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P Block Elements, Class 12, Chemistry Detailed Chapter Notes PDF Download

Group-III  - The p block elements, Chemistry, Class 12

p-block Elements

Group-III

Isolation of "B" :

(i) Preparation of B2O3 from Borax or Colemanite

Na2B4O7 HCl / H2SO4 → H2B4O7

H2B4O7 5H2O → 4H3BO3 chemistry B2O3 H2O

(ii) Reduction of B2O3

B2O3 Na / K / Mg / Al → B Na2O / K2O / MgO / Al2O3

 

Chemical Props. :

(i) Burning in air : 4B 3O2 → 2B2O3

4Al 3O2 → 2Al2O3

(ii) Reaction with water

B H2O (Cold & Hot) → no reaction

2B 3H2O → B2O3 H2

                         (red hot)

Al 3H2O → Al(OH)3 3/2 H2

(iii) B HCl → no reaction

B H2SO4(dil.) → no reaction

2B 3H2SO4(conc.) → 2H3BO3 3SO2

B 3HNO3 → H3BO3 3NO2

2Al 6H2SO4 → Al2(SO4)3 3SO2 6H2O

Al HNO3(80%) → Al2O3 (passive layer) and does not react further.

(iv) 2B 2NaOH 2H2O → 2NaBO2 3H2

2Al 2NaOH 2H2O → 2NaAlO2 3H2

(v) 2B N2 → 2BN 2Al N2 → 2AlN

4B C → B4C 4Al 3C → Al4C3

(vi) 3Mg 2B → Mg3B2

Preparation of B2H6 :

(i) Mg3B2 HCl (10%) → B2H6 B4H10 B5H9 etc.

(ii) B4H10 chemistry B2H6 H2 higher borane

(iii) BCl3 (or BBr3) 6H2 chemistry B2H6 6HCl

(iv) 3LiAlH4 or (LiBH4) 4BF3 → 3LiF 3AlF3 or 3(BF3) 2B2H6

Reaction of B2H6 :

(i) B2H6 O2 chemistry B2O3 H2O

(ii) B2H6 H2O (Cold is enough) → H3BO3 6H2

(iii) B2H6 HCl (dyr) chemistry B2H5Cl H2

• Heating of Boric Acid :

H3BO3 chemistry HBO2 chemistry H2B4O7 B2O3

Metaboric acid Tetraboric acid Glassy mass

• H3BO3 H2O2 → (H2O) (HO)2B-O-O-H chemistry chemistry

Sodium peroxy borate used in washing

powder as whitener

Preparation of Borax :

2CaO·3B2O3 2Na2CO3 → 2CaCO3¯ Na2B4O7 2NaBO2

Colemanite chemistry

chemistry chemistrychemistry

chemistry [4NaBO2 CO2 → Na2B4O7 Na2CO3

Na2B4O7·10H 2

Uses of Borax :

(i) In making glass, enamel and gaze or pottery.

(ii) As antiseptics in medicinal soaps preparation.

Al2O3 preparation :

(i) 2Al(OH)3 chemistry Al2O3 3H2O

(ii) Al2(SO4)3 chemistry Al2O3 3SO3

(iii) (NH4)2SO4· Al2(SO4)3· 24H2O chemistry Al2O3 2NH3 4SO3 25H2O

Uses : (i) In making refractory brick

(ii) as abrasive

(iii) To make high alumina cement

AlCl3 Preparation :

(i) 2Al 6HCl(vap.) → 2AlCl3 3H2

(over heated) (dry)

(ii) Al2O3 3C 3Cl2 chemistry 2AlCl3 (vap.) 3CO

 

Solid anh. AlCl3

Props :

(i) Its anhydrous formed is deliquescent and fumes in air.

(ii) It sublimes at 180ºC.

(iii) It is covalent and exists in the form of dimer even if in non polar solvents e.g. alc., ether, benzene, where it is soluble in fair extent.

chemistry

Uses : (i) Friedel-Craft reaction

(ii) Dyeing, drug & perfumes etc.

 

Alumns : M2SO4, M'2(SO4)3·24H 2O Props : Swelling characteristics

where M = Na , K , Rb , Cs , As , Tl , NH4

M' = Al 3, Cr 3, Fe 3, Mn 3, Co 3

K2SO4·Al2 (SO4)3·24H2 O Potash alum

(NH4)2SO4· Al2(SO4)3· 24H2O Ammonium alum

K2SO4·Cr2 (SO4)3·24H2 O Chrome alum

(NH4)2SO4· Fe2(SO4)3· 24H2O Ferric alum

Preparation :

Al2O3 3H2SO4 → Al2(SO4)3 3H2O

Al2(SO4)3 K2SO4 aq. solution → crystallise

Uses : (i) Act as coagulant. (ii) Purification of water (iii) Tanning of leather

(iv) Mordant in dying (v) Antiseptic

==============================================================

Group-IV - The p block elements, Chemistry, Class 12

Group-IV

Types of Carbide :

(i) Ionic and salt like

classification on basis of (a) C1 unit

no. of carbon atoms (b) C2 unit

present in hydrocarbon (c) C3 unit

found on their hydrolysis

C1 unit : Al4C3, Be2C

Be2C H2O → Be(OH)2 CH4

Al4C3 12H2O → 4Al(OH)3 3CH4

C2 unit : CaC2, BaC2

CaC2 12H2O → Ca(OH)2 CH º CH

C3 unit : Mg2C3

Mg2C3 H2O → 2Mg(OH)2 CH3-C º CH : Propyne

(ii) Covalent carbinde : SiC & B4C

(iii) Interstitial carbide : MC (Transition element or inner transitional elements forms this kind of carbide)

Interstitial carbide formation doesn't affect the metallic lusture and electrical conductivity. (chemistryno chemical bond is present, no change in property.)

SiC

Preparation : SiO2 2C(coke) chemistry Si 2CO­

Si C chemistry SiC diamond like structure colourless to yellow solid in room temp.

¯

when impurity is present

Properties :

(i) It is very hard and is used in cutting tools and abrassive powder (polishing material).

(ii) It is very much inert.

(iii) It is not being affected by any acid except H3PO4.

CO

- How to detect

- How to estimate

- What are its absorbers

(i) How to detect

(a) burns with blue flame.

(b) CO is passed through PdCl2 solution giving rise to black ppt.

CO PdCl2 H2O → CO2­ Pd¯ 2HCl

Black metallic deposition

(ii) How to estimate

I2O5 5CO → I2 5CO2

I2 S2O32- → 2I- S4O62-

(iii) What are its absorbers

(a) Cu2Cl2 : CuCl CO 2H2O → [CuCl(CO)(H2O)2]

Uses :

In the Mond's process of Ni-extraction

CO is the purifying agent for Ni

Impure chemistry

Producer gas : CO N2 H2

Water gas : CO H2

Water gas is higher calorific value than producer gas.

chemistry in water gas, both CO & H2 burns while in producer gas N2 doesn't burn.

Taflon chemistry

CHCl3 HF chemistry CF2HCl chemistry CF2 = CF2 chemistry chemistry

Purpose

Temp. withstanding capacity upto 500-550ºC (1st organic compound withstand this kind of high temperature.)

Silicon (Si)

Occurence :

Silicon is the second most abundant (27.2%) element after oxygen (45.5%) in the earth's crust. It does not occur free in nature but in the combined state, it occurs widely in form of silica and silicates. All mineral rocks, clays and soils are built of silicates of magnesium, aluminium, potassium or iron. Aluminium silicate is howeve the most common constituent of rocks and clays.

Silikca is found in the free state in sand, flint and quartz and in the combined state as silicates like

(i) Feldspar - K2O.Al2O3.6SiO 2

(ii) Kaolinite - Al2O3.2SiO2.2H 2O

(iii) Asbestos - CaO.3MgO.4SiO2

Preparation :

(i) From silica (sand) : Elemental silicon is obtained by the reduction of silica (SiO2) with high purity coke in an electric furnace.

SiO2(s) 2C(s) Si(s) 2CO(g)

(ii) From silicon tetrachloride (SiCl4) or silicon chloroform (SiHCl3) : Silicon of very high purity required for making semiconductors is obtained by reduction of highly purified silicon tetrachloride or silicon chloroform with dihydrogen followed by purification by zone refining.

SiCl4(l) 2H2(g) → Si(s) 4HCl(g)

SiHCl3(s) H2(g) → Si(s) 3HCl(g)

Physical Properties :

(i) Elemental silicon is very hard having diamond like structure.

(ii) It has shining luster with a melting point of 1793 K and boiling point of about 3550 K.

(iii) Silicon exists in three isotopes, i.e. 14Si28, 14Si29 and 14Si30 but 14Si28 is the most common isotope.

Chemical Properties :

Silicon is particularly unreactive at room temperature towards most of the elements except fluorine. Some important chemical reactions of silicon are discussed below.

(i) Action of air : Silicon reacts with oxygen of air at 1173 K to form silicon dioxide and with nitrogen of air at 1673 K to form silicon nitride,

Si(s) O2(g) chemistry SiO2(s)

Silicon dioxide

3Si(s) 2N2(g) Si3N4(s)

Silicon nitride

(ii) Action of steam : It is slowly attacked by steam when heated to redness liberating dihydrogen gas.

Si(s) 2H2O(g) SiO2(s) 2H2(g)

(iii) Reaction with halogens : It burns spontaneously in fluorine gas at room temperature to form silicon tetrafluoride (SiF4).

Si(s) 2F2 SiF4(l)

However, with other halogens, it combines at high temperature forming tetrahalides.

(iv) Reaction with carbon : Silicon combines with carbon at 2500ºC forming silicon carbide (SiC) known as carborundum.

Si(s) C(s) SiC(s)

Carborundum is an extremely hard substance next only to diamond. It is mainly used as an abrasive and as a refractory material.

 

Uses :

(i) Silicon is added to steel as such or more sually in form of ferrosilicon (an alloy of Fe and Si) to make it acid-resistant.

(ii) High purity silicon is used as semiconductors in electronic devices such as transistors.

(iii) It is used in the preparation of alloys such as silicon-bronze, magnesium silicon bronze and ferrosilicon.

Compounds of Silicon :

What is silane. SinH2n 2 SiH4 & Si2H6

Only these two are found

Higher molecules are not formed. chemistry Si can't show catanetion property.

Hot Mg Si-vap → Mg2Si chemistry MgSO4 SiH4 Si2H6 ......

Ques. SiH4 is more reactive than CH4. Explain.

Reasons :

(i) Sid - Hd- in Cd- - Hd

C - electro -ve than H

Si less electro -ve than H

So bond polarity is reversed when Nu- attacks, it faces repulsion in C but not in Si.

(ii) Silicon is having vacant d orbital which is not in case of carbon.

(iii) Silicon is larger in size compared to C. By which the incoming Nu- doesn't face any steric hindrance to attack at Si whereas CH4 is tightly held from all sides.

Silicones :

It is organo silicon polymer,

CCl4 H2O → no hydrolysis

but CCl4 H2O → COCl2 2HCl

super heated steam

SiCl4 H2O → Si(OH)4 4HCl

chemistry SiO2(3-D silicate)

R2SiCl2 H2O chemistry R2Si(OH)2 chemistry chemistry

Linear silicone

R2CCl2 H2O chemistry R2C(OH)2 chemistry chemistry

Silicones may have the cyclic structure also having 3, 4, 5 and 6 nos. of silicon atoms within the ring. Alcohol analogue of silicon is known as silanol.

chemistry chemistry

R3SiCl chemistry chemistry R3Si-O-SiR3

R2SiCl2 R3SiCl chemistrychemistry chemistry

* Using R3SiCl in a certain proportion we can control the chain length of the polymer.

RSiCl3 H2O → R-Si(OH)3 chemistry chemistry

It provides the crosslinking among the chain making the polymer more hard and hence controling the proportion of RSiCl3 we can control the hardness of polymer.

Uses :

(1) It can be used as electrical insulator (due to inertness of Si-O-Si bonds).

(2) It is used as water repellant (chemistry surface is covered) eg. car polish, shoe polish, massonary work in buildings.

(3) It is used as antifoaming agent in sewage disposal, beer making and in cooking oil used to prepare potato chips.

(4) As a lubricant in the gear boxes.

Silica (SiO2)

Occurrence :

Silica or silicon dioxide occurs in nature in the free state as sand, quartz and flint and in the combined state as silicates like, Feldspar : K2O.Al2O3.6SiO 2, Kaolinite : Al2O3.2SiO2.2H 2O etc.

Properties :

(i) Pure silica is colourless, but sand is usually coloured yellow or brown due to the presence of ferric oxide as an impurity.

(ii) Silicon dioxide is insoluble in water and all acids except hydrofluoric acid.

SiO2(s) 4HF(l) → SiF4(l) 2H2O(l)

(iii) It also combines with metallic oxides at high temperature giving silicates e.g.,

SiO2(s) CaO(s) chemistry CaSiO3(s)

 

(iv) When silica is heated strongly with metallic salts, silicates are formed and the volatile oxides are driven off as vapours.

SiO2(s) Na2CO3(s) chemistry Na2SiO3(s) CO2(g)

SiO2(s) Na2SO4(s) chemistry Na2SiO3(s) CO3(g)

3SiO2(s) Ca3(PO4)2(s) chemistry 3CaSiO3(s) P2O5(g)

The first two examples quoted here are important in glass making.

Structure of Silica :

Silica has a three-dimensional network structure. In silica, silicon is sp3-hybridized and in thus linked to four oxygen atoms and each oxygen atom is linked to two silicon atoms forming a three-dimensional giant molecule as shown in figure. This three-dimensional network structure imparts stability to SiO2 crystal and hence a large amount of energy is required to break the crystal resulting in high melting point.

chemistry

Uses :

(i) Sand is used in large quantities to make mortar and cement.

(ii) Being transparent to ultraviolet light, large crystal of quartz are used for making lenses for optical instruments and for controlling the frequency of radio-transmitters.

(iii) Powdered quartz is used for making silica bricks.

(iv) Silica gel (SiO2.xH2O) is used as a desiccant (for absorbing moisture) and as an absorbent in chromatography.

Tin & Its Compound

(i) chemistry [Burns with a bright flame]

(ii) Sn 2H2O chemistry

(iii) Reaction with acid,

chemistry

(iv) Sn 2NaOH H2O → Na2SnO3 2H2­.

or

KOH [In absence of air Na2SnO2 forms and in contact with air it readily converts into Na2SnO3.]

Oxides : SnO(grey) & SnO2(white)

chemistry

Both are amphoteric in nature :

SnO H2SO4 → SnSO4 H2O

SnO 2HCl → SnCl2 H2O

SnO 2NaOH or KOH chemistry Na2SnO2 or K2SnO2 H2O

But conc. hot alkali behaves differently.

2SnO 2KOH or NaOH → K2SnO3 or Na2SnO3 Sn H2O

Bi(OH)3 [Sn(OH)4]2- → Bi¯ [Sn(OH)6]2-

(black)

SnO2 2H2SO4 chemistry Sn(SO4)2 2H2O

(Soluble only in hot conc. H2SO4)

SnO2 2NaOH → Na2SnO3 H2O

SnCl2 & SnCl4 :

(1) Sn 2HCl (hot conc.) → SnCl2 H2­

SnCl2.2H2O chemistry Sn(OH)Cl HCl­ H2O­ Þ Hence anh. SnCl2 cannot be obtained.

¯

SnO HCl­

{SnCl4 4H2O → Sn(OH)4 4HCl­ fumes comes out}

(2) A piece of Sn is always added to preserved a solution of SnCl2. Explain.

6SnCl2 2H2O O2 → 2SnCl4 4Sn(OH)Cl¯ (white ppt)

SnCl4 Sn → 2SnCl2

SnCl4 4H2O → Sn(OH)4¯ (white ppt.) 4HCl

(3) SnCl2 HCl → HSnCl3 chemistry H2SnCl4

chemistry

SnCl4 2HCl → H2SnCl6 (Hexachloro stannic (IV) acid)

SnCl4 2NH4Cl → (NH4)2SnCl6 (colourless crystalline compound known as "pink salt")

(4) Red Prop. of SnCl2 :

Sn 2 2Fe 3 → 2Fe 2 Sn 4

2Cu2 Sn 2 → 2Cu Sn 4

Hg 2 Sn 2 → Hg¯ Sn 4

PhNO2 SnCl2 / HCl → PhNH2 Sn 4

K2Cr2O7 SnCl2 HCl → Cr 3 Sn 4 KCl H2O

(5) Readily combines with I2 Þ SnCl2I2 Þ This reaction is used to estimate tin.

Formation of SnCl4 :

(i) Sn Cl2(Excess) → SnCl4

(molten) (dry)

(ii) 2HgCl2 SnCl2 → 2Hg¯ SnCl4

(iii) Sn Aq. rigia → SnCl4 NO H2O

chemistry SnCl4.5H2O is known as butter of tin Þ used as mordant.

(NH4)2SnCl6 is known as `pink salt' Þ used as calico printing.

Mosaic gold : SnS2 yellow crystalline substance :

Sn 4NH4Cl → (NH4)2SnCl4 2NH3 H2

2(NH4)2SnCl4 2S → SnS2 2NH4Cl (NH4)2SnCl6

chemistry Distinction of Sn 2 / Sn 4 :

(i) H2S (ii) Hg 2 (iii) Fe 3 K3[Fe(CN)6 chemistry Blue ppt.

Compound of Lead

Oxides of Lead :.

(i) PbO (ii) Pb3O4 (Red) (iii) Pb2O3 (reddish yellow) (Sesquioxide)

(iv) PbO2 (dark brown)

(1) chemistry

Laboratory Preparation :

Pb(NO3)2 → 2PbO 4NO2 O2

PbO2 chemistry

Pb3O4

Pb2O3

Preparation of Pb2O3 :

2PbO NaOCl → Pb2O3 NaCl

chemistry chemistry

Pb2O3 2HNO3 → PbO2¯ Pb(NO3)2 H2O

This reaction suggest that Pb2O3 contains PbO2.

(2) Pb3O4 : 6PbO O2 chemistry 2Pb3O4 (In the same way, prove that its formula is 2PbO.PbO2)

Pb3O4 4HNO3 (cold. conc.) or (hot dil.) → 2Pb(NO3)2 PbO2 2H2O

But 2Pb3O4 6H2SO4 chemistry 6PbSO4 6H2O O2

Pb3O4 8HCl → 3PbCl2 4H2O Cl2

(3) PbO2 : Insoluble in water. HNO3, But reacts with HCl H2SO4 (hot conc.) and in hot NaOH/ KOH.

(i) Pb3O4 4HNO3 → 2Pb(NO3)2 PbO2 2H2O

(ii) Pb(OAc)2 Ca(OCl)Cl H2O → PbO2 [Brown (dark)] CaCl2 2CH3CO2H

¯

Excess bleaching powder is being removed by stirring with HNO3.

Reaction : PbO2 4HCl → PbCl2 Cl2 2H2O

2PbO2 2H2SO4 chemistry 2PbSO4 2H2O O2

PbO2 2NaOH → Na2PbO3 H2O

PbO2 : Powerful oxidising agent :

(i) PbO2 SO2 → PbSO4 [spontaneously]

(ii) PbO2 2HNO3 (COOH)2 → Pb(NO3)2 2CO2 2H2O

(iii) 2Mn(NO3)2 5PbO2 6HNO3 → 3Pb(NO3)2 2PbSO4¯ 2HMnO4 2H2O

PbCl4 : Exists as H2[PbCl6]

PbO2 4HCl → PbCl4 2H2O

{ice cold conc. saturated with Cl2}

PbCl4 2HCl → H2PbCl6

TetraEthyl lead :

4Na-Pb (alloy 10%-Na) 4C2H5Cl (vap.) → 3Pb Pb(Et)4 4NaCl

It is antiknocking agent.

==========================================================

Group - V - The p block elements, Chemistry, Class 12

Group - V

Preparation of N2 :

(i) NH4NO2 chemistry N2 2H2O

(ii) (NH4)2Cr2O7 chemistry N2 4H2O Cr2O3

(iii) Ba(N3)2 chemistry Ba 3N2

2NaN3 chemistry 2Na 3N2

(iv) 2NH3 3NaOCl → N2 3NaCl 3H2O

(v) 2NO 2Cu → 2CuO N2

(red, overheated) (Black)

(vi) Cl2 passed into liquor NH3

3Cl2 2NH3 → N2 6HCl

6NH3 6HCl → 6NH4Cl

----------------------------------------------------

3Cl2 8NH3 → N2 6NH4Cl

In this method NH3 conc. should not be lowered down beyond a particular limit.

3Cl2 NH3 → NCl3 3HCl

(Tremendously explosive)

Properties of N2 :

(i) It is inert due to high bond energy.

(ii) It is absorbed by hot metal like Ca, Mg, Al etc.

3Ca N2 → Ca3N2

Bright hot 2Al N2 → 2AlN

Al2O3 3C N2 chemistry 2AlN 3CO

(BN)x : Inorganic graphite

White slippery solid having 2D-sheet structure.

(BN)x chemistry (BN)x

3-D network structure similar to diamond (Borazon) which is harder than diamond and used for diamond cutting.

Na2B4O7 2NH4Cl chemistry 2NaCl 2NH3 2B2O3 H2O

B2O3 2NH3 → 2BN 3H2O

(iii) N2 can be absorbed by calcium carbide at the temp around 1000ºC, CaC2

chemistry it is a very good fertiliser.

Cyanamide ion : chemistry

(iv) chemistry

Types of Nitride :

(i) Salt like or ionic : Li3N, Na3N, K3N (?), Ca3N2, Mg3N2, Be3N2

(ii) Covalent : AlN, BN, Si3N4, Ge3N4, Sn3N4

(iii) Interstitial : MN chemistry

No of metal atom per unit cell is equal to no of octahedral voids per unit cell.

All the octahedral voids are occupied by nitrogen atoms. Hence the formula is MN.

HCP : Hexagonal closed pack FCC : Face centred cubic

NH3 preparation :

(i) Nitrate or nitrite reduction : NO3- / NO2- Zn or Al NaOH → NH3 [Zn(OH)4]2- or [Al(OH)4]-

(ii) Metal nitride hydrolysis : N3- 3H2O → NH3­ 3OH-

(iii) Haber's process : N2 3H2 chemistry 2NH3

 

Q.1 NH3 can't be dried by H2SO4, P2O5 and anh. CaCl2 because :

2NH3 H2SO4 → (NH4)2SO4

H2O NH3 P2O5 → (NH4)3PO4

CaCl2 8NH3 → CaCl2.8NH3

forms adduct

Quick lime is used for this purpose

chemistry chemistry

Properties :

(i) It dissolves several electropositive metals like Li, Na, K, Rb, Cs, Sr, Ba etc.

Eg. : K in liq NH3 Þ (i) Blue in colour

(ii) Conducts electricity

(iii) having reducing property

chemistry

K2[Ni(CN)4 chemistry K4[Ni(CN)4]

Square planar Tetrahedral

complex complex

(ii) Ag(NO3)(aq) BaCl2(aq) → AgCl ¯ Ba(NO3)2

chemistry

(iii) CH3COOH is strong acid in liq. NH3 while in water is weak acid.

chemistry

NH3 H → NH4 H2O H → H3O

Basisity order NH3 > H2O

more solvation of H in NH3.

(iv) Hydrolysis and Ammonolysis occurs is a same way.

SiCl4 4H2O → 4HCl Si(OH)4 chemistry SiO2 2H2O

SiCl4 8NH3 → 4NH4Cl Si(NH2)4 chemistry Si3N4 NH3­

Rate of hydrolysis and Ammonolysis will be affected by the presence of HCl vapour & NH4Cl vapour respectively.

NH4 - Salts Preparation

chemistry

Oxides of Nitrogen :

Oxides of Nitrogen Structure Physical state colour of gas

N2O Gas Colourless

NO chemistry or chemistry Gas Colourless

N2O3 chemistry Gas Blue liquid (-30ºC)

NO2 chemistry Gas Brown

N2O5 chemistry Colourless solid -(no existance in gas phase)

Preparations :

1. N2O :

(i) NH4NO3 → N2O H2O

(ii) (NH4)2SO4 NaNO3 → NH4NO3 Na2SO4

¯

N2O 2H2O

(iii) Zn HNO3 → Zn(NO3)2 N2O H2O

(dil.&Cold)

2. NO :

(i) Cu HNO3 (1 : 1) → Cu(NO3)2 NO H2O

hot

(ii) KNO3 FeSO4 H2SO4 → Fe2(SO4)3 K2SO4 NO H2O

FeSO4 NO → FeSO4 . NO chemistry FeSO4 NO­

(iii) Ostwald process - Restricted oxidation of NH3.

Industrial process :

4NH3 5O2 chemistry 4NO 6H2O

3. N2O3 :

(i) HNO3 As2O3 → H3AsO4 N2O3

(ii) Cu HNO3(6M) → Cu(NO3)2 chemistry

4. NO2 :

(i) M(NO3)2 MO 2NO2 1/2O2 [M = Pb, Cu, Ba, Ca]

(ii) (Cu, Pb, Ag) HNO3 → M-nitrate NO2 H2O

Hot & Conc.

5. N2O5 :

(i) 2HNO3 P2O5 → 2HPO3 N2O5

(ii) 4AgNO3 2Cl2(dry gas) → 4AgCl 2N2O5 O2

Properties :

(I) Decomposition Behaviour :

(i) N2O chemistry 2N2 O2

(ii) 2NO chemistry N2 O2

(iii) N2O3 chemistry NO2 NO

(Blue liq.) at (-30º C)

(iv) 2NO2 chemistry 2NO O2

N2O4 chemistry 2NO2

(white solid) Brown gas

at (-11ºC)

(v) N2O4 chemistry N2O5 chemistry 2NO2 1/2O2

colourless yellow

solid liq.

(II) Reaction with H2O & NaOH :

H2O NaOH

(i) N2O : Fairly soluble in water and

produces neutral solution .............

(ii) NO : Sparingly soluble in water

and produces neutral solution ............

(iii) N2O3 : 2HNO2

Hence it is known as

anhydride of HNO2 NaNO2

(iv) NO2 : HNO2 HNO3

called as mixed anhydride NaNO2 NaNO3

(v) N2O5 : 2HNO3

called as anhydride of HNO3 NaNO3

Other properties :

N2O : 2N2O → 2N2 O2

Hence it is better supporter

for combustion

S N2O → SO2 N2

P N2O → P2O5 N2

Mg N2O → MgO N2

Na N2O → Na2O N2

Cu N2O → CuO N2

H2 N2O → H2O N2

NO : (i) It burns : NO 1/2 O2 → NO2

(ii) It supports combustion also for molten sulphur and hot phosphorous.

S 2NO → SO2 N2

2P 5NO → P2O5 5/2 N2

(iii) It is being absorbed by FeSO4 solution.

(iv) It is having reducing property.

KMnO4 NO H2SO4 → K2SO4 MnSO4 HNO3 H2O

HOCl NO H2O → HNO3 HCl

(v) NO shows oxidising property also.

SO2 2NO H2O → H2SO4 N2O

H2S 2NO → H2O S¯ N2O

3SnCl2 2NO 6HCl → 3SnCl4 2NH2OH

(Used for NH2OH) preparation)

(vi) NO combines with X2 (X2 = Cl2Br2F2) to produce NO X.

2NO X2 → 2NOX

N2O3 : No more properties.

NO2 : (1) It is having oxidising property.

S NO2 → SO2 NO

P NO2 → P2O5 NO

C NO2 → CO2 NO

SO2 NO2 H2O → H2SO4 NO

H2S NO2 → H2O S¯ NO

CO NO2 → CO2 NO

NO not formed : 2KI 2NO2 → I2 2KNO2

(2) Reducing property of NO2.

KMnO4 NO2 H2SO4 → K2SO4 MnSO4 HNO3 H2O

chemistry

N2O5 : I2 5N2O5 → I2O5 10NO2 (I2O5 is used for the estimation of CO)

I2O5 5CO → I2 5CO2

I2 2S2O32- → 2I- S4O62-

N2O5 NaCl → NaNO3 NO2Cl

It proves that N2O5 is consisting of ion pair of NO2 & NO3-.

Oxyacids of N :

HNO2 : Preparation

(i) M-nitrite chemistry HNO2

(ii) N2O3 H2O → 2HNO2

Properties :

(i) Oxidising property of HNO2

KI HNO2 HCl → KCl H2O NO I2

SnCl2 HNO2 HCl → SnCl4 NO H2O

SO2 HNO2 H2O → H2SO4 NO

H2S HNO2 → H2O S¯ NO

FeSO4 HNO2 H2SO4 → Fe2(SO4)3 NO H2O

Na3AsO3 HNO2 → Na2AsO4 NO H2O

(ii) Reducing property of HNO2

KMnO4 HNO2 H2SO4 → K2SO4 MnSO4 HNO3 H2O

K2Cr2O7 HNO2 H2SO4 → K2SO4 Cr2(SO4)3 HNO3 H2O

H2O2 HNO2 → H2O HNO3

HNO2 urea →

thiourea →

sulphamic acid →

NH3 → NH4NO2

C2H5NH2 → C2H5OH N2

Ph-NH2 chemistry PhN2 X-

nitric acid (HNO3)

1. It was named aqua forties (means strong water) by alchemists.

Preparation

(i) Laboratory Method

KNO3 conc. H2SO4 chemistry KHSO4 HNO3(vap)

 

vapour of nitric acid evolved are condensed in a glass receiver.

(ii) Industrial Preparation

(A) Birkeland Eyde Process or arc process

Step 1 N2 O2 chemistry 2NO - heat

Step 2 NO O2 chemistry NO2

Step 3 NO2 H2O chemistry HNO2 HNO3

Step 4 HNO2 chemistry HNO3 NO H2O

(B) Ostwald's Process

Step 1 NH3 O2 chemistry NO H2O heat

Step 2 NO O2 chemistry NO2

Step 3 NO2 H2O chemistry HNO2 HNO3

Step 4 HNO2 chemistry HNO3 NO H2O

PROPERTIES

Physical

Nitric acid usually acquires yellow colour due to its decomposition by sunlight into NO2.

4HNO3 chemistry 4 NO2 2H2O O2

The yellow colour of the acid can be removed by warming it to 60-80ºC and bubbling dry air through it.

It has extremely corrosive action on the skin and causes painful sores.

Chemical

(a) It is very strong acid. It exhibits usual properties of acids. It reacts with basic oxides, carbonates, bicarbonates and hydroxides forming corresponding salts.

CaO 2HNO3 chemistry Ca(NO3)2 H2O

Na2CO3 2HNO3 chemistry 2NaNO3 H2O CO2

NaOH HNO3 chemistry NaNO3 H2O

(b) Oxidising nature : Nitric acid acts as a strong oxidising agent as it decomposes to give nascent oxygen easily.

2HNO3 chemistry H2O 2NO2 O

or 2HNO3 chemistry H2O 2NO 3O

(i) Oxidation of non- metals : The nascent oxygen oxidises various non - metals to their corresponding highest oxyacids.

(1) Sulphur is oxidised to sulphuric acid

chemistry

(2) Carbon is oxidised to carbonic acid

C 4HNO3 chemistry H2CO3 4NO2 2H2O

(3) Phosphorus is oxidised to orthophosphoric acid.

2P 10HNO3 chemistry 2H3PO4 10NO2 2H2O

conc. and hot

(4) Iodine is oxidised to iodic acid

I2 10HNO3 chemistry 2HIO3 10NO2 4H2O

conc. and hot

(ii) Oxidation of metalloids

Metalloids like non-metals also form highest oxyacids

(1) Arsenic is oxidised to arsenic acid

2As 10HNO3 chemistry 2H3AsO4 10NO2 2H2O

or As 5HNO3 chemistry H3AsO4 5NO2 H2O

conc. and hot

(2) Antimony is oxidised to antimonic acid

Sb 5HNO3 chemistry H3SbO4 5NO2 H2O

conc. and hot

(3) Tin is oxidised to meta - stannic acid.

Sn 2HNO3 chemistry H2SnO3 4NO2 H2O

(iii) Oxidation of compounds :

(1) Sulphur dioxide is oxidised to sulphuric acid

SO2 2HNO3 chemistry H2SO4 2NO2

(2) Hydrogen sulphide is oxidised to sulphur

H2S 2HNO3 chemistry 2NO2 2H2O S

(3) Ferrous sulphate is oxidised to ferric sulphate in presence of H2SO4

6FeSO4 3H2SO4 2HNO3 chemistry 3Fe2(SO4)3 2NO 4H2O

(4) Iodine is liberated from KI.

6KI 8HNO3 chemistry 6KNO3 2NO 3I2 4H2O

(5) HBr, HI are oxidised to Br2 and I2, respectively.

2HBr 2HNO3 chemistry Br2 2NO2 2H2O

Similarly, 2HI 2HNO3 chemistry I2 2NO2 2H2O

(6) Ferrous sulphide is oxidised to ferrous sulphate

FeS HNO3 chemistry Fe2(SO4)3 8NO2 4H2O

(7) Stannous chloride is oxidised to stannic chloride is presence of HCl.

2HNO3 14H chemistry NH2OH NH3 5H2O

Hydroxylamine

NH3 HNO3 chemistry NH4NO3

------------------------------------------------------------------------

7SnCl2 14HCl 3HNO3 chemistry 7SnCl4 NH2OH NH4NO3 5H2O

(8) Cane sugar is oxidised to oxalic acid.

C12H22O11 36HNO3 chemistry 6(COOH)2 36NO2 23H2O

(c) Action on Metals : Most of the metals will the exception of noble metals like gold and platinum are attacked by Nitric acid plays a double role in the action of metals, i,e, it acts as an acid as well as an oxidising agent. Amstrong postulated that primary action of nitric acid is to produce hydrogen in the nascent form. Before this hydrogen is allowed to escape, it reduces the nitric acid into number of products like NO2, NO, H2O, N2 or NH3 according to the following reactions :

Metal HNO3 chemistry Nitrate H

2HNO3 2H chemistry 2NO 2H2O

2HNO3 6H chemistry 2NO 4H2O

2HNO3 10H chemistry N2 6H2O

2HNO3 16H chemistry 2NH3 6H2O

The progress of the reaction is controlled by a number of factors :

(a) the nature of the metal

(b) the concentration of the acid

(c) the temperature of the reaction

(d) the presence of other impurities.

------------------------------------------------------------------------------------------

Concentration of Metal Main Products

nitric acid

------------------------------------------------------------------------------------------

Very dilute HNO3 (6%) Mg, Mn H2 Metal nitrate

----------------------------------------------------------

Fe, Zn, Sn NH4NO3 metal nitrate H2O

------------------------------------------------------------------------------------------

Dilute HNO3 (20%) Pb, Cu, Ag, Hg NO metal nitrate H2O

----------------------------------------------------------

Fe, Zn N2O metal nitrate H2O

----------------------------------------------------------

Sn NH4NO3 Sn(NO3)2

------------------------------------------------------------------------------------------

Conc. HNO3(70%) Zn, Fe, Pb, Cu, Ag NO2 metal nitrate H2O

----------------------------------------------------------

Sn NO2 H2SnO3

Metastannic acid

------------------------------------------------------------------------------------------

Action on Proteins

(i) Nitric acid attacks proteins forming a yellow nitro compound called xanthoprotein. It, therefore, stains skin and renders wool yellow colour. This property is utilized for the test of proteins.

 

(ii) Oxidation A number of organic compounds are oxidised.

Sawdust catches fire when nitric acid is poured on it. Turpentine oil bursts into flames when treated with fuming nitric acid, Cane sugar is oxidised to oxalic acid. Toluene is oxidised to benzoic acid with dil. HNO3.

Structure

Nitric acid is a monobasic acid, i.e., the molecule consist of one hdyroxyl group as it is formed by the hdyrolysis of nitryl chloride, NO2Cl. It may be structurally represented as bellow :

chemistry

Gaseous nitric acid is a planar molecule. The bond lengths and bond angles as present in the molecule

are represented in the figure :

chemistry

PHOSPHOROUS

INTERCONVERSION OF WHITE `P' & RED `p'

chemistry

chemistry

PREPARATION OF WHITE `P'

(i) chemistry

(ii) Ca3(PO4)2 3H2SO4 (conc.) chemistry 3CaSO4 2H3PO4

H3PO4 chemistry HPO3

meta phosphoric acid

12C 4HPO3 chemistry 2H2 chemistry 12COchemistry P4

Coke white `P'

REACTIONS OF `P'

. P H2SO4 (hot & conc.) chemistry H3PO4 SO2 H2O

P KIO3 H2SO4 chemistry H3PO4 I2 K2SO4

. Reaction with hot metal -

3Na P chemistry Na3P

3Mg 2P chemistry Mg3P2

3Ca 2P chemistry Ca3P2

2Cu 2P chemistry Cu3P2

Al P chemistry AIP

Ca3P2 H2O chemistry M(OH)n PH3

or Mg3P2

or AIP

 

PREPARATION OF PH3 (PHOSPHINE GAS)

 

(i) 4H3PO3 chemistry PH3 2H3PO4

chemistry

PHYSICAL PROPERTIES

(i) It is having rotten fish smell

(ii) It is soluble in CS2 and insoluble in water.

(NH3 is soluble in water)

chemistry

chemistry

chemistry is formed with acids

chemistry

PH3 can be absorbed by Ca(OCl)Cl.

PH3 3Ca(OCl)Cl 3H2Ochemistry PCl3 3HCl 3Ca(OH)2

2NH3 3Ca(OCl)Cl chemistry N2 3CaCl2 3H2O

OTHER REACTIONS OF PH3

(i) PH3 O2 chemistry P2O5 H2O

(ii) PH3 3Cl2 chemistry PCl3 3HCl

(iii) PH3 4N2O chemistry H3PO4 4N2

(iv) 2PH3 3CuSO4 chemistry Cu3PO2 chemistry 3H2SO4

Detection of PH3 Black ppt.

(v) PH3 6AgNO3 chemistry [Ag3P .3AgNO3chemistry] 3HNO3

yellow ppt.

Ag3P . 3AgNO3 3H2O chemistry 6Agchemistry 3HNO3 H3PO3

Black ppt.

(vi) PH3 4HCHO HClchemistry [P(CH2OH)4] Cl -

white/colourless solid

which is used for making

fire-proof cotton fabrics

 

EXAMPLE OF DEHYDRATING REACTION OF P2O5

HClO3 P2O5 chemistry 2HPO3 Cl2O7

H2SO4 P2O5 chemistry 2HPO3 SO3

HNO3 P2O5 chemistry 2HPO3 N2O5

===============================================================================

GROUP VI - The p block elements, Chemistry, Class 12

GROUP VI

SULPHUR CHEMISTRY

Allotropes :

chemistry

(iii) g-Sulphur

Amorphous forms are

(i) Plastic sulphur

(ii) Milk of sulphur

(iii) Colloidal sulphur

chemistry

Viscosity of `S' with temperature

m.p. of `S' chemistry 112.8ºC

(i) > 112.8ºC to 160ºCchemistry slow decrease due to

S8 rings slip and roll over one another easily.

(ii) > 160ºC, increases sharply due to breaking of

S8 rings into chains and polymerises into large size chain.

(iii) 190ºC, again large chains are being broken into small chain.

* Milk of sulphur :

Powdered `S' Ca(OH)2 suspension chemistry Solution chemistry Milk of `S'

12 S 3Ca(OH)2 chemistry 2CaS5 CaS2O3 3H2O

2CaS5 CaS2O3 6HCl chemistry 3CaCl2 12 S 3H2O

* Colloidal Sulphur : Na2S2O3 2HCl chemistry 2NaCl H2O SO2 Schemistry

2H2S SO2 chemistry 3S chemistry 2H2O

Props. of `S'

(a) Thin Cu-strip catches fire in sulphur vapour.

Cu S chemistry CuS.

(b) `S' burns spontaneously in fluorine. S 3F2 chemistry SF6

Cl2 passed into liq. sulphur 2 S Cl2 chemistry S2Cl2

(c) S 2H2SO4 chemistry 3SO2 2H2O

S 2HNO3 chemistry H2SO4 2NO

(d) 4 S 6 KOH chemistry 2K2S K2S2O3 3H2O

(e) Burns in air : S O2 chemistry SO2

H2S :

Prepn :

FeS dil. H2SO4 chemistry FeSO4 H2S

FeS dil. HCl chemistry FeCl2 H2S

Sb2S3 (conc.) 6HCl chemistry 2SbCl3 3H2S

Drying agent for this gas : fused CaCl2, Al2O3 (dehydrated)

P2O5 etc. But not H2SO4, because

H2SO4 H2Schemistry 2H2O SO2 S

Reducing property of H2S :

Cl2 H2S chemistry 2HCl S

I2 H2S chemistry 2HI S

H2O2 H2S chemistry 2H2O S

SO2 2H2S chemistry 2H2O 3 S

2FeCl3 H2S chemistry 2FeCl2 2HCl S

4H2O 4Cl2 H2S chemistry H2SO4 8HCl

KMnO4 H2S H2SO4 chemistry S Mn2

H2Cr2O7 H2S H2SO4 chemistry Cr3 S

HNO3 H2S chemistry S NO2 H2O

With metal (hot)

2Na H2S chemistry Na2S H2

Cu H2S chemistry CuS H2

Pb H2S chemistry PbS H2

With metal oxide (hot)

CaO H2S chemistry CaS H2O

ZnO H2S chemistry ZnS H2O

Metal ion H2S chemistry M-Sulphides

(i) Alkali-sulphide chemistry water soluble

(ii) Alkaline earth - sulphide chemistry sparingly soluble

(iii) Al2S3 & Cr2S3 6H2O chemistry Al(OH)3 or Cr(OH)3 3H2S

Test :

(i) Smell chemistry rotten egg.

(ii) Pb- Acetate paper - black

(iii) Purple colour when alk. Nitropruside H2S

Absorbent :

NaOH , KOH , PbNO3 solution

Pb(NO3)2 H2S chemistry 2HNO3 PbS (Black)

 

SO2

Prep :

Industrial :

4FeS2 11O2 chemistry 2Fe2O3 8SO2

2ZnS 3O2 chemistry 2ZnO 2SO2

Lab prepn :

Cu 2H2SO4 (conc.) chemistry CuSO4 2H2O SO2

Hg H2SO4 chemistry HgSO4 H2O SO2

2Ag H2SO4 chemistry Ag2SO4 H2O SO2

S 2H2SO4 chemistry 3SO2 2H2O

(Charcoal) C 2H2SO4 chemistry CO2 2SO2 2H2O

NaHSO3 H2SO4 chemistry NaHSO4 H2O SO2

Props :

(i) Incombustible gas, but heated K burns in SO2

4K 3SO2 chemistry K2SO3 K2S2O3

chemistry

Reducing Prop.: (Revise from acid radical)

chemistry

4FeCl2 SO2 4HCl chemistry 4FeCl3 H2O S

6SnCl2 2SO2 8HCl chemistry 5SnCl4 4H2O SnS2 (Yellow solid)

(ii) SO2 2H2SO3 chemistry 2H2SO4 S

FeSO4 chemistry Fe2O3 SO2 SO3

Fe2(SO4)3 chemistry Fe2O3 3SO3

H2SO4 & SO3 :

chemistry

H2SO4 2PCl5 chemistry ........chemistry SO2Cl2 2POCl3 2HCl

chemistry

Use of H2SO4 as nitrating mixture : good chlorinating agent

** P2O5 is stronger dehydrating agent than H2SO4 : H2SO4 P2O5 chemistry 2HPO3 SO3

Properties of H2SO4 :

(a) Dissociation : At 444ºC. H2SO4 chemistry H2O SO3

(b) Acidic nature : NaOH H2SO4 H2O chemistry Na2SO4 H2O

(c) CO32- H2SO4 chemistry SO42- H2O CO2

HCO3 H2SO4 chemistry H3SO4- H2O CO2

 

(d) Zn / Fe H2SO4 chemistry ZnSO4 & FeSO4 H2

where as

Cu 2H2SO4 chemistry CuSO4 SO2 2H2O

2Ag 2H2SO4 chemistry Ag2SO4 SO2 2H2O

Hg 2H2SO4 chemistry HgSO4 SO2 2H2O

(e) chemistry

(f) Oxidising Prop. :

HBr / HI H2SO4 chemistry I2/Cl2 SO2 H2O

C 2H2SO4 chemistry CO2 2SO2 2H2O

S 2H2SO4 chemistry 3SO2 2H2O

2P 5H2SO4 chemistry H3PO4 5SO2

(g) Dehydrating agent :

chemistry


 

C6H12O6 chemistry 6 C

(COOH)2 chemistry CO CO2 PhH chemistry Ph - SO3H

HCO2H chemistry CO

SODIUM THIOSULPHATE

Propn". :

(i) Na2SO3soln S (powder) chemistry Na2S2O3 chemistry Na2S2O3.5H2 O, monoclinic crystal

chemistry

(ii) chemistry

(iii) 2Na2S Na2CO3 4SO2 chemistry 3Na2S2O3 CO2

(iv) 6NaOH 4S chemistry Na2S2O3 2Na2S 3H2O

3Ca(OH)2 12 S chemistry CaS2O3 3H2O 2CaS5

(v) Na2SO3 Na2S I2 chemistry Na2S2O3 2NaI

(vi) 2Na2S 2O2 H2O chemistry Na2S2O3 2NaOH [Na2S is readily oxidised in air giving rise to Na2S2O3]

Props : (i) 4Na2S2O3 chemistry Na2S5 3Na2SO4

(ii) Na2S2O3 2H chemistry H2S2O3 chemistry H2O SO2 S (White turbidity)

Reaction :

(i) Na2S2O3 I2 chemistry S4O62- 2I-

Cl2 - water chemistry SO42- S 2HCl

Br2 - water chemistry SO42- S 2HBr

4OI- 2OH- chemistry 2SO42- 4I- H2O

4Cl2 5H2O chemistry Na2SO4 8HCl H2SO4

(excess)

OZONE

chemistry Unstable deep blue, diamagnetic gas, with fishy smell. Toxic enough (more toxic than KCN). It's intense blue colour is due to the absorption of red light.

chemistry chemistry

chemistry Oxidising property of O3

It is one of best oxidising agent in acid solution. Its standard reduction potential value is 2.07 V.

O3 2H 2echemistry O2 H2O Eº = 2.07 V

It is next to F2. [above 2.07 V, only F2, F2O are there ]

(i) Metal Sulphides to Sulphates.

MS 4O3 chemistry MSO4 4O2 [M = Pb, Cu, Zn, Cd]

(ii) 2HX O3 chemistry X2 H2O O2 [X = Cl, Br, I]

(iii) NaNO2 O3 chemistry NaNO3 O2

Na2SO3 O3 chemistry Na2SO4 O2

Na2AsO3 O3 chemistry Na2AsO4 O2

(iv) Moist S, P, As O3 chemistry

S H2O 3O3 chemistry H2SO4 3O2

2P 3H2O 5O3 chemistry 2H3PO4 5O2

2As 3H2O 5O3 chemistry 2H3AsO4 5O2

(v) Moist I2 chemistry HIO3 whereas dry iodine chemistry I4O9 (yellow)

I2 5O3 H2O chemistry 2HIO3 5O2

2I2 9O3 chemistry I4O9 9O2

(vi) 2K2MnO4 O3 H2O chemistry 2KMnO4 2KOH O2

2K4[Fe(CN)6] O3 H2O chemistry 2K3[Fe(CN)6] 2KOH O2

2FeSO4 O3 H2SO4 chemistry Fe2(SO4)3 O2 H2O

(vii)(a) 2KI (acidified) O3 2HCl chemistry I2 2KCl H2O O2

(b) chemistry

(c) alk.chemistry

(viii) Hg loses its fluidity (tailing of Hg)

2Hg O3 chemistry Hg2O O2

similarly 2Ag O3 chemistry Ag2O O2

Brown

(ix) BaO2 O3 chemistry BaO 2O2

H2O2 O3 chemistry H2O 2O2

Na2O2 O3 H2O chemistry 2NaOH 2O2

(x) 2KOH 5O3 chemistry 2KO3 5O2 H2O

In all above reaction O3 gives up O2 but some reactions are there which consumes all O-atom

(i) 3SO2 O2 chemistry 3SO3

(ii) 3SnCl2 6HCl O3 chemistry 3SnCl4 3H2O

Absorbent :

(i) Turpentine oil

(ii) Oil of cinnamon

test :

(i) Sterilising water

(ii) Detection of position of the double bond in the unsaturated compound.

H2O2

Method preparation :

(i) Na2O2 H2O (ice cold water) chemistry 2NaOH H2O2

(ii) BaO2 H2SO4 chemistry BaSO4 H2O2

Instead of H2SO4, H3PO4 is added now -a - days because H2SO4 catalyses the decomposition of H2O2 whereas H3PO4 favours to restore it.

3BaO2 2H3PO4 chemistry Ba3(PO4)2 3H2O2 and Ba3(PO4)2 3H2SO4 chemistry 3BaSO4 2H3PO4 (reused again)

(iii) Electrolysis of 50% H2SO4 using high current density.

2H2SO4 chemistry 2H 2H2SO4-

2H2SO4- chemistry H2S2O8 2e. [At anode] [At cathode 2H 2e chemistry H2]

H2S2O8 2H2Ochemistry 2H2SO4 H2O2

(iv) chemistry

Properties :

(i) Colourless, odourless liquid (b.p. 152º)

(ii) Acidic nature :

H2O2 2NaOH chemistry Na2O2 H2O

H2O2 Ba(OH)2 chemistry BaO2 2H2O

H2O2 Na2CO3 chemistry Na2O2 CO2 H2O
 

(iii) It is oxidant as well as reductant.

H2O2 2H 2echemistry 2H2O [reaction in acidic medium]

H2O2 2e chemistry 2OH- [reaction in alkali medium]

Oxidising Properties :

(i) PbS 4H2O2 chemistry PbSO4 4H2O ( Used in washing of oil painting)

(ii) NaNO2 H2O2 chemistry NaNO3 H2O

Na2SO3 H2O2 chemistry Na2SO4 H2O

Na3AsO3 H2O2 chemistry Na3AsO4 H2O

2KI H2O2 chemistry 2KOH I2

H2S H2O2 chemistry S chemistry 2H2O

H2SO4 2FeSO4 H2O2 chemistry Fe2(SO4)3 2H2O

2K4[Fe(CN)6] H2O2 H2SO4 chemistry 2K3[Fe(CN)6] K2SO4 2H2O

2[Cr(OH)4]- 3H2O2 2OH- chemistry 2CrO42- 8H2O

CrO42- 2H H2O2 chemistry CrO5 (Blue)chemistry 3H2O

4CrO5 12H chemistry 4Cr 3 7O2 6H2O

Mn 2 OH- H2O2 chemistry MnO2 2H2Ochemistry This reaction can be utilised to detect NH3

Reducing properties :

(a) Ag2O H2O2 chemistry 2Ag H2O O2

(b) O3 H2O2 chemistry H2O 2O2

(c) MnO2 H2O2 H2SO4 chemistry MnSO4 2H2O O2

(d) PbO2 H2O2 chemistry PbO H2O O2

(e) Pb3O4 4HNO3 chemistry 2Pb(NO3)2 PbO2 2H2O

PbO2 H2O2 chemistry PbO H2O O2

PbO 2HNO3 chemistry Pb(NO3)2 H2O

Pb3O4 H2O2 6HNO3 chemistry 3Pb(NO3)2 4H2O O2

(f) X2 H2O2 chemistry 2HX O2 [X = Cl, Br]

2KMnO4 3H2O chemistry 2KOH 2MnO2 2H2O 3O2

2MnO4- 2OH- chemistry 2MnO42- H2O O

2MnO42- 2H2O chemistry 2MnO2 4OH- 2O

2MnO4- H2O chemistry 2MnO2 2OH- 3O

(g) 2KMnO4 5H2O2 3H2SO4 chemistry 2MnSO4 K2SO4 5O2 8H2O

(h) 2[Fe(CN)6]3- 2OH- H2O2 chemistry 2[Fe(CN)6]4- 2H2O O2

(i) NaOCl H2O2 chemistry NaCl H2O O2

(j) NaIO4 H2O2 chemistry NaIO3 H2O O2

Uses :

(i) As a rocket propellant :

NH2.NH2 2H2O2 chemistry N2 4H2O [highly exothemic and large increase in volume]

(ii) In detection of Cr 3, Ti 4 etc.

Ti(SO4)2 H2O2 2H2O chemistry H2TiO4 2H2SO4

Yellow or orange

Pertitanic acid

================================================================

GROUP - VII - The p block elements, Chemistry, Class 12

GROUP - VII

HALOGENS

Method of Prep" :

F2 : By electrolysis of KHF2 (which is obtained from CaF2)

CaF2 H2SO4 chemistry CaSO4 2HF

HF KF chemistry KHF2

KHF2 chemistry H2(at cathode) F2 (at anode)

Cl2 :

(i) By electrolysis of aq. NaCl

2NaCl 2H2O chemistry chemistry

(ii) 2NaCl chemistry 2Na Cl2

(Molten) (cathode) (anode)

(iii) In laboratory : Oxidising HCl by KMnO4 or MnO2

2KMnO4 16HCl chemistry 2KCl 2MnCl2 5Cl2 8H2O

MnO2 4HCl chemistry MnCl2 Cl2 2H2O

Br2 : From Bromine water (contains 65 ppm of Br-)

Cl2 2Br- chemistry 2Cl- Br2 (Br2 is volatite in nature

Hence it is collected by

(i) removal of Br2 vapour by stream of air.

(ii) absorbing it into Na2CO3 solution.

Br2 6OH- chemistry Br- BrO3- 3H2O

Then acidified to get pure Br2

5 Br- BrO3- 6H chemistry 3Br2 3H2O

I2 : Chille salt petre contains traces ofNaIO3 which is reduced to I- by NaHSO3, then oxidation of I- to I2 by IO3- .

2IO3- 6HSO3- chemistry 2I- 6SO42- 6H

5I- IO3- chemistry 3I2 3H2O

Q. Liquid I2 conducts electricity. Explain

Ans. Due to its self ionisation 3I2 chemistry I3 I3-

Q. X2 OH- chemistry X- OX- H2O but on acidification the disproportionated product gives

chemistry X- XO3- H2O back the same element.

X2 = Cl2, Br2, I2 But For F2 i.e. X- OX- 2H chemistry X2 H2O

5X- XO-3 6H chemistry 3X2 2H2O

2F2 2NaOH chemistry 2NaF F2O H2O X = Cl, Br, I

 

F2O 2NaOH chemistry 2NaF O2 H2O

---------------------------------------

2F2 4NaOH chemistry 4NaF O2 2H2O

HALOGEN ACID :

Acidity order : HI > HBr > HCl >> HF. (due to hydrogen bonding & less effective overlap with H atom)

Q. CaF2 used in HF prepn must be free from SiO2. Explain

Ans. CaF2 H2SO4 chemistry CaSO4 HF

If SiO2 present as impurity

chemistry

Q. HF can not be stored in glass vessel. Explain.(same reason.)

Q. In the salt-cake method of prepn. of HCl, NH4Cl is being used instead of NaCl. Explain.

Ans. NaCl H2SO4 chemistry NaHSO4 HCl

Insoluble

NaCl NaHSO4 chemistry Na2SO4 HCl

(Salt Cake)

2NH4Cl H2SO4 chemistry 2HCl (NH4)2SO4

[NH4HSO4 intermediate is water soluble and easy to handle]

** Another altermative process to avoid the formation of NaHSO4

chemistry

Q. In the similar type of preparation of HBr and HI from bromide and iodide, H2SO4 can not be used and H3PO4 is used. Explain.

Ans. Since H2SO4 is an oxidising agent it oxidises HBr & HI to Br2 and I2 respectively.

2HBr H2SO4 chemistry Br2 SO2 2H2O

Hence, NaBr H3PO4 chemistry NaH2PO4 3HBr

Another process ; PBr3 3H2O chemistry H3PO4 3HBr

Q. Boiling point order HX : HF > HI > HBr > HCl

chemistry

Due to H-bonding

Q. HCl, H2SO4, HNO3 are bases in liquid HF where as HClO4 is acid. Comment.

Ans. HCl HF chemistry H2Cl F- ; H2SO4 HF chemistry H3SO4 F-; HNO3 HF chemistry H2NO3 P-

But HClO4 HF chemistry H2F ClO4-

* HF is weak acid but addition of BF3, AsF5, PF5, SbF5 makes it strongly acidic. Explain

OXOACIDS :

HOF : H2O F2 chemistry HOF HF

 

HOX : very unstable becuase

it reacts with both H2O

and F2 as follows :

chemistry

OX- disproportionates in hot solution eg. 3OCl- chemistry 2Cl- ClO3-

X = Cl, Br, I

Bleaching Powder : chemistry

Prepn. : Cl2(g) Ca(OH)2 chemistry Ca(OCl)Cl H2O

Slaked lime

(a) On long standing it undergoes

(i) auto oxiation 6Ca(OCl)Cl chemistry Ca(ClO3)2 5CaCl2

(ii) 2Ca(OCl)Cl chemistry 2CaCl2 O2

(iii) Ca(OCl)Cl H2O chemistry Ca(OH)2 Cl2

Oxidising Prop :

CaOCl2 H2S chemistry S CaCl2 H2O

CaOCl2 2FeSO4 H2SO4 chemistry Fe2(SO4) 3 CaCl2 H2O

CaOCl2 KNO2 chemistry CaCl2 KNO3

3CaOCl2 2NH3 chemistry 3CaCl2 3H2O N2

CaOCl2 2KI 2HCl chemistry CaCl2 2KCl H2O I2

CaOCl2 2KI 2AcOH chemistry CaCl2 2KOAc H2O I2

CaOCl2 Na3AsO3 chemistry Na3AsO4 CaCl2

Reaction with acid :

CaOCl2 2HCl chemistry CaCl2 H2O Cl2 ; Ca(OCl)Cl H2SO4 chemistry CaSO4 H2O C

Ca(OCl)Cl CO2 chemistry CaCO3 Cl2

HXO2 :

BaO2 2ClO2 chemistry Ba(ClO2)2 O2, Ba(ClO2)2 H2SO4 chemistry BaSO4 chemistry HClO2

(dil)

Only Known HClO2. It is stable in alkaline solution but disproportionates in acid solution.

5HClO2 chemistry 4ClO2 HCl 2H2O

HXO3 : HClO3 > HBrO3 > HIO3 are known and acidic order is as shown

Prepn:

HClO3 : Cl2 6NaOH chemistry 5NaCl NaClO3 3H2O

Similarly electrolysis of hot halide solution with severe stirring gives the same product.

2Cl- 2H2O chemistry Cl2 2OH- H2


 

 

Cl2 6NaOH chemistry 5NaCl NaClO3 3H2O chemistry

 

Properties :

* 3HClO3 chemistry 2ClO2 H2O HClO4

* IO3- 5I- 6H chemistry 3I2 3H2O

ClO3- 3SO32- chemistry Cl- 3SO42-

Disproportionation : 4KClO3 chemistry KCl 3KClO4

2KClO3 chemistry 2KCl 3O2

HXO4 : NaClO3 H2O chemistry NaClO4 H2

KClO4 H2SO4 (conc.) chemistry HClO4 KHSO4

Electrode reaction chemistry

Props : K HClO4 chemistry KClO4(¯) H

Zn 2HClO4 chemistryZn(ClO4)2 H2

Fe 2HClO4 chemistry Fe(ClO4)2 H2

Acidity order : HOX < HXO2 < HXO3 < HXO4

Oxidising power : HOX > HXO2 > HXO3 > HXO4

Thermal stability : HOX < HXO2 < HXO3 < HXO4

 

OXIDES OF CHILORINE

1 4 6 7

Cl2O ClO2 Cl2O6 Cl2O7

(Brownish yellow) (Pale yelloow) (liq. - dark red colourless

solid - yellow) solid

Prepn :

Cl2 does not combine directly to produce its oxides but indirect methods are there.

Cl2O : 2Cl2 2HgO(s) chemistry HgO. HgCl2 Cl2O (Brownish yellow gas)

dry in cooled tube Basic Hg(II) chloride ¯

Condensed to oragne liq.

Props :

It dissolves in water : Cl2O H2O chemistry 2HClO

Explodes violently with NH3.

3Cl2O 10 NH3 → 2N2 6NH4Cl 3H2O

It is oxidising agent

Cl2O 2HCl chemistry 2Cl2 H2O

Structures : chemistry

ClO2 : Prepn :

3KClO3 3H2SO4 chemistry 3KHSO4 HClO4 2ClO2 chemistry H2O

(powder) conc. Pale yellow gas

2HClO3 H2C2O4 chemistry 2H2O 2ClO2 2CO2

2AgClO3 Cl2 chemistry 2AgCl 2ClO2 O2 [By this reaction pure ClO2 obtained]

ClO2 dissolves in water ClO2 chemistry ClO O

producing dark green 2ClO H2O chemistry HCl HClO3

solution which decomposes

in presence of light.

but in alkali gives mixture of chlorite and chlorate.

2ClO2 2NaOH chemistry NaClO2 H2O

where 2ClO2 2NaOH H2O2 chemistry 2NaClO2 O2 2H2O

used in bleaching

textiles and paper.

ClO2 does not dimerise because odd es undergoes delocalisation (in its own vaccant 3d-orbital)

Cl2O4 (Cl.ClO4) is not the dimer of ClO2. Actually it is Cl-perchlorate.

CsClO4 ClOSO2F chemistry Cs(SO3)F ClOClO3

Cl2O6 : Possible structures are :

chemistry

liq chemistry dark red

Solid chemistry Yellow

Q. Prove that Cl2O6 is consisting ClO2 and ClO4-

Prepn : 2ClO2 2O3 chemistry Cl2O6 2O2

Cl2O6 chemistry2ClO3 (monomer is paramagnetic)

Reactions : Cl2O6 H2Ochemistry HClO3 HClO

Cl2O6 NaOH chemistry NaClO3 NaClO4 H2O

Cl2O6 HF chemistry ClO2F HClO4

Cl2O6 NO2 chemistry ClO2 [NO2] [ClO4]-

Cl2O7 (colourless solid) : It is the anhydride of HClO4 and prepared from it by the action P2O5.

2HClO4 P2O5 → 2HPO3 Cl2O7

 

Structure : chemistry

INTER HALOGEN

Types : AX AX3 AX5 AX7

ClF ClF3 ClF5 IF7

BrF BrF3 BrF5

BrCl (lCl3)2 IF5

ICl IF3(unstable)

IBr

IF (unstable)

* 5IF chemistry IF5 2I2 [The overall system gains B.E. by 250 kJ /mol]

* There are never more than two halogens in a moelcule.

* bonds are essentially covalent and b.p. increases as the E.N. difference increases.

* AX5 & AX7 type formed by large atoms like Br & I to accommodate mroe atoms around it.

* The interhalogens are genrally more reactive than the halogens (except F2) due to weaker A-X bonds compared to X - X bond.

Reactions : ICl H2O chemistry HCl HOI

BrF5 3H2O chemistry HBrO3 5HF

IF5 3H2O chemistry HBrO3 5HF

 

IF7 H2O chemistry IOF5 2HF (less)

4H2O chemistry HIO4 7HF

(i) ClF is hightly reactive and as a fluorinating agent.

6ClF 2Al chemistry 2AlF3 3Cl2

6ClF U chemistry UF6 3Cl2

6ClF S chemistry SF6 3Cl2

ClF SF4 chemistry SF5Cl

One pecularity with Cl :

chemistry

In IInd case, the attacking species is I which has been supported by the formation of I in fuse state as follows :

3ICl chemistry[I2Cl] [ICl2]-

* ICl3 does not exist

but its dimer exist. chemistry 2ICl3 chemistry I2Cl6

 

Structure is palnar.

chemistry

I2Cl6 : liq. has appreciable electrical conductivity like other interhalogens.

I2Cl6 chemistry [ICl2] [ICl4]-

BrF3 chemistry [BrF2] [BrF4]-

IF5 chemistry [IF4] [IF6]-

3ICl chemistry [I2Cl] [ICl2]-

Polyhalides :

(i) Ki I2 chemistry KI3

(ii) ICl KCl chemistry K [ICl2]-

(iii) ICl3 KCl chemistry K [ICl4]-

(iv) IF5 CsF chemistry Cs [IF6]-

(v) ICl KBr chemistry K [BrICl]-

Rb[ICl2] chemistry RbCl ICl [not RbI Cl2]

Here the products on heating depends on the lattice energy of the product halide. The lattice energy of alkali halide with smaller halogen is highest since the interatomic distance is least.

Structure of I5-, I-7, I8-2

chemistry

in [N(CH3)4] I7- in Cs2I8

* Only F3- not known [due to absence of d-orbital] [i.e. Cs2I3 - I2 - I3]

I3-, Br3-, Cl3- are known Cl3- compounds are very less.

Stability order : I3- > Br3- > Cl3- : depends upon the donating ability of X-.

PSEUDO HALOGEN

There are univalent ion consisting of two or more atoms of which at least one is N, that have property similar to those of the halide ions. E.g.

(i) Na-salts are soluble in water but Ag-salts are insoluble in water.

(ii) H-compounds are acids like HX.

(iii) some anions can be oxidised to give molecules X2.

 

Anions : Acids Dimer

CN- HCN (CN)2

SCN- HSCN(thiocyanic acid) (SCN)2

SeCN- (SeCN)2

OCN- HOCN (cyanic acid)

NCN2-(Bivalent) H2NCN(cyanamide)

ONC- HONC (Fulminic acid)

N3- HN3 (Hydrazoic acid)

CNchemistry shows maximum similarties with Cl-, Br-, I-

(i) froms HCN

(ii) forms (CN)2

(iii) AgCN, Pb(CN)2, are insoluble

(iv) Inter pseudo halogen compounds ClCN, BrCN, ICN can be formed

(v) AgCN is insoluble in H2O but soluble in NH3

(vi) forms large no. of complex e.g. [Cu(CN)4]3- & [CuCl4]-3

[Co(CN)6]-3 & [CoCl6]-3

NOBLE GASES

* I.E. order : He > Ne > Ar > Kr > Xe > Rn

* M.P. order : He < Ne < Ar < Kr < Xe < Rn

chemistry

* B.P. order : (-269ºC) same

* Atomic radius order : Same

* Density order : Same

* Relative abundance : Ar is highest (Ne, Kr, He, Rn)

"He" (helium) has the lowest b.p (-269ºC) of any liquid (lowest of any substance)

(i) It is used in cryoscopy to obtain the very low temperature required for superconductor and laser.

(ii) It is used in airships though H2 is cheaper and has lower density compared to He because H is highly inflammable.

(iii) He is used in preference to N2 to dil. O2 in the gas cylinders used by divers. This is because N2 is quite soluble in blood, so a sudden change in pressure causes degassing and gives bubbles of N2 in the blood. This causes the painful condition called bends.

He is slightly soluble so the risk of bends is reduced.

* Noble gases are all able to diffuse through glass, rubber, plastics and some metals

* He liquid can exist in two forms . I-form when changes to II-form at l-point temperature many physical properties change abruptly.

e.g.

(i) Sp. heat changes by a factor of 10

(ii) Thermal conductivity increases by 106 and it becomes 800 times faster than Cu

(iii) It shows zero resistance

(iv) It can flow up the sides of the vessel

 

* Ar, Kr, Xe can form clathrate compounds but He, Ne cannot due to their smaller size.

What is noble gas hydrate ?

e.g. Xe . 6H2O formed only when

Ar . 6H2O water freezes at high

Kr. 6H2O pressure together with noble gas

===============================================================

Structure of Xenon Fluorides - The p-block Elements, CBSE, Class 12, Chemistry

Xenon Fluorides :-

(1) Xe F2 chemistry

(2) H2 reduces Xe - fluorides to Xe

XeF2 H2 chemistry Xe 2HF and so on

(3) Xe - fluorides oxidise Cl- to Cl2 and I- to I2

XeF2 2HCl chemistry 2HF Xe Cl2

XeF4 4KI chemistry 4KF Xe 2I2

(4) Hydrolysis

XeF2 reacts slowly with water

2XeF2 2H2O chemistry 2Xe 4HF O2

XeF4 and XeF6 react violently with water giving XeO3

3XeF4 6H2O chemistry 2Xe XeO2 12HF chemistry

XeF6 2H2O chemistry XeO3 6HF

chemistry

(explosive, white hygroscopic solid)

(5) SiO2 also converts XeF6 into XeOF4

2XeF6 SiO2 chemistry SiF4 2XeOF4

violet

Similary, XeO3 XeOF4 chemistry 2XeO2F2 , XeO3 2XeF6 chemistry 3XeOF4

(6) Xe - fluorides are also hydrolysed in alkaline medium.

2XeF2 4OH- chemistry 2Xe 4F- 2H2O O2

XeF6 7OH- chemistry HXeO4- 3H2O 6F-

Xenate ion

2HXeO4- 2OH- chemistry XeO64-¯ Xe 2H2O O2

(7) They are used as fluorinating agent

2SF4 XeF4 chemistry 2SF6 Xe

Pt XeF4 chemistry PtF4 Xe

(8) Act as a fluoride donor

XeF2 MF5 chemistry [XeF] [MF6]- (M = As, Sb, P)

XeF6 BF3 chemistry [XeF5] [BF4-]

XeF6 HF chemistry [XeF5] [HF2]-

(9) Act as Flouride acceptor also :

XeF6 RbF /CsF chemistry Rb /Cs [XeF7]-

2Cs [XeF7]- chemistry XeF6 Cs2[XeF8]

XeF4 MF chemistry M XeF5-

(alkali metals fluoride)

The document P Block Elements, Class 12, Chemistry Detailed Chapter Notes is a part of Class 12 category.
All you need of Class 12 at this link: Class 12

FAQs on P Block Elements, Class 12, Chemistry Detailed Chapter Notes

1. What are P Block Elements in Chemistry?
Ans. P Block Elements in Chemistry are those elements in the periodic table that belong to group 13 to 18. They are called p-block elements because their valence electrons are in the p orbital. These elements play a crucial role in many chemical reactions and are essential for the survival of living organisms.
2. What are the properties of P Block Elements?
Ans. The properties of P Block Elements include the following: 1. They are non-metal, metalloids, and metals. 2. They have a high electronegativity. 3. They have a high ionization energy. 4. They have a small atomic radius. 5. They have a high melting and boiling point. 6. They have a low thermal and electrical conductivity.
3. What are the applications of P Block Elements?
Ans. P Block Elements have numerous applications in various fields. Some of the applications are: 1. Boron is used in the production of borosilicate glass, semiconductors, and fire retardants. 2. Carbon is used in the production of graphite, diamond, and fullerenes. 3. Nitrogen is used in the production of fertilizers, explosives, and ammonia. 4. Oxygen is used in the production of steel, welding, and breathing apparatus. 5. Silicon is used in the production of semiconductors, solar cells, and glass.
4. What are the trends in the physical and chemical properties of P Block Elements?
Ans. The trends in the physical and chemical properties of P Block Elements are as follows: 1. Atomic size increases down the group. 2. Electronegativity decreases down the group. 3. Ionization energy decreases down the group. 4. Metallic character increases down the group. 5. Reactivity with oxygen and halogens increases down the group.
5. What is the importance of P Block Elements in our daily life?
Ans. P Block Elements are essential for our daily life. Some of the importance of P Block Elements in our daily life are: 1. Boron is used in the production of borosilicate glass, which is used in laboratory equipment and kitchenware. 2. Carbon is used in the production of fuel, pencils, and jewelry. 3. Nitrogen is used in the production of fertilizers, which is used in agriculture. 4. Oxygen is essential for breathing and combustion. 5. Silicon is used in the production of computer chips, solar cells, and glass.
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