SMELTING : PYROMETALLURGY:

When roasting forms a liquid product, which makes separation easier, it is called smelting. Metal is extracted by heating calcined or roasted ore with powdered coke in presence of a flux.

Consider, for example, the smelting of zinc oxide:

The gaseous carbon monoxide separates from the liquid zinc, allowing the metal to be readily recovered. Other examples are

Slag:

In some cases, a flux must be added to the mixture during smelting to help separate the two materials. The flux is a material that will react with the gangue to form a substance with a low melting point. For example, oxides of silicon within gangue can be liquefied by reaction with calcium carbonate according to the reaction:

The waste liquid solution that forms from the flux and gangue is usually a silicate material called a slag. The liquid metal and the liquid slag have different densities and therefore separate. Holes tapped at different heights into the side of the container holding the liquid metal and slag allow the more dense liquid to flow out of the lower tap holes and the less dense liquid to flow out of the higher tap holes.

Principle of Slag formation:

The principle of slag formation is essentially the following:

Nonmetal oxide (acidic) + Metal oxide (basic) to form a Fusible (easily melted) slag

Removal of unwanted basic and acidic oxides: For example, FeO is the impurity in extraction of Cu from copper pyrite.

Matte also contains a very small amount of iron (II) sulphide.

To remove unwanted acidic impurities like sand and P₄O₁₀, smelting is done in the presence of limestone.

Properties of a Slag:

(1) Slag is a fusible mass.

(2) It has low melting point.

(3) It is lighter than and immiscible with the molten metal. It is due to these impurities that the slag floats as a separate layer on the molten metal and can thus be easily separated from the metal. The layer of the slag on the molten metal prevents the metal from being oxidised.

SLAG : PYROMETALLURGY:

 In some cases, a flux must be added to the mixture during smelting to help separate the two materials. The flux is a material that will react with the gangue to form a substance with a low melting point. For example, oxides of silicon within gangue can be liquefied by reaction with calcium carbonate according to the reaction:

The waste liquid solution that forms from the flux and gangue is usually a silicate material called a slag. The liquid metal and the liquid slag have different densities and therefore separate. Holes tapped at different heights into the side of the container holding the liquid metal and slag allow the more dense liquid to flow out of the lower tap holes and the less dense liquid to flow out of the higher tap holes.

Principle of Slag formation:

The principle of slag formation is essentially the following:

Nonmetal oxide (acidic) + Metal oxide (basic) to form a Fusible (easily melted) slag

Removal of unwanted basic and acidic oxides: For example, FeO is the impurity in extraction of Cu from copper pyrite.

Matte also contains a very small amount of iron (II) sulphide.

To remove unwanted acidic impurities like sand and P₄O₁₀, smelting is done in the presence of limestone.

Properties of a Slag:

(1) Slag is a fusible mass.

(2) It has low melting point.

(3) It is lighter than and immiscible with the molten metal. It is due to these impurities that the slag floats as a separate layer on the molten metal and can thus be easily separated from the metal. The layer of the slag on the molten metal prevents the metal from being oxidised.

FLUX : PYROMETALLURGY:

The substance used in metallurgical process to decrease melting point of an ore or a substance used to react gangue (impurities present in ore) to form Slag.

Type of flux: Fluxes are of two types’ viz., acidic flux and basic flux.

(A) Acidic flux: It is an acidic oxide (oxide of a non-metal) like SiO₂, P₂O₅, and B₂O₃ (from borax).

It is used to remove the basic impurity like CaO, FeO, MgO etc. The acidic flux combines with the basic impurity and forms a slag. 

(B) Basic flux: It is a basic oxide (i.e., oxide of a metal) like CaO (obtained from lime stone, CaCO₃), MgO (from magnesite, MgCO₃), haematite (Fe₂O₃) etc. It is used to remove the acidic impurity like SiO₂, P₂O₅ etc. The basic flux combines with the acidic impurity and forms a slag. 

Thus, slag can be defined as a fusible mass, which is obtained when a flux reacts with an infusible acidic or basic impurity present in the oxide ore.

METALLURGY-INTRODUCTION:

Minerals and Ores:

The biggest source of metals is earth’s crust. Metals are also found in rocks, sea water, some impurities, etc depending upon their chemical nature. Less electropositive metals have less affinity for oxygen, moisture and hence occur in free or native or uncombined state, e.g. Au, Pt, Ag, etc. While the metals with higher electropositive character occurs in combined state as compounds.

Minerals:

The naturally occurring chemical substances in the earth’s crust which are obtained by mining are known as minerals.

Ores:

Minerals which can be used as a source for commercial recovery of a desired substance are termed as ores. Earthy substances associated with ores are called gangue.

List of Important Ores:

Sl No	Name of the Element	Ores	Chemical Formulas
1	Aluminum (Al)	Bauxite	Al2O32H2O
		Corundum	Al2O3
		Kryolite	Na3AlF6
2	Calcium (Ca)	Dolomite	MgCO3CaCO3
		Lime Ston	CaCO3
3	Copper (Cu)	Copper Glance	Cu2S
		Copper Pyrite	CuFeS2
		Malachite	2CuCO3Cu(OH)2
4	Gold (Au)	Calve rite	AuTe2
		Sybarite	AgAuTe2
5	Iron (Fe)	Hematite	Fe2O3
		IronPyrite	FeS2
		Magnetite	Fe3O4
		Siderite	FeCO3
6	Lead (Pb)	Anglesite	PbCl2
		Galena	PbS
7	Phosphorous (P)	Floreopetite	3Ca3(PO4)CaFe2
		Phosphorite	Ca3(PO4)CaFe2
8	Potassium (K)	Karnalite	KClMgCl6H2O
		Salt Petre	KNO3
9	Magnesium (Mg)	Dolomite	MgCO3CaCO3
		Karnalite	KClMgCl26H2O
10	Mercury (Hg)	Calomel	Hg2Cl2
		Cinnabar	HgS
11	Silver (Ag)	Silver Glance	Ag2S
12	Sodium (Na)	Rock Salt	NaCl
		Sodium Carbonate	Na2CO3
13	Tin (Sn)	Classiterite	SnO2

ENERGY IN BOHR'S ORBITS:

_­­Total energy of (E) of an electron revolving in nth orbit is equal to sum of kinetic energy and Potential energy.

We know the electron revolve around nucleus due balancing of two forces columbic and centrifugal forces

This is the famous Bohr’s equation applicable to Hydrogen like atoms or ions as He⁺¹, Li⁺² , Be⁺³ 

etc.

The factor (4 pi epsilon zero) is known as permittivity factor and its numerical value is 1.11268*10^-10C²N^-1M^-2  ( In CGS Unit K= 1)

Pi= 22/7= 3.424, me=9.109 *10^-31 kg, e = 1.602 *10^-10 C and h= 6.626*10^-34 j-s

Calculation of E_n in SI Unit:

Bohr’s energy in electron volt:

We know that, 1eV = 1.602 *10^-19 J hence

Energy in term of Rydberg’s Constant:

Relation between Total energy (TE), Kinetic energy (KE) and Potential energy (PE):

Important conclusions:

(1) The minus sign for the energy of an electron in an orbit represents attraction between the +vely charged nucleus and negatively charged electron.

(2) Energy of an electron at infinite distance from the nucleus is zero.

(3) As an electron approaches the nucleus, the electrical attraction increases, energy of electron decreases and it becomes negative.

(4) Energy of an electron increases as the value of ‘n’ increases i.e.

(5) Value of ‘n’ remaining unchanged, the amount of energy associated with an electron remains unaltered.

(6) Energy of electron in first, second, third and fourth orbit are –13.6, –3.4, –1.5, and –0.85 eV/atom respectively.

(7) Although the energy of electron increases with increase in the value of ‘n’ (orbit), yet the difference of energy between successive orbits decreases. Thus E₂ – E₁ > E₃ – E₂ > E₄ – E₃ > E₅ – E₄ >, etc….