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1. Voltammetry. AIT. Basics. a redox reaction transfers electrons between the reactant species and the electrode produces a measurable current the greater concentration of reactive species, the greater the current measurement of currents can be used to determine concentrations
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1. Voltammetry AIT
Basics • a redox reaction transfers electrons between the reactant species and the electrode • produces a measurable current • the greater concentration of reactive species, the greater the current • measurement of currents can be used to determine concentrations • voltammetry - an electrical current is measured as a function of applied potential • used to identify and quantify
M+ + e M (s) • reaction will only occur if both the following conditions apply: • the ion is close enough to the electrode • the voltage applied at the electrode is enough to allow the reaction to occur (the reduction potential) • some ions will always be close to the electrode by sheer chance • voltage as the controlling factor for whether reaction will occur
Current Reduction potential Applied potential Initial potential Too low, so no reaction can occur Current is zero As potential approaches redn V, some ions react Current is low and increasing As potential pass redn V, all ions near electrode react Current is high After redn V, ions newly arrived near electrode react Current is high and constant
a measurable change in current as a consequence of a voltage change • this is known as a wave • whole scan is a voltammogram
Exercise 1.1 • an analogy between spectroscopy and voltammetry
Uses of voltammetry • for both quantitative and qualitative analysis: • the wave position (voltage) is characteristic of a particular species • the wave height (current) is proportional to concentration
Movement of ions • diffusion (simple random motion), • electrostatic attraction, and • convection • current-concentration only linear, if diffusion is the only mechanism • minimise the other two processes as much as possible
Removing problems • not stirring the solution controls convection • not possible to prevent electrostatic attraction between the positive ions and the negative electrode • reduced by addition of a high concentration of non-reactive ions, known as the supporting electrolyte • KCl or KNO3 at concentrations around 0.1 M • the very high level of other ions masks attraction to the electrode
electrostatic attraction diffusion
supporting electrolyte has two other functions: • masks matrix interference due to different levels of background ions in different samples • ensures that the solution will have enough electrical conductivity • voltammetry only ever uses up a tiny fraction of the reducible species in the sample • multiple scans can be run on the one sample without changing its overall concentration
1.2 Polarography • the most commonly used form of voltammetry • one of the electrodes is made from a capillary of mercury, forming a drop at the end • known as a dropping mercury electrode (DME) • scan is called a polarogram
Exercise 1.2 Measure the half-wave potential and diffusion current • Applied potential: each scale division is equal to 0.5 V, becoming more negative from 0 V • Current: each scale division is equal to 1 uA starting from 0. • (a) -1.1 V • (b) 7.5 uA
Hg reservoir DME auxiliary electrode reference electrode N2 bubbler Polarographic cell
Cell components • Dropping mercury electrode – the electrode at which the analyte reaction occurs • Reference electrode –an electrode which maintains a constant voltage regardless of the solution and reactions occurring • Auxiliary electrode – provides a path through which current can flow and be measured; usually a platinum wire • Nitrogen bubbler – dissolved oxygen produces two visible polarographic waves, at around –0.1 and –0.9 V bubbling nitrogen through the solution for 5 minutes removes the oxygen
Auxiliary DME Reference Why 3 electrodes? • one pair (DME & ref.) to control voltage • one pair (DME & aux.) for current path and measurement Current Voltage
Why a DME? • does not seem like the most obvious choice • one significant advantage: it presents a fresh surface to the solution every second or so • allows a much more reproducible control of potential than a fixed electrode, where the reduced metal (for example) becomes coated to it • Hg oxidised >+0.4 V, so a Pt or graphite working electrode must be used
Matrix effects • presence of complexing agents (ligands) shifts E½ • working voltage range of +0.4 to –1.8V • >+0.4: the mercury drop will be oxidised • < –1.8V (varies with pH) water is reduced to hydrogen gas
Improvements to polarography • limited sensitivity – DC polarography is limited to about 5 mg/L for most species • difficulty in measurement – due to the waveform shape and the oscillations • improve the former and get rid of the latter by changing the way that: • the voltage changes • the current is measured
measurement point polarogram output 1. Sampled DC • most obvious problem is the oscillations • “digitise” the current measurement, so that a single measure per drop was taken • measurement is timed at just before the drop falls off (knocker) • slightly improved sensitivity
2. Pulsed polarography • sensitivity is limited by the relatively high level of background current • it “hides” analyte response • three causes: • other species – apart from oxygen, not solvable • voltage changes – the drop charges like a capacitor as the V changes • drop growth – high bkgd current at start of drop growth
pulsed change continuous voltage change V time Solutions • V changes – apply V increases in steps (pulses), since capacitor behaviour fades if V is constant • drop growth – measure at end of drop life: bkgd current has faded away • 10 x improvement in sensitivity
3. Differential pulse • pulse still gives difficult to measure wave • DP measures at two points (start and end of drop) • current plotted is difference • 20 x increase in sensitivity • change of shape to peak (like 1st derivative titration curve)
Advantages • sensitivity – realistic detection limits for differential pulse polarography are around 50 ug/L, • multi-component analysis – provided the half-wave potentials are at least 100 mV apart, • equipment that is relatively simple and not particularly expensive – typically $40,000 for a computer-controlled device capable of polarography and voltammetry, • a wide range of analytes - metallic ions, non-metallic ions and organic species.
Disadvantages • contaminated mercury – which can be purified by distillation with special apparatus, • relatively slow – due to purging time • matrix interference – due to complex formation, which can make a species not analysable because the half-wave potential is outside the measurable range
DO electrode • an electrode which measures dissolved oxygen (DO) • not an ion-selective electrode • relies on current, not potential, measurement • the oxygen is not an interference but the analyte • non- scanning: V held at -0.8V • current is proportional to the oxygen concentration • calibrated using a saturated solution (9 mg/L at 25C)
Anodic stripping voltammetry • the most sensitive form • analyses much more of the sample than normal polarography • requires stirring & longer reaction period • cannot do a very slow scan • Hg drop electrode still used • Step 1 (slow) - fixed voltage, with stirring for 90s to 10 minutes • M+ + e => M (Hg amalgam) • Step 2 (normal speed) – scan • M(Hg amalgam) => M+ + e
ASV • not all analyte is reduced – time dependent • can measure at ng/L (not ug/L) level • limited to those which form an amalgam with Hg • copper, lead, cadmium, zinc, indium and bismuth
Exercise 1.4 • What is the problem with using a DME for this analysis? • reduced analyte in step 1 falls to the bottom of the cell and is lost • What could be done to get around this problem, still using a mercury drop as the electrode? • both steps are done with a single drop • called Hanging Drop Mercury Electrode (HDME)