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LECTURER: Prof. Yung-Eun Sung ( 성영은 ) School of Chemical & Biological EngineeringOffice: 302-729, Phone: 880-1889, E-mail: [email protected]
TEXTBOOK & REFERENCESA.J. Bard, L. R. Faulkner, Electrochemical Methods, Wiley, 2001.H. B. Oldham, J. C. Myland, Fundamentals of Electrochemical Science, Academic, 1994.P. G. Bruce, Solid State Electrochemistry, Cambridge, 1995.
Lecture Schedule5/3 (Thurs): Basic & Principle of Electrochemistry5/9 (Wed): Characterization Technique: Voltammetry5/17 (Thurs): Electric Double Layer Structure
Information on Electrochemistry JOURNALSElectrochemical and Solid State LettersElectrochemistry CommunicationsElectroanalysisElectrochimica Acta Fuel Cells - From Fundamentals to SystemsFuel Cells BulletinFuel Cell ReviewIonicsInterface International Journal of Hydrogen Energy Journal of The Electrochemical Society Journal of Power SourcesJournal of Solid State ElectrochemistryJournal of Applied ElectrochemistryJournal of Electroceramics Journal of New Materials for Electrochemical SystemsJournal of Electroanalytical Chemistry Journal of the Electrochemical Society of Japan Journal of the Korean Electrochemical SocietyJournal of the Bioelectrochemical Society Russian Journal of Electrochemistry (English Version)Solid State Ionics
REVIEW & PROCEEDINGS SERIESCurrent Topics in Electrochemistry, http://www.iscpubs.com/jce/ Electroanalysis, http://www.wiley-vch.de/publish/en/journals/alphabeticIndex/2049/Electroanalytical Chemistry, http://www.dekker.com/servlet/product/productid/9996-8/sub?n=i Electrochemical Technology, The Electrochemical SocietyFrontiers of Electrochemistry, VCH PublishersModern Aspects of Electrochemistry, http://www.springeronline.com/sgw/cda/Advances in Electrochemical Science and Engineering, Wiley-VCHTechniques of ElectrochemistrySolid state ionics proceedings; MRS (Materials research Society) homepageThe Electrochemical Society, proceedings; ECS homepage
SOCIETIESThe Electrochemical Society, Inc. (ECS) http://www.electrochem.orgElectrochemical Society of Japan http://www.electrochem.jp/index-e.htmlInternational Society of Electrochemistry (ISE) http://www.ise-online.org/International Association for Hydrogen Energy (IAHE) http://www.iahe.org/Korean Electrochemical Society ( 한국전기화학회 )International Battery Materials Association (IBA) [email protected] Society for Solid State Ionics http://www.issi.org/National Hydrogen Association http://www.hydrogenus.com/공업화학회 , 화학공학회 , 화학회 , 신재생학회 , 부식학회 등등
HANDBOOKSReference electrodes, theory and practice, D.J.G. Ives, NACE International, 1996. Encyclopedia of electrochemistry of the elements (15 volumes), A.J. Bard, Marcel Dekker, 73-84. Atlas of electrochemical equilibria in aqueous solutions, M.J.N. Pourbaix, NACE, 1974. Kinetic parameters of electrode reactions of metallic compounds, R. Tamamushi, 1975. CRC handbook series in organic electrochemistry (6 volumes), L. Meites, CRC Press, 1977-1983. Tables of standard electrode potentials, G. Milazzo and S. Caroli, Wiley, 1978. CRC handbook series in inorganic electrochemistry (8 volumes), L. Meites, CRC Press, 1980-1988. Handbook of aqueous electrolyte solutions, A.L. Horvath, Chichester, 1985. Electrochemical synthesis of inorganic compounds, a bibliography, Z. Nagy, Plenum Press, 1985. Standard potentials in aqueous solutions, A.J. Bard, Marcell Dekker, 1985. Handbook of aqueous electrolyte thermodynamics, J.F. Zemaitis, AICE, 1986. Handbook of conducting polymers, 2 volumes, T.A. Skotheim (Ed), Marcel Dekker, 1986. Fuel cell handbook, A.J. Appleby, Krieger, Malabar, 1993. Handbook of electrolyte solutions (2 volumes), V.M.M. Lobo, Elsevier, 1989. Properties of aqueous solutions of electrolytes, I.D. Zaytsev, CRC Press, Boca Raton, 1992. CRC handbook of solid state electrochemistry, P.J. Gellings, CRC, Boca Raton, 1997. Handbook of organic conductive molecules and polymers (Vol. 1-4), H.S. Nalwa (Ed), Wiley, 1997. Handbook of conducting polymers (2nd ed), T.A. Skotheim, Marcel Dekker, 1998. Battery reference book (3rd ed), T.R. Crompton, Newnes, 2000. Uhlig's corrosion handbook (2nd ed), R.W. Revie (Ed), Wiley, 2000. Modern electroplating (4th ed), M. Schlesinger and M. Paunovic (Ed), Wiley, 2000. Handbook of batteries (3rd ed), D. Linden and T.B. Reddy (Ed), McGraw-Hill, 2001. Handbook of fuel cells: fundamentals, technology, applications, Vol. 1-4, W. Vielstich, Wiley, 03.
BOOKSA.J. Bard, L. R. Faulkner, Electrochemical Methods, Wiley, 2000.H. B. Oldham, J. C. Myland, Fundamentals of Electrochemical Science, Academic, 1994.D. B. Hibbert, Introduction to Electrochemistry, Macmillan, 1993.C. M. A. Brett, Electrochemistry, Oxford Univ. Press, 1993.D. T. Sawyer, A. Sobkowiak, J. L. Roberts, Electrochemistry for Chemists, Wiley, 1995.J. R. Macdonald, Impedance Spectroscopy, John Wiley & Sons, 1987.P. J. Gellings, H. J. M. Bouwmeester, Handbook of Solid State Electrochem., CRC, 1997.P. G. Bruce, Solid State Electrochemistry, Cambridge, 1995.Electrochemistry & Solid State Science, The Electrochemical Society, 1992.Koto, Solid State Electrochemistry & Its Applications to Sensors & Electronic Devices, Elsevier, 1988.H. Rickert, Electrochemistry of Solids, Springer-Verlag, 1982.N. Masuko, T. Osaka, Y. Ito, Electrochemical Technology, Gordon & Breach, 1996.D. Pletcher, F. C. Walsh, Industrial Electrochemistry, Blackie, 1990.남종우 역 , 현대의 전기화학 , 청문각T. Kudo, K. Fueki, Solid State Ionics, Kodansha/VCH, 1990.N. Sata, Electrochemistry at Metal & Semiconductor Electrodes, Elsevier, 1998.
Other Electrochemical InformationElectrochemical Science & Technology Information Resources: http://electrochem.cwru.edu/estir/
• Electronics: the transport of electrons (or positive holes) Optoelectronics: light + electronics• Electrochemical system (electrodics + ionics)
• Electrochemistry: the coupling of chemical changes to the passage of electricity ionic conduction (flow of ions) + electronic conduction (flow of electrons) Electrochemical devices & electrochemical technologies Materials & devices & processing
What is electrochemistry?
• Examples of Electrochemical devices/technologies Battery or Fuel cell: chemical state changes(electrochemistry) electric power Photoelectrochemical cell (Solar cell): light + electrochemistry electric power Photocatalysis: light hydrogen or chemical reaction Electrochromic display: chemical state changes by electric signal coloration Sensors: chemical state changes by mass electric signal Electrolysis: electric power chemical species by chemical state changes Electrodeposition: electric power chemical change: thin film, Cu metallization Corrosion: potential difference chemical change Etching • Solid State ElectrochemistrySolid electrolyte: solid substances which can conduct electric current by ionic motion as do electrolyte solutions “solid state electrochemistry” or “solid state ionics” “solid state device”
Several distinct states may correspond to the same energy. That is, each energy level may be degenerate. Three energy levels are shown here, possessing one, three, and five distinct states.
Basic Concepts for Electrochemistry
Electric charge & currentElectric charge (=amount of electricity) Q (unit: Coulomb, C), time tElectric current (unit: ampere (A)): I = dQ/dt Q = Idt Current density (unit: A/m2): i = I/A, A: surface of areaAmmeter: measuring current Circuit: electric current flows in a closed path
Electrical potential & electric fieldElectrical potential (unit; volts, V), : the pressure of the electric fluidVoltage: the electrical potential difference ()Voltmeter: measuring an electrical potential difference Electric field strength (unit: V/m) X = -d/dx
Ohm’s law: most conductors obey this lawCurrent density is proportional to the field strength
i X
i = X = - d/dx
; electrical conductivity (siemens/m, S = A/V), 1/; resistivity
= -RIR;resistance (unit of ohm), G; conductance,
G = 1/R = A/L = -I/L; conductor length, A; cross sectionOhm’s law does not have universal validity. It does not apply to electrochemical cells.Resistor: a device that is fabricated to have a stable and known resistance Power (watts) = I2R
Electrical quantities & their SI units
Quantity Unit
Current (I)Current density (i)
Charge (Q)Charge density ()
Potential ()Field strength (X)Conductivity ()Resistance (R)
Conductance (G)Permittivity ()
Energy of work (w)Power
Capacitance (C)
Ampere (A)Ampere per square meter (A/m2)
Coulomb (C = As)Coulomb per cubic meter (C/m3)
Volt (V = J/C)Volt per meter (V/m)
Siemens per meter (S/m)Ohm ( =1/S = V/A)Siemens (S = A/V)
Farad per meter (F/m = C/Vm)Joule (J = VC)
Watt (W = J/s = AV)Farad (F = s/ = Ss), F = C/V
Classes of conductorsMaterials 1.Conductors Electronic conductors Ionic conductors 2. Insulators Conductors: metalsInsulators: plastics, ceramics, gasesNo clear cut distinction between conductor and insulator
Typical value of electrical conductivity
S/m x10-2 for S/cm
Material /Sm-1
Ionic conductors Electronic conductors
Ionic crystalsSolid electrolytesStrong(liquid) electrolytes MetalsSemiconductorsInsulators
10-16 – 10-2
10-1 – 103
10-1 – 103
103 – 107
10-3 – 104
<10-10
Material /Sm-1 Charge carriers
Electron pairsElectronsElectronsElectronsPi electronsPi electronsK+ and Cl-
H+ and HSO4-
Cations & anionsElectrons and holesK+ and Cl-
H+ and OH-
Univalent cations?
Electrical conductivity of various materials (most at 298 K)
Superconductors (low temp) AgCuHgC (graphite)Doped polypyrroleMolten KCl (at 1043 K)5.2 M H2SO4 (battery acid)SeawaterGe0.1 M KClH2OTypical glassTeflon, (CF2)nVacuum & most gases
6.3 x 107
6.0 x 107
1.0 x 106
4 x 104
6 x 103
217 82 5.2 2.2 1.3 5.7 x 10-6
3 x 10-10
10-15
0
Mobility: conduction from the standpoint of the charge carriersElectric current = rate at which charge crosses any plane = [number of carriers per unit volume][cross sectional area][charge on each carrier][average carrier speed]
I = dQ/dt = (NAci)(A)(Qi)(i)
i: particular charge carrier, ci; concentration, Qi; charge, i; average velocity,
NA; Avogadro’s constant (6.0220 x 1023 mol-1), A; area
zi; charge number = Qi/Qe where Qe (1.6022 x 10-19 C),
e.g., electrons:-1, Mg2+; +2 i fi X d/dx
fi; force exerted on the charge carrier, X; electric field strength
mobility of the carrier, ui (m2s-1V-1 unit) = velocity to field ratio (i / X)
i = uiX = - (zi/zi)uid/dx
zi: absolute value of the charge number
ue- of electrons: 6.7 x 10-3 m2s-1V-1 for Ag, less mobile in other metals
mobility of ions in aqueous solution: smaller than the factor of 105 (factor 105 slower); ucu2+
o = 5.9 x 10-8 m2s-1V-1 in extremely diluted solution
Current I,
I = -A NAQeziuicid/dx
Faraday constant
F = NAQe = (6.02 x 1023 mol-1)(1.6022 x 10-19 C) = 96485 Cmol-1
is numerically equal to the charge carried by one mole of univalent cations.(F is large. Small amount of chemicals higher electricity)
If there are several kind of charge carriers,
I = -AFd/dxziuici
i = -Fd/dxziuici
Transport number ti; the fraction of the total current carried by one particular
charge carrier ti = (ziuici )/(ziuici)
From i = X = -d/dx, conductivity
= Fziuici
molar ionic conductivity (i); Fui
Solid electrolyte: ions move under electric field without solvent → 전도도 존재→ batteries, fuel cells, and electrochemical devices
Ionic mobilities at extreme dilution in aqueous solution at 298 K
Grotthuss mechanism
Capacitance parallel conducting plate separated by a narrow gap containing air or insulator
Idt = Q E
Q = -CEC; capacitance (unit; farads (F) = C/V)
C = -Q/E = A/LA;cross-section area of the gap, L; width, ; permittivity of the insulator
• Relative permittivity (r) or dielectric constant ( 유전상수 )
air: ~ 1water: 78 Coulomb interaction energy is reduced by two orders of magnitudes from its vacuum valuepolar molecules: rrefractive index: nr = r
1/2 at the frequency
Capacitor; ; current integrator
/0; relative permittivity or dielectric constant
mylar; poly(ethylene glycol terephthalate), (CH2OOCC6H4COOCH2)n
Liquid > solid: large capacitance in electrochemical capacitor (supercapacitor)
Material 1012 /Fm-1 Material 1012 /Fm-1
vacuum (0)
N2(g)
Teflon(s), (CF2)n
CCl4(l)
Polyethene (s)Mylar (s)SiO2(s)
Typical glass (s)C6H5Cl(l)
8.854198.859051819.7202838.14449.8
NeopreneClC2H4Cl(l)
CH3OH(l)
C6H5NO2(l)
CH3CN(l)
H2O(l)
HCONH2(l)
TiO2(s)
BaTiO3(s)
5891.7288.9308.3332695.49331500110000
Permittivity of various materials
Electricity flows either by electron motion or ion motionIn both cases, the intensity of the flow (= current density) electric field strength
i = X = -d/dxconductivity
= Fziuici
determined by the concentration of charge carriers and their mobilities one form of Ohm’s law
E = -RI
potential difference across resistor to the current flowing through it
Resistor: dissipate energy Capacitor: store energy
Summary
. Potential & Thermodynamics
Introduction
Electrochemistry: chemical change electric forceElectrodics: in which the reactions at electrodes are consideredIonics: in which the properties of electrolytes have the central attention concentration of ions, their mobilities, interactions etc Basic laws were developed in systems with liquid electrolytes “solid state” (same and different features of solid electrolyte system)
Ionic solutionsMost important ionic conductor e.g., aqueous solution of electrolyteElectrolyte; a substance that produces ions so enhance the electrical conductivity e.g., solid(NaCl), liquid(H2SO4), gas(NH3)
cf) solid electrolyte
ElectrodeThe junction between electronic conductor and ionic conductor that the chemistry of electrochemistry occurs
Electrochemical cellBasic unit: an ionic conductor sandwiched between two electronic conductorse.g., aqueous solution of electrolyte between two pieces of metal, solid electrolyte between two metals
Cell voltage (E) or emf(electromotive force)electric potential difference between the two electronic conductors voltameter e.g., lead/acid cell (car battery)Electronic conductors: PbO2, Pb
Ionic conductor: concentrated aqueous solution of sulfuric acid
Electrochemical reactionAnode: Pb(s) + HSO4
-(aq) 2e- + PbSO4(s) + H+(aq)
Cathode: PbO2(s) + HSO4-(aq) + 3H+(aq) + 2e- PbSO4(s) + 2H2O(l)
Cell: PbO2(s) + Pb(s) + 2H+(aq) + 2HSO4-(aq) 2PbSO4(s) + 2H2O(l)
Right-hand electrode: electrons produced: oxidation, “anode”Left-hand electrode: electrons consumed; reduction, “cathode” Energy is delivered by the cell into the load; ex) car: starting engine, lighting lamps Galvanic cell: a cell which provides energy in this way, “discharge”( 방전 ) 2.0 V without current flow, 1.8 V with current flow (load); “polarization”; voltages decrease in magnitude when energy is taken from them. the effect becomes greater if the current is increased.
“charge” ( 충전 ): current flow in the opposite direction by using an external source (ex. Battery); Electrolytic cell; opposite direction to its spontaneous motionPbO2 : anode, Pb: cathode
2.0 V; perfect balance between the applied and cell voltages, no current flow equilibrium cell voltage or reversible cell voltage or null voltage or rest voltage or “open-circuit voltage”(since no current flows, it makes no difference if the circuit is interrupted, as by opening the switch)
VVoltammogramA Plot of cell currents versus the cell voltages (volt + am(pere) + mogram)
N
N
ONNot linear electrochemical cells do not obey Ohm’s law
Notation of the structure of cells
ZZn/Zn2+, Cl-/AgCl/AgHHg/Hg2Cl2/Cl-(aq)//Zn2+(aq)/Zn
//: phase boundary, “,” or : two components in the same phase, ///: liquid junction (a salt bridge)lleft: oxidation (anode), right: reduction(cathode)
ThermodynamicsWhy is it that chemical reactions in electrochemical cells proceed spontaneously in one direction and furnish current?(thermodynamics: 평형상태에 대한 정보 , kinetics: 전극반응속도에 대한 정보 ):Cell potential of an electrochemical cell
Ecell = Eright – Eleft
or Ecell = Ecathode – Eanode
E obtained from the Nernst equation oO + …+ ne- = rR + …. (reduction)pP + …. = qQ + … + ne- (oxidation)oO + pP + … = qQ + rR + … Ecell (cell reaction)
Ecell = E0 – (RT/nF)ln[(aQqaR
r..)/(aOoaP
p..)]
Gibbs free energy, G = -nFEcell
G <0 spontaneous
E0: standard electrode potential = Eright0 – Eleft
0
Eright
0, Eleft0,,: standard electrode potential of half reactions expresses as reductions
vs. NHE(normal hydrogen electrode) with all species at unit activity (ai =1)
(see the Table of Standard Potentials)
e.g., MnO2 + 4H+ + 2e- Mn2+ + 2H2O E0 = + 1.23 V
E = E0 –(RT/2F)ln[(aH+
4)/aMn2+], aMnO2, aH2O = unity
G = -nFE cf. RT/2F = [(8.314 JK-1mol-1)(298 K)/2(96485 JV-1mol-1)] = 0.01285 V
Several distinct states may correspond to the same energy. That is, each energy level may be degenerate. Three energy levels are shown here, possessing one, three, and five distinct states.
ee.g., Zn/Zn2+(aq), Cu2+(aq)/Cu Ccell: Zn + Cu2+ Zn2+ + CuRright: Cu2+ + 2e- Cu E0 = +0.34 V Left: Zn2+ + 2e- Zn E0 = -0.76 V Ecell
0 = +0.34 – (-0.76) = +1.10 VG0 = -2 x 1.10(V) x 96485 (JV-1mol-1) = -212 kJmol-1
rreaction spontaneousEEcell = E0 – (RT/2F)ln(aZn2+/(aCu2+)
IIf we assume aZn2+= aCu2+, Ecell = 1.10 V ------HHg/Hg2Cl2/Cl-(aq)//Zn2+(aq)/Zn 2Hg + Cl- + Zn2+ Hg2Cl2 + Znrright: Zn2+ + 2e- Zn E0 = -0.76 Vlleft: Hg2Cl2 + 2e- 2Hg + 2Cl- E0 = +0.27 V EEcell
0 = -0.76 –0.27 =-1.03 V, G0 = +199 kJmol-1, should be opposite direction
Measurement of E0: (i) experiment(ii) E0 = (RT/nF)lnK, K; equilibrium constant of cell K = exp(-G0/RT)(iii) E0 = Eright
0 – Eleft0 or E0 = Ecathode
0 – Eanode0 (from Table)
(iv) E0 = -G0/nF Cell: PbO2(s) + Pb(s) + 2H+(aq) + 2HSO4
-(aq) 2PbSO4(s) + 2H2O(l)
From thermodynamics Table,Standard Gibbs Energy (kJmol-1): -813.76 (PbSO4(s)), -237.13 (H2O(l)), -218.96
(PbO2(s)), -755.91 (HSO4-(aq)), cf) G0 for element (Pb(s)) and H+(aq) = 0
G0 = 2G0 (PbSO4(s)) + 2G0 (H2O(l)) – [G0 (PbO2(s)) + 2G0 (HSO4
-(aq))]
= -371 kJmol-1 G0 = -nFE0 E0 = 371000(Jmol-1)/[2 x 96485 (JV-1mol-1)] = 1.923 V battery acid: 5.2 M
Ecell = 1.923 V – (RT/2F)ln[aH2O(l)2/(aH+(aq)
2aHSO4-(aq)2)]
= 1.923 V – 0.01285ln [1/(5.2)2] = 2.008 V
activity term: minor contribution to the cell voltageactivity (a) concentration (c); a = c, ; activity coefficientai 1(solvent, pure solid, ideal solution)
(Examples) 1. Indicate in the following reactions which are reductions and which are oxidations:(1) Fe2+ + 2e- Fe (2) Cl- 1/2Cl2 + e- (3) Fe2+ Fe3+ + e-
(4) CrO42- + 3e- Cr3+ (5) O2 + 4e- 2O2- (6) Br2 + 2e- 2Br-
2. A Galvanic cell is constructed from a Cu2+/Cu electrode and an Ag+/Ag electrode.(1) Make a schematic drawing of the cell (2) Write the reactions at the electrode (3) Indicate the anode and the cathode 3. Assuming standard states for all reactants and products, determine the spontaneous direction of the following reactions by calculating the cell potential:(1) Cu + 2HCl = CuCl2 + H2
(2) Ag + FeCl3 = FeCl2 + AgCl
Definitions
Two equal electrodes interest in one electrode only
ElectrodesWorking electrode(WE): electrode of interestReference electrode(RE): second electrode, measure potential of WE with respect to REElectrode potential E = Ework –Eref
Reference electrodes
SHE (standard hydrogen electrode) or NHE(normal hydrogen electrode): universally accepted standard
H+(aq, a=1) + e- = 1/2H2(g, 105 Pa) E = 0 V
SCE (saturated calomel electrode)
Hg2Cl2(s) + 2e- = 2Hg + Cl- Eref = 0.244 V vs. NHE
Ag/AgClAgCl(s) + e- = Ag(s) + Cl-(aq) Eref = 0.199 V with saturated KCl
Potentials of reference electrodes E(RHE) = E(NHE) + 0.05916pHE(SCE) = E(NHE) – 0.2444E(Ag/AgCl) = E(NHE) – 0.2223E(Ag/AgCl, sat.KCl) = E(NHE) – 0.196E(Hg/HgO 1M KOH) = E(NHE) – 0.1100 + 0.05946pHE(Hg/Hg2SO4) = E(NHE) – 0.6152
Controlling potential of the working electrode with respect to the reference controlling the energy of the electrons within the working electrode More negitive potential energy of electrons is raised reach a level to occupy vacant states (LUMO) on species in the electrolyte flow of electrons from electrode to solution (a reduction current) More positive potential electron flow from solution (HOMO) to electrode (oxidation current)
Working electrode can act (i) as only a source (for reduction) or a sink (for oxidation) of electrons transferred to or from species in electrolyte (e.g., C, Au, Pt, Hg) or can (ii) take part in the electrode reaction, as in dissolution of a metal M (Zn Zn2+ + 2e-)
PolarizationVoltammogram: historical one vs. new one E > 0 working electrode potential > 0 (positive: right of x-axis)I > 0 oxidation at the working electrode
Polarization: the shift in the voltage across a cell caused by the passage of current Departure of the cell potential from the reversible(or equilibrium or nernstian) potential
Ohmic polarizationActivation polarizationConcentration polarization
Overvoltage (): the voltage shift caused by each kind of polarizationExtent of potential measured by the overpotential: = E - Eeq
E = En + ohm + act + conc
(i) ohmic polarization
ohm = IRsol, “IR drop”
Rsol = L/A
If free of activation & concentration polarization, slope = 1/Rsol
Rsol = L/A
If free of activation & concentration polarization, slope = 1/Rsol
Electrochemistry needs to minimize ohm
(conductivity) ohm (by adding extra electrolyte: “supporting electrolyte”)
three-electrode system
two-electrode cell vs. three-electrode cell
Eappl = E + iRs = Eeq + + iRs
IRs: ohmic drop in the solution (ohmic polarization) should be minimized
short distance between working and reference electrode & three-electrode cell Two-electrode cell: iRs problem due to high current flow
Three-electrode cell: current between WE and auxiliary electrode(or counter electrode) Potential measurement between WE and RE almost no current to reference electrode
Potentiostat, etc electrochemical system: three electrode system
(ii) activation polarizationslow electrode reaction activation polarization; slow kinetics activation energy This can be overcome by increasing the temperature and by applying extra voltage (activation overvoltage (act))
(iii) concentration polarizationfrom difference between the electrode surface and bulk concentration
R O + ne-
conc = E –En = (RT/nF)ln[(cRbcO
s)/cRscO
b]]
Limiting currentIdeal polarizable electrode (totally polarized electrode): a very large change in potential upon small currentIdeal nonpolarizable electrode: potential does not change upon passage of current (e.g., reference electrode)
Semiconductor electrodeSemiconductor/electrolyte space charge region due to space charge capacity, Csc, 0.001 ~ 1 Fcm-2, (cf; Cdl = 10 ~ 100 Fcm-2 ) band bending
n-type SC
when EF of SC lies above that in electrolyte electron flow from SC (positively
charged) to electrolyte (negatively charged) bent upwardby applying potential of bulk = surface, band bending & space charge region
disappear “flat band potential (fb or Efb)”
space charge capacitance Csc Mott-Schottly equation
1/Csc
2 = (2/e0N)1/2(- - kT/e)
: dielectric constant, N: donor or acceptor densities, e: quantity of charge, - = E-Efb
A plot of 1/Csc
2 vs. potential E should be linear Efb, doping level N