Basic Organic Definitions

Old Definition of Organic Chemistry

The word organic derived from Latin word was first introduced by Swedish chemist, Berzelius in 1806 which means living organism.  The term organic was misleading because, previously organic chemistry was defined as the chemistry of those compounds which were produced or obtained from living things (plants or animals) through the agency of vital force.

Modern Definition of Organic Chemistry

Now a days, organic compounds are considered to be essential for life. They are compounds of carbon regardless of their origin. The study of covalent compounds of carbon containing H, and often O, N, S, P and halogens (Cl, Br and I) is termed as Organic Chemistry. OR The study of hydrocarbons and their derivatives is called Organic Chemistry.

Exceptions

However there are certain compounds of carbon which are not included in organic compounds. These are carbides (CaC₂), cyanides (NaCN), metal carbonates (Na₂CO₃), metal bicarbonates (NaHCO₃), cyanates (CNO¯), sulphocyanides (CNS¯) and oxides of carbon (CO and CO₂).

Vital Force Theory

According to this theory, it was assumed that all living organism contained an unknown, mysterious and super-natural force known as vital force which was the basic requirement for their production. This force was considered to be originated by living cells and is beyond human control.  So nobody can synthesize organic compounds in the laboratory.

In 1828, a German chemist Friedrich Wohler accidentally prepared Urea (a typical organic compound) in the laboratory by controlled heating of ammonium cyanate. This synthesis proved that there is no necessity of vital force for the preparation of organic compounds. Thus vital force theory was completely over thrown or discarded.

                                                            

              NH₄CNO        →    (NH₂)₂CO

                                             Urea/Carbamide

Catenation

Carbon shows catenation. The property of carbon atom to bond or link itself with its own atoms to form long chains or rings is called Catenation. [Any number of carbon atoms can unite with each other through single, double or triple covalent bonds to form stable chains and rings of any size and length]. The tendency of carbon for catenation is due to:

(i)   Unique electronic arrangements.

(ii) Tendency for forming strong covalent bonds capable of holding greater no. of carbon atoms.

                                                    

Alkyl radicals

The residual hydrocarbon group left after the removal of a hydrogen atom from a saturated hydrocarbon is called alkyl group or radical.   OR The radical obtained from alkanes by the removal of one H atom are called alkyl groups or radicals. All alkyl radicals are expressed by a general formula C_nH_2n+1. The name of an alkyl radical is derived from the parent alkane by substituting ane of alkane by yl. They are generally represented by ‘R–‘.  Propyl and higher alkyl groups exist in more than one structure.

                         R – H  →  R –           

                e.g.   CH₄     → CH₃ –

Homologous Series

The members of the same class of organic compounds arranged in order of ascending molecular masses with a common difference of methylene groups (–CH₂–) are said to form a Homologous Series. OR A homologous series is a set or series of similar organic compounds differing by an integral number of methylene groups (–CH₂–) in their molecular formulae (or by molecular mass of 14) which have same elements, same functional groups, same general formula and identical chemical properties. Each member of the series is known as homologue of the other and the phenomenon itself is called Homology.

Functional Group

An atom or group of atoms whose presence confers on an organic molecule characteristics properties unique to that group is called Functional Group.  OR An atom or group of atoms which is present within the organic molecule and is responsible for its chemical behaviour and characteristic properties is called Functional Group. The functional group determines the basic chemistry of an organic compound. It gives specific and characteristic properties to an organic molecule, while the remainder hydrocarbon part (alkyl group) of the molecule has an effect on its physical properties.

1.  Open Chain / Aliphatic / Acyclic Compounds

The organic compounds whose molecules are composed of open chains of carbon atoms either branched or unbranched are called Acyclic Compounds. In acyclic compounds, there is no link between first and the last carbon atoms. They are commonly called Aliphatic Compounds (Greek word; means oil-fats characteristics) as some of the important members are found in fats. They burn without soot (smoke) due to complete oxidation. The aliphatic compounds may be saturated or unsaturated.

2.  Cyclic or Ring Compounds

Compounds whose molecules are composed of closed chains or rings of carbon atoms (with or without atom of other elements) are called Cyclic Compounds. Cyclic compounds are further divided into two types:

(a)     Heterocyclic or non-carbocyclic compounds

(b)     Homocyclic or carbocyclic compounds.

Heterocyclic Compounds

The cyclic compounds having one or more hetero atoms (like nitrogen, sulphur or oxygen) along with carbon in the ring are called Heterocyclic or Non-Carbocyclic Compounds. More or less 3600 heterocylic compounds are known. The various different prefixes are used to indicate the kind and number of hetero atoms. 

Homocyclic Compounds

These are the cyclic compounds in which the main skeleton or ring is made up of carbon atoms only. Homocyclic compounds are further divided into two groups:

 (i)     Aromatic or Benzenoids.

(ii)      Alicyclic  or Non-Benzenoids.

Alicyclic Compounds

They are carbocyclic or homocyclic compounds which do not contain any benzene ring. They resemble aliphatic compounds in many ways. They are homocyclic organic compounds which contain a ring of three or more carbon atoms (other than benzene ring) resembling aliphatic compounds. They may be saturated or unsaturated. They have general formula C_nH_2n or C_nH_2n–2

Saturated alicyclic compounds have general formula of C_nH_2n (n=3, 4, 5, 6) and have two hydrogen atoms less than their corresponding open chain saturated hydrocarbon alkanes.

Unsaturated alicyclic compounds have general formula of C_nH_2n–2 (n=3, 4, 5, 6) and have four hydrogen atoms less than their corresponding open chain saturated hydrocarbon alkanes. 

Aromatic Compounds or Arenes 

Aromatic compounds are benzenoid homocyclic (or carbocyclic) compounds containing one or more benzene rings (which is a hexagonal ring of six carbon atoms with three alternating double and single bonds) in their molecules. Aromatic compounds and their derivatives have characteristic smell. The pungency (fragrant odour or aroma) of benzene gives rise to the name aromatic (Greek, arome = smell) for all the members of the class (even though many are odourless).

Aromatic compounds also include the polycyclic (many-ringed) analogues of benzene having two or more benzene rings fused together in ortho positions. Two of the most important are naphthalene (bicyclic, C₁₀H₈; C_nH_n–2) and anthracene (tricyclic, C₁₄H₁₀; C_nH_n–4). The formula of polycyclic homologues of benzene is derived by inserting –C₄H₂– group into the formula of benzene. Anthracene and phenanthrene are positional isomers]. Now the term ‘aromatic’ is associated with ‘chemical stability’ rather than any aroma. The modern name of all benzene derivatives is Arenes (ar from aromatic and –ene, the letter denoting double bonds). All the other aromatic compounds are considered to be the derivative of benzene.

Aromatic compounds burn with soot or smoke due to incomplete oxidation owing to high percentage of carbon.

Aromatic compounds are always unsaturated. But their unsaturated character is masked by the presence of highly stable delocalized pi bonds, making them highly inert towards addition reactions.

Isomerism

The word isomer is a combination of two words, iso means same and mers means unit and this term was invented by Berzelius.

Isomerism is the existence of different compounds exhibiting different physical or chemical properties or both having same molecular formula. Isomers refer to those compounds which have the same molecular formula but differ in physical or chemical properties or both i.e. Isomers have entirely different physical properties and in many cases also have distantly different chemical properties (except chain isomers, metamers).

Isomerism is due to the different arrangement of atoms or groups in a molecule (structural isomerism) or due to different spatial configuration of the atoms or groups (stereoisomerism).

Structural or Constitutional Isomerism

When isomerism is caused by the difference in the arrangement of atoms within molecule without any reference to space is called Structural or Constitutional Isomerism. Structural or Constitutional Isomers are compounds that have same molecular formula but different structural formulae due to different arrangement of atoms or groups.  Structural Isomers have entirely different physical and in most cases also have distantly different chemical properties. Structural or Constitutional Isomerism is of following five types:

1.	Chain or skeletal or nuclear isomerism
2.	Position Isomerism
3.	Functional Group Isomerism
4.	Metamerism
5.	Tautomerism or keto-enol isomerism

Stereoisomerism

The prefix stereo- is derived from the Greek word stereos meaning solid. When isomerism is caused by the different spatial configuration (i.e. three-dimensional arrangement) of atoms or groups in space is called Stereoisomerism. Stereoisomers have same molecular formula and also the same structural formula but differ in arrangement of the bonds (atoms) in space. Stereochemistry is the term applied to the three-dimensional aspects of molecular structure and reactivity. Stereoisomerism is of three types: 

1.	Geometrical/cis-trans Isomerism
2.	Optical Isomerism
3.	Conformational Isomerism

Chain Isomerism

1.  Isomerism resulting from varying configuration of main carbon skeleton or chain is called skeletal or nuclear isomerism. Different compounds which have same molecular formula but they differ in the configuration of their main carbon skeleton or chains having different carbon chains are called chain or skeletal isomers.

2. Skeletal isomers are chemically similar because they posses the same functional group belonging to the same homologous series but they differ in physical properties as the van der Waal’s forces between molecules of the straight chain isomer are much stronger than those between molecules of the other two branched isomers.

3.  Skeletal isomerism is found in all aliphatic homologous series except monosubstituted benzenes.

4. Skeletal isomerism starts with C₄.                                                   

  

Metallurgy of Copper

Extraction of Copper from Sulphide Ore

Ore used and Type of Metallurgy

Copper is extracted mainly from sulphide ore, copper pyrite (Chalcopyrite), CuFeS₂ (CuS + FeS or Cu₂Fe₂S₄ i.e. Cu₂S + Fe₂S₃) which contain about 34% (6% in book) copper by Pyrometallurgy (Dry Process).

Main steps of Metallurgy

Extraction of Copper from sulphide ore involves the following steps:

1. Crushing of Ores into Powdered Form

The big blocks of ores are crushed into small pieces and then finally powdered.

2. Concentration of Crushed Ore

Ores are often contaminated with non-metallic and rocky impurities like sand (quartz), clay, mica, lime stone etc which are called gangue or matrix. The removal of unwanted impurities from the ore before metallurgical process is called Concentration or benefication or ore dressing. Copper pyrite is a low grade copper ore containing about 34% copper along with impurities such as sand, clay, lime stone etc.

The powdered ore is concentrated by froth floatation process (Selective Wetting) which is based upon preferential wetting of surfaces by liquids on account of the surface tension forces.

The powdered or crushed ore is concentrated by froth floatation process, in which the crushed ore is mixed with a mixture of Pine Oil or creosote oil and water and then thoroughly agitated with a blast of air. The ore is miscible (get wetted) with oil forming froth and rises to the top from where they are skimmed off and dried to get concentrated enriched ore whereas the gangue particles (impurities) are wetted by water and settle at bottom. Copper content is increased to 25-30% in this way. 

3. Roasting

Roasting is a process in which the concentrated ore is strongly heated in a current of excess of air below the melting point of ore in the hearth of a large flat Reverberatory Furnace. Roasting not only dries the ore but also bring about following changes:

(i) Impurities like C, S, P, As,Sb in the ore are removed as their volatile oxides. It also removes organic matter

S	+	O2	¾¾¾¾¾®	SO2­
4Sb	+	3O2	¾¾¾¾¾®	2Sb2O3­
4As	+	3O2	¾¾¾¾¾®	2As2O3­

(ii)Copper pyrite (ore) is converted into a mixture of Cuprous Sulphide and Ferrous Oxide. Some FeS present in the ore remains unreacted. At the end of roasting, the ore has been now contained Cu₂S, FeO and FeS.

4. Smelting (Formation of Molten Matte)

Smelting is the process of reduction of oxide of ore by reducing agent (like coke) under such conditions that metal is obtained in molten state.(In copper extraction, smelting serves to remove gangue).

A charge consisting of Roasted Ore, powdered Coke (reducing agent) and sand (flux) is strongly heated in a Water Jacketed Blast Furnace and a blast of hot air is blown at the lower part of furnace through tuyeres. During smelting coke burns releasing heat of combustion which serves to keep the charge in molten state.

The Ferrous oxide present in ore combines with sand (flux) to form fusible ferrous silicate (slag) which being lighter rises to the top and is withdrawn from the upper hole.

The molten mixture of Cu₂S and FeS is left behind after smelting which is called Molten Matte or Course Metal wchih contains about 45% copper. It being heavier, forms the lower layer and is withdrawn from the lower hole periodically.

5. Bessemerisation (Formation of Blister Copper)

The reduction of molten matte is carried out in a pear-shaped stainless steel furnace called Bessemer converter which is lined inside with MgO also provided with tuyers.

The molten matte is heated in Bessemer converter by blowing hot blast of air through pipes called Tuyers with more silica. The following changes occur in the converter:

(i) Air oxidizes most of FeS to FeO by direct oxidation which is removed as ferrous silicate (slag) by combining with silica. FeS is also converted into FeO by reacting with Cu₂O (formed by partial oxidation of Cu₂S).

(ii)  After the iron has been removed, hot blast of air partially oxidizes Cu₂S into Cu₂O (leaving some unreacted Cu₂S). Now Cu₂O and remaining Cu₂S reduce each other (Auto or self reduction) without any external reducing agent to give metallic copper in molten state.

Blistered Copper

The molten metal produced is now cooled to solidify in sand moulds, the dissolved and hidden SO₂ gas escapes out, produces blisters (bubbles) on the surface of solid metal, so copper obtained is called BLISTERED COPPER which is 98-99% pure.

Since the reaction is exothermic, the heat liberated keeps the crude copper in the molten state. The completion of the reaction is indicated by the appearance of green flame produced by the vapourization of copper.

6. Electrolytic Refining of Blistered Copper

Blistered copper contains impurities mainly Ag, Au, Pt, Ni, Zn, Fe, As, Pb, As etc. Hence for electrical purposes, blister copper obtained after bessemerization is refined electrolytically to get copper of high purity (99.95-99.99).

The refining of Blistered Copper is carried out in a large Lead-Lined Tank using a series of anode of thick impure blister copper which places alternately with a series of cathodes of thin plates of 100% pure copper (The cathodes are coated with graphite so that the deposited pure copper may be removed easily). These electrodes are suspended in an electrolytic solution of CuSO₄ (15%) acidified with traces of dilute H₂SO₄ (5%).

On electrolysis, the atoms of anode (impure copper metal and other active metals such as Fe, Zn, Bi etc) are oxidized to their corresponding cations and pass into solution. The impurities of less active metals such as Ag, Au etc are not oxidized and settle down just below the anode as anode mud.  The current of 1.3–1.5 volt is used for electrolysis which helps to deposit only copper on cathode leaving behind other metal ions in solution. The electrolytically refined copper is 100% (99.99%) pure. With the deposition of copper, cathode grows thick and anode becomes thin due to dissolution of the metal. 

Electrolytic Reactions

Transition Elements

Corrosion, Its causes, affecting factors and its Prevention

Definition of Corrosion                                  

The slow, continuous and spontaneous destruction of metals at their exposed surface due to their interaction with atmospheric oxygen and water involving the conversion of uncombined metal into its oxide or hydrated oxide or carbonates by the harmful and undesirable combined action of atmosphere or any chemical agent is called corrosion. It is essentially an Electro-Chemical Oxidation-Reduction Reaction. 

Metal + Air + Water → Metal Oxide

Metals are eaten away or corroded by the process of corrosion on their exposed surface followed by the corrosion of the inner surface and then continues up to certain depth.

Metals to be effected

Corrosion affects almost all metals except noble metals like Ag, Au and Pt. corrosion is said to have been taken place when

1.  Iron gets coated with a brittle reddish brown flaky rusty layer.      

2.  Copper develops green coloured deposits.  

3.  Zinc is coated with whitish deposits.

4. Aluminium surface becomes dull and loses its shine.

5. Silver gets tarnished i.e. it loses its shine.

Rate of Corrosion

Different metals corrode at different rates on exposure to the atmosphere or water or any reactive agent. e.g.

(1).   Alkali metals like Na and K readily tarnish in air.           

(2).   Alkaline earth metals like Ca corrodes quickly.

(3).   Iron gets rusted slowly.                                  

(4).   Other less reactive metals like Sn, Pb and Cu corrode very slowly.

Adverse effects of Corrosion

Corrosion causes enormous damage to the buildings, bridges, ships and many other things made up of metals especially iron. e.g.

1. It reduces the mechanical strength of metals making them weak and brittle. 

2. It decreases conductivity of metals for heat and electricity.

3. It reduces resistance of metals for acids and alkalis.

Cause of Corrosion

The corrosion of metals is due to combined effect of atmospheric oxygen and water which is generally accelerated by the presence of CO₂, acids and gaseous pollutants like SO₂ in the air.

Rusting of iron

Rusting is the process of corrosion of iron which is an electrochemical redox reaction during which iron is covered or coated by combining with atmospheric moist oxygen in presence of water developing a porous, thin, flaky and easily detachable Reddish Brown Deposits called Rust, which consists of hydrated ferric oxide Fe₂O₃.nH₂O.      

4Fe

+

3O2   +   2nH2O

→

2Fe2O3.nH2O

Conditions favouring Rusting

Following conditions favour the rusting of iron

1.	Presence of moisture
2.	Presence of oxygen or air.
3.	Presence of weakly acidic atmosphere.
4.	Presence of electrolyte (like NaCl, H2SO4)
7.	Presence of dissolved salts in water. (e.g. iron corrodes faster in sea water)
5.		Presence of impurity in iron.
6.		Presence of reactive gases like CO2, SO2, NO2 etc.
8.		Presence of uneven surface of iron.
9.		Presence of rust itself (auto catalysis).
10.		High temperature

   

Prevention from Corrosion

The protection of iron from rusting can be brought about by:

1.	By electroplating	e.g.;	Nickel plating, chromium plating etc.
2.	By protective metallic coating;	e.g.;	galvanizing (coating with zinc), tin plating
3.	By alloying with other metals;	e.g.;	stainless steel (Fe, Cr and Ni).
4.	Non-metallic material coating;	e.g.;	Paint, oils, grease, varnish, plastic emulsion.
5.	By other coating; phosphate coating,	e.g.;	concrete coating, Fe3O4 coating.
6.	By using corrosion inhibitors;	e.g.;	K2CrO4.

Tin Plating

Definition

The process of depositing or coating thin layer of metallic tin on base metals (e.g. Fe, Cu) to protect them from Corrosion is called Tin Plating.

Methods of Tinning the Metals

The process of tinning may be carried out by 2 methods:

1. Mechanical Tin Plating.                              

2. Electrolytic Tin Plating.

1. Mechanical Tin Plating

(a) Tinning of Sheets

(i)   The iron sheet which is to be tinned is cleaned thoroughly by dipping in dilute H₂SO₄ to remove oxide layer.

(ii)  The sheets, after washing and drying, then dip in the bath containing Molten Tin (on the surface of which floats a flux, ZnCl₂).

(iii) After the process of completion of tinning, the tinned sheets of iron are then passed through Hot Roller to give uniform coating by removing superfluous tin.

(b)    Tinning of Utensils

(i)     The utensils are cleaned by ammonium chloride.

(ii)    After cleaning, they are heated strongly.

(iii)   A small quantity of tin is rubbed on the utensils.  It produces a thin layer of tin all over the utensils.

2. Electrolytic Tin Plating

(i)     The process is carried out in an electrolytic cell.

(ii)    Cathode is made up of the metallic object which is to be coated.

(iii)   Anode is made up of the tin plate.

(iv)   Both electrodes are immersed in electrolytic mixture which consists of salt of tin such as stannous chloride (SnCl₂) and hydrochloric acid (HCl).

(v)    On passing electric current, oxidation takes place at anode where tin atoms change to stannous ions by the loss of two electrons.

Sn

–

2e–

→

Sn2+

(Stannous ion)

––––

Oxidation

(vi)   These Sn²⁺ ions migrate towards cathode which is to be coated, where Sn²⁺ ions are reduced by the gain of two electrons to form tin metal which is deposited over metallic object.

Sn2+

+

2e–

→

Sn

––––

Reduction

Stainless Steel

Definition

Stainless steel is a term applied to the alloy of iron with chromium and nickel containing very low percentage of carbon which shows resistance to corrosion.

Composition

Stainless steel contains 0.15–2.0% of carbon. In addition, some metals chromium or nickel are added to give the steel of desired quality and property.

Properties

1. It is hard, heat resistant and has high tensile strength and it is practically non-oxidisable.

2. It gives resistance to corrosion and usually considered as rust proof.

Types of Steel

There are three types of stainless steel according to %ages of different constituents.

1. Mild Steel (Low carbon steels)                    (13% Cr, 5% Ni and 0.1–0.4% carbon)

2. Medium Steel (Medium Carbon Steels)      (17% Cr, 6% Ni and 0.2–0.6% carbon)   

3. Super or Hard Steels (High Carbon Steels) (18% Cr, 8% Ni and 0.18% carbon)

1. Mild Steel (Low carbon steels)

It contains 13% Cr, 5% Ni and 0.1–0.4% carbon. It is soft, malleable and ductile. It is used in making boiler plates, rods and nut bolts.

2. Medium Steel (Medium Carbon Steels)

It contains 17% Cr, 6% Ni and 0.2–0.6% carbon. It is used in preparing Axle, Beams.

3. Super or Hard Steels (High Carbon Steels)

It contains 18% Cr, 8% Ni and 0.18% Carbon. It is used in making surgical equipments, blades and automobile parts.

Silvering of Mirrors

Definition of Silvering of Mirrors

The process of deposition of thin and uniform layer of silver on a clean glass surface by the reduction of silver ions by an organic compound forming light reflecting surface (mirror) is called Silvering of Mirrors. This process was first discovered by Sliebig in 1938.

Principle of Process

The process is based on the reduction of Ammonical Silver Nitrate (Tollen’s Reagent, a silver complex, which acts as oxidizing agent) by organic compounds containing aldehydic group (–CHO) i.e. glucose, formaldehyde, tartarates (acts as reducing agent) to metallic silver. Aldehyde gets oxidized to carboxylic acid. Silver formed is deposited in the form of mirror on the walls of glass.

Solutions required

1.   Ammonical Silver Nitrate Solution (Tollen’s Reagent)

It is prepared by adding NH₄OH solution to AgNO₃ solution, till the brown precipitate of Ag₂O first formed is re-dissolved.

2. Solution of Reducing Agent

Glucose or Formaldehyde (HCHO) solutions are reducing agent. Rochelle salt (sodium potassium tartarate) can also be used as Reducing Agent.      

Method of Silvering the Glass

The process of silvering of mirror is summarized as:

1. The glass plate to be silvered is cleansed with alcoholic KOH, then washed with distilled water and dried.

2. The clean glass plate to be silvered is brought in contact with ammonical silver nitrate solution, over which an equal amount of organic reducing agent such as formaldehyde is poured.

3. The reduction of silver ions immediately begins and metallic silver produced is deposited on the glass as a thin film.

4. The plate is washed with water, dried and polished.

5. The back of glass is coated with a mixture of red lead (Pb₃O₄) and turpentine (a varnish); to get a looking glass.