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Square wave amplitude

Fig. 2.2 The dependence of the dimensionless net peak current (i) and the ratio of the dimensionless net peak current and the half-peak width (2) on the product of number of electrons and the square-wave amplitude... Fig. 2.2 The dependence of the dimensionless net peak current (i) and the ratio of the dimensionless net peak current and the half-peak width (2) on the product of number of electrons and the square-wave amplitude...
Figure 2.23b shows the dependenee of the net peak potentials on the logarithm of the parameter A. If the film is very thin (A < 0.1), this relationship is linear, with the slope dE /d log A = 2.3RTjnF. On very thiek films (A > 10) the net peak potential is independent of A, regardless of square-wave amplitude. So, if at the lowest frequency A > 10, the net peak potential is independent of frequency. On... [Pg.34]

Fig. 2.11 Square wave voltammograms for blanks of azurite and smalt, and for two samples from the Palomino s frescoes in the Sant Joan del Mercat church in Valencia, in contact with 0.50 M potassium phosphate buffer, pH 7.4 (a) azurite, (b) sample PV8b, (c) smalt, and (d) sample PA5b. Potential scan initiated at —0.85 mV in the positive direction. Potential step increment 4 mV square wave amplitude 15mV frequency 2Hz [133]... Fig. 2.11 Square wave voltammograms for blanks of azurite and smalt, and for two samples from the Palomino s frescoes in the Sant Joan del Mercat church in Valencia, in contact with 0.50 M potassium phosphate buffer, pH 7.4 (a) azurite, (b) sample PV8b, (c) smalt, and (d) sample PA5b. Potential scan initiated at —0.85 mV in the positive direction. Potential step increment 4 mV square wave amplitude 15mV frequency 2Hz [133]...
Fig. 2.14 SQWVs of PIGEs modified with (a) Caput mortum, (b) Venetian red, immersed into 0.10 M HCl. Potential scan initiated at -1-0.65 V in the negative direction potential step increment 4 mV square wave amplitude 25 mV frequency 5 Hz [139]... Fig. 2.14 SQWVs of PIGEs modified with (a) Caput mortum, (b) Venetian red, immersed into 0.10 M HCl. Potential scan initiated at -1-0.65 V in the negative direction potential step increment 4 mV square wave amplitude 25 mV frequency 5 Hz [139]...
Fig. 2.16 SQWVs for silk fibers pigmented with (a) granado (b) alazor, (c) curcuma, (d) weld, and (e) cochineal red in contact with acetic/acetate buffer (total concentration 0.50 M) at pH 4.85. Potential step increment 4 mV square wave amplitude 25 mV frequency 5 Hz... Fig. 2.16 SQWVs for silk fibers pigmented with (a) granado (b) alazor, (c) curcuma, (d) weld, and (e) cochineal red in contact with acetic/acetate buffer (total concentration 0.50 M) at pH 4.85. Potential step increment 4 mV square wave amplitude 25 mV frequency 5 Hz...
Fig. 2.20 SQWVs (first scan) of weld (a, b) and logwood (c, d) immersed into 0.25 M HAc + 0.25 M NaAc (a, c) and that electrolyte plus 0.05 M AICI3 (b, d). Potential step increment 4 mV square wave amplitude 25 mV frequency 15 Hz [124]... Fig. 2.20 SQWVs (first scan) of weld (a, b) and logwood (c, d) immersed into 0.25 M HAc + 0.25 M NaAc (a, c) and that electrolyte plus 0.05 M AICI3 (b, d). Potential step increment 4 mV square wave amplitude 25 mV frequency 15 Hz [124]...
M sodium acetate buffer, pH 4.85. Potential step increment 4 mV square wave amplitude 25 mV frequency 15 Hz [177]... [Pg.69]

Table 3.1 Diagnostic criteria for characterizing lead pigments via voltammetry of microparticles using deposits of the pristine pigments on parafiSn-impregnated graphite electrodes. Data from square-wave voltammograms at a potential step increment of 4 mV, square-wave amplitude of 25 mV, and frequency of 15 Hz. All potentials refer to AgQ (3M NaCl)/Ag. Electrolyte, 0.50 M acetate buffer, pH 4.85... Table 3.1 Diagnostic criteria for characterizing lead pigments via voltammetry of microparticles using deposits of the pristine pigments on parafiSn-impregnated graphite electrodes. Data from square-wave voltammograms at a potential step increment of 4 mV, square-wave amplitude of 25 mV, and frequency of 15 Hz. All potentials refer to AgQ (3M NaCl)/Ag. Electrolyte, 0.50 M acetate buffer, pH 4.85...
In these equations, Ej represents the electrode potential during the yth half period, 5 the fraction of the square-wave half period at which the current is measured, / is the square-wave frequency (equal to the inverse of the square-wave period), and the other symbols have their customary meaning. As long as the square-wave amplitude, Esw, is lower than 0.5RT jnF—a condition easily accomplished under the usual experimental conditions—the differential sum of the currents flowing during the anodic and cathodic half cycles can be represented by an expression such as [184]... [Pg.77]

Fig. 3.12 Tafel SL vs. 00 diagram for the most common copper pigments and copper alteration products. From SQWVs of specimen-modified paraffin-impregnated graphite electrodes immersed into 0.50 M phosphate buffer, pH 7.4. Potential scan initiated at -1-0.45 mV in the negative direction. Potential step increment 4 mV square wave amplitude 15 mV frequency 2 Hz... Fig. 3.12 Tafel SL vs. 00 diagram for the most common copper pigments and copper alteration products. From SQWVs of specimen-modified paraffin-impregnated graphite electrodes immersed into 0.50 M phosphate buffer, pH 7.4. Potential scan initiated at -1-0.45 mV in the negative direction. Potential step increment 4 mV square wave amplitude 15 mV frequency 2 Hz...
Fig. 4.13 Square-wave voltammograms of PIGEs modified with mixtures of a zirconium-containing sample plus Zr02 (standard) and ZnO (auxiliary reference material) in contact with O.IOM VaCZ. Sample ZnO mass ratio equal to 4.422 ZnO Zr02 mass ratio equal to (a) 0.163 (b) 1.216 and (c) 5.374. Potential scan initiated at —1.45 V in the positive direction without prior electrodeposition step. Potential step increment 4 mV square-wave amplitude 25 mV frequency 15 Hz. [234]... Fig. 4.13 Square-wave voltammograms of PIGEs modified with mixtures of a zirconium-containing sample plus Zr02 (standard) and ZnO (auxiliary reference material) in contact with O.IOM VaCZ. Sample ZnO mass ratio equal to 4.422 ZnO Zr02 mass ratio equal to (a) 0.163 (b) 1.216 and (c) 5.374. Potential scan initiated at —1.45 V in the positive direction without prior electrodeposition step. Potential step increment 4 mV square-wave amplitude 25 mV frequency 15 Hz. [234]...
Fig. 4.16 Square-wave voltammograms for (a) alizarin (15.72%) + morin (7.16%) -I- silica (77.12%) and (b) alizarin (19.03%) + purpurin (8.30%) -I- raorin (12.48%) -I- silica mixtures (60.19%). Electrolyte 0.50M sodium acetate buffer, pH 4.90. Potential step increment 4 mV square-wave amplitude 25 mV frequency 15 Hz [241]... Fig. 4.16 Square-wave voltammograms for (a) alizarin (15.72%) + morin (7.16%) -I- silica (77.12%) and (b) alizarin (19.03%) + purpurin (8.30%) -I- raorin (12.48%) -I- silica mixtures (60.19%). Electrolyte 0.50M sodium acetate buffer, pH 4.90. Potential step increment 4 mV square-wave amplitude 25 mV frequency 15 Hz [241]...
Fig. 4.18 Stripping oxidation peaks recorded for (a) Sn02 plus auxiliary clay (50%, 50% w/w mixture), and (b) Sn02 plus PbCOs plus auxiliary clay (20%, 40%, 40% w/w mixture) specimens attached to PlGEs in contact with 0.50 M acetate buffer. Square-wave voltammograms initiated at — 1.05 V after an electrodeposition step of 30 s at that potential. Potential step increment 4 mV square-wave amplitude 25 mV frequency 15 Hz [242]... Fig. 4.18 Stripping oxidation peaks recorded for (a) Sn02 plus auxiliary clay (50%, 50% w/w mixture), and (b) Sn02 plus PbCOs plus auxiliary clay (20%, 40%, 40% w/w mixture) specimens attached to PlGEs in contact with 0.50 M acetate buffer. Square-wave voltammograms initiated at — 1.05 V after an electrodeposition step of 30 s at that potential. Potential step increment 4 mV square-wave amplitude 25 mV frequency 15 Hz [242]...
Fig. 7.8 Variation of the half-peak width (Wi/2, Eq. (7.32)) of the SWV curve with the square wave amplitude ( sw) for the four geometries considered discs, spheres, cylinders, and bands. A s = 5mV. T= 298.15 K... Fig. 7.8 Variation of the half-peak width (Wi/2, Eq. (7.32)) of the SWV curve with the square wave amplitude ( sw) for the four geometries considered discs, spheres, cylinders, and bands. A s = 5mV. T= 298.15 K...
Fig. 7.10 Influence of the square wave amplitude ( sw) on the SWV curves at discs (solid lines), spheres (dotted lines), cylinders (dashed lines), and bands (dashed-dotted lines). Five sff values are considered 50, 75, 100, 125, and 150 mV. A s = 5mV, t = 10ms,... Fig. 7.10 Influence of the square wave amplitude ( sw) on the SWV curves at discs (solid lines), spheres (dotted lines), cylinders (dashed lines), and bands (dashed-dotted lines). Five sff values are considered 50, 75, 100, 125, and 150 mV. A s = 5mV, t = 10ms,...
See other pages where Square wave amplitude is mentioned: [Pg.333]    [Pg.333]    [Pg.113]    [Pg.4]    [Pg.6]    [Pg.33]    [Pg.146]    [Pg.56]    [Pg.83]    [Pg.103]    [Pg.307]    [Pg.467]    [Pg.479]   
See also in sourсe #XX -- [ Pg.6 ]

See also in sourсe #XX -- [ Pg.6 ]



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Square-wave amplitude backward current

Square-wave amplitude current components

Square-wave amplitude forward current

Square-wave amplitude frequency

Square-wave amplitude instrumentation

Square-wave amplitude peak current

Square-wave amplitude peak potential

Square-wave amplitude polarography

Square-wave amplitude potential increment

Square-wave amplitude voltammetry

Wave amplitude

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