There are many types of titrations with different procedures and goals. The most common types of qualitative titration are
acid–base titrations and
redox titrations.
Acid–base titration Acid–base titrations depend on the
neutralization between an acid and a base when mixed in solution. In addition to the sample, an appropriate
pH indicator is added to the titration chamber, representing the pH range of the equivalence point. The acid–base indicator indicates the endpoint of the titration by changing color. The endpoint and the equivalence point are not exactly the same because the equivalence point is determined by the stoichiometry of the reaction while the endpoint is just the color change from the indicator. Thus, a careful selection of the indicator will reduce the indicator error. For example, if the equivalence point is at a pH of 8.4, then the phenolphthalein indicator would be used instead of Alizarin Yellow because phenolphthalein would reduce the indicator error. Common indicators, their colors, and the pH range in which they change color are given in the table above. When more precise results are required, or when the reagents are a weak acid and a weak base, a
pH meter or a conductance meter are used. For very strong bases, such as
organolithium reagent,
metal amides, and
hydrides, water is generally not a suitable solvent and indicators whose
pKa are in the range of aqueous pH changes are of little use. Instead, the titrant and indicator used are much weaker acids, and anhydrous solvents such as
THF are used. The approximate pH during titration can be approximated by three kinds of calculations. Before beginning of titration, the concentration of [H+] is calculated in an aqueous solution of weak acid before adding any base. When the number of moles of bases added equals the number of moles of initial acid or so called
equivalence point, one of hydrolysis and the pH is calculated in the same way that the conjugate bases of the acid titrated was calculated. Between starting and end points, [H+] is obtained from the
Henderson-Hasselbalch equation and titration mixture is considered as buffer. In Henderson-Hasselbalch equation the and are said to be the molarities that would have been present even with dissociation or hydrolysis. In a buffer, [H+] can be calculated exactly but the dissociation of , the hydrolysis of A- and self-ionization of water must be taken into account. Four independent equations must be used: :[\ce{H+}][\ce{OH-}] = 10^{-14} :[\ce{H+}] = K_a\ce{\frac{[HA]}{[A^{-}]}} :[\ce{HA}] + [\ce{A-}] = \frac{(n_\ce{A} + n_\ce{B})}{V} :[\ce{H+}] + \frac{n_\ce{B}}{V} = [\ce{A-}] + [\ce{OH-}] In the equations, n_\ce{A} and n_\ce{B} are the moles of acid () and salt ( where X is the cation), respectively, used in the buffer, and the volume of solution is . The
law of mass action is applied to the ionization of water and the dissociation of acid to derived the first and second equations. The mass balance is used in the third equation, where the sum of V[\ce{HA}] and V[\ce{A-}] must equal to the number of moles of dissolved acid and base, respectively. Charge balance is used in the fourth equation, where the left hand side represents the total charge of the cations and the right hand side represents the total charge of the anions: \frac{n_\ce{B}}{V} is the molarity of the cation (e.g. sodium, if sodium salt of the acid or sodium hydroxide is used in making the buffer).
Redox titration Redox titrations are based on a
reduction-oxidation reaction between an oxidizing agent and a reducing agent. A
potentiometer or a
redox indicator is usually used to determine the endpoint of the titration, as when one of the constituents is the oxidizing agent
potassium dichromate. The color change of the solution from orange to green is not definite, therefore an indicator such as sodium diphenylamine is used. Analysis of wines for
sulfur dioxide requires iodine as an oxidizing agent. In this case, starch is used as an indicator; a blue starch-iodine complex is formed in the presence of excess iodine, signalling the endpoint. Some redox titrations do not require an indicator, due to the intense color of the constituents. For instance, in
permanganometry a slight persisting pink color signals the endpoint of the titration because of the color of the excess oxidizing agent
potassium permanganate. In
iodometry, at sufficiently large concentrations, the disappearance of the deep red-brown
triiodide ion can itself be used as an endpoint, though at lower concentrations sensitivity is improved by adding
starch indicator, which forms an intensely blue complex with triiodide. titration mixture before (left) and after (right) the end point.
Gas phase titration Gas phase titrations are titrations done in the
gas phase, specifically as methods for determining reactive species by reaction with an excess of some other
gas, acting as the titrant. In one common gas phase titration, gaseous
ozone is titrated with nitrogen oxide according to the reaction :O3 + NO → O2 + NO2. After the reaction is complete, the remaining titrant and product are quantified (e.g., by
Fourier transform spectroscopy) (FT-IR); this is used to determine the amount of analyte in the original sample. Gas phase titration has several advantages over simple
spectrophotometry. First, the measurement does not depend on path length, because the same path length is used for the measurement of both the excess titrant and the product. Second, the measurement does not depend on a linear change in absorbance as a function of analyte concentration as defined by the
Beer–Lambert law. Third, it is useful for samples containing species which interfere at wavelengths typically used for the analyte.
Complexometric titration Complexometric titrations rely on the formation of a
complex between the analyte and the titrant. In general, they require specialized
complexometric indicators that form weak complexes with the analyte. The most common example is the use of
starch indicator to increase the sensitivity of iodometric titration, the dark blue complex of starch with iodine and iodide being more visible than iodine alone. Other complexometric indicators are
Eriochrome Black T for the titration of
calcium and
magnesium ions, and the
chelating agent EDTA used to titrate metal ions in solution.
Zeta potential titration Zeta potential titrations are titrations in which the completion is monitored by the
zeta potential, rather than by an
indicator, in order to characterize
heterogeneous systems, such as
colloids. One of the uses is to determine the
iso-electric point when
surface charge becomes zero, achieved by changing the
pH or adding
surfactant. Another use is to determine the optimum dose for
flocculation or
stabilization.
Assay An assay is a type of biological titration used to determine the concentration of a
virus or
bacterium. Serial dilutions are performed on a sample in a fixed ratio (such as 1:1, 1:2, 1:4, 1:8, etc.) until the last dilution does not give a positive test for the presence of the virus. The positive or negative value may be determined by inspecting the infected cells visually under a
microscope or by an immunoenzymetric method such as
enzyme-linked immunosorbent assay (ELISA). This value is known as the
titer. ==Measuring the endpoint of a titration==