1. IIT-JEE Syllabus Carbohydrates: Classification – mono, di and polysaccharides (Glucose, Sucrose and Starch only); hydrolysis of sucrose. Amino acids and Peptides: General structure and physical properties. Properties and uses of some important polymers (natural rubber, cellulose, nylon, teflon, PVC), Dyes and their application. 2. Carbohydrates 2.1 Introduction Old Definition: The group of compounds known as carbohydrates received their general name because of early observations that they often have the formula Cx(H2O)y – that is, they appear to be hydrates of carbon. Limitations of the old definition: The above definition could not survive long due to the following reasons: i) A number of compounds such as rhamnose, (C6H12O5) and deoxyribose (C5H10O4) are known which are carbohydrates by their chemical behaviour but cannot be represented as hydrates of carbon. ii) There are other substances like formaldehyde (HCHO, CH2O) and acetic acid [CH3COOH, C2 (H2O)2] which do not behave like carbohydrates but can be represented by the general formula, Cx(H2O)y. New definition: Carbohydrates are defined as polyhydroxy aldehydes or polyhydroxy ketones or substances which give these on hydrolysis and contain at least one chiral carbon atom. It may be noted here that aldehydic and ketonic groups in carbohydrates are not present as such but usually exist in combination with one of the hydroxyl group of the molecule in the form of hemiacetals and hemiketals respectively. 2.2 Classification The carbohydrates are divided into three major classes depending upon whether or not they undergo hydrolysis, and if they do, on the number of products formed. i) Monosaccharides: The monosaccharides are polyhydroxy aldehydes or polyhydroxy ketones which cannot be decomposed by hydrolysis to give simpler carbohydrates. Examples are glucose and fructose, both of which have molecular formula, C6H12O6. ii) Oligosaccharides: The oligosaccharides (Greek, oligo, few) are carbohydrates which yield a definite number (2-9) of monosaccharide molecules on hydrolysis. They include, a) Disaccharides, which yield two monosaccharide molecules on hydrolysis. Examples are sucrose and maltose, both of which have molecular formula, C12H22O11. b) Trisaccharides, which yield three monosaccharide molecules on hydrolysis. Example is, raffinose, which has molecular formula, C18H32O16. c) Tetrasaccharides, etc. iii) Polysaccharides: The polysaccahrides are carbohydrates of high molecular weight which yield many monosaccharide molecules on hydrolysis. Examples are starch and cellulose, both of which have molecular formula, (C6H10O5)n. In general, the monosaccharides and oligosaccharides are crystalline solids, soluble in water and sweet to taste. They are collectively known as sugars. The polysaccharides, on the other hand, are amorphous, insoluble in water and tasteless. They are called non-sugars. The carbohydrates may also be classified as either reducing or non-reducing sugars. All those carbohydrates which have the ability to reduce Fehling’s solution and Tollen’s reagent are referred to as reducing sugars, while others are non-reducing sugars. All monosaccharides and the disaccharides other than sucrose are reducing sugars. 3. Monosaccharides The monosaccharides are the basis of carbohydrate chemistry since all carbohydrates are either monosaccharides or are converted into monosaccharides on hydrolysis. The monosaccharides are polyhydroxy aldehydes or polyhydroxy ketones. There are, therefore, two main classes of monosaccharides. 1. The Aldoses, which contain an aldehyde group 2. The Ketoses, which contain a ketone group (— —) The aldoses and ketoses are further divided into sub-groups on the basis of the number of carbon atoms in their molecules, as trioses, tetroses, pentoses, hexoses, etc. To classify a monosaccharide completely, it is necessary to specify both, the type of the carbonyl group and the number of carbon atoms present in the molecule. Thus monosaccharides are generally referred to as aldotrioses, aldotetroses, aldopentoses, aldohexoses, ketohexoses, etc. The aldoses and ketoses may be represented by the following general formulas. Glucose and fructose are specific examples of an aldose and a ketose. 3.1 Trioses D and L Terminology: The simplest of all carbohydrates that fit the definition we have given for carbohydrates are the trioses, glyceraldehyde and dihydroxyacetone. Glyceraldehyde is aldotriose, and dihydroxyacetone is a ketotriose. Glyceraldehyde contains one asymmetric carbon atom (marked by an asterisk) and can thus exist in two optically active forms, called the D-form and the L-form. Clearly, the two forms are mirror images that cannot be superimposed, that is they are enantiomers. The two forms of glyceraldehyde are especially important because the more complex monosaccharides may be considered to be derived from them. They serve as a reference point for designating and drawing all other monosaccharides. In carbohydrate chemistry, the Fischer projection formulas are always written with the aldehyde or ketone groups at the top of the structure. By definition, if the hydroxyl group on the asymmetric carbon atom farthest from aldehyde or ketone group projects to the right, the compound is a member of the D-family. If the hydroxyl group on the farthest asymmetric carbon projects to the left, the compound is a member of the L-family. The maximum number of optical isomers of a sugar is related to the number of asymmetric carbon atoms in the molecule and may be calculated by the following simple equation. Maximum Number of Optical Isomers = 2n, where n = the number of asymmetric carbon atoms. Since glyceraldehyde contains only one asymmetric carbon atom, the number of optical isomer is 21. We know that 21 is = 2, and we have seen that there are indeed two different glyceraldehydes. 3.2 Aldotetroses If we examine the general formula of an aldotetrose, we see that they contain two asymmetric carbon atoms (marked by asterisks). This means that 22 or 4 optical isomers are possible. They may be represented as the following two pairs: All four isomers have been prepared synthetically. The D- and L-erythrose are mirror images, that is, they are enantiomers. They have exactly the same degree of rotation but in opposite directions. Equal amounts of the two would constitute a racemic mixture, that is, a mixture that would allow a plane-polarised light to pass through the solution unchanged but could be separated into detrorotatory and laevorotatory isomers. The same comments hold for D- and L-threose. However, D-erythrose and L-threose are not images, that is, they are diastereomers (optical isomers that are not mirror images are called diastereomers), and the degree of rotation of each would probably differ. 3.3 Aldopentoses If we examine the general formula of an aldopentose, we see that they contain three asymmetric carbon atoms. This means that 23 or 8 optical isomers are possible. These are: – D(–) lyxose, L(+)-lyxose, D(–) xylose, L(–)xylose, D(–) arabinose, L(+)-arabinose, D(–)-ribose, L(+)-ribose 3.4 Aldohexoses If we examine the general formula of aldohexose, we see that it contains four asymmetric carbon atoms. This means that 24 or 16 optical isomers are possible. D and L forms of altrose, allose glucose, mannose, galactose, talose, arabinose and idose Only three of the sixteen possible aldohexoses are found in nature (all sixteen isomers have been prepared synthetically). They are D-glucose, D- mannose, and D-galactose. No one of these three optical iosmers is a mirror image of any of the others, so all three are diastereomers of each other. 3.5 Epimers A pair of diastereomers that differ only in the configuration about of a single carbon atom are said to be epimers. e.g D(+)- glucose is epimeric with D(+) -mannose and D(+) -galactose as shown below: 3.6 Cyclic structure of monosaccharides We know that aldoses (and ketoses) react with alcohols to give first hemiacetals (and hemiketals) and then acetals (and ketals), i.e., Since monosaccharides contain a number of hydroxyl groups and an aldehyde or a keto group, therefore, any one of the –OH groups (usually C4 or C5 in aldohexoses and C5 or C6 in ketohexoses) may combine with the aldehyde or the keto group to form intramolecular hemiacetal or hemiketal. As a result, the open chain formulae do not represent the actual structures of the monosaccharides. Their actual structures are cyclic involving five or six membered rings containing an oxygen atom. The five membered ring containing one oxygen atom because of its similarity with furan is called the furanose form and the six membered ring containing one oxygen atom because of its resemblance with pyran is called the pyranose form. In nut shell, all the monosaccharides (pentoses and hexoses) in the free state always exist in the pyranose form. However, in the combined state some monosaccharides such as ribose, 2-deoxyribose, fructose etc., usually exist in the furanose form. 3.7 Cyclic structure of Glucose – Anomers We have discussed above that monosaccharides have cyclic hemiacetal or hemiketal structures. To illustrate, let us first consider the example of D-glucose. During hemiacetal formation C5 – OH of glucose combines with the C1 – aldehydic group. As a result, C1 becomes chiral or asymmetric and thus has two possible arrangements of H and OH groups around it. In other words, D-glucose exists in two stereoisomeric forms, i.e., α-D-glucose and β-D-glucose as shown below: In α-D-glucose, the OH group at C1 is towards right while in β-D-glucose, the OH group at C1 is towards left. Such a pair of stereoisomers which differ in configuration only around C1 are called anomers and the C1 carbon is called Anomeric carbon (or glycosidic carbon. The cyclic structures of monosaccharides can be better represented by Haworth Projection formulae. To get such a formula for any monosaccharide (say α-and β-D-glucose), draw a hexagon with its oxygen atom at the upper right hand corner. Place all the groups (on C1, C2, C3 and C4) which are present on left hand side in structures I and II, above the plane of the ring and all those groups on the right hand side below the plane of the ring. The terminal – CH2OH group is always placed above the plane of the hexagon ring (in D-series). Following the above procedure, Haworth Projection Formulae for α-D-glucose (I) and β-D-glucose (II) are obtained as shown below: 3.8 Cyclic structure of Fructose Like glucose, fructose also has a cyclic structure. Since fructose contains a keto group, it forms an intramolecular hemiketal. In the hemiketal formation, C5– OH of the fructose combines with C2-keto group. As a result, C2 becomes chiral and thus has two possible arrangements of CH2OH and OH group around it. Thus, D-fructose exists in two stereoisomeric forms, i.e., α-D-fructopyranose and β-D fructopyranose. However in the combined state (such as sucrose), fructose exists in furanose form as shown below: 3.9 Mutarotation The two stereoisomeric forms of glucose, i.e., α-D-glucose and β-D-glucose exist in separate crystalline forms and thus have different melting points and specific roations. For example α-D-glucose has a m.p. of 419 K with a specific rotation of +112° while β-D-glucose has a m.p. of 424 K and has a specific rotation of +19°. However, when either of these two forms is dissolved in water and allowed to stand, it gets converted into an equilibrium mixture of α-and β-forms through a small amount of the open chain form. As a result of this equilibrium, the specific rotation of a freshly prepared solution of α-D-glucose gradually decreases from of +112° to +52.7° and that of β-D-glucose gradually increases from +19° to +52.7°. This change in specific rotation of an optically active compound in solution with time, to an equilibrium value, is called mutarotation. During mutarotation, the ring opens and then recloses either in the inverted position or in the original position giving a mixture of α-and-β-forms. All reducing carbohydrates, i.e., monosaccharides and disacchardies (maltose, lactose etc.) undergo mutarotation in aqueous solution. 3.10 Reactions of Glucose a) With HI/P: It undergoes reduction to form n-hexane while with sodium amalgam it forms sorbitol. n-hexane s-orbitol b) With H2O: It forms neutral solution c) With Hydroxylamine (NH2OH) d) With HCN: It form addition product cyanohydrin e) Oxidation: Glucose on oxidation with Br2 gives gluconic acid which on further oxidation with HNO3 gives glucaric acid f) With Tollen reagent and Fehling solution. Glucose forms silver mirror and red ppt. of Cu2O respectively. g) With acetic anhydride. In presence of pyridine glucose forms pentaacetate. h) With phenylhydrazine: it forms glucosazone i) With conc. HCl acid: Glucose gives laevulinic acid j) Glycoside formation: When a small amount of gaseous HCl is passed into a solution of D (+) glucose in methanol , a reaction takes place that results in the formation of amomeric methyl acetals. Carbolydrate acetals, genrally are called glycosides and an acetal of glucose is called glucoside. Other reactions a) Kiliani – Fischer Synthesis: – This is a method of lengthening the carbon chain of an aldose. To illustrate, we take synthesis of D-threose and D-erythrose (Aldotetroses) from D-glyceraldehyde (an aldotriose). Addition to HCN to glyceraldehyde produces two epimeric cyanohydrins because reaction creates a new stereoicenter. The cyanohydrins can be separated easily (since they are diastereomers) and each can be converted to an aldose through hydrolysis, acidification and lactonisation, and reduction with Na—Hg. One cyanohydrin ultimately yields D-erythrose and D-threose. Here we can see that both sugars are D-sugars because starting compound is D-glyceraldehyde and its stereocentrer is unaffected by its synthesis. b) Ruff Degradation: It is opposite to Kiliani Fischer synthesis that can be used to shorten the chain by a similar unit. The ruff degradation involves (i) Oxidation of the aldose to an aldonic acid using Bromine water. (ii)Oxidative decarboxylation of the aldonic acid to the next lower aldose using H2O2 and Fe2(SO4)3. D-ribose for example can be reduced to D-erythrose. Exercise 1: Treatment of (+)– glucose with HIO4 gives results that confirm its aldohexose structure. What product should be formed, and how much HIO4 should be consumed. 4. Disaccharides Carbohydrates which upon hydrolysis give two molecules of the same or different monosaccharides are called disaccharides. Their general formula is C12H22O11. The three most important disaccharides are sucrose, maltose, and lactose. Each one of these on hydrolysis with either an acid or an enzyme gives two molecules of the same or different monosaccharides as shown below: Disaccharides may also be considered to be formed by a condensation reaction between two molecules of the same or different monosaccharides with the eliminatioin of a molecule of water. This reaction involves the formation of an acetal from a hemiacetal and an alcohol – in which one of the monosaccharides acts as the hemiacetal while the other acts as the alcohol. 4.1 Sucrose It is formed by condensation of one molecule of glucose and one molecule of fructose. Unlike maltose and lactose, it is non-reducing sugar since both glucose (C1 – α) and fructose (C2 – β) are connected to each other through their reducing centres. Its structure is shown below: Hydrolysis: (Invert Sugar or Invertose). Hydrolysis of sucrose with hot dilute acid yields D-glucose and D-fructose. Sucrose is dextrorotatory, its specific rotation being +66.5%, D-glucose is also dextrorotatory, [α]D = +53°, but D-fructose has a large negative rotation, [α]D = -92°. Since D-fructose has a greater specific rotation than D-glucose, the resulting mixture is laevorotatory. Because of this the hydrolysis of sucrose is known as the inversion of sucrose, and the equimolecular mixture of glucose and fructose is known is invert sugar or invertose. 5. Polysaccharides Polysaccharides are formed when a large number (hundreds to even thousands) of monosaccharide molecules join together with the elimination of water molecule. Thus, polysaccharides may be regarded as condensation polymers in which the monosaccharides are joined together by glycosidic linkages. Some important polysaccharides are: 1. Cellulose 2. Starch 3. Glycogen 4. Gums and 5. Pectins 5.1 Starch It is a polymer of glucose. Its molecular formula is (C6H10O5)n where the value of n (200 – 1000) varies from source to source. It is the chief food reserve material or storage polysaccharide of plants and is found mainly in seeds, roots, tubers, etc. Wheat, rice, potatoes, corn, bananas etc., are rich sources of starch. Starch is not a single compound but is a mixture of two components – a water soluble component called amylose (20%) and a water insoluble component called amylopectin (80%). Both amylose and amylopectin are polymers of α-D-glucose. Amylose is a linear polymer of α-D-glucose. It contains about 200 glucose units which are linked to one another through α-linkage involving C1 of one glucose unit with C4 of the other as shown below: Amylopectin, on the other hand, is a highly branched polymer. It consists of a large number (several branches) of short chains each containing 20-25 glucose units which are joined together through α-linkages involving C1 of one glucose unit with C4 of the other. The C1 of terminal glucose unit in each chain is further linked to C6 of the other glucose unit in the next chain through C1 – C6 α-linkage. This gives amylopectin a highly branched structure as shown below.- Hydrolysis: Hydrolysis of starch with hot dilute acids or by enzymes gives dextrins of varying complexity, maltose and finally D-glucose. Starch does not reduce Tollen’s reagent and Fehling’s solution. Uses: It is used as a food. It is encountered daily in the form of potatoes, bread, cakes, rice etc. It is used in coating and sizing paper to improve the writing qualities. Starch is used to treat textile fibres before they are woven into cloth so that they can be woven without breaking. It is used in manufacture of dextrins, glucose and ethyl alcohol. Starch is also used in manufacture of starch nitrate, which is used as an explosive. 6. Amino Acids 6.1 Introduction and Nomenclature Amino acids are molecules, which contain two functional groups, one is carboxylic group and another is amino group. Amino acids are derivatives of carboxylic acids in which one hydrogen atom of carbon chain is substituted by Amino group. Amino group may be at α, β, γ position with respect to carboxylic group H2N ⎯ CH2 ⎯ COOH Amino acetic acid, or Glycine CH3 ⎯ CH (NH2) ⎯ COOH α – Amino propionic acid or Alanine H2N ⎯ CH2 ⎯ CH2 ⎯COOH β – Amino propionic acid H2N ⎯ CH2 ⎯ (CH2)2 ⎯ COOH γ – Amino butyric acid Some amino acids contain a second carboxyl group or a potential carboxyl group in the form of carboxamide: these are called acidic amino acid some contain a second basic group which may be an amino group these are called basic amino acids. 6.2 Physical Properties and Structure Although the amino acids are commonly shown as containing an amino group and a carboxyl group, certain properties are not consistent with this structure. 1. In contrast to amines and carboxylic acids, the amino acids are nonvolatile solids, which melt at fairly high temperatures. 2. They are insoluble in organic solvents [i.e. non polar solvents] and are highly soluble in water. 3. Their aqueous solution is neutral. 4. Their aqueous solutions behave like solutions of substances of high dipole moment. 5. Acidity and basicity constants are ridiculously low for – COOH and – NH2 groups All these properties are quite consistent with a dipolar ion structure for the amino acids (I) +H3N ⎯ CHR ⎯ COO–– (I) Amino acid : dipolar ions In the physical properties melting points, solubility, and high dipole moment are just what would be expected of such a salt. The acid base properties also become understandable when it is realized that the measured Ka actually refers to the acidity of an ammonium ion, RNH3+ +H3NCHRCOO– + H2O H3O+ + H2NCHRCOO– and Kb actually refers to the basicity of a carboxylate ion, RCOO– +H3N ⎯ CH ⎯ RCOO– + H2O +H3N ⎯ CHR ⎯COOH + OH– When the solution of an amino acid is made alkaline, the dipolar ion(I) is converted to the anion (II); the stronger base, hydroxide ion, removes a proton from the ammonium ion and displaces the weaker base, the amine +H3N ⎯ CHRCOO– + OH– H2N CHRCOO– + H2O (I) (II) Stronger Stronger Weaker Weaker acid base base acid When the solution of an amino acid is made acidic; the dipolar ion I is converted into the cation (III); the stronger acid , gives up a proton to the carboxylate ion, and displaces the weaker carboxylic acid. +H3N CHRCOO– + H3O+ +H3N CHRCOOH + H2O (I) (III) Stronger Stronger Weaker Weaker base acid acid base In summary, the acidic group of a simple amino acid like glycine is not –COOH, and basic group is –COO- not –NH2. Exercise 2: The amino acids in water acts as ampholyte. Explain? 6.3 Iso Electric Point What happens when a solution of an amino acid is placed in an electric field depends upon the acidity or basicity of solution. In quite alkaline solution. Anions (II) exceed cations (III), and there is a net migration of amino acid toward the anode. In quite acidic solution cations (III) are in excess, and there is a net migration of amino acid towards the cathode. If (II) and (III) are exactly balanced, there is no net migration; under such conditions any one molecule exists as a positive ion and as a negative ion for exactly the same amount of time and any small movement in the direction of one electrode is subsequently cancelled by an equal movement back towards the other electrode. The hydrogen ion concentration of the solution in which a particular amino acid does not migrate under the influence of an electric field is called the isoelectric point of that amino acid. An amino acid shows its lowest solubility in a solution at the isoelectric point, since here there is the highest concentration of the dipolar ion. As the solution is made more alkaline or more acidic, the concentration of one of the more soluble ions, II or III increases. If an amino acid has amino group and one carboxyl group, it has two pK values. The isoelectric point (PI) of this amino acid has the average value of the both pK values. We take example of glycine. H3+N ⎯ CH2 ⎯ COOH H3N+ ⎯ CH2 ⎯ COO– + H+ …(1) Conjugated acid (CA) Dipolar Ion (DI) At equilibrium H3N+ ⎯ CH2 ⎯ COO– H2N ⎯ CH2 ⎯ COO– + H+ …(2) DI Conjugated Base (CB) At equilibrium [CA] = [CB] = At isoelectric point [CA] = [CB] Where = conc. of [H+] at isoelectric point. or, = K1 K2 or, 2log [Hi+] = log K1 + log K2 or –2 log (Hi+] = – log k1 – logK2 or 2pHi = pK1 + pK2 or pHi = 7. Peptides As the amino acid molecules contain both basic as well as acidic group it might be expected that an intermolecular reaction may take place between the carboxyl group of one amino acid and the amino group of another amino acid, with the elimination of a molecule of water. R R′ R R′ ⏐ ⏐ ⏐ ⏐ H2N ⎯ CH ⎯ COOH + H2N ⎯ CH ⎯ COOH ⎯→ H2 N ⎯ CHCO ⎯ NH ⎯ CHCOOH Since the resulting molecule still has a free amino and a carboxyl group, it may react with other amino acids at either of the ends to give a higher molecular weight linear or condensation product. Every two amino acids are linked by means of a –CO-NH group, which is commonly referred as peptide bond. So now we can define a peptides as the amides formed by interaction between amino groups and carboxyl groups of amino acids. Depending upon the number of amino acid residues per molecule, they are known as dipeptides, tripeptides and so on and finally polypeptides. 7.1 Naming of Polypeptide A convenient way of representing peptide structures by use of standard abbreviations. According to convention the N-terminal amino acid residue [having the free amino group] is written as the left and the C terminal amino acid residue (having the free carboxyl group) at the right end. A peptide is named by indicating its sequence of amino acids beginning with the N-terminal residue. H2N ⎯ CH ⎯ CONH ⎯ CH ⎯ CONH ⎯ CH ⎯ CONH ⎯ CH ⎯ CONHCH2 COOH | | | | CH3 CH2-OH CH2-C6H5 CH2-CONH2 Alanine Serine Phenylalamine Asparagine glycine This pentapeptide is called alanyl-sery-phenylalanyl-asparaginyl-glycine or using the common abbreviations as H-Ala-Ser-phe-Asn-gly-OH. All naturally occurring important peptides, however, posses a shorter individual name. 7.2 Structure of Poly peptides To identify the structure of a peptide, the peptide in question is first hydrolysed to its constituent amino acids, which are separated and identified. The amount of each amino acid is measured, and hence the number of each kind of amino acid can be calculated. The next problem is to determine the sequence of the various amino acids constituting the peptide. This is very difficult task, because there is a large number of possibilities in which the constituent amino acids may be linked in the peptide, e.g. even is a dipeptide, having glycine and alanine, the two amino-acids may be present in either of the two ways. The two structures differ in the respect that in the first the N-terminal amino acid is glycine (i.e. the amino group of glycine is free) and C-terminal amino acid is alanine, while in the latter the N-terminal amino acid is alanine and C-terminal acid is glycine. Various chemical methods have been developed to remove either of the two terminal amino acid residues of a polypeptide in a stepwise manner and hence the arrangement of the various amino acids in a polypeptide can be established. 7.3 Sanger’s Method Sanger reagent, 1-fluoro-2, 4-dinitrobenzene (FDNB) was first used to determine that which amino acid constituted the amino end of the polypeptide. The method consists in treating the polypeptide with the reagent in the presence of sodium-hydrogen-carbonate solution at room temperature to form a 2, 4-dinitrophenyl (DNP) derivative of the polypeptide. The product is hydrolysed be means of acid (which causes the cleavage of the peptide bond connecting the N-terminal amino acid to the rest of the polypeptide molecule) to form dinitrophenyl (DNP) derivative of the N-terminal amino acid and the rest of the polypeptide molecule or amino acid residues. 8. Dyes 8.1 Definition The chemical substances which are used to impart colour to fabrics, foods and other objects for their beautification and distinction are called dyes. These chemical substances used as dyes are capable of getting fixed to the fabrics permanently and are resistant to the action of water, soap, light, acid and alkalies. The colour of dyes is attributed to their ability to absorb some wavelengths of visible region of electromagnetic spectrum (380 nm to 760 nm). The part of the colour which reflected back gives the colour of the dye i.e. complementary to the colour absorbed. The colour of visible light absorbed and the complementary colour reflected are listed in table. Wave length (nm) Colour absorbed Complementary colour 400 – 435 Violet Yellow, Green 435 – 480 Blue Yellow 480 – 490 Greenish Blue Orange 490 – 500 Bluish Green Red 500 – 560 Green Purple 560 – 580 Yellowish Green Violet 580 – 595 Yellow Blue 595 – 605 Orange Greenish Blue 605 – 750 Red Blue, Green In the earlier days fabrics were coloured by the dyes mainly from Alizarin (red dye) and indigo (blue dye). But now a days, many natural dyes have been synthesized in the laboratory. This helped us to produce dyes of desired shades which otherwise are not available in natural dyes. 8.2 Classification These dyes have been classified into two categories a) Classification based on constitution: Depending upon the characteristic structural units the dyes are classified as follows. Sl. No. Type of Dye Structural Unit Examples 1. Nitro dyes Martius yellow, Naphthol yellow 2. Azo dyes – N = N – (azo group) Orange-I, Orange-II, Congo red 3. Triphenyl methane dyes (C6H5)3C – Malachite green, Rosaniline 4. Phthalein dyes Phenolphthalein, Mercurochrome 5. Anthraquinone dyes Alizarin 6. Indigoid dyes Indigo, Tyrian purple Structures Diphenyl methane dye Auromine – 0 8.3 Classification Based on Application A particular dye may be suitable for one kind of fibre and may be unsuitable for the other. For example, a dye suitable for wool and silk may not be applied or used for dyeing cotton or rayon. Thus based on the class, shade and other properties like resistance to acids, alkalies, and fastness to light a classification of dyes is done, as given below: a) Acid dyes b) Basic dyes c) Direct dyes d) Disperse dyes e) Fibre reactive dyes f) Vat dyes g) Insoluble azodyes h) Mordant dyes a) Acid dyes: These dyes are characterised by the presence of acid group like sulphonic acid (– SO3H), carboxylic acid (– COOH) and phenolic group. The presence of such groups make the dyes more soluble and also serve as the reactive points for fixing the dye to the fibre. Application: These dyes are applied to wool, silk and nylon. These have no affinity for cotton. Examples: Orange-I and Orange-II can be obtained by the action of sulphonic compounds with naphthols or by coupling sulphonic compounds with naphthols. b) Basic Dyes: These dyes contain (–NH2) group or (–NR2) group as chromophore (colour bearing group) or auxochrome (colour enhancing group). In acidic solutions these form water soluble cations. These dyes use the anionic side on the fabric to get themselves attached. Application: This type of dyes is used to dye nylon, polyester, wool, cotton, leather, paper, etc. Example 1. Aniline yellow 2. Butter yellow 3. Crysodine G c) Direct Dyes: These dyes also belong to the class of azo dyes and are used to dye the fabrics directly by placing it in aqueous solution of the dye. The direct dyes attack the fibre by means of hydrogen bonding. Application: These are very effective for dying cotton, wool and rayon Example: 1. Martius yellow 2. Congo Red c) Disperse Dyes: These dyes, as the name signifies, are usually applied in the form of a dispersion of finely divided dye in a soap solution in the presence of phenol, cresol or benzoic acid. Application: These are mainly used to dye rayon, dacron nylon, synthetic fibres, polysters and poly acrylonitrile. Examples: 1. Celliton fast pink B 2. Cellition fast blue B d) Fibre Reactive Dyes: These dyes are used to dye fibres like cotton, wool or silk. These are linked to the fibre by virtue of the hydroxy or amino group present on the fibre. These dyes induce fast colour on fibres which is retained for a longer time. e) Insoluble azo dyes: The dyes belonging to this class are directly synthesised on the fibre. The fabric to be coloured is soaked in an alkaline solution of phenol or naphthol and is than treated with a solution of diazotised amine to produced the azo dye on the surface of the fabric. Application: These dyes can be used to dye cotton silk, polyester, nylon, etc. Example: f) Vat Dyes: Before being introduced on to fabric these dyes are first reduced to colourless leuco compounds in wooden vats by alkaline reducing agent. The fibre is then soaked in the solution of the dye. After proper absorption of the dye, the fibre is then exposed to air or to an oxidising agent. By doing so the dye gets oxidised to yield insoluble coloured dye on the fabric. Example: Indigo dye g) Mordant Dyes: A dye which imparts different colours to the fabric in the presence of different metal ions (called mordants) is referred to as mordant dye. Nowadays it is rarely used Application: These dyes are used for dyeing of wool. The method involves the precipitation of certain substances on the fabrics which then combine with the dye with the dye to form an insoluble coloured complex called lake. Depending on the kind of mordant used different colours. For example, Alizarin, a mordant dye, gives red colour with aluminium and tin salts, where as brownish red colour chromium mordant and black violet with iron mordant. 9. Polymers 9.1 Introduction Sit quietly and think about your activities today from the morning. You wake up in the morning, You want to brush your teeth. You fetch your toothpaste. The tube is made up of a polymer. Your brush is made up of a polymer. When you want to rinse your mouth, you open your plastic(polymer) tap. The pipe lines used to bring water to your tap is made of PVC(polymer). Skip it. You start preparing your break fast. You take a non-stick tawa. Non-stick? What does that mean? What is it made of? It is poly tetrafluoro ethylene abbreviated as teflon, a polymer. See, how polymers play an important role in our daily life from dawn to dusk. The molded chair in which you are sitting is a polymer. The pen with which I’m writing this is a polymer. Want to know more about polymers? Read further. Polymers can be called as macromolecules. Macromolecules can be considered as an association of small molecules to give a big molecule. Macromolecules can be man-made, too. The first syntheses were aimed at making substitutes for the natural macromolecules, rubber and silk; but a vast technology has grown up that now produces hundreds of substances that have no natural counterparts. Synthetic macromolecular compounds include: elastomers, which have the particular kind of elasticity characteristic of rubber; fibers, long, thin and threadlike, with the great strength along the fiber that characterizes cotton, wool, and silk; and plastics, which can be extruded as sheets or pipes, painted on surfaces, or molded to form countless objects. We wear these manmade materials, eat and drink from them, sleep between them, sit and stand on them; turn knobs, pull switches, and grasp handles made of them; with their help we hear sounds and see sights remote from us in time and space; we live in houses and move about in vehicles that are increasingly made of them. 9.2 Polymers and polymerization Macromolecules, both natural and man-made, owe their great size to the fact that they are polymers (Greek: many parts); that is, each one is made up of a great many simpler units — identical to each other or at least chemically similar — joined together in a regular way. They are formed by a process we touched on earlier: polymerization, the joining together of many small molecules to form very large molecules. The simple compounds from which polymers are made are called monomers. Polymers are formed in two general ways. In chain-reaction polymerization, there is a series of reactions each of which consumes a reactive particle and produces another, similar particle; each individual reaction thus depends upon the previous one. The reactive particles can be free radicals, cations, or anions. A typical example is the polymerization of ethylene. Here the chain-carrying particles are free radicals, each of which adds to a monomer molecule to form a new, bigger free radical. Rad. + CH2 = CH2 ⎯→ RadCH2CH2⋅ RadCH2CH2CH2CH2⋅ ⎯→ etc. b) In step reaction polymerization, there is a series of reactions each of which is essentially independent of the preceding one; a polymer is formed simply because the monomer happens to undergo reaction at more than one functional group. A diol, for example, reacts with a dicarboxylic acid to form an ester; but each moiety of the simple ester still contains a group that can react to generate another ester linkage and hence a larger molecule, which itself can react further, and so on. a) Free-radical vinyl polymerization: In we discussed briefly the polymerization of ethylene and substituted ethylenes under conditions where free radicals are generated — typically in the presence of small amounts of an initiator, such as a peroxide. Reaction occurs. At the doubly bonded carbons — the vinyl groups — and is called vinyl polymerization. A wide variety of unsaturated monomers may be used, to yield polymers with different pendant groups (G) attached to the polymer backbone. For example. b) Copolymerization: So far, we have discussed only polymerisation of a single monomeric compound to form a homopolymer, a polymer made up — except, of course, at the two ends of the long molecule — of identical units. Now, if a mixture of two (or more) monomers is allowed to undergo polymerization, there is obtained a copolymer a polymer that contains two (or more) kinds of monomeric units in the same molecule. For example: Through copolymerization there can be made materials with different properties than those of either homopolymer, and thus another dimension is added to the technology. Consider, for example, styrene. Polymerized alone, it gives a good electric insulator that is molded into parts for radios, television sets, and automobiles. Copolymerization with butadiene (30%) adds toughness; with acrylonitrile (20-30%) increases resistance to impact and to hydrocarbon; with maleic anhyride yeilds a material that, on hydrolysis, is water-soluble, and is used as a dispersant and sizing agent. The copolymer in which butadiene predominates (75%) butadiene, 25% styrene) is an elastomer, and since World War II has been the principal rubber substitute manufactured in the United States. Copolymers can be made not just from two different monomers but from three, four, or even more. They can be made not only by free-radical chain reactions, but by any of the polymerization methods we shall take up; ionic, coordination, or step-reaction. The monomer units may be distributed in various ways, depending on the technique used. As we have seen, they may alternate along a chain, either randomly or with varying degrees of regularity. In block copolymers sections made up of one monomer alternate with sections of another: — M1M1M1M1M1 – M2M2M2M2 — Block copolymer If graft copolymers, a branch of one kind is grafted to a chain of another kind: Fibres are long thin, threadlike bits of material that are characterized by great tensile (pulling) strength in the direction of the fiber. The natural fibres – cotton, wool, silk – are typical. Fibres are twisted into threads, which can then be woven into cloth, or embedded in plastic material to impart strength. The tensile strength can be enormous, some synthetic fibres rivaling – on a weight basis – steel. The gross characteristics of fibres are reflected on the molecular level – the molecules, too, are long, thin, and threadlike. Furthermore, and most essential, they lie stretched out alongside each other, lined up in the direction of the fiber. The strength of the fiber resides, ultimately, in the strength of the chemical bonds of the polymer chains. The lining-up is brought about by drawing – stretching — the return to random looping and coiling is overcome by strong intermolecular attractions. In a fiber, enthalpy wins out over entropy. This high degree of molecular orientation is usually — although not always — accompanied by appreciable crystallinity. An elastomer possesses the high degree of elasticity that is characteristic of rubber: it can be greatly deformed — stretched to eight times its original length, for example — and yet return to its original shape. Here, as in fibres, the molecules are long and thin; as in fibres, they become lined up when the material is stretched. The big difference is this: when the stretching force is removed, the molecular chains of an elastomer do not remain extended and aligned but return to their original random conformations favored by entropy. They do not remain aligned because the intermolecular forces necessary to hold them that way are weaker than in a fiber. In general, elastomers do not contain highly polar groups or sites for hydrogen bonding; the extended chains do not fit together well enough for Vander Waals forces to do the job. In an elastomer entropy beats enthalpy. One further requirement the long chains of an elastomer must be connected to each other by occasional cross – links: enough of them to prevent slipping of molecules past one another; not so many as to deprive the chains of the flexibility that is need for ready extension and return to randomness. Natural rubber illustrates these structural requirements of an elastomer; long flexible chains; weak intermoecular forces and occasional cross – linking. Rubber is cis 1,4-polyisoprene . With no highly polar substituents, intermolecular attraction is largely limited to van der Waals forces. But these are weak because of the all – cis configuration about the double bond. Figure below compares the extended chains of rubber with those of its trans stereoisomer. As we can see, the trans configuration permits highly regular zig – zags that fit together well; the cis configuration does not. The all-trans stereoisomer occurs naturally as gutta percha; it is highly crystalline and non-elastic. Chief among the synthetic elastomers is SBR, a copolymer of butadiene (75%) and styrene (25%) produced under free-radical conditions; it competes with natural rubber in the main use of elastomers, the making of automobile tires. All-cis polybutadiene and polyisoprene can be made by Ziegler – Natta polymerization. An elastomer that is entirely or mostly polydiene is, of course, highly unsaturated. All that is required of an elastomer, however, is enough unsaturation to permit cross-linking. In making butyl rubber for example, only 5% of isoprene is copolymerized with isobutylene. Exercise 3: What is the difference between addition and condensation polymersiation give an examples. Some Important Polymers: a) Natural Rubber: Natural rubber is an addition polymer of isoprene (2-methyl-1,3-butadiene) Rubber has an average chain length of 5000 monomer units of isoprene. The rubber in which the arrangement of carbon chain is trans with respect to the double bond is known as Gutta Percha and this is the natural rubber obtained from bark of various trees. Natural rubber is sticky material. This disadvantage is removed by ‘VULCANISATION’ which involves addition of sulphur to rubber and heating the mixture. sulphur forms short chains of sulphur atoms that link two hydrocarbon (isoprene) units together. When tension is applied the chains can strengthen out but they cannot slip past each other because of sulphur bridges. Thus rubber can be stretched only to a certain extent and hydrocarbon chains have the tendency to regain their shape when tension is removed. Vulcanised rubber is thus stronger and less sticky than the natural rubber. b) Synthetic rubber: (Polychloroprene) or Neoprene) It is obtained by free radical polymerisation of chloroprene in it is a thermoplastic and need not to be vulcanised. It is a good general purpose rubber and superior to natural rubber as it is resistant to the reaction of aire, heat, light chemicals, alkalis and acids below 50% strength. It is used for making transmission belts, printing rolls and flexible tubing employed for conveyence of oil and petrol. c) Buna rubbers: Butadiene polymerises in the presence of sodium to give a rubber substitute viz. BuNa. It is of two types i) Buna – N or GRA: it is synthetic rubber obtained by copolymerisation of one part of acryl nitrile and two parts of butadiene. It is more rigid responds less to heat and very resistant to swelling action of petorol, oils and other organic solvents. ii) Buna -S or GRS (General purpose Styrene rubber): It is a copolymer of three moles of butadiene and one mole of styrene\ and is an elastomer. It is obtained as a result of free radical copolymerisation of its monomers. It is generally compounded with carbon black and vulcanised with sulphur. It is extremely resistant to wear and tear and finds use in manufacture of tyres and other mechanical rubber goods. d) Teflon: It is polymer of tetrafluorethylene (F2C=CF2) which on polymerisation gives Telfon. nCF2=CF2 (—CF2—CF2—)n It is thermoplastic polymer with a high softening point (600K). It is very tough and difficult to work. It is inert to most chemicals except fluorine and molten alkali metals. It withstands high temperatures. Its electrical properties make it an ideal insulating material for high frequency installation. e) Nylon -66: It is a polymer resin. It is a condensation polymer formed by reaction between adipic acid and hexamethylene diamine. Both monomer units consist of 6 carbon atoms and therefore named nylon -66. It is thermoplastic polymer when extruded above its melting point (536 K) through spinneret, it gives nylon fiber which is extremely tough and resistant to friction. It possess greater tensile strength, elasticity and lusture than any natural fiber. It is chemically inert and is fabricated into sheet, bristles and textile fibres. f) Nylon 6 or Perolon – L: A polyamide is prepared by prolonged heating of caprolactam at 530 – 540 K. The fiber is practically identical to Nylon in properties Exercise 4: Complete the reactions Exercise 5: a) What is the structure of nylon-6, made by alkaline polymerisation of caprolactom? b) Suggest a mechanism for the process. Is polymerisation of the chain reaction or step reaction type? 8. Solutions to Exercise Exercise 1: Since in glucose there are five –OH groups so five moles of HIO4 are consumed giving main product formic acid and formaldehyde as shown below : Glucose + 5HIO4 ⎯→ 5HCOOH + HCHO Exercise 4: Exercise 5: a) b) The reaction is anionic chain reaction polymerization, involving nucleophilic substitution at the acyl group of the cyclic amide. The base could be OH– itself or the anion formed by abstraction of the –NH proton from a molecule of lactam. 9. Solved Problems (Subjective) 9.1 Subjective Complete the reactions (Question 1 to 3) Problem 1: nCF2 = CF2 (–CF2 – CF2 –)n Teflon Solution: A = (NH4)2S2O8 Problem 2: Solution: B = Problem 3: Solution: Problem 3: Give the classification of polymers obtained from esters of acrylic acid (CH2 = CH.COOH) Solution: Formula of monomer Polymer Characteristics Uses Hard transparent, high optical clarity. It is capable of acquiring different colours and tints Lenses, transparent object domes and skylights plastic jewellery Tough and rubbery polymer Similar to above Hard, horney and high melting material Used in preparing cloth, carpets and blankets Problem 4: a) Show how an aldohexose can be used to synthesize 2-ketohexose. (b) Since glucose is converted to fructose by this method, what can you say about the configurations of C3, C4 and C5 in the sugars. Here aldohexose reacts with one molecule of phenylhyrazine which condenses with the aldehyde group to give phenylhydrazone. When warmed with excess of phenyl hydrazine, the secondary alcoholic group adjacent to the aldehyde group is oxidised by another molecule of phenylhydrazine, to a ketonic group. With this ketonic group, the third molecule of phenylhydrazine condenses to give osazone. The phenylhydrazinyl group is transferred from osazone to C6H5CHO giving C6H5CH = N⋅NHC6H5 and a dicarbonyl compound called an osone. The more reactive aldehyde group of the osone is reduced, not the less reactive keto group and it gives the 2-ketohexose. b) The configurations of these carbons which are unchanged in the reactions, must be identical in order to get the same osazone. Problem 5: a) Supply structures for H through K. Given: An aldohexose K. b) Explain the last step (c). What is net structural change (d) Name this overall method. (e) Discuss the possibility of epimer formation. Solution: a) H is an oxime HOCH2(CHOH)4CH = NOH; I is the completely acetylated oxime, AcOCH2(CHOAc)4CH = NOAc that loses 1 mole of HOAc to form J, AcOCH2(CHOAc)4 C≡N; K is an aldopentose, HOCH2(CHOH)3CHO. b) The acetates undergo transesterification to give methyl acetate freeing all the sugar OH’s. This is followed by reversal of HCN addition. c) There is loss of one C from the carbon chain. d) Wohl degradation e) The α-CHOH becomes the –CH = O without any configurational changes of the other chiral carbons. Thus no epimers are formed. Problem 6: Although both polymers are prepared by free radical processes, poly (vinyl chloride) is amorphous and poly (vinylidene chloride) (saran) is highly crystallilne. How do you account for the different? (vinylidene chloride is 1,1-dichloroethene). Solution: As poly (vinyl chloride) is able to show stereoisomerism and further it is formed by a free radical process, it is atactic (chlorine atoms distributed randomly), the molecules fit together poorly. Poly (vinylidene chlroide) has two identical substituents on each carbon and the chains fit together well. Problem 7: Show the fundamental uni

  1. IIT-JEE Syllabus 

Carbohydrates: Classification – mono, di and polysaccharides (Glucose, Sucrose and Starch only); hydrolysis of sucrose. Amino acids and Peptides: General structure and physical properties. Properties and uses of some important polymers (natural rubber, cellulose, nylon, teflon, PVC), Dyes and their application.

2. Carbohydrates

 

2.1 Introduction

Old Definition: The group of compounds known as carbohydrates received their general name because of early observations that they often have the formula Cx(H2O)y – that is, they appear to be hydrates  of carbon.

Limitations of the old definition: The above definition could not survive long due to the following reasons:

  1. i) A number of compounds such as rhamnose, (C6H12O5) and deoxyribose (C5H10O4) are known which are carbohydrates by their chemical behaviour but cannot be represented as hydrates of carbon.
  2. ii) There are other substances like formaldehyde (HCHO, CH2O) and acetic acid [CH3COOH, C2 (H2O)2] which do not behave like carbohydrates but can be represented by the general formula, Cx(H2O)y.

New definition: Carbohydrates are defined as polyhydroxy aldehydes or polyhydroxy ketones or substances which give these on hydrolysis and contain at least one chiral carbon atom. It may be noted here that aldehydic and ketonic groups in carbohydrates are not present as such but usually exist in combination with one of the hydroxyl group of the molecule in the form of hemiacetals and hemiketals respectively.

2.2 Classification 

The carbohydrates are divided into three major classes depending upon whether or not they undergo hydrolysis, and if they do, on the number of products formed.

  1. i) Monosaccharides: The monosaccharides are polyhydroxy aldehydes or polyhydroxy ketones which cannot be decomposed by hydrolysis to give simpler carbohydrates. Examples are glucose and fructose, both of which have molecular formula, C6H12O6.
  2. ii) Oligosaccharides: The oligosaccharides (Greek, oligo, few) are carbohydrates which yield a definite number (2-9) of monosaccharide molecules on hydrolysis. They include, 
  3. a) Disaccharides, which yield two monosaccharide molecules on hydrolysis. Examples are sucrose and maltose, both of which have molecular formula, C12H22O11.
  4. b) Trisaccharides, which yield three monosaccharide molecules on hydrolysis. Example is, raffinose, which has molecular formula, C18H32O16.
  5. c) Tetrasaccharides, etc.

iii) Polysaccharides: The polysaccahrides are carbohydrates of high molecular weight which yield many monosaccharide molecules on hydrolysis. Examples are starch and cellulose, both of which have molecular formula, (C6H10O5)n.

In general, the monosaccharides and oligosaccharides are crystalline solids, soluble in water and sweet to taste. They are collectively known as sugars. The polysaccharides, on the other hand, are amorphous, insoluble in water and tasteless. They are called non-sugars.

The carbohydrates may also be classified as either reducing or non-reducing sugars. All those carbohydrates which have the ability to reduce Fehling’s solution and Tollen’s reagent are referred to as reducing sugars, while others are non-reducing sugars. All monosaccharides and the disaccharides other than sucrose are reducing sugars.

3. Monosaccharides

The monosaccharides are the basis of carbohydrate chemistry since all carbohydrates are either monosaccharides or are converted into monosaccharides on hydrolysis. The monosaccharides are polyhydroxy aldehydes or polyhydroxy ketones. There are, therefore, two main classes of monosaccharides.

  1. The Aldoses, which contain an aldehyde group
  2. The Ketoses, which contain a ketone group (— —)

The aldoses and ketoses are further divided into sub-groups on the basis of the number of carbon atoms in their molecules, as trioses, tetroses, pentoses, hexoses, etc. To classify a monosaccharide completely, it is necessary to specify both, the type of the carbonyl group and the number of carbon atoms present in the molecule. Thus monosaccharides are generally referred to as aldotrioses, aldotetroses, aldopentoses, aldohexoses, ketohexoses, etc.

The aldoses and ketoses may be represented by the following general formulas.

Glucose and fructose are specific examples of an aldose and a ketose.

3.1 Trioses

D and L Terminology:  The simplest of all carbohydrates that fit the definition we have given for carbohydrates are the trioses, glyceraldehyde and dihydroxyacetone. Glyceraldehyde is aldotriose, and dihydroxyacetone is a ketotriose.
Glyceraldehyde contains one asymmetric carbon atom (marked by an asterisk) and can thus exist in two optically active forms, called the D-form and the L-form. Clearly, the two forms are mirror images that cannot be superimposed, that is they are enantiomers.

The two forms of glyceraldehyde are especially important because the more complex monosaccharides may be considered to be derived from them. They serve as a reference point for designating and drawing all other monosaccharides. In carbohydrate chemistry, the Fischer projection formulas are always written with the aldehyde or ketone groups at the top of the structure. By definition, if the hydroxyl group on the asymmetric carbon atom farthest from aldehyde or ketone group projects to the right, the compound is a member of the D-family. If the hydroxyl group on the farthest asymmetric carbon projects to the left, the compound is a member of the L-family. The maximum number of optical isomers of a sugar is related to the number of asymmetric carbon atoms in the molecule and may be calculated by the following simple equation. 

Maximum Number of Optical Isomers = 2n, where n = the number of asymmetric carbon atoms.

Since glyceraldehyde contains only one asymmetric carbon atom, the number of optical isomer is 21. We know that 21 is = 2, and we have seen that there are indeed two different glyceraldehydes.

3.2 Aldotetroses

If we examine the general formula of an aldotetrose, we see that they contain two asymmetric carbon atoms (marked by asterisks).

This means that 22 or 4 optical isomers are possible. They may be represented as the following two pairs:

All four isomers have been prepared synthetically. The D- and L-erythrose are mirror images, that is, they are enantiomers. They have exactly the same degree of rotation but in  opposite directions. Equal amounts of the two would constitute a racemic mixture, that is, a mixture that would allow a plane-polarised light to pass through the solution unchanged but could be separated into detrorotatory and laevorotatory isomers. The same comments  hold for D- and L-threose. However, D-erythrose and L-threose are not images, that is, they are diastereomers (optical isomers that are not mirror images are called diastereomers), and the degree of rotation of each would probably differ.

3.3 Aldopentoses

If we examine the general formula of an aldopentose, we see that they contain three asymmetric carbon atoms. 

This means that 23 or 8 optical isomers are possible.  These are:
– D(–) lyxose, L(+)-lyxose, D(–) xylose,  L(–)xylose, D(–) arabinose, L(+)-arabinose,  D(–)-ribose, L(+)-ribose

3.4 Aldohexoses

If we examine the general formula of aldohexose, we see that it contains four asymmetric carbon atoms. This means that 24 or 16 optical isomers are possible. D and L forms of altrose, allose  glucose, mannose, galactose, talose, arabinose and idose

Only three of the sixteen possible aldohexoses are found in nature (all sixteen isomers have been prepared synthetically). They are D-glucose, D- mannose, and D-galactose. No one of these three optical iosmers is a mirror image of any of the others, so all three are diastereomers of each other.

3.5 Epimers

A pair of diastereomers that differ only in the configuration about of a single carbon atom are said to be epimers. e.g D(+)- glucose is epimeric with D(+) -mannose and D(+) -galactose as shown below:

3.6 Cyclic structure of monosaccharides 

We know that aldoses (and ketoses) react with alcohols to give first hemiacetals (and hemiketals) and then acetals (and ketals), i.e.,

Since monosaccharides contain a number of hydroxyl groups and an aldehyde or a keto group, therefore, any one of the –OH groups (usually C4 or C5 in aldohexoses and C5 or C6 in ketohexoses) may combine with the aldehyde or the keto group to form intramolecular hemiacetal or hemiketal. 

As a result, the open chain formulae do not represent the actual structures of the monosaccharides. Their actual structures are cyclic involving five or six membered rings containing an oxygen atom. The five membered ring containing one oxygen atom because of its similarity with furan is called the furanose form and the six membered ring containing one oxygen atom because of its resemblance with pyran is called the pyranose form. In nut shell, all the monosaccharides (pentoses and hexoses) in the free state always exist in the pyranose form. However, in the combined state some monosaccharides such as ribose, 2-deoxyribose, fructose etc., usually exist in the furanose form.

3.7 Cyclic structure of Glucose – Anomers 

We have discussed above that monosaccharides have cyclic hemiacetal or hemiketal structures. To illustrate, let us first consider the example of D-glucose. During hemiacetal formation C5 – OH of glucose combines with the C1 – aldehydic group. As a result, C1 becomes chiral or asymmetric and thus has two possible arrangements of H and OH groups around it. In other words, D-glucose exists in two stereoisomeric forms, i.e., α-D-glucose and β-D-glucose as shown below:

In α-D-glucose, the OH group at C1 is towards right while in β-D-glucose, the OH group at C1 is towards left. Such a pair of stereoisomers which differ in configuration only around C1 are called anomers and the C1 carbon is called Anomeric carbon (or glycosidic carbon.  The cyclic structures of monosaccharides can be better represented by Haworth Projection formulae. To get such a formula for any monosaccharide (say α-and β-D-glucose), draw a hexagon with its oxygen atom at the upper right hand corner. Place all the groups (on C1, C2, C3 and C4) which are present on left hand side in structures I and II, above the plane of the ring and all those groups on the right hand side below the plane of the ring. 

The terminal – CH2OH group is always placed above the plane of the hexagon ring (in D-series). Following the above procedure, Haworth Projection Formulae for α-D-glucose (I) and β-D-glucose (II) are obtained as shown below:

3.8 Cyclic structure of Fructose 

Like glucose, fructose also has a cyclic structure. Since fructose contains a keto group, it forms an intramolecular hemiketal. In the hemiketal formation, C5– OH of the fructose combines with C2-keto group. As a result, C2 becomes chiral and thus has two possible arrangements of CH2OH and OH group around it. Thus, D-fructose exists in two stereoisomeric forms, i.e., α-D-fructopyranose and β-D fructopyranose. However in the combined state (such as sucrose), fructose exists in furanose form  as shown below:

3.9 Mutarotation 

The two stereoisomeric forms of glucose, i.e., α-D-glucose and β-D-glucose exist in separate crystalline forms and thus have different melting points and specific roations. For example α-D-glucose has a m.p. of 419 K with a specific rotation of +112° while  β-D-glucose has a m.p. of 424 K and has a specific rotation of +19°. However, when either of these two forms is dissolved in water and allowed to stand, it gets converted into an equilibrium mixture of α-and β-forms through a small amount of the open chain form.

As a result of this equilibrium, the specific rotation of a freshly prepared solution of α-D-glucose gradually decreases from of +112° to +52.7° and that of β-D-glucose gradually increases from +19° to +52.7°.

This change in specific rotation of an optically active compound in solution with time, to an equilibrium value, is called mutarotation. During mutarotation, the ring opens and then recloses either in the inverted position or in the original position giving a mixture of α-and-β-forms. All reducing carbohydrates, i.e., monosaccharides and disacchardies (maltose, lactose etc.) undergo mutarotation in aqueous solution.

3.10 Reactions of Glucose 

  1. a) With HI/P: It undergoes reduction to form n-hexane while with sodium amalgam it forms sorbitol. 

                                n-hexane

s-orbitol

  1. b) With H2O: It forms neutral solution
  2. c) With Hydroxylamine (NH2OH)
  3. d) With HCN: It form addition product cyanohydrin 
  4. e) Oxidation: Glucose on oxidation with Br2 gives gluconic acid which on further oxidation with HNO3 gives glucaric acid 
  5. f) With Tollen reagent and Fehling solution. Glucose forms silver mirror and red ppt. of Cu2O respectively.
  6. g) With acetic anhydride. In presence of pyridine glucose forms pentaacetate.
  7. h) With phenylhydrazine: it forms glucosazone
  8. i) With conc. HCl acid: Glucose gives laevulinic acid
  9. j) Glycoside formation: When a small amount of gaseous HCl is passed into a solution of
    D (+) glucose in methanol , a reaction takes place that results in the formation of amomeric methyl acetals.

Carbolydrate acetals, genrally are called glycosides and an acetal of glucose is called glucoside.

Other reactions

  1. a) Kiliani – Fischer Synthesis: – This is a method of lengthening the carbon chain of an aldose. To illustrate, we take synthesis of D-threose and D-erythrose (Aldotetroses) from D-glyceraldehyde (an aldotriose).

Addition to HCN to glyceraldehyde produces two epimeric cyanohydrins because reaction creates a new stereoicenter. The cyanohydrins can be separated easily (since they are diastereomers) and each can be converted to an aldose through hydrolysis, acidification and lactonisation, and reduction with Na—Hg. One cyanohydrin ultimately yields D-erythrose and D-threose. 

Here we can see that both sugars are D-sugars because starting  compound is D-glyceraldehyde and its stereocentrer is unaffected by its synthesis.

  1. b) Ruff Degradation: It is opposite to Kiliani Fischer synthesis that can be used to shorten the chain by a similar unit. The ruff degradation involves (i) Oxidation of the aldose to an aldonic acid using Bromine water. (ii)Oxidative decarboxylation of the aldonic acid to the next lower aldose using H2O2 and Fe2(SO4)3. D-ribose for example can be reduced to D-erythrose.

Exercise 1: Treatment of (+)– glucose with HIO4 gives results that confirm its aldohexose structure. What product should be formed, and how much HIO4 should be consumed.

4. Disaccharides

Carbohydrates which upon hydrolysis give two molecules of the same or different monosaccharides are called disaccharides. Their general formula is C12H22O11. The three most important disaccharides are sucrose, maltose, and lactose. Each one of these on hydrolysis with either an acid or an enzyme gives two molecules of the same  or different monosaccharides as shown below:

Disaccharides may also be considered to be formed by a condensation reaction between two molecules of the same or different monosaccharides with the eliminatioin of a molecule of water. This reaction involves the formation of an acetal from a hemiacetal and an alcohol – in which one of the monosaccharides acts as the hemiacetal while the other acts as the alcohol.

4.1 Sucrose 

It is formed by condensation of one molecule of glucose and one molecule of fructose. Unlike maltose and lactose, it is non-reducing sugar since both glucose (C1 – α) and fructose (C2 – β) are connected to each other through their reducing centres. Its structure is shown below:

Hydrolysis: (Invert Sugar or Invertose). Hydrolysis of sucrose with hot dilute acid yields
D-glucose and D-fructose.Sucrose is dextrorotatory, its specific rotation being +66.5%, D-glucose is also dextrorotatory, [α]D = +53°, but D-fructose has a large negative rotation, [α]D = -92°. Since D-fructose has a greater specific rotation than D-glucose, the resulting  mixture  is  laevorotatory.   Because   of this the hydrolysis of sucrose is known as the inversion of sucrose, and the equimolecular mixture of glucose and fructose is known is invert sugar or invertose.

5. Polysaccharides

Polysaccharides are formed when a large number (hundreds to even thousands) of monosaccharide molecules join together with the elimination of water molecule. Thus, polysaccharides may be regarded as condensation polymers in which the monosaccharides are joined together by glycosidic linkages. Some important polysaccharides are:

  1. Cellulose 2. Starch 3. Glycogen
  2. Gums and 5. Pectins

5.1 Starch

It is a polymer of glucose.  Its molecular formula is (C6H10O5)n where the value of
n (200 – 1000) varies from source to source. It is the chief food reserve material or storage polysaccharide of plants and is found mainly in seeds, roots, tubers, etc. Wheat, rice, potatoes, corn, bananas etc., are rich sources of starch.

Starch is not a single compound but is a mixture of two components – a water soluble component called amylose (20%) and a water insoluble component called amylopectin (80%). Both amylose and amylopectin are polymers of α-D-glucose.

Amylose is a linear polymer of α-D-glucose. It contains about 200 glucose units which are linked to one another through α-linkage involving C1 of one glucose unit with C4 of the other as shown below:

Amylopectin, on the other hand, is a highly branched polymer. It consists of a large number (several branches) of short chains each containing 20-25 glucose units which are joined together through α-linkages involving C1 of one glucose unit with C4 of the other. The C1 of terminal glucose unit in each chain is further linked to C6 of the other glucose unit in the next chain through C1 – C6 α-linkage. This gives amylopectin a highly branched structure as shown below.-

Hydrolysis: Hydrolysis of starch with hot dilute acids or by enzymes gives dextrins of varying complexity, maltose and finally D-glucose. Starch does not reduce Tollen’s reagent and Fehling’s solution.

Uses:  It is used as a food. It is encountered daily in the form of potatoes, bread, cakes, rice etc. It is used in coating and sizing paper to improve the writing qualities. Starch is used to treat textile fibres before they are woven into cloth so that they can be woven without breaking. It is used in manufacture of dextrins, glucose and ethyl alcohol. Starch is also used in  manufacture of starch nitrate, which is used as an explosive.

6. Amino Acids

6.1 Introduction and Nomenclature

Amino acids are molecules, which contain two functional groups, one is carboxylic group and another is amino group. Amino acids are derivatives of carboxylic acids in which one hydrogen atom of carbon chain is substituted by Amino group.

Amino group may be at α, β, γ position with respect to carboxylic group

H2N ⎯ CH2 ⎯ COOH Amino acetic acid, or Glycine

CH3 ⎯ CH (NH2) ⎯ COOH α – Amino propionic acid or Alanine

H2N ⎯ CH2 ⎯ CH2 ⎯COOH β – Amino propionic acid

H2N ⎯ CH2 ⎯ (CH2)2 ⎯ COOH γ – Amino butyric acid

Some amino acids contain a second carboxyl group or a potential carboxyl group in the form of carboxamide: these are called acidic amino acid some contain a second basic group which may be an amino group these are called basic amino acids.

6.2 Physical Properties  and  Structure

Although the amino acids are commonly shown as containing an amino group and a carboxyl group, certain properties are not consistent with this structure.

  1. In contrast to amines and carboxylic acids, the amino acids are nonvolatile solids, which melt at fairly high temperatures.
  2. They are insoluble in organic solvents [i.e. non polar solvents] and are highly soluble in water.
  3. Their aqueous solution is neutral.
  4. Their aqueous solutions behave like solutions of substances of high dipole moment.
  5. Acidity and basicity constants are ridiculously low for – COOH and – NH2 groups

All these properties are quite consistent with a dipolar ion structure for the amino
acids (I)

+H3N ⎯ CHR ⎯ COO––

(I)

Amino acid : dipolar ions

In the physical properties melting points, solubility, and high dipole moment are just what would be expected of such a salt.

The acid base properties also become understandable when it is realized that the measured Ka actually refers to the acidity of an ammonium ion, RNH3+

+H3NCHRCOO + H2O H3O+ + H2NCHRCOO

and Kb actually refers to the basicity of a carboxylate ion, RCOO

+H3N ⎯ CH ⎯ RCOO + H2O +H3N ⎯ CHR ⎯COOH + OH

When the solution of an amino acid is made alkaline, the dipolar ion(I) is converted to the anion (II); the stronger base, hydroxide ion, removes a proton from the ammonium ion and displaces the weaker base, the amine

+H3N ⎯ CHRCOO + OH H2N CHRCOO + H2O

(I) (II)

      Stronger Stronger Weaker Weaker 

        acid base base acid

When the solution of an amino acid is made acidic; the dipolar ion I is converted into the cation (III); the stronger acid , gives up a proton to  the carboxylate ion, and displaces the weaker carboxylic acid.

+H3N  CHRCOO + H3O+ +H3N CHRCOOH + H2O

(I) (III)

Stronger Stronger Weaker Weaker 

base acid acid base

In summary, the acidic group of a simple amino acid like glycine is not –COOH, and basic group is –COO not –NH2.

Exercise 2: The amino acids in water acts as ampholyte. Explain?

6.3 Iso Electric Point

What happens when a solution of an amino acid is placed in an electric field depends upon the acidity or basicity of solution. In quite alkaline solution.

Anions (II) exceed cations (III), and there is a net migration of amino acid toward the anode. In quite acidic solution cations (III) are in excess, and there is a net migration of amino acid towards the cathode. If (II) and (III) are exactly balanced, there is no net migration; under such conditions any one molecule exists as a positive ion and as a negative ion for exactly the same amount of time and any small movement in the direction of one electrode is subsequently cancelled by an equal movement back towards the other electrode. The hydrogen ion concentration of the solution in which a particular amino acid does not migrate under the influence of an electric field is called the isoelectric point of that amino acid.

An amino acid shows its lowest solubility in a solution at the isoelectric point, since here there is the highest concentration of the dipolar ion. As the solution is made more alkaline or more acidic, the concentration of one of the more soluble ions, II or III increases.

If an amino acid has amino group and one carboxyl group, it has two pK values. The isoelectric point (PI) of this amino acid has the average value of the both pK values.

We take example of glycine.

H3+N ⎯ CH2 ⎯ COOH H3N+ ⎯ CH2 ⎯ COO + H+ …(1)

Conjugated acid (CA) Dipolar Ion (DI)

At equilibrium

H3N+ ⎯ CH2 ⎯ COO H2N ⎯ CH2 ⎯ COO + H+ …(2)

DI Conjugated Base (CB)

At equilibrium

[CA] =

[CB] =

At isoelectric point [CA] = [CB]

Where = conc. of [H+] at isoelectric point.

or, = K1 K2

or, 2log [Hi+] = log K1 + log K2

or –2 log (Hi+] = – log k1 – logK2

or 2pHi = pK1 + pK2

or pHi =

7. Peptides

As the amino acid molecules contain both basic as well as acidic group it might be expected that an intermolecular reaction may take place between the carboxyl group of one  amino acid and the amino group of another amino acid, with the elimination of a molecule of water.

R R′ R R′

H2N ⎯ CH ⎯ COOH + H2N ⎯ CH ⎯ COOH ⎯→ H2 N ⎯ CHCO ⎯ NH ⎯ CHCOOH

Since the resulting molecule still has a free amino and a carboxyl group, it may react with other amino acids at either of the ends to give a higher molecular weight linear or condensation product. Every two amino acids are linked by means of a –CO-NH group, which is commonly referred as peptide bond. So now we can define a peptides as the amides formed by interaction between amino groups and carboxyl groups of amino acids.

Depending upon the number of amino acid residues per molecule, they are known as dipeptides, tripeptides and so on and finally polypeptides.

7.1 Naming of Polypeptide

A convenient way of representing peptide structures by use of standard abbreviations. According to convention the N-terminal amino acid residue [having the free amino group] is written as the left and the C terminal amino acid residue (having the free carboxyl group) at the right end.

A peptide is named by indicating its sequence of amino acids beginning with the N-terminal residue. 

H2N ⎯ CH ⎯ CONH ⎯ CH ⎯ CONH ⎯ CH ⎯ CONH ⎯ CH ⎯ CONHCH2 COOH

  |       |           |  |

CH3 CH2-OH CH2-C6H5 CH2-CONH2

Alanine Serine Phenylalamine         Asparagine glycine

This pentapeptide is called alanyl-sery-phenylalanyl-asparaginyl-glycine or using the common abbreviations as H-Ala-Ser-phe-Asn-gly-OH. All naturally occurring important peptides, however, posses a shorter individual name.

7.2 Structure of Poly peptides

To identify the structure of a peptide, the peptide in question is first hydrolysed to its constituent amino acids, which are separated and identified. The amount of each amino acid is measured, and hence the number of each kind of amino acid can be calculated.

The next problem is to determine the sequence of the various amino acids constituting the peptide. This is very difficult task, because there is a large number of possibilities in which the constituent amino acids may be linked in the peptide, e.g. even is a dipeptide, having glycine and alanine, the two amino-acids may be present in either of the two ways.

The two structures differ in the respect that in the first the N-terminal amino acid is glycine (i.e. the amino group of glycine is free) and C-terminal amino acid is alanine, while in the latter the N-terminal amino acid is alanine and C-terminal acid is glycine. Various chemical methods have been developed to remove either of the two terminal amino acid residues of a polypeptide in a stepwise manner and hence the arrangement of the various amino acids in a polypeptide can be established.

7.3 Sanger’s Method

Sanger reagent, 1-fluoro-2, 4-dinitrobenzene (FDNB) was first used to determine that which amino acid constituted the amino end of the polypeptide. The method consists in treating the polypeptide with the reagent in the presence of sodium-hydrogen-carbonate solution at room temperature to form a 2, 4-dinitrophenyl (DNP) derivative of the polypeptide. The product is hydrolysed be means of acid (which causes the cleavage of the peptide bond connecting the N-terminal amino acid to the rest of the polypeptide molecule) to form dinitrophenyl (DNP) derivative of the N-terminal amino acid and the rest of the polypeptide molecule or amino acid residues.

8. Dyes

 

8.1 Definition

The chemical substances which are used to impart colour to fabrics, foods and other objects for their beautification and distinction are called dyes.

These chemical substances used as dyes are capable of getting fixed to the fabrics permanently and are resistant to the action of water, soap, light, acid and alkalies.

The colour of dyes is attributed to their ability to absorb some wavelengths of visible region of electromagnetic spectrum (380 nm to 760 nm). The part of the colour which reflected back gives the colour of the dye i.e. complementary to the colour absorbed. The colour of visible light absorbed and the complementary colour reflected are listed in table.

Wave length (nm) Colour absorbed Complementary colour
400 – 435 Violet Yellow, Green
435 – 480 Blue Yellow
480 – 490 Greenish Blue Orange
490 – 500 Bluish Green Red
500 – 560 Green Purple
560 – 580 Yellowish Green Violet
580 – 595 Yellow Blue
595 – 605 Orange Greenish Blue
605 – 750 Red Blue, Green

In the earlier days fabrics were coloured by the dyes mainly from Alizarin (red dye) and indigo (blue dye). But now a days, many natural dyes have been synthesized in the laboratory. This helped us to produce dyes of desired shades which otherwise are not available in natural dyes.

8.2 Classification

These dyes have been classified into two categories

  1. a) Classification based on constitution: Depending upon the characteristic structural units the dyes are classified as follows.
Sl. No. Type of Dye Structural Unit Examples
1. Nitro dyes Martius yellow,
Naphthol yellow
2. Azo dyes – N = N –
(azo group)
Orange-I, Orange-II, Congo red
3. Triphenyl methane dyes (C6H5)3C – Malachite green, Rosaniline
4. Phthalein dyes Phenolphthalein, Mercurochrome
5. Anthraquinone dyes Alizarin
6. Indigoid dyes Indigo, Tyrian purple

Structures

Diphenyl methane dye

Auromine – 0

8.3 Classification Based on Application

A particular dye may be suitable for one kind of fibre and may be unsuitable for the other. For example, a dye suitable for wool and silk may not be applied or used for dyeing cotton or rayon. Thus based on the class, shade and other properties like resistance to acids, alkalies, and fastness to light a classification of dyes is done, as given below:

  1. a) Acid dyes b) Basic dyes
  2. c) Direct dyes d) Disperse dyes
  3. e) Fibre reactive dyes f) Vat dyes
  4. g) Insoluble azodyes h) Mordant dyes
  5. a) Acid dyes: These dyes are characterised by the presence of acid group like sulphonic acid (– SO3H), carboxylic acid (– COOH) and phenolic group. The presence of such groups make the dyes more soluble and also serve as the reactive points for fixing the dye to the fibre.

Application: These dyes are applied to wool, silk and nylon. These have no affinity for cotton.

Examples: Orange-I and Orange-II can be obtained by the action of sulphonic compounds with naphthols or by coupling sulphonic compounds with naphthols.

  1. b) Basic Dyes: These dyes contain (–NH2) group or (–NR2) group as chromophore (colour bearing group) or auxochrome (colour enhancing group). In acidic solutions these form water soluble cations. These dyes use the anionic side on the fabric to get themselves attached.

Application: This type of dyes is used to dye nylon, polyester, wool, cotton, leather, paper, etc.

Example

1. Aniline yellow
2. Butter yellow
3. Crysodine G
  1. c) Direct Dyes: These dyes also belong to the class of azo dyes and are used to dye the fabrics directly by placing it in aqueous solution of the dye. The direct dyes attack the fibre by means of hydrogen bonding.

Application: These are very effective for dying cotton, wool and rayon

Example:

  1. Martius yellow
  2. Congo Red
  3. c) Disperse Dyes: These dyes, as the name signifies, are usually applied in the form of a dispersion of finely divided dye in a soap solution in the presence of phenol, cresol or benzoic acid.

Application: These are mainly used to dye rayon, dacron nylon, synthetic fibres, polysters and poly acrylonitrile.

Examples:

1. Celliton fast pink B
2. Cellition fast blue B
  1. d) Fibre Reactive Dyes: These dyes are used to dye fibres like cotton, wool or silk. These are linked to the fibre by virtue of the hydroxy or amino group present on the fibre. These dyes induce fast colour on fibres which is retained for a longer time.
  2. e) Insoluble azo dyes: The dyes belonging to this class are directly synthesised on the fibre. The fabric to be coloured is soaked in an alkaline solution of phenol or naphthol and is than treated with a solution of diazotised amine to produced the azo dye on the surface of the fabric.

Application: These dyes can be used to dye cotton silk, polyester, nylon, etc.

Example:

  1. f) Vat Dyes: Before being introduced on to fabric these dyes are first reduced to colourless leuco compounds in wooden vats by alkaline reducing agent. The fibre is then soaked in the solution of the dye. After proper absorption of the dye, the fibre is then exposed to air or to an oxidising agent. By doing so the dye gets oxidised to yield insoluble coloured dye on the fabric.

Example: Indigo dye

  1. g) Mordant Dyes: A dye which imparts different colours to the fabric in the presence of different metal ions (called mordants) is referred to as mordant dye. Nowadays it is rarely used

Application: These dyes are used for dyeing of wool. The method involves the precipitation of certain substances on the fabrics which then combine with the dye with the dye to form an insoluble coloured complex called lake. Depending on the kind of mordant used different colours. For example, Alizarin, a mordant dye, gives red colour with aluminium and tin salts, where as brownish red colour chromium mordant and black violet  with iron mordant.

9. Polymers

 

9.1 Introduction

Sit quietly and think about your activities today from the morning. You wake up in the morning, You want to brush your teeth. You fetch your toothpaste. The tube is made up of a polymer. Your brush is made up of a polymer. When you want to rinse your mouth, you open your plastic(polymer) tap. The pipe lines used to bring water to your tap is made of PVC(polymer). Skip it. You start preparing your break fast. You take a non-stick tawa. Non-stick? What does that mean? What is it made of? It is poly tetrafluoro ethylene abbreviated as teflon, a polymer. See, how polymers play an important role in our daily life from dawn to dusk. The molded chair in which you are sitting is a polymer. The pen with which I’m writing this is a polymer. Want to know more about polymers? Read further.

Polymers can be called as macromolecules. Macromolecules can be considered as an association of small molecules to give a big molecule. Macromolecules can be man-made, too. The first syntheses were aimed at making substitutes for the natural macromolecules, rubber and silk; but a vast technology has grown up that now produces hundreds of substances that have no natural counterparts. Synthetic macromolecular compounds include: elastomers, which have the particular kind of elasticity characteristic of rubber; fibers, long, thin and threadlike, with the great strength along the fiber that characterizes cotton, wool, and silk; and plastics, which can be extruded as sheets or pipes, painted on surfaces, or molded to form countless objects. We wear these manmade materials, eat and drink from them, sleep between them, sit and stand on them; turn knobs, pull switches, and grasp handles made of them; with their help we hear sounds and see sights remote from us in time and space; we live in houses and move about in vehicles that are increasingly made of them.

9.2 Polymers and polymerization

Macromolecules, both natural and man-made, owe their great size to the fact that they are polymers (Greek: many parts); that is, each one is made up of a great many simpler units — identical to each other or at least chemically similar — joined together in a regular way. They are formed by a process we touched on earlier: polymerization, the joining together of many small molecules to form very large molecules. The simple compounds from which polymers are made are called monomers.

Polymers are formed in two general ways.

  1. In chain-reaction polymerization, there is a series of reactions each of which consumes a reactive particle and produces another, similar particle; each individual reaction thus depends upon the previous one. The reactive particles can be free radicals, cations, or anions. A typical example is the polymerization of ethylene. Here the chain-carrying particles are free radicals, each of which adds to a monomer molecule to form a new, bigger free radical.

Rad. + CH2 = CH2 ⎯→ RadCH2CH2RadCH2CH2CH2CH2⋅ ⎯→ etc.

  1. b) In step reaction polymerization, there is a series of reactions each of which is essentially independent of the preceding one; a polymer is formed simply because the monomer happens to undergo reaction at more than one functional group. A diol, for example, reacts with a dicarboxylic acid to form an ester; but each moiety of the simple ester still contains a group that can react to generate another ester linkage and hence a larger molecule, which itself can react further, and so on.

a) Free-radical vinyl polymerization: In we discussed briefly the polymerization of ethylene and substituted ethylenes under conditions where free radicals are generated — typically in the presence of small amounts of an initiator, such as a peroxide. Reaction occurs.

At the doubly bonded carbons — the vinyl groups — and is called vinyl polymerization. A wide variety of unsaturated monomers may be used, to yield polymers with different pendant groups (G) attached to the polymer backbone. For example.

b) Copolymerization: So far, we have discussed only polymerisation of a single monomeric compound to form a homopolymer, a polymer made up — except, of course, at the two ends of the long molecule — of identical units.

Now, if a mixture of two (or more) monomers is allowed to undergo polymerization, there is obtained a copolymer a polymer that contains two (or more) kinds of monomeric units in the same molecule. For example:

Through copolymerization there can be made materials with different properties than those of either homopolymer, and thus another dimension is added to the technology. Consider, for example, styrene. Polymerized alone, it gives a good electric insulator that is molded into parts for radios, television sets, and automobiles. Copolymerization with butadiene (30%) adds toughness; with acrylonitrile (20-30%) increases resistance to impact and to hydrocarbon; with maleic anhyride yeilds a material that, on hydrolysis, is water-soluble, and is used as a dispersant and sizing agent. The copolymer in which butadiene predominates (75%) butadiene, 25% styrene) is an elastomer, and since World War II has been the principal rubber substitute manufactured in the United States.

Copolymers can be made not just from two different monomers but from three, four, or even more. They can be made not only by free-radical chain reactions, but by any of the polymerization methods we shall take up; ionic, coordination, or step-reaction. The monomer units may be distributed in various ways, depending on the technique used. As we have seen, they may alternate along a chain, either randomly or with varying degrees of regularity. In block copolymers sections made up of one monomer alternate with sections of another:

— M1M1M1M1M1 – M2M2M2M2 Block copolymer

If graft copolymers, a branch of one kind is grafted to a chain of another kind:

Fibres are long thin, threadlike bits of material that are characterized by great tensile (pulling) strength in the direction of the fiber.  The natural fibres – cotton, wool, silk – are typical. Fibres are twisted into threads, which can then be woven into cloth, or embedded in plastic material to impart strength. The tensile strength can be enormous, some synthetic fibres rivaling – on a weight basis – steel.

The gross characteristics of fibres are reflected on the molecular level – the molecules, too, are long, thin, and threadlike. Furthermore, and most essential, they lie stretched out alongside each other, lined up in the direction of the fiber. The strength of the fiber resides, ultimately, in the strength of the chemical bonds of the polymer chains. The lining-up is brought about by drawing – stretching — the return to random looping and coiling is overcome by strong intermolecular attractions. In a fiber, enthalpy wins out over entropy. This high degree of molecular orientation is usually — although not always — accompanied by appreciable crystallinity.

An elastomer possesses the high degree of elasticity that is characteristic of rubber: it can be greatly deformed — stretched to eight times its original length, for example — and yet return to its original shape. Here, as in fibres, the molecules are long and thin; as in fibres, they become lined up when the material is stretched. The big difference is this: when the stretching force is removed, the molecular chains of an elastomer do not remain extended and aligned  but return to their original random conformations favored by entropy. They do not remain aligned because the intermolecular forces necessary to hold them that way are weaker than in a fiber. In general, elastomers do not contain highly polar groups or sites for hydrogen bonding; the extended chains do not fit together well enough for Vander Waals forces to do the job. In an elastomer entropy beats enthalpy.

One further requirement the long chains of an elastomer must be connected to each other by occasional cross – links: enough of them to prevent slipping of molecules past one another; not so many as to deprive the chains of the flexibility that is need for ready extension and return to randomness.

Natural rubber illustrates these structural requirements of an elastomer; long flexible chains; weak intermoecular forces and occasional cross – linking. Rubber is cis 1,4-polyisoprene . With no highly polar substituents, intermolecular attraction is largely limited to van der Waals forces. But these are weak because of the all – cis configuration about the double bond. Figure below compares the extended chains of rubber with those of its trans stereoisomer. As we can see, the trans configuration permits highly regular zig – zags that fit together well; the cis configuration does not. The all-trans stereoisomer occurs naturally as gutta percha; it is highly crystalline and non-elastic.

Chief among the synthetic elastomers is SBR, a copolymer of butadiene (75%) and styrene (25%) produced under free-radical conditions; it competes with natural rubber in the main use of elastomers, the making of automobile tires. All-cis polybutadiene and polyisoprene can be made by Ziegler – Natta polymerization.

An elastomer that is entirely or mostly polydiene is, of course, highly unsaturated. All that is required of an elastomer, however, is enough unsaturation to permit cross-linking. In making butyl rubber for example, only 5% of isoprene is copolymerized with isobutylene.

Exercise 3: What is the difference between addition and condensation polymersiation give an examples.

Some Important Polymers:

  1. a) Natural Rubber: Natural rubber is an addition polymer of isoprene (2-methyl-1,3-butadiene)

Rubber has an average chain length of 5000 monomer units of isoprene.

The rubber in which the arrangement of carbon chain is trans with respect to the double bond is known as Gutta Percha and this is the natural rubber obtained from bark of various trees. Natural rubber is sticky material. This disadvantage is removed by ‘VULCANISATION’ which involves addition of sulphur to rubber and heating the mixture. sulphur forms short chains of sulphur atoms that link two hydrocarbon (isoprene) units together.

When tension is applied the chains can strengthen out but they cannot slip past each other because of sulphur bridges. Thus rubber can be stretched only to a certain extent and hydrocarbon chains have the tendency to regain their shape when tension is removed. Vulcanised rubber is thus stronger and less sticky than the natural rubber.

  1. b) Synthetic rubber: (Polychloroprene) or Neoprene) It is obtained by free radical polymerisation of chloroprene in 

it is a thermoplastic and need not to be vulcanised. It is a good general purpose rubber and superior to natural rubber as it is resistant to the reaction of aire, heat, light chemicals, alkalis and acids below 50% strength. It is used for making transmission belts, printing rolls and flexible tubing employed for conveyence of oil and petrol.

  1. c) Buna rubbers: Butadiene polymerises in the presence of sodium to give a rubber substitute viz. BuNa. It is of two types 
  2. i) Buna – N or GRA: it is synthetic rubber obtained by copolymerisation of one part of acryl nitrile and two parts of butadiene. 

It is more rigid responds less to heat and very resistant to swelling action of petorol, oils and other organic solvents.

  1. ii) Buna -S or GRS (General purpose Styrene rubber): It is a copolymer of three moles of butadiene and one mole of styrene\ and is an elastomer. It is obtained as a result of free radical copolymerisation of its monomers.

It is generally compounded with carbon black and vulcanised with sulphur. It is extremely resistant to wear and tear and finds use in manufacture of tyres and other mechanical rubber goods.

  1. d) Teflon: It is polymer of tetrafluorethylene (F2C=CF2)  which on polymerisation gives Telfon.  

nCF2=CF2 (—CF2—CF2—)n

It is thermoplastic polymer with a high softening point (600K). It is very tough and difficult to work. It is inert to most chemicals except fluorine and molten alkali metals. It withstands high temperatures. Its electrical properties make it an ideal insulating material for high frequency installation.

  1. e) Nylon -66: It is a polymer resin. It is a condensation polymer formed by reaction between adipic acid and hexamethylene diamine. Both monomer units consist of 6 carbon atoms and therefore named nylon -66.

It is thermoplastic polymer when extruded above its melting point (536 K) through spinneret, it gives nylon fiber which is extremely tough and resistant to friction. It possess greater tensile strength, elasticity and lusture than any natural fiber. It is chemically inert and is fabricated into sheet, bristles and textile fibres.

  1. f) Nylon 6 or Perolon – L: A polyamide is prepared by prolonged heating of caprolactam at 530 – 540 K.

The fiber is practically identical to Nylon in properties

Exercise 4: Complete the reactions

Exercise 5: a) What is the structure of nylon-6, made by alkaline polymerisation of caprolactom?

  1. b) Suggest a mechanism for the process. Is polymerisation of the chain reaction or step reaction type?

 

  1. Solutions to Exercise

Exercise 1: Since in glucose there are five –OH groups so five moles of HIO4 are consumed giving main product formic acid and formaldehyde as shown below :

Glucose + 5HIO4 ⎯→ 5HCOOH + HCHO

Exercise 4:

Exercise 5: a)

b)

The reaction is anionic chain reaction polymerization, involving nucleophilic substitution at the acyl group of the cyclic amide. The base could be OH itself or the anion formed by abstraction of the –NH proton from a molecule of lactam.

 

  1. Solved Problems (Subjective)

 

9.1 Subjective

Complete the reactions (Question 1 to 3)

Problem 1: nCF2 = CF2  (–CF2 – CF2 –)n Teflon

Solution: A = (NH4)2S2O8

Problem 2:
Solution: B =
Problem 3:
Solution:

Problem 3: Give the classification of polymers obtained from esters of acrylic acid (CH2 = CH.COOH)

Solution: Formula of monomer Polymer Characteristics Uses
Hard transparent, high optical clarity. It is capable of acquiring different colours and tints Lenses, transparent object domes and skylights plastic jewellery
Tough and rubbery polymer Similar to above
Hard, horney and high melting material Used in preparing cloth, carpets and blankets

Problem 4: a) Show how an aldohexose can be used to synthesize 2-ketohexose. (b) Since glucose is converted to fructose by this method, what can you say about the configurations of C3, C4 and C5 in the sugars.

Here aldohexose reacts with one molecule of phenylhyrazine which condenses with the aldehyde group to give phenylhydrazone. When warmed with excess of phenyl hydrazine, the secondary alcoholic group adjacent to the aldehyde group is oxidised by another molecule of phenylhydrazine, to a ketonic group. With this ketonic group, the third molecule of phenylhydrazine condenses to give osazone. The phenylhydrazinyl group is transferred from osazone to C6H5CHO giving C6H5CH = N⋅NHC6H5 and a dicarbonyl compound called an osone. The more reactive aldehyde group of the osone is reduced, not the less reactive keto group and it gives the 2-ketohexose.

  1. b) The configurations of these carbons which are unchanged in the reactions, must be identical in order to get the same osazone.

Problem 5: a) Supply structures for H through K. Given:

An aldohexose K.

  1. b) Explain the last step (c). What is net structural change (d) Name this overall method. (e) Discuss the possibility of epimer formation.

Solution: a) H is an oxime HOCH2(CHOH)4CH = NOH; I is the completely acetylated oxime, AcOCH2(CHOAc)4CH = NOAc that loses 1 mole of HOAc to form J, AcOCH2(CHOAc)4 C≡N; K is an aldopentose, HOCH2(CHOH)3CHO.

  1. b) The acetates undergo transesterification to give methyl acetate freeing all the sugar OH’s. This is followed by reversal of HCN addition.
  2. c) There is loss of one C from the carbon chain.
  3. d) Wohl degradation
  4. e) The α-CHOH becomes the –CH = O without any configurational changes of the other chiral carbons. Thus no epimers are formed.

Problem 6: Although both polymers are prepared by free radical processes, poly (vinyl chloride) is amorphous and poly (vinylidene chloride) (saran) is highly crystallilne. How do you account for the different? (vinylidene chloride is 1,1-dichloroethene).

Solution:

As poly (vinyl chloride) is able to show stereoisomerism and further it is formed by a free radical process, it is atactic (chlorine atoms distributed randomly), the molecules fit together poorly.

Poly (vinylidene chlroide) has two identical substituents on each carbon and the chains fit together well.

Problem 7: Show the fundamental unit of structure common to all polypeptides and proteins and show how cross linking occurs between two chains by H – bonding.

Solution:

Problem 8: How will you synthesize Alanine from acetylene.

Solution:

Problem 9: Glycine exists as (H3N+CH2COO) while anthranilic acid 
(P–NH2–C6H4 – COOH) does not exist as dipolar ion.

Solution: –COOH is too weakly acidic to transfer H+ to the weakly basic –NH2 attached to the electron withdrawing benzene ring. When attached to an aliphatic carbon, the –NH2 is sufficiently basic to accept H+ form
–COOH group.

Problem 10: i) Sulphanilic acid  although has acidic as well as basic group, it is soluble in alkali but insoluble in mineral acid

  1. ii) Sulphanilic acid is not  soluble in organic solvents.

Solution: i) Sulphanilic acid exist as Zwitterion

The weakly acidic –+NH3 transfers H+ to OH to form a soluble salt, P–NH2–C6H4Na+ on the other hand – is too weakly basic to accept H+ from strong acids.

  1. ii) Due to its ionic character it is insoluble in organic solvents.

Problem 11: Why should isoelectric point for Aspartic acid (2.98) be so much lower than that of leucine?

Solution: This may be explained by considering following ion equilibria

It is apparent  that ions (A) and (B) are neutral, while (C) is a cation and (D) is dianion. In species (D), the anion is derived from the second —COOH group present in aspartic acid and is not possible in leucine. At neutral pH a significant concentration of (D), will be present in aqueous solution. It will therefore, be necessary to decrease the pH of such a solution if the formation of (D) is to be suppressed to a stage
where anions and cations are present in equal concentration
(the isoelectric point).

9.2 Objective

Problem 1: Nylon-66 is a polyamide of

(A) Vinylchloride and formaldehyde

(B) Adipic acid and methyl amine

(C) Adipic acid and hexamethylene diamine

(D) Formaldehyde and malamine

Solution:

∴ (C)

Problem 2: Which of the following is not a condensation polymer?

(A) Glyptal (B) Nylon-66

(C) Dacron (D) PTFE

Solution: Others are condensed polymer

∴ (C)

Problem 3: Which of the following is an example of basic dye?

(A) Alizarine (B) Indigo

(C) Malachite (D) Orange – I

Solution:

∴ (C)

Problem 4: Which of the following is not a chromophone?

(A) – NH2 (B) – NO

(C) – NO2 (D) – N = N –

Solution: Chromophore is colour bearing group

∴ (A)

Problem 5: Which of the following is a natural fibre?

(A) Starch (B) Cellulose

(C) Rubber (D) Nylon-6

 

Solution: (B)

 

  1. Assingments (Subjective Problems)

 

LEVEL – I

  1. How the configuration of (–) fructose related to those of (+) glucose & (+) mannose?
  2. Give the configuration of the (–) – glucose, (–)-mannose and (+) – fructose.
  3. What are carbohydrates and how they are classified? Give examples. What is their importance is everyday life?
  4. How will you distinguish between glucose and fructose
  5. What type of substances are included in the term carbohydrates? 
  6. Why aldoses react with Fehling’s solutionand PhNHNH2, but not with NaHSO3?
  7. What are diastereomers? Explain by taking examples from aldohexoses.
  8. Briefly discuss the ring structure and mutarotation of glucose.
  9. Lactose and sucrose are both disaccharides having the formula C12H22O11, lactose is reducing sugar but sucrose is not why?
  10. Why hydrolysis of sucrose is called inversion also?

Complete the following equations (Question No. 11 to 15)

11.
12. A C, D
13.
14.
15.

 

LEVEL – II

  1. Identify from A to I

L(+) lactic acid

(+)-2-butanol

  1. Write equations to show how D – (+)– glucose could be converted into
  2. a) Methyl-β-D-glucoside
  3. b) 2,3,4,6-tetra-o-methyl-D-glucose
  4. c) D-fructose
  5. In what respect does natural rubber differ from synthetic rubber? Give the synthesis of neoprene from acetylene.
  6. a) No. only enantiomers have this property and anomers are not enantiomers. 
  7. b) Anomers are epimers whose conformations differ only about C1.
  8. What structural feature distinguishes proline from other α-amino acids.
  9. How many chiral centers are there in (–) – fructose? (b) How many stereo isomeric
    2-keto hexoses should be there.
  10. How does acidic medium of stomach helps in the digestion of proteins.
  11. (+) glucose reacts with Ac2O to give two isomeric pentaacetyl derivatives neither of which reduces Fehling’s (or) Tollen’s reagent. Account for these facts.
  12. How do you account for the experimentally observed [α] = 19.9° for invert sugar?
  13. What would be the molecular formula of (+) sucrose if C–1 of glucose were attached to, say C–4 of fructose, and C–2 of fructose were joined to C–4 of glucose? Would this be a reducing (or) a non – reducing sugar?
11. Complete the equation

nH2N – (CH2)6 – NH2 + A [–HN – (CH2)6– (CH2)8]n + 2nHCl

  1. A hydrocarbon (A) which decolourises when treated with Br2/CCl4 and gets reduced by 1 mole of H2 in presence of Ni. When A is treated with dilute aqueous KMnO4 solutions gives B which on treatment with phthalic acid gives a polymeric compound C which is poly (ethylene glycol phthalate). Write the structures of A, B
    and C.
  2. Distinguish between acid dye and basic dye
  3. Give the structure of the following
  4. a) Alizarin b) Indigo
  5. c) Phenolphthalein d) Martius Yellow
  6. Give the method of preparation of Buna-S rubber.

LEVEL – III

  1. Show the product from A to F with Fischer projection

D(+)-glucose (+) glucaric acid A + B (lactones)

A C (aldonic acid) D (lactone) D – (+)-glucose

B E (aldonic acid) F (lactone)

F (lactone) (+)-gulose

  1. In an electric field, the amino acid migrates towards cathode when pH is below the isoelectric point while it migrates towards anode when pH is higher than isoelectric point.
  2. Why do glucose, mannose and fructose form identical osazone.
  3. How  will you distinguish between Glycine and acetamide.
  4. Give the two isomeric products from the reaction of D-threose with NaCN/HCN. What is the net result of this reaction? Why epimers formed are in unequal amounts?
  5. a) Give structures for E through G. Given:

An aldohexose

  1. b) Name this overall method (c). Discuss possibility of epimer formation.
  2. Two Ruff degradations of an aldohexose give an aldodetrose that is oxidised by HNO3 to meso-tartaric acid. Give the family configuration of the aldohexose.
  3. Compare and explain the difference in behaviour when an aldohexose and a typical aldehyde react with an excess of ROH in dry HCl. Give the general name for the product from an aldohexose and the specific name when the sugar is glucose.
  4. a) Account for isolation of two diastereomers of naturally occuring glucose from water solution. 
  5. b) Give the structures and names for the diastereomers. (C) Classify the type of diastereomers (d) How many methyl glucosides are there?
  6. a) Give the structure of disaccharide sucrose, the common table sugar from following (i) It does not reduce Fehling reagent and does not mutarotate (ii) It is hydrolysed by maltase or emulsion to D-glucose and D-fructose (iii) Methylation and hydrolysis give 2, 3, 4, 6-tetra-O-methyl-D-glucopyranose and a tetramethyl-D-fructose. 
  7. b) What structural features are uncertain.
  8. c) Give IUPAC name of sucrose.
  9. a) Give a simple test for starch.
  10. b) Describe the change that occurs when the test is performed at elevated temperatures.
  11. c) Discuss the structural change that accounts for the variation in the test.
  12. d) Do amylose and amylopectin give the same colour? Explain.
  13. Like other oxygen- containing compounds, alcohols dissolve in cold concentrated H2SO4. In case of some secondary and tertiary alcohols, dissolution is followed by the gradual separation of an insoluble liquid of high boiling point. How do you account for this behaviour?
  14. What products would be obtained if (+)-maltose itself were subjected to methylation and hydrolysis? What would this tell us. About the structure of (+)-maltose? What uncertainty would remain in the (+) maltose structure? Why was it necessary to oxidize (+) maltose first before methylene?
  15. Predict the products of the treatment of glycine with
  16. a) Aqueous NaOH
  17. b) Aqueous HCl
  18. c) Benzoyl chloride + aqueous NaOH
  19. d) Acetic anhydride
  20. e) NaNO2 + HCl
  21. Predict the products of the following reactions
  22. a) N-benzoylglycine + SOCl2
  23. b) Product (a) + NH3
  24. c) Product (a) + alanine
  25. d) Product (a) + C2H5OH

 

  1. Assignments (Objective Problems)

 

LEVEL I

  1. Which of the following is/are addition polymer/s?

(A) PVC (B) Nylon-6

(C) Teflon (D) Terylene

  1. Nylon-6, 6 is formed by heating

(A) Adipic acid and methane (B) Succinic acid and 1,3-butadiene

(C) Adipic acid and hexamethylene (D) none

  1. Terylene (Dacron) is a condensation polymer of

(A) Formaldehyde and urea

(B) Ethylene glycol and ethylene diisocyanate

(C) Ethylene glycol and dimethyl terephthalic acid

(D) Maleic anhydride and methyelene glycol

  1. Polystyrene is a

(A) Copolymer (B) Addition polymer

(C) Condensation polymer (D) None

  1. The polymer having strongest intermolecular forces is 

(A) Fibres (B) Elastomer

(C) Thermoplastic (D) Thermosetting polymer

  1. Which of the following is not a monosaccharide?

(A) Glucose (B) Fructose

(C) Cellulose (D) Ribose

  1. Glucose is

(A) Aldopentose (B) Aldohexose

(C) Ketopentose (D) Ketohexose

  1. The monomer units of starch are

(A) α-glucose (B) β-glucose

(C) Pyranose (D) Galactose

  1. Which of the following is the sweetest?

(A) Glucose (B) Fructose

(C) Maltose (D) Sucrose

  1. Maltose is made up of

(A) α-D-glucose (B) D-fructose

(C) α-D-Glucose and β-D-glucose (D) Glucose and fructose

  1. Which is used to identify glucose

(A) Neutral FeCl3 (B) CHCl3 + KOH (alc.)

(C) C2H5ONa (D) Ammoniacal AgNO3

  1. Number of possible isomers of glucose is

(A) 16 (B) 14

(C) 10 (D) 8

  1. The carbohydrate which cannot be hydrolysed by the human digestive system is:

(A) Starch (B) Glycogen

(C) Cellulose (D) All the above

  1. A carbohydrate which cannot be hydrolysed to simpler compounds is called:

(A) Monosaccharide (B) Polysaccharide

(C) Disaccharide (D) Trisaccharide

  1. Which of the following has a branched chain structure?

(A) Amylopectin (B) Amylose

(C) Cellulose (D) Nylon

  1. Glucose reacts with acetic anhydride to form:

(A) Monoacetate (B) Tetra-acetate

(C) Penta-acetate (D) Hexa-acetate

  1. Glucose molecule reacts with X number of molecules of phenylhydrazine to yield osazone. The value of X is

(A) Three (B) Two

(C) One (D) Four

  1. When sucrose is heated with conc. HNO3 acid the product is

(A) Saccharic acid (B) Oxalic acid

(C) Formic acid (D) Invert sugar

  1. Glucose is hydrolysed by zymase into

(A) Dicarboxylic acid (B) Alcohol

(C) Amino acids (D) Aromatic acids

  1. Ozazone formation involves only 2-carbon atoms of glucose because of

(A) Oxidation (B) Reduction

(C) Chelation (D) Hydrolysis

 

LEVEL II

 

1.

(A) L(+) – Ribose (B) L–(+) – Arabinose

(C) L–(–) Xylose (D) L – (+) – Lyxose

 

2. ‘A’ is
(A) (B)
(C) (D)

 

3. A & B are

(A) CH3CHO & CH3COCH3 (B) CH3COCOOH & CH3CHO

(C) 2CH3COOH + HCOOH (D) CH3COCH3 + 2HCOOH

 

4. A & B are

(A) HCHO & HCOCH(OCH3)2 (B) (CH3O)2CH – COOH & HCHO

(C) (CH3O)2C = O and (D) HCOOH & HCOCH(OCH3)2

  1. Which of the following is a basic amino acid?
(A) (B)
(C) (D)
  1. Glucose . A is

(A) Heptanoic acid (B) 2-iodohexane

(C) Heptane (D) Heptanol

  1. Glucose Product is

(A) Glucaric acid (B) Gluconic acid

(C) Hexanoic acid (D) Bromo hexane

  1. Sugars which is/are non-reducing

(A) Glucose (B) Starch

(C) Sucrose (D) Maltose

  1. Carbohydrates which differ in configuration at the glycosidic carbon (i.e. C1 in aldose and C2 in ketoses) are called

(A) Anomers (B) Epimers

(C) Diastereomers (D) Enantiomers

  1. A pair of diastereomers that difer only in the configuration about a single carbon atom are called

(A) Anomers (B) Epimers

(C) Conformers (D) Enantiomers

  1. Main structural unit of protein is:

(A) Ester linkage (B) Ether linkage

(C) Peptide linkage (D) All the above

  1. The reagent used for detection of protein is 

(A) Conc. HNO3 (B) Fehling’s solution

(C) Tollen’s reagent (D) Baeyer’s reagent 

  1. The pH value of a solution in which a polar amino acids does not migrate under the influence of electric field is called

(A) Iso electric point (B) Iso electronic point

(C) Neutralisation point (D) None

  1. The sequence in which amino acids are arranged in protein is called 

(A) Primary structure (B) Secondary Structure 

(C) Tertiary Structure (D) Quaternary structure  

  1. The bond that determines the secondary structure of protein is:

(A) Ionic bond (B) Covalent bond

(C) Coordinate bond (D) Hydrogen bond

  1. Nylon-6,6 is an example of

(A) Fibres (B) Elastomer

(C) Thermoplastic (D) Thermosetting polymer

  1. Teflon is an example of:

(A) Fibres (B) Elastomer

(C) Thermoplastic (D) Thermosetting polymer

  1. Nylon-6 is a polyamide having monomer

(A) Caprolactam (B) Cyclohexane

(C) Cyclohexanone-oxime (D) None.

  1. Natural rubber is a polymer of

(A) Chloroprene (B) Isoprene

(C) 1, 3-Butadiene (D) None

  1. In vulcanization of rubber we add

(A) Sulphur (B) Phosphorus

(C) Magnesium (D) Chlorine

 

 

 

  1. Answers to Objective Assignments

 

LEVEL – I

 

  1. A, C 2. C
  2. C 4. B
  3. A 6. C
  4. B 8. A
  5. B 10. A
  6. D 12. A
  7. C 14. A
  8. A 16. C
  9. A 18. B
  10. B 20. A

LEVEL – II

 

  1. A 2. B
  2. C 4. A
  3. C 6. A
  4. B 8. B, C
  5. A 10. B
  6. C 12. A
  7. A 14. A
  8. D 16. A
  9. D 18. A
  10. B 20. A

 

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