ELECTROCHEMICAL METHODS Fundamentals and Applications - Allen.J.Bard

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Major Symbols xi Symbol Meaning Usual Units Section References Е щ E F Em Eg E; Щ E m E P A£ P Ep/2 £pa £pc £ Z *л Еф E\I2 Ещ Е Ъ1А e e\ e 0 ег%) erfc(x) F f /(E) fUk) G AG G G° equilibrium potential of an electrode Fermi level flat-band potential bandgap of a semiconductor initial potential junction potential membrane potential peak potential (a)|£ pa -£ pc |inCV (b) pulse height in SWV potential where / = / p /2 in LSV anodic peak potential cathodic peak potential staircase step height in SWV potential of zero charge switching potential for cyclic voltammetry quarter-wave potential in chronopotentiometry (a) measured or expected half-wave potential in voltammetry (b) in derivations, the "reversible" half-wave potential, E o> + (RT/nF)\n(D R /D 0 ) l/2 potential where i/i^ =1/4 potential where /// d = 3/4 (a) electronic charge (b) voltage in an electric circuit input voltage output voltage voltage across the input terminals of an amplifier error function of x error function complement of x the Faraday constant; charge on one mole of electrons (a) F/RT (b) frequency of rotation (c) frequency of a sinusoidal oscillation (d) SWV frequency (e) fraction titrated Fermi function fractional concentration of species / in boxy after iteration к in a simulation Gibbs free energy Gibbs free energy change in a chemical process electrochemical free energy standard Gibbs free energy V eV V eV V mV mV V V mV V V V mV V V V V V V V с V V V /xV none none С V" 1 r/s s- 1 s- 1 none none none kJ, kJ/mol kJ, kJ/mol kJ, kJ/mol kJ, kJ/mol 1.3.2,3.4.1 2.2.5, 3.6.3 18.2.2 18.2.2 6.2.1 2.3.4 2.4 6.2.2 6.5 7.3.5 6.2.2 6.5 6.5 7.3.5 13.2.2 6.5 8.3.1 1.4.2,5.4,5.5 5.4 5.4.1 5.4.1 10.1.1,15.1 15.2 15.1.1 15.1.1 A.3 A.3 9.3 10.1.2 7.3.5 11.5.2 3.6.3 B.1.3 2.2.4 2.1.2,2.1.3 2.2.4 3.1.2
xii Major Symbols Symbol Meaning Usual Units AG° дс! H Mi A#° / /(0 / 7 А/ 8i /(0) *А j transfer, j Od)max standard Gibbs free energy change in a chemical process standard Gibbs free energy of activation standard free energy of transfer for species j from phase a into phase /3 (a) gravitational acceleration (b) interaction parameter in adsorption isotherms (a) enthalpy enthalpy change in a chemical process standard enthalpy change in a chemical process standard enthalpy of activation Planck constant corrected mercury column height at a DME amplitude of an ac current convolutive transform of current; semi-integral of current current phasor diffusion current constant for average current diffusion current constant for maximum current peak value of ac current amplitude current difference current in SWV = if — i r difference current in DPV = /(r) - Z(r') initial current in bulk electrolysis characteristic current describing flux of the primary reactant to a modified RDE anodic component current (a) charging current (b) cathodic component current (a) current due to diffusive flux (b) diffusion-limited current average diffusion-limited current flow over a drop lifetime at a DME diffusion-limited current at t m . dX at a DME (maximum current) characteristic current describing diffusion of electrons within the film at a modified electrode (a) faradaic current (b) forward current kinetically limited current characteristic current describing cross-reaction within the film at a modified electrode kJ, kJ/mol kJ/mol kJ/mol cm/s 2 J-cm 2 /mol 2 kJ, kJ/mol s-l/2 kJ, kJ/mol kJ, kJ/mol kJ/mol J-s cm A C/s 1/2 A ^A-s 1/2 /(mg 2/3 -mM) Section References 2.1.2,2.1.3 3.1.2 2.3.6 13.5.2 2.1.2 5.5.1 2.1.2 2.1.2 3.1.2 7.1.4 10.1.2 6.7.1 10.1.2 7.1.3 M-s 1/2 /(mg 2/3 -mM) 7.1.3 A A A A A A A A A A A A A A A A A A 10.5.1 1.3.2 7.3.5 7.3.4 11.3.1 14.4.2 3.2 6.2.4 3.2 4.1 5.2.1 7.1.2 7.1.2 14.4.2 5.7 9.3.4 14.4.2
Page 1 and 2: SECOND EDITION ELECTROCHEMICAL METH
Page 3 and 4: PREFACE In the twenty years since t
Page 5 and 6: CONTENTS MAJOR SYMBOLS ix STANDARD
Page 7: Major Symbols Symbol Meaning Usual
Page 11 and 12: xiv Major Symbols Symbol Meaning Us
Page 13 and 14: xvi Major Symbols Symbol Meaning Us
Page 15 and 16: xviii Major Symbols Symbol Meaning
Page 17 and 18: xx Major Symbols Abbreviation Meani
Page 19 and 20: CHAPTER 1 INTRODUCTION AND OVERVIEW
Page 21 and 22: Pt H 2 1.1 Introduction 3 Zn Ag С
Page 23 and 24: 1.1 Introduction 5 Power supply -Ag
Page 25 and 26: 1.1 Introduction 7 idation of Br~ t
Page 27 and 28: 1.1 Introduction Hg/I-Г, ВГ(1 М
Page 29 and 30: 1.2 Nonfaradaic Processes and the N
Page 37 and 38: 1.3 Faradaic Processes and Factors
Page 47 and 48: 1.4 Introduction to Mass-Transfer-C
Page 55 and 56: 1.5 Semiempirical Treatment of Nems
Page 57 and 58: 1.6 The Literature of Electrochemis
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1.6 The Literature of Electrochemis
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1.8 Problems 43 1.6 For the electro
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Thus the net cell reaction is 1 Zn
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2.1 Basic Electrochemical Thermodyn
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2.2 A More Detailed View of Interfa
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(a) Properties of the Electrochemic
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2.3 Liquid Junction Potentials л :
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2.3 Liquid Junction Potentials < 65
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2.3 Liquid Junction Potentials 67 T
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2.3 Liquid Junction Potentials 69 W
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2.3 Liquid Junction Potentials «I
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2.3 Liquid Junction Potentials : 73
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2.4 Selective Electrodes \ 75 Ag wi
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2.4 Selective Electrodes 77 The fir
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Other Ion-Selective Electrodes 2.4
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2.4 Selective Electrodes •« 81 (
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2.5 References 83 8. M. W. Chase, J
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2.3 Devise a cell in which the foll
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3 KINETICS OF ELECTRODE REACTIONS I
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3.1 Review of Homogeneous Kinetics
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3.2 Essentials of Electrode Reactio
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3.3 Butler-Volmer Model of Electrod
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3.4 Implications of the Butler-Volm
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Г " т - ') = e f(E-E«) ( 3 A 2 7
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3.5 Multistep Mechanisms 107 -200 -
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3.5 Multistep Mechanisms 109 one-st
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3.5 Multistep Mechanisms 111 which
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3.5 Multistep Mechanisms 113 dent o
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3.6 Microscopic Theories of Charge
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3.7 References 133 17. J. A. V. But
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3.8 Problems 135 Use a spreadsheet
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CHAPTER 4 MASS TRANSFER BY MIGRATIO
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4.2 Migration 139 component at any
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4.3 Mixed Migration and Diffusion N
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4.4 Diffusion i 147 -5/ -41 -31 -21
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4.4 Diffusion 149 net mass-transfer
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4.4 Diffusion 151 X IТ i i i \ \\
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4.5 References i 153 4.4.4 Solution
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4.6 Problems 155 4.4 The mobility,
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5.1 Overview of Step Experiments 15
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5.1 Overview of Step Experiments 15
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5.2 Potential Step Under Diffusion
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and inversion produces the current-
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5.3 Diffusion-Controlled Currents a
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Responses to a Large-Amplitude Pote
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5.4 Sampled-Current Voltammetry for
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5.6 Multicomponent Systems and Mult
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5.7 Chronoamperometric Reversal Tec
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5.7 Chronoamperometric Reversal Tec
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5.8 Chronocoulometry 211 nal-to-noi
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5.8 Chronocoulometry 213 100 200 30
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5.8 Chronocoulometry «i 215 The ap
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5.9 Special Applications of Ultrami
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5.9 Special Applications of Ultrami
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5.10 References « 221 would diffus
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5.11 Problems 223 0.2, 0.5, 1, 2, 3
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5.11 Problems < 225 5.19 G. Denault
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6.1 Introduction -I 227 0 t E t E°
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6.2 Nemstian (Reversible) Systems 2
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6.2 Nemstian (Reversible) Systems <
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6.2 Nernstian (Reversible) Systems
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where Introducing E(t) from (6.2.1)
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6.4 Quasireversible Systems *4 237
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6.5 Cyclic Voltammetry 239 Figure 6
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6.5 Cyclic Voltammetry 241 0.5 -0.3
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6.7 Convolutive or Semi-Integral Te
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6.8 Cyclic Voltammetry of the Liqui
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6.9 References 255 100 I -100 I I I
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6.10 Problems 257 20 r- 15 /, цА
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6.10 Problems *« 259 -0.8 -1.0 -1.
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CHAPTER 7 POLAROGRAPHY AND PULSE VO
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7.1 Behavior at Polarographic Elect
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7.2 Polarographic Waves 273 Kouteck
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7.3 PULSE VOLTAMMETRY 7.3 Pulse Vol
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7.3 Pulse Voltammetry 277 -0.4 -0.6
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7.3 Pulse Voltammetry < 279 • Dro
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7.3 Pulse Voltammetry 281 Potential
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7.3 Pulse Voltammetry 283 duration
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7.3 Pulse Voltammetry \. 285 cant c
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7.3 Pulse Voltammetry < 287 Second
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7.3 Pulse Voltammetry 289 The shape
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7.3 Pulse Voltammetry I 291 one ref
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7.3 Pulse Voltammetry 293 effects o
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7.3 Pulse Voltammetry 295 In genera
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7.3 Pulse Voltammetry < 297 1.0 i
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7.3 Pulse Voltammetry 299 (d) Appli
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7.4 References 301 Therefore, the b
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7.5 Problems < 303 49. L. Ramaley a
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8 CONTROLLED-CURRENT TECHNIQUES 8.1
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8.2 General Theory of Controlled-Cu
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8.2 General Theory of Controlled-Cu
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8.2.3 Programmed Current Chronopote
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8.3 Potential-Time Curves in Consta
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8.3 Potential-Time Curves in Consta
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8.4 Reversal Techniques 317 connect
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8.6 The Galvanostatic Double Pulse
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8.7 Charge Step (Coulostatic) Metho
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8.9 Problems 329 electrolysis time
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CHAPTER 9 METHODS INVOLVING FORCED
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9.2 Theoretical Treatment of Convec
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9.3 Rotating Disk Electrode 335 9.3
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9.3 Rotating Disk Electrode 337 Fig
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9.3 Rotating Disk Electrode i 339 T
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9.3 Rotating Disk Electrode 341 For
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9.3 Rotating Disk Electrode 343 1 0
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9.3 Rotating Disk Electrode 345 to
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7iim» o f j lim =l№l(i u /A)s l/
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9.4 Rotating Ring and Ring-Disk Ele
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9.4 Rotating Ring and Ring-Disk Ele
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9.5 Transients at the RDE and RRDE
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9.5.2 Transients at the RRDE 9.5 Tr
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9.6 Modulated RDE «1 357 600 400 -
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9.6 Modulated RDE < 359 Full-wave r
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9.7 Convection at Ultramicroelectro
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9.8 Electrohydrodynamics and Relate
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9.10 Problems 365 40. D. A. Saville
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9.10 Problems 367 +1.0 -0.2 Figure
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ЮЛ Introduction 369 Potentiometer
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10.1 Introduction 371 Figure 10.1.3
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10.1 Introduction 373 In this way w
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10.1 Introduction 375 *I_L -3 -2 -1
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10.2 Interpretation of the Faradaic
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10.2 Interpretation of the Faradaic
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10.3 Kinetic Parameters from Impeda
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10.4 Electrochemical Impedance Spec
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10.5 ас Voltammetry < 389 voltamm
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10.5 ас Voltammetry «I 391 exper
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10.5 ас Voltammetry 393 heterogen
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10.5 ас Voltammetry 395 This maxi
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10.5 ас Voltammetry < 397 The str
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10.5 ас Voltammetry -Щ 399 peak
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10.6 Higher Harmonics -m 401 f В R
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10.6 Higher Harmonics 403 Output H
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10.7 Chemical Analysis by ac Voltam
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10.8 Instrumentation for Electroche
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10.8 Instrumentation for Electroche
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10.9 Analysis of Data in the Laplac
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10.9 Analysis of Data in the Laplac
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10.11 Problems « 415 22. J. Vareec
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CHAPTER 11 BULK ELECTROLYSIS METHOD
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General Considerations in Bulk Elec
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General Considerations in Bulk Elec
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Controlled-Potential Methods < 423
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Controlled-Potential Methods 425 lo
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11.3.3 Electroseparations Controlle
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Controlled-Potential Methods 429 ur
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Controlled-Current Methods ^ 431 Ba
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Controlled-Current Methods i 433 Th
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Electrometric End-Point Detection 4
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Electrometric End-Point Detection i
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Electrometric End-Point Detection <
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Flow Electrolysis 441 11.6 FLOW ELE
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Flow Electrolysis ) = nFv dC o (x)
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Flow Electrolysis 445 This allows t
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Flow Electrolysis ^ 447 I Solution
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Flow Electrolysis 449 Spacer Auxili
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Flow Electrolysis 451 are much high
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Thin-Layer Electrochemistry 453 Mic
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Thin-Layer Electrochemistry 455 thr
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Thin-Layer Electrochemistry 457 -0.
Page 477 and 478:
Stripping Analysis 459 Deposition (
Page 479 and 480:
Stripping Analysis 461 -0.6 Figure
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Stripping Analysis 463 0 -0.2 1 1 1
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References 465 7. N. Tanaka, op. ci
Page 485 and 486:
Problems 467 1.0 +0.8 +0.6 +0.4 +0.
Page 487 and 488:
Problems 469 are equal and (b) thos
Page 489 and 490:
CHAPTER 12 ELECTRODE REACTIONS WITH
Page 491 and 492:
12.1 Classification of Reactions i
Page 493 and 494:
12.1 Classification of Reactions 47
Page 495 and 496:
Page 497 and 498:
Page 499 and 500:
12.2 Fundamentals of Theory for Vol
Page 501 and 502:
(as above) дС т д2 С т С О2
Page 503 and 504:
12.2 Fundamentals of Theory for Vol
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12.3 Theory for Transient Voltammet
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Catalytic Reaction—E r Cj 12.3 Th
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Icurr< 12.3 Theory for Transient Vo
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12.4 Rotating Disk and Ring-Disk Me
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12.7 Controlled-Potential Coulometr
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12.8 References « 529 12.8 REFEREN
Page 549 and 550:
12.9 Problems =4 531 92. G. Denuaul
Page 551 and 552:
12.9 Problems 533 12.11 Consider cu
Page 553 and 554:
13.1 Thermodynamics of the Double L
Page 555 and 556:
13.1 Thermodynamics of the Double L
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13.2 Experimental Evaluation of Sur
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13.2 Experimental Evaluation of Sur
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13.2.3 Relative Surface Excesses 13
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13.3 Models for Double-Layer Struct
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The total charge per unit volume in
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13.4 Studies at Solid Electrodes 55
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13.5 Extent and Rate of Specific Ad
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13.6 Effect of Adsorption of Electr
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13.7 Double-Layer Effects on Electr
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13.7.2 Double-Layer Effects in the
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13.8 Referencess 575 / / / 4 —% -
Page 595 and 596:
13.9 Problems 577 64. D. M. Mohilne
Page 597 and 598:
13.9 Problems 579 13.13 Aramata and
Page 599 and 600:
14.2 Types, Preparation, and Proper
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Page 603 and 604:
Page 605 and 606:
Page 607 and 608:
14.3 Electrochemical Responses of A
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Page 617 and 618:
Page 619 and 620:
Page 621 and 622:
Page 623 and 624:
Page 625 and 626:
Page 627 and 628:
14.4 Overview of Processes at Modif
Page 629 and 630:
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where the permeation current, ip, i
Page 633 and 634:
Page 635 and 636:
Page 637 and 638:
14.5 Blocking Layers 619 One can al
Page 639 and 640:
14.5 Blocking Layers 621 current at
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14.5 Blocking Layers 623 The parame
Page 643 and 644:
14.5 Blocking Layers 625 at the ele
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14.6 Other Methods of Characterizat
Page 647 and 648:
14.7 References . 629 (b) H. S. Whi
Page 649 and 650:
14.8 Problems 631 15 20 25 [ВГ],
Page 651 and 652:
15.1 Operational Amplifiers 633 +15
Page 653 and 654:
15.2 Current Feedback 635 (f) Other
Page 655 and 656:
15.2 Current Feedback < 637 i Figur
Page 657 and 658:
15.3 Voltage Feedback * 639 This ki
Page 659 and 660:
15.4 Potentiostats 641 Counter Work
Page 661 and 662:
15.4 Potentiostats -4 643 I Potenti
Page 663 and 664:
15.6 Difficulties with Potential Co
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Page 667 and 668:
Page 669 and 670:
15.7 Measurement of Low Currents
Page 671 and 672:
15.8 Computer-Controlled Instrument
Page 673 and 674:
15.9 Troubleshooting Electrochemica
Page 675 and 676:
15.11 Problems 657 25. P. He, J. P.
Page 677 and 678:
CHAPTER 16 SCANNING PROBE TECHNIQUE
Page 679 and 680:
16.2 Scanning Tunneling Microscopy
Page 681 and 682:
Page 683 and 684:
Page 685 and 686:
16.3 Atomic Force Microscopy 667 no
Page 687 and 688:
16.4 Scanning Electrochemical Micro
Page 689 and 690:
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Page 693 and 694:
Page 695 and 696:
Page 697 and 698:
16.6 Problems 679 tip and the subst
Page 699 and 700:
17.1 Ultraviolet and Visible Spectr
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17.2 Vibrational Spectroscopy 701 R
Page 721 and 722:
17.2 Vibrational Spectroscopy ; 703
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17.2 Vibrational Spectroscopy 705 h
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17.2 Vibrational Spectroscopy 707 0
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17.3 Electron and Ion Spectrometry
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17.4 Magnetic Resonance Methods 723
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17.5 Quartz Crystal Microbalance 72
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17.5 Quartz Crystal Microbalance ;
Page 747 and 748:
17.6 X-Ray Methods 729 few millimet
Page 749 and 750:
17.7 References 731 17.7 REFERENCES
Page 751 and 752:
17.7 References =- 733 87. D. M. Ko
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17.8 Problems 735 17.2 Given D = 6.
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18.1 ElectrogeneratedChemiluminesce
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18.2 Photoelectrochemistry at Semic
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18.3 Electrochemical Detection of P
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18.3 Electrochemical Detection of P
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18.4 References ! 765 41. L. L. Shu
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18.5 Problems 767 18.4 The transien
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А Р Р #Й D IX А MATHEMATICAL M
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АЛ Solving Differential Equations
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А. 1 Solving Differential Equation
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А. 1 Solving Differential Equation
Page 795 and 796:
А.2 Taylor Expansions 777 10 Figur
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А.З The Error Function and the Ga
Page 799 and 800:
А.5 Complex Notation «i 781 A val
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А.8 Problems 783 In most applicati
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APPENDIX В DIGITAL SIMULATIONS OF
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ut the definition of a derivative a
Page 807 and 808:
B.I Setting Up the Model 789 1. C*
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B.I Setting Up the Model 791 could
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В.2 An Example < 793 and imax « 6
Page 813 and 814:
В.2 An Example « 795 mensionless
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В.З Incorporating Homogeneous Kin
Page 817 and 818:
В.4 Boundary Conditions for Variou
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В.4 Boundary Conditions for Variou
Page 821 and 822:
В.6 Miscellaneous Digital Simulati
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В.6 Miscellaneous Digital Simulati
Page 825 and 826:
В.8 Problems 807 / B vs. x f° r t
Page 827 and 828:
TABLE C.I (continued) Reaction 2H +
Page 829 and 830:
Reference Tables 811 TABLE C.3 Esti
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Referem TABLE C.4 Selected Diffusio
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816 • Index Blocking polymers, 58
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818 Index Convective-diffusion equa
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820 Index Dropping mercury electrod
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822 ; Index Ellipsometry, described
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824 Index Instrumentation (continue
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826 Index Multicomponent systems: m
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828 Index Potential step methods (c
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830 • Index Sampled-current volta
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832 Index Thin-layer electrochemist
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ELECTROCHEMICAL METHODS Fundamentals and Applications - Allen.J.Bard

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