemical potential in liquid phase
Reversible work required for changing the activity of the solute in solution

µi ( l ) = µio ,ideal-dil + RT ln ( xi ) + RT ln ( γ i ) = µio ,ideal-dil + RT ln ( ai ) eqn. 1.12

RT ln γ i

the reversible work associated with interaction between solutes

ai = γ i xi

is defined as the activity of the solute i.

µio ,ideal-dil

Henry’s reference state for solutes: “i” only interacts with solvent (eq. 1.11)

µio ,ideal

Raoult’s reference state for liquids: “i” in its pure state (eq. 1.8)

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eqn. 1.11

ideal dilute solution eqn. 1.8

ideal solution

Fig. 1.2 Variation of the chemical potential and the definition of the standard chemical potential at 298 K in the scale of mole fractions for an ideally diluted solution [Girault 2001]. 12

1.3 Molality and Molarity scales Both concentration scales used for diluted solutions

ni mi = nsMs

eqn. 1.13

mol × kg-1

ni ci = V

ni number of moles of the solute ns number of moles of the solvent Ms molar mass of the solvent

mol × dm-3

V solution volume From eqn. 1.12,

 

µi = µio ,c + RT ln  γ ic

ci  c o 

eqn. 1.16

µio ,c = µio ,ideal-dil + RT ln ( c oVM,s )

c o standard molarity 1 mol dm-3 VM,s molar volume of the solvent

eqn. 1.17

Relationship between activity coefficient in the molar and molal scales

d smi γ =γ ci c i

m i

eqn. 1.18

ds density of the pure solvent 13

1.4 Electrostatic potential of condensed phases In the case of charged species, the chemical potential also depends on the electrostatic inner potential associated with the liquid (condensed) phase:

r

x

+

ψ (x) =

q

χ

q

eqn. 1.19

4πεε 0 ( x + r )

surface dipoles – e.g. water molecules

Table 1.1 Relative permittivity

q the charge of the condensed phase

ψ outer potential (Volta potential)

solvent

εr at 293 K

Water

80.1

χ surface potential

Nitrobenzene

35.6

εr relative permittivity

Ethanol

25.3

Benzene

2.3

Cyclohexane

2.0

ε permittivity of free space (8.854×10-12 J-1 C2 m-1)

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Volta potential (ψ): phase is charged too – dependent on distance (x). The surface potential (χ): differential work for bringing the charge into the phase.

ψ (x) =

q 4πεε 0 ( x + r )

r

+ x q

χ

Galvani potential

φ =ψ + χ If the phase is neutral, ψ = 0 and φ = χ

eqn. 1.20

χ = 0.13 V for water (Trasatti 1980) 15

1.5 Electrochemical potential of charged species The star equation of the day: Electrochemical potential

µ%i = µi + RT ln ( ai ) + ziFφ o

eqn. 1.22

Vacuum

zF i ψ G

Outer potential

bulk

µi

zi F χ

µ% i

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Summary
Chemical potential (µi) – reversible work for transferring one mol of a component from vacuum to a given phase at constant T and p o
Standard states ( µi ) are defined for the solvent and solute


Activity (ai) accounts for “non-ideal” behaviour of solute
The Galvani potential (φ) is determined by the “charge” of the solvent and surface dipoles

µ%i = µi + RT ln ( ai ) + ziFφ o

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Giants of the day

Josiah Willard Gibbs American Engineer 1839 - 1903

François-Marie Raoult French Chemist 1830 - 1901

William Henry English Chemist 1775 - 1836

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