Class XII Chemistry Ch 6: General Principles & Processes Of Isolation of Elements

 

Top concepts:

1.               Minerals: The naturally occurring chemical substances in the earth's crust which are obtained by mining are known as minerals. Metals may or may not be extracted profitably from them.

2.               Ores: The rocky materials which contain sufficient quantity of mineral so that the metal can be extracted profitably or economically are known as ores.

3.               Gangue: The earthy or undesirable materials present in ore are known as gangue.

4.               Metallurgy: The entire scientific and technological process used for isolation of the metal from its ores is known as metallurgy.

5. Chief Ores and Methods of Extraction of Some Common Metals: Metals Occurrence Extraction Method Remark Sodium Rock salt: NaCl Feldspar:Na3AlShO8 Electrolysis of fused NaCl or NaCl/ CaCl2 Sodium        is       highly reactive, it reacts with water Copper Copper pyrites:CuFeS2 Malachite:CuCO3.Cu(OH)2 Cuprite: Cu2O Copper glance: Cu2S Roasting of sulphide partially and reduction 2Cu2O + Cu2S ^ 6 Cu +SO2 It is self reduction in a specially          designed converter.        Sulphuric acid leaching is also employed. Aluminium Bauxite: AlOx(OH)3-2x where 0<x<1 Cryolite: Na3AlF6 Kaolinite: [A^OH^SbOs] Electrolysis of        AhO3 dissolved in molten cryolite or in Na3AlCl6 A good source of electricity is needed in the extraction of Al Zinc Zinc blende or Sphalerite: ZnS Zincite: ZnO Calamine: ZnCO3 Roasting      and       then reduction with C The metal may be purified by fractional distillation. Lead Galena: PbS Roasting of the sulphide ore and then reduction of the oxide Sulphide         ore         is concentrated by froth floatation process Silver Argentite: Ag2S Sodium cyanide leaching of the sulphide ore and finally replacement of Ag by Zn It involves complex formation                  and displacement

 

Gold	Native, small amounts in many ores such as those of copper and silver	Cyanide leaching, same as in case of silver	Gold reacts with cyanide to form complex
Iron	Haematite: Fe2O3 Magnetite: Fe3O4 Siderite: FeCO3 Iron pyrites: FeS2	Reduction with the help of CO and coke in blast furnace.	Limestone is added as flux which removes SiO2 as calcium silicate (slag) floats over molten iron and             prevents         its oxidation. Temperatures approaching 2170 K is required.

 

6.               Steps of metallurgy:

a.     Concentration of ore

b.     Conversion of concentrated ore to oxide

c.     Reduction of oxide to metal

d.     Refining of metal

7.               Concentration of ore: The process of removal unwanted materials like sand, clay, rocks etc from the ore is known as concentration, ore - dressing or benefaction. It involves several steps which depend upon physical properties of metal compound and impurity (gangue). The type of metal, available facilities and environmental factors are also taken into consideration.

8.               Hydraulic washing (or gravity separation): It is based on difference in densities of ore and gangue particles. Ore is washed with a stream of water under pressure so that lighter impurities are washed away whereas heavy ores are left behind.

9.               Magnetic separation: This method is based on the difference in magnetic and non - magnetic properties of two components of ore (pure and impure). This method is used to remove tungsten ore particles from cassiterite (SnO2). It is also used to concentrate magnetite (Fe3O4), chromite (FeCr2O4) and pyrolusite (MnO2) from unwanted gangue.

10.           Froth Floatation Process: The principle of froth floatation process is that sulphide ores are preferentially wetted by the pine oil, whereas the gangue particles are wetted by the water. Collectors are added to enhance the non-wettability of the mineral particles. Examples are pine oil, fatty acids and xanthates are added to it. Froth stabilizers are added to stabilize the froth. Examples are cresols, aniline. If two sulphide ores are present, it is possible to separate the two sulphide ores by adjusting proportion of oil to water or by adding depressants. For example- In the case of an ore containing ZnS and PbS, the depressant used is NaCN. It selectively prevents ZnS from coming to froth but allows PbS to come with the froth.

11.           Leaching (Chemical separation): It is a process in which ore is treated with suitable solvent which dissolves the ore but not the impurities.

12.      Purification of Bauxite by Leaching: Baeyer's process:

Step 1:

Al2O3 (s) + 2NaOH (aq) + 3H2O (l)   change to  2Na[Al(OH)4](aq)

Step 2:

2Na[Al(OH)₄](aq) + CO₂ (g)------- > Al₂O₃.xH₂O(s) + 2NaHCO₃ (aq) Step 3:

Al₂O₃.xH₂O(s)---- Heat atl4⁷°K ----_> A|_2O3 (s) + xH₂O(g)

13.      Concentration of Gold and Silver Ores by Leaching:

4M(s) + 8CN” (aq) + 2H₂O(aq) + O₂(g)---> 4[M(CN)₂]"(aq) + 4OH(aq) 2[M(CN)₂]^-(aq) + Zn(s)------> [Zn(CN)₄]^2-(aq) + 2M(s)

Where :

[M = Agor Au]

14.      Conversion of ore into oxide: It is easier to reduce oxide than sulphide or carbonate ore. Therefore, the given ore should be converted into oxide by suitable method:

Roasting	Calcination
It is a process in which ore is heated in a regular supply of air at a temperature below melting point of the metal so as to convert the given ore into oxide	It is a process of heating ore in limited supply of air so as to convert carbonate ores into oxides.

 

ore.
Sulphide ores are converted into oxide by roasting	Carbonate ores are converted into oxide by roasting
It is also used to remove impurities as volatile oxides	It is also used to remove moisture and volatile impurities
E.g.: 2ZnS+ 3O2 -------> 2ZnO + 2SO2	E.g.: CaCO3 —heat > CaO + CO2

 

15.          Reduction of oxide to metal: The process of converting metal oxide into metal is called reduction. It needs a suitable reducing agent depending upon the reactivity or reducing power of metal. The common reducing agents used are carbon or carbon monoxide or any other metals like Al, Mg etc.

16.          Thermodynamic principles of metallurgy: Some basic concepts of thermodynamics help in understanding the conditions of temperature and selecting suitable reducing agent in metallurgical processes:

a.     Gibbs free energy change at any temperature is given by AG = AH - TAS where AG is free energy change, AH is enthalpy change and AS is entropy change.

b.     The relationship between AG^e and K is AG^e = -2.303 RT log K where K is equilibrium constant. R = 8.314 JK"¹ mol^-1, T is temperature in Kelvin.

c.     A negative AG means +ve value of K i.e., products are formed more than the reactants. The reaction will proceed in forward direction.

d.     If AS is +ve, on increasing temperature the value of TAS increases so that TAS > AH and AG will become negative.

17. Coupled reactions: If reactants and products of two reactions are put together in a system and the net AG of two possible reactions is -ve the overall reaction will take place. These reactions are called coupled reactions.

18.  Ellingham diagrams: The plots between A_fG^e of formation of oxides of elements vs. temperature are called Ellingham diagrams. It provides a sound idea about selecting a reducing agent in reduction of oxides. Such diagrams help in predicting the feasibility of a thermal reduction of an ore. AG must be negative at a given temperature for a reaction to be feasible.

19.  Limitations of Ellingham Diagrams: It does not take kinetics of reduction into consideration, i.e., how fast reduction will take place cannot be determined.

20.  Reduction of iron oxide in blast furnace: Reduction of oxides takes place in different zones.

At 500 - 800 K (lower temperature range in blast furnace)

3Fe2O3 + CO----- > 2Fe3O4 + CO2 

Fe3O4 + 4CO ----> 3Fe + 4CO2

Fe2O3 + CO -----> 2FeO + CO2

At 900 - 1500 K (higher temperature range in blast furnace)

C + CO2 ----> 2CO

FeO + CO -----> Fe + CO2

Limestone decomposes to CaO and CO2

CaCO3 —^heat > CaO + CO₂

Silica (impurity) reacts with CaO to form calcium silicate which forms slag. It floats over molten iron and prevents oxidation of iron.

CaO + SiO2 > CaSiO3

Calcium silicate (Slag)

21.  Types of iron:

a.      Pig iron: The iron obtained from blast furnace is called pig iron. It is impure from of iron contains 4% carbon and small amount of S,.P, Si and Mn. It can be casted into variety of shapes.

b.     Cast iron: It is made by melting pig iron with scrap iron and coke using hot air blast. It contains about 3% of carbon content. It is extremely hard and brittle.

c.     Wrought iron: It is the purest form of commercial iron. It is also called malleable iron.

It is prepared by oxidative refining of pig iron in reverberatory furnace lined with haematite which oxidises carbon to carbon monoxide.

Fe2O3 + 3C ----> 2Fe + 3CO

The substance which reacts with impurity to form slag is called flux

e.  g. limestone is flux.

S + O2 -----> SO2

4P + 5O2 -------> 2P2O5

Si + O2 ------> SiO2

CaO + SiO2 ----> CaSiO3 (slag)

3CaO + P2O5 ------> Ca3(PO4)2 (slag)

The metal is removed and freed from slag by passing through rollers.

22.           Electrolytic Reduction (Hall - Heroult Process): Purified bauxite ore is mixed with cryolite (Na₃AlF₆) or CaF₂ which lowers its melting point and increases electrical conductivity. Molten mixture is electrolysed using a number of graphite rods as anode and carbon lining as cathode.

The graphite anode is useful for reduction of metal oxide to metal. 2Al2O3 + 3C -----> 4Al + 3CO2

A|₂o₃ —^{electrolysis----} > 2 Al³⁺ + 3O^2_

At cathode: AP+ (melt) + 3e" --------> Al (l)

At anode:        C(s) + O2^- (melt) ----> CO (g) + 2e"

C(s) + 2O2" (melt) -----> CO2 (g) + 4e"

Graphite rods get burnt forming CO and CO₂. The aluminium thus obtained is refined electrolytically using impure Al as anode, pure Al as cathode and molten cryolite as electrolyte.

At anode:        Al ----> Al³⁺ + 3e"

(Impure)

At cathode: A|3+ + 3e" ---> Al (pure)

23.           Electrolysis of molten NaCI:

Thus sodium metal is obtained at cathode and Cl2 (g) is liberated at anode.

24.           Refining: It is the process of converting an impure metal into pure metal depending upon the nature of metal.

25.           Distillation: It is the process used to purify those metals which have low boiling points, e.g., zinc, mercury, sodium, potassium. Impure metal is heated so as to convert it into vapours which changes into pure metal on condensation and is obtained as distillate.

26.           Liquation: Those metals which have impurities whose melting points are higher than metal can be purified by this method. In this method, Sn metal can be purified. Tin containing iron as impurities heated on the top of sloping furnace. Tin melts and flows down the sloping surface where iron is left behind and pure tin is obtained.

27.           Electrolytic refining: In this method, impure metal is taken as anode, pure metal is taken as cathode, and a soluble salt of metal is used as electrolyte. When electric current is passed, impure metal forms metal ions which are discharged at cathode forming pure metal.

At anode:        M -->Mⁿ+ + ne"

(Impure)

At cathode: Mn++ ne" ---> M

(Pure)

28.           Zone refining: It is based on the principle that impurities are more soluble in the melt than in the solid state of the metal.

The impure metal is heated with the help of circular heaters at one end of the rod of impure metal. The molten zone moves forward along with

the heater with impurities and reaches the other end and is discarded. Pure metal crystallizes out of the melt.

The process is repeated several times and heater is moved in the same direction. It is used for purifying semiconductors like B, Ge, Si, Ga and In.

29.           Vapour phase refining: Nickel is purified by Mond's process. Nickel, when heated in stream of carbon monoxide forms volatile Ni(CO)₄ which on further subjecting to higher temperature decomposes to give pure metal.

Ni + 4 CO —³³⁰~^350K >Ni(CO)₄ ---------------- ► Ni + 4 CO

Impure                                                                          Pure

30.           van- Arkel method: It is used to get ultra pure metals. Zr and Ti are purified by this process. Zr or Ti are heated in iodine vapours at about 870 K to form volatile ZrI₄ or TiI₄ which are heated over tungsten filament at 1800K to give pure Zr or Ti.

Ti + 2I2	---- > TiI4	---- > Ti + 2I2
Impure		Pure
Zr + 2IZ	---- > ZrI4	---- > Zr + 2I2
Impure		Pure

 31.           Chromatographic method: It is based on the principle of separation or purification by chromatography which is based on differential adsorption on an adsorbent. In column chromatography, Al2O3 is used as adsorbent. The mixture to be separated is taken in suitable solvent and applied on the column. They are then eluted out with suitable solvent (eluant). The weakly adsorbed component is eluted first. This method is suitable for such elements which are available only in minute quantities and the impurities are not very much different in their chemical behaviour from the element to be purified.