Titration Copy 140218131913 Phpapp01

8/10/2019 Titration Copy 140218131913 Phpapp01

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TITRIMETRIC

ANALYSIS

Siham Abdoun

Msc., PhD


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Introduction

A chemical test is a qualitative or quantitative

procedure designed to prove the existence of, or

to quantify, a chemical compound or chemical

group with the aid of a specific reagent.

A presumptive test is specifically used inmedical and forensic science.


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Pharmaceutical analysis is the quantitative

measurement of the active ingredient and relatedcompounds in the pharmaceutical product 1].

These determinations require the highest

accuracy, precision, and reliability because of the

intended use of the data as in:

1. Manufacturing control (identify drug in

formulation),
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2. Stability evaluation (determine the impurity

and degradation products in the stability study),

and shelf-life prediction.

3. Determination of drugs and their metabolites inbiological samples, generally plasma or urine, is

important in elucidation of drug metabolism

pathways as well as comparing bioavailability

of different formulas.


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There are several methods used in chemical

analysis starting from simple manual

method to complicated and sophisticated

ones of these are: titration,

spectrophotometric ,HPLC with multi

detectors ,.etc


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Titration

Titration involves the addition of a reactant

to a solution being analyzed until some

equivalence point is reached. Most familiar

one is the acid-base titration involving a

color changing indicator. There are many

other types of titrations, for example

potentiometric titrations.


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Applications :

1. Provide standard pharmacopeial methods forthe assay of unformulated drugs and

excipents and some formulated drugs e.g.

those lack strong chromophore

2. Used for standardization of raw materials and

intermediates used in drug synthesis.

3. Certain specialist titration such as Karl

Fischer


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Advantages:

1. Capable of higher degree of precision and

accuracy.

2. The method are generally robust

3. Analysis can be automated

4. Cheap to do and not require specialized

apparatus


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Limitations:

1. Non selective

2. Time consuming if not automated and

require greater level of operator skill

3. Require large amount of sample

4. Reaction of standard solution should be rapidand complete 1]


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Depending on the endpoint desired, single

drops or less than a single drop of the titrantcan make the difference between a

permanent and temporary change in the

indicator. When the end point of the

reaction is reached, the volume of reactant

consumed is measured and used to calculate

the concentration of analyte


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Preparation techniques

Typical titrations require titrant and analyte to

be in a liquid (solution) form. Though solids

are usually dissolved into an aqueoussolution, other solvents such as glacial acetic

acid or ethanol are also used. [2]

Concentrated analytes are often diluted to

improve accuracy.


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Many non-acid-base titrations require a

constant pH throughout the reaction. Therefore

a buffer solution may be added to the titration

chamber to maintain the pH.[3]

In instances where two reactants in a samplemay react with the titrant and only one is the

desired analyte, a separate masking solution

may be added to the reaction chamber which

masks the unwanted ion.[4]
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Some redox reactions may require heating

the sample solution and titrating while the

solution is still hot to increase the reaction

rate. For instance, the oxidation of someoxalate solutions requires heating to 60 C

(140 F) to maintain a reasonable rate of

reaction.[5]


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Titration curves

A titration curve is a curve in the plane whosex-

coordinate is the volume of titrant added since

the beginning of the titration, and whosey-

coordinate is the concentration of the analyte at

the corresponding stage of the titration (in an

acid-base titration, they-coordinate is usually

the pH of the solution).[6]


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In an acid-base titration, the titration curve

reflects the strength of the corresponding acidand base. For a strong acid and a strong base,

the curve will be relatively smooth and very

steep near the equivalence point. Because of

this, a small change in titrant volume near the

equivalence point results in a large pH changeand many indicators would be appropriate (e.g.

phenolphthalein or bromothymol blue).


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Strong acid and strong base curve


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If one reagent is a weak acid or base and the

other is a strong acid or base, the titration curve

is irregular and the pH shifts less with small

additions of titrant near the equivalence point.

For example, the titration curve for the titration

between oxalic acid (a weak acid) and Na OH

(a strong base), the equivalence point occurs

between pH 8-10,


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Indicating the solution is basic at the

equivalence point and an indicator such as

phenolphthalein would be appropriate.

Titration curves corresponding to weak bases

and strong acids are similarly behaved, with the

solution being acidic at the equivalence point

and indicators such as methyl orange and

bromothymol blue being most appropriate.


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Strong acid and weak base curve


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Titrations between a weak acid and a weak

base have titration curves which are highly

irregular. Because of this, no definite

indicator may be appropriate and a pH meteris often used to monitor the reaction.[7]

The type of function that can be used to

describe the curve is called a sigmoid

function.


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Weak acid and weak base curve


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Endpoint and equivalence point

Although equivalence point and endpoint areused interchangeably, they are different terms.

Equivalence pointis the theoretical completion

of the reaction: the volume of added titrant at

which the number of moles of titrant is equal to

the number of moles of analyte, or some

multiple thereof (as in polyprotic acids).


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Endpointis what is actually measured, a

physical change in the solution as determinedby an indicator or an instrument mentioned

above.[8]

There is a slight difference between the

endpoint and the equivalence point of the

titration. This error is referred to as an

indicator error, and it is indeterminate.[9]
http://en.wikipedia.org/wiki/Titrationhttp://en.wikipedia.org/wiki/Titrationhttp://en.wikipedia.org/wiki/Titrationhttp://en.wikipedia.org/wiki/Titration


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Types of titrations:

There are many types of titrations with

different procedures and goals. The most

common types of quantitative titration are

acid base titrations and redox titrations.


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1. Acid base titrations

Acid-base titrations depend on the neutralization

between an acid and a base when mixed in solution.

In addition to the sample, an appropriate indicator

is added to the titration chamber, reflecting the pH

range of the equivalence point. The acid-base

indicator indicates the endpoint of the titration by

changing color.


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Indicator Color on acidic side Range of pH color change Color on basic side

Methyl Violet Yellow 0.01.6 Violet

Bromophenol Blue Yellow 3.04.6 Blue

Methyl Orange Red 3.14.4 Yellow

Methyl Red Red 4.46.3 Yellow

Litmus Red 5.08.0 Blue

Bromothymol Blue Yellow 6.07.6 Blue

Phenolphthalein Colorless 8.310.0 Pink

Alizarin Yellow Yellow 10.112.0 Red

The following table show some

indicators used with their pH ranges

and colors of each :


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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.


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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

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.


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2. 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 exact, therefore

an indicator such as sodium diphenylamine is used.


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Some redox titrations do not require an

indicator, due to the intense color of the

constituents. For example, in permanganometry

a slight faint persisting pink color signals the

endpoint of the titration because of the color of

the excess oxidizing agent potassium

permanganate.[10]
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3.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 the gas phase titration, gaseous ozone is

titrated with nitrogen oxide according to the

reaction:

O3 + NO O2 + NO2.[11][12]


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After the reaction is complete, the

remaining titrant and product arequantified (e.g., by FT-IR); this is used to

determine the amount of analyte in the

original sample.


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4. Complexometric titration

Complexometric titrations rely on the formation

of a complex between the analyte and the titrant.

In general, they require specialized indicators

that form weak complexes with the analyte.

Common examples are Eriochrome Black T for

the titration of calcium and magnesium ions, and

the chelating agent EDTA used to titrate metal

ions in solution.[13]


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5. Back titration

Back titration is a titration done in reverse;

instead of titrating the original sample, a known

excess of standard reagent is added to the

solution, and the excess is titrated. A back

titration is useful if the endpoint of the reverse

titration is easier to identify than the endpoint of

the normal titration, as with precipitation

reactions.


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Back titrations are also useful if the reaction

between the analyte and the titrant is very

slow, or when the analyte is in a non-soluble

solid.[16]

M i th d i t f tit ti


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Measuring the endpoint of a titration

There are different methods to determine the

endpoint include:[17]

1. Indicator: A substance that changes color in

response to a chemical change. An acid-base

indicator (e.g., phenolphthalein) changes color

depending on the pH. Redox indicators are also

used. A drop of indicator solution is added tothe titration at the beginning; the endpoint has

been reached when the color changes.


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2. Potentiometer: An instrument that measures

the electrode potential of the solution. These are

used for redox titrations; the potential of the

working electrode will suddenly change as the

endpoint is reached.

The pH meter is a potentiometer with an

electrode whose potential depends on theamount of H+ ion present in the solution. (This

is an example of an ion-selective electrode.)


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3. Conductivity: A measurement of ions in a

solution. Ion concentration can changesignificantly in a titration, which changes the

conductivity. (For instance, during an acid-base

titration, the H+ and OH- ions react to form

neutral H2O.) As total conductance depends on

all ions present in the solution and not all ionscontribute equally (due to mobility and ionic

strength).


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4. Color change: In some reactions, the solution

changes color without any added indicator. This is

often seen in redox titrations when the different

oxidation states of the product and reactant produce

different colors.

5. Spectroscopy: Used to measure the absorption of

light by the solution during titration if the spectrum of

the reactant, titrant or product is known. The

concentration of the material can be determined by

Beer's Law.


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7. Amperometry: Measures the current

produced by the titration reaction as a result of

the oxidation or reduction of the analyte. The

endpoint is detected as a change in the current.

This method is most useful when the excess

titrant can be reduced, as in the titration of

halides with Ag+.


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8. Isothermal titration calorimeter :

An instrument that measures the heat produced

or consumed by the reaction to determine the

endpoint. Used in biochemical titrations, such

as the determination of how substrates bind to

enzymes.


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9. Thermometric titrimetry:

Differentiated from calorimetric titrimetry

because the heat of the reaction (as indicated

by temperature rise or fall) is not used todetermine the amount of analyte in the

sample solution. Instead, the endpoint is

determined by the rate of temperature

change.

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Titration Copy 140218131913 Phpapp01