Applied Chemistry Textbook 2021 PDF

Summary

This textbook is on Applied Chemistry. It is designed for diploma engineering students and is based on the AICTE Model Curriculum. It provides a comprehensive explanation of the fundamental concepts of chemistry.

Full Transcript

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ISBN: 978-93-91505-44-8
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Book Code: DIP121EN reproduced, stored in a retrieval system or
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Applied Chemistry by Anju Rawlley, electronic, mechanical, photocopying,
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 ACKNOWLEDGEMENT

The author(s) are grateful to AICTE for their meticulous planning and execution to publish the
technical book for Diploma Engineering students.
We sincerely acknowledge the valuable contributions of the reviewer of the book Prof. Sunita
Mukesh Patil, for making it students’ friendly and giving a better shape in an artistic manner.
This book is an outcome of various suggestions of AICTE members, experts and authors who
shared their opinion and thoughts to further develop the engineering education in our country.
It is also with great honour that we state that this book is aligned to the AICTE Model
Curriculum and in line with the guidelines of National Education Policy (NEP) -2020. Towards
promoting education in regional languages, this book is being translated in scheduled Indian
regional languages.
Acknowledgements are due to the contributors and different workers in this field whose
published books, review articles, papers, photographs, footnotes, references and other valuable
information enriched us at the time of writing the book.
Finally, we like to express our sincere thanks to the publishing house, M/s. Khanna Book
Publishing Company Private Limited, New Delhi, whose entire team was always ready to
cooperate on all the aspects of publishing to make it a wonderful experience.

Anju Rawlley
Devdatta Vinayakrao Saraf

(v)
 Preface

Chemistry has been used for understanding and solving the intricacies of life. The advancement
in chemistry is closely associated with the well being of all human beings and has made the life
simpler and comfortable.
The textbook on “Applied Chemistry” has been developed as per AICTE model curriculum.
This book is written, keeping in mind that basic concepts of chemistry should be comprehended in
depth by budding diploma engineers, as these concepts may be applied in many of the engineering
applications in industries and day to day life. The present text book is a sincere efforts in this
direction.
Efforts have been made to make this book useful and interesting for learning, in self-learning
mode. The structure of the textbook is comprehensive, wherein sixteen practical exercises are
integral part of each theory units, from one to five.
Key feature of the book is that the text is presented in a very simple way with illustrations,
examples, tables, flow charts, self-assessment questions with their solutions. Micro projects,
points/issues for the creative inquisitiveness and curiosity, know more, video links, case study
and summary points are integral part of different units to facilitate the students to develop the
attitude of scientific inquiry, investigate the cause and effect relationship, systematic, scientific
&logical thinking, ability to observe, analyse and interpret. All these abilities are essentially needed
by diploma engineering passouts in the world of work.
Details of practicals listed in the curriculum of each unit are mentioned in a systematic format
for ease of performance and implementation by students, laboratory personnel and teachers.
Laboratory practical format is comprising of practical significance, relevant theory, stepwise
procedure, safety precautions, sample probing questions for viva- voce etc. To meet the requirement
of outcome based education (OBE) and outcome based assessment (OBA), criterion referenced
testing (CRT) have been used as an integral part of assessment in each practical. For this, specific
and measurable criteria of process and product assessment with their percentage weightage is
included in each experiment. This would enable students, teachers and evaluators to know the
criterion of performance and assessment of each experiment for attainment of out comes.
While every care has been taken to bring out this textbook error free. Nevertheless, there
could inevitably be occasional errors. It would be our great pleasure to know from readers to make
necessary modifications. Moreover, suggestions are welcome for the improvement of the book.

Anju Rawlley
Devdatta Vinayakrao Saraf

(vii)
 OUTCOME BASED EDUCATION

Though, there are many challenges and issues in implementation and assessment of Outcome Based
Education (OBE) and Outcome Based Curriculum (OBC), but the management and teachers need
to ensure that the programme outcomes, as stated by NBA, for diploma engineering programme
should be developed by the students, at the exit point of the diploma programme,through effective
implementation and assessment of outcomes of different courses. The seven programme outcomes
of the diploma engineering programme are as follows:

PO1. Basic and Discipline Specific Knowledge: Apply knowledge of basic mathematics, science
and engineering fundamentals and engineering specialization to solve the engineering
problems.
PO2. Problem Analysis: Identify and analyse well-defined engineering problems using codified
standard methods.
PO3. Design/ Development of Solutions: Design solutions for well-defined technical problems
and assist with the design of systems components or processes to meet specified needs.
PO4. Engineering Tools, Experimentation and Testing: Apply modern engineering tools and
appropriate technique to conduct standard tests and measurements.
PO5. Engineering Practices for Society, Sustainability and Environment: Apply appropriate
technology in context of society, sustainability, environment and ethical practices.
PO6. Project Management: Use engineering management principles individually, as a team
member or a leader to manage projects and effectively communicate about well-defined
engineering activities.
PO7. Life-Long Learning: Ability to analyse individual needs and engage in updating in the context
of technological changes.

(ix)
 Course Outcomes

After completion of the course the students will be able to:

CO-1: Solve various engineering problems applying the basic concepts of atomic structure,
chemical bonding and solutions.

CO-2: Use relevant water treatment method to solve domestic and industrial problems.

CO-3: Solve the engineering problems using concepts of engineering materials and properties.

CO-4: Use relevant fuel and lubricants for domestic and industrial applications.

CO-5: Solve the engineering problems using concept of electrochemistry and corrosion.

Course Expected Mapping with Programme Outcomes
Outcomes (1-Weak Correlation; 2-Medium correlation; 3-Strong Correlation)
PO-1 PO-2 PO-3 PO-4 PO-5 PO-6 PO-7
CO-1 3 2 1 1 2 1 1
CO-2 3 3 2 3 2 3 2
CO-3 3 2 3 3 3 2 2
CO-4 3 3 2 3 3 2 2
CO-5 3 2 2 2 2 2 2

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 Abbreviations and Symbols

List of Abbreviations

Abbreviations Full form Abbreviations Full form
C.E. Chemical Equivalent TAN Total Acid Number
or Equivalent Weight
CO Course Outcome TEL Tetra Ethyl Lead
EDTA Ethylene Diamine UO Unit Outcome
Tetra Acetic acid
HCV Higher Calorific Value VII Viscosity Index
Improvers

LCV Lower Calorific Value VM Viscosity Modifiers
PO Programme Outcome Z or E.C.E. Electrochemical Equivalent
RCC Reinforced Cement
Concrete

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 List of Symbols

Symbols Description
n Principal Quantum Number
l Angular Momentum or Azimuthal Quantum Number
m Magnetic Quantum Number
ms Spin Quantum Number

Units Used
Abbreviations Full form
B.Th.U/ft3 British Thermal Units Per Cubic Foot
B.Th.U./lb British Thermal Units Per Pound
Cals/g Calories Per Gram
C.H.U./lb Centigrade Heat Unit Per Pound
0
Cl 0Clark
0
Fr 0French
K Kelvin
K cals / kg Kilocalories Per Kilogram
Kcal/m
3
Kilocalories Per Cubic Meter
mg / L Milligrams Per Litre
meq / L Milliequivalent Per Litre
ppm Parts Per Million
ppt Precipitate

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 List of Figures

Unit 1
Figure Nos Titles of Figures Page.Nos.
Fig. 1.1 Rutherford Experiment 3
Fig. 1.1(a) Gold Foil Experimention 3
Fig. 1.1 (b) Scattering of α-Rays through an Atom 3

Fig. 1.2 Bohr’s Representation of Forces acting on Electrons and Orbits in an Atom 4
Fig. 1.2 (a) Electrostatic Force of Attraction between Proton and 4
Electron Exactly equal to the Centrifugal Force
Fig. 1.2 (b) Structure of Bohr’s Atom 4
Fig. 1.3 Jumping of an Electron after Absorbing and Emitting the Energy 5
Fig. 1.3 (a) Electron absorb Energy & Jump to Higher Energy Level 5
Fig. 1.3 (b) Electron Emits Energy & Jump to Lower Shell 5
Fig. 1.4. Hydrogen Spectrum Lines due to Jumping of Electrons 6
Fig. 1.5 Shape of s-Orbitals 7
Fig. 1.6 Dumbbell Shape of p-Orbitals 8
Fig. 1.7 Double Dumbbell Shape of d-Orbitals 8
Fig. 1.8 Importance of Chemical Compounds in Daily Life 13
Fig. 1.9 Lewis Structure of Ammonia 14
Fig. 1.10 Electrovalent Bond/Ionic Bond Formation due to Transfer of Electrons 16
Fig. 1.11 Lewis Dot Structure 18
Fig. 1.12 Formation of Hydrogen Molecule 18
Fig. 1.13 Types of Covalent Bond 19
Fig. 1.14 Comparison of Electrovalent and Covalent Bonding 20
Fig. 1.15 Orbital overlap along the Axis 22
Fig. 1.16 Formation of H2 molecule (s-s Overlapping) 22
Fig. 1.17 Formation of F2 Molecule (p-p Overlapping) 22
Fig. 1.18 Formation of HF Molecule (s-p Overlapping) 22
Fig. 1.19 Orbital Overlap Sidewise 22
Fig. 1.20 Formation of sp Hybrid Orbitals and Shape of BF3 Molecule
2
23
Fig. 1.21 Formation of sp Hybrid Orbitals & Shape of Methane (CH4) Molecule
3
23
Fig. 1.22 sp3 Hybridisation - NH3 24

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Fig. 1.23 sp3 Hybridisation-H2O 24
Fig. 1.24 Co-ordinate Bonding in NH4+ 25
Fig. 1.25 Hydrogen Bonding in Water Molecule 26
Fig. 1.26 Inter molecular H Bonding 27
Fig. 1.27 Delocalised Electrons in Metallic Bond 29
Fig. 1.28 Solute-Solvent-Solution 31
Fig. 1.29 Concentration of Solution 31
Unit 2
Fig.2.1 Earths Water 50
Fig.2.2 Fresh Water 50
Fig.2.3 Surface Water 50
Fig.2.4 Sludge Formation 55
Fig. 2.5 Scale Formation 55
Fig. 2.6 Removal of Dissolved Oxygen by Heating 58
Fig. 2.7 Ethylene Diamine Tetra Acetic Acid (EDTA) 60
Fig. 2.8 Ca EDTA Complex
2+
60
Fig. 2.9 Intermittent Type Softener 64
Fig. 2.10 Continuous Type Softener 64
Fig. 2.11 Continuous Type Hot Soda lime softener 65
Fig. 2.12 Zeolite Softener 65
Fig. 2.13 Demineralization of Water 69
Fig. 2.14 Sand Filter 72
Fig. 2.15 Vertical Pressure Filter 73
Fig. 2.16 Chlorinator 74
Fig. 2.17 Ozonolysis Method 76
Unit 3
Fig. 3.1 Ore and Mineral 95
Fig. 3.2 An Ore 95
Fig. 3.3 Crushing and Grinding of Ore 96
Fig. 3.4 Gravity Separation 97
Fig. 3.5 Froth Flotation Process 97
Fig. 3.6 Magnetic Separation 97
Fig. 3.7 Alumino Thermic Process 100
Fig. 3.8 Electrolytic Refining of Copper 101

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Fig. 3.9 Reverberatory Furnace 102
Fig. 3.10 Blast Furnace 103
Fig. 3.11 Electrolysis of Bauxite 108
Fig. 3.12 Purification of Aluminium 108
Unit 4
Fig. 4.1 Structure of Graphite 149
Fig. 4.2 Thick Film Lubrication 151
Fig 4.3 Boundary Film Lubrication 151
Fig. 4.4 Viscosity 152
Unit 5
Fig. 5.1 Faraday’s Second Law of Electrolysis 179
Fig. 5.2 Extraction of Sodium 181
Fig. 5.3 Electroplating 182
Fig. 5.4 Electrolytic Refining of Copper 183
Fig. 5.5 Primary Cell 185
Fig. 5.6 Lead Acid Storage Cell 186
Fig. 5.7 Hydrogen Oxygen Fuel Cell 188
Fig. 5.8 Photovoltaic Solar Cell 189
Fig. 5.9 Corrosion by Oxygen 191
Fig. 5.10 Wet or Electrochemical Corrosion 192
Fig. 5.11 Oxygen Absorption Type 193
Fig. 5.12 Sacrificial Anodic Protection Method 198
Fig. 5.13 Galvanizing (Zinc Coating on Iron) 199

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 List of Tables

Unit 1
Tables Nos Titles of Tables Page. Nos.
Table 1.1 Appearance of Hydrogen Spectrum in Different Region 6
Table 1.2 Magnetic Quantum Number 10
Table 1.3 Four Quantum Numbers for First 10 Electrons in [Ne] 10
Table 1.4 Pairing Arrangement of Electrons Permitted by Hund’s Rule 11
Table 1.5 Orbital Electronic Configuration of Elements up to Atomic No. 11 12
Table 1.6 Combining Capacity of Different Elements 13
Table 1.7 Types of Bonds 15
Table 1.8 Participation of Electrons in Covalent Bond Formation 19
Table 1.9 Properties and Comparison of Electrovalent and Covalent Compounds 20
Table 1.10 Types of Hybridisation 23
Table 1.11 Difference between Hydrogen Bond and Covalent Bond 28
Table 1.12 Difference between Metallic Bond and Ionic Bond 29
Unit 2
Table 2.1 Difference between Soft Water and Hard Water 51
Table 2.2 Relation between Various Units of Hardness 53
Table 2.3 Difference between Sludge and Scale 56
Table 2.4 Calculation of Alkalinity of water 62
Table 2.5 Comparison between the Zeolite Process & Soda-Lime Process 67
Table 2.6 Organoleptic and Physical Parameters for Drinking Water 77
Table 2.7 Bacteriological Quality of Drinking Water 78
Table 2.8 General Parameters Concerning Substances
Undesirable in Excessive Amounts 78
Unit 3
Table 3.1 Difference between Minerals and Ore 95
Table 3.2 Ores of Iron, Aluminium and Copper 95
Table 3.3 Composition, Properties and Uses of Some Alloys of Copper 110
Table 3.4 Composition, Properties and Uses of Some Alloys of Iron 110
Table 3.5 Composition, Properties and Uses of Some Alloys of Aluminium 111

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Table 3.6 Composition of Portland Cement 112
Table 3.7 Average Compound Composition of Portland Cement 112
Table 3.8 Composition of Glass 115
Table 3.9 Types of Glasses and their Uses 115
Table 3.10 Composition, Properties and Uses of Refractories 116
Table 3.11 Composite Classification Based on Types of Matrix & Reinforcement 117
Table 3.12 Polymerisation Reactions and their Uses 118
Table 3.13 Difference between Thermoplastics and Thermosetting Plastics 120
Table 3.14 Difference Between Natural Rubber and Vulcanised Rubber 121
Unit 4
Table 4.1 Classification of Fuels 139
Table 4.2 Higher Calorific Values of Fuel Constituents 140
Table 4.3 Octane Rating of some Common Hydrocarbon 143
Table 4.4 Composition, Calorific Values and Applications of Fuels 144
Table 4.5 Liquid Lubricants: Classification their Properties 147
Table 4.6 Classification and Properties of Semi Solid Lubricants 148
Unit 5
Table 5.1 Strong Electrolyte & Weak Electrolyte 178
Table 5.2 Difference between Electrolytic cell and Electrochemical Cell 187
Table 5.3 Difference between Dry/ Chemical and Wet/ Electrochemical Corrosion 194

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 Some Ionic Compounds (Electrovalent Compounds)

Sr.No Name Formula Ions present
1. Sodium Chloride NaCl Na+ and Cl–
2. Potassium Chloride KCl K+ and Cl–
3. Ammonium Chloride NH4Cl NH4+ and Cl–
4. Magnesium Chloride MgCl2 Mg2+ and Cl–
5. Calcium Chloride CaCl2 Ca2+ and Cl–
6. Sodium Oxide Na2O Na+ and O2–
7. Magnesium Oxide MgO Mg2+ and O2–
8. Calcium Oxide CaO Ca++ and O2–
9. Aluminium Oxide Al2O3 Al3+ and O2–
10. Sodium Hydroxide NaOH Na+ and OH–
11. Copper Sulphate CuSO4 Cu2+ and SO42–
12. Calcium Nitrate Ca(NO3)2 Ca2+ and NO3–
13. Aluminium Chloride AlCl3 Al3+ and Cl–

Some Covalent Compounds

Sr. No. Name Formula Present Atoms
1. Methane CH4 C and H
2. Ethane C2H6 C and H
3. Ethylene C2H4 C and H
4. Ethyne (Acetylene) C2H2 C and H
5. Water H2O H and O
6. Ammonia NH3 N and H
7. Ethyl Alcohol (Ethanol) C2H5OH C, H and O
8. Hydrogen Chloride Gas HCl H and Cl
9. Hydrogen Sulphide Gas H2S H and S
10. Carbon Dioxide CO2 C and O
11. Carbon Disulphide CS2 C and S
12. Carbon Tetrachloride CCl4 C and Cl
13. Glucose C6H12O6 C, H and O
14. Cane Sugar C12H22O11 C, H and O
15. Urea CO(NH2)2 C, O, N and H
16. Benzene C6H6 C and H
17. Hydrogen Gas H2 H
18. Chlorine Gas Cl2 Cl
19. Oxygen gas O2 O

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 Some Common Salts Present in Water
Sr.No Name Formula Ions present
1 Calcium Carbonate CaCO3 Ca2+ and CO32–
2 Magnesium Carbonate MgCO3 Mg2+ and CO32–
3 Calcium Bicarbonate Ca(HCO3)2 Ca2+ and HCO3–
4 Magnesium Bicarbonate Mg(HCO3)2 Mg2+ and HCO3–
5 Calcium Chloride CaCl2 Ca2+ and Cl–
6 Magnesium Chloride MgCl2 Mg2+ and Cl–
7 Calcium sulphate CaSO4 Ca2+ and SO42–
8 Magnesium sulphate MgSO4 Mg2+ and SO42–
9 Ferrous Chloride FeCl2 Fe2+ and Cl–
10 Ferrous Sulphate FeSO4 Fe2+ and SO42–
11 Manganese Chloride MnCl2 Mn2+ and Cl-
12 Manganese Sulphate MnSO4 Mn2+ and SO42–
13 Calcium Silicate CaSiO3 Ca2+, Si4+ and O2–
14 Magnesium Silicate MgSiO3 Mg2+, Si4+ and O2–
15 Sodium Carbonate Na2CO3 Na+ and CO32–
16 Sodium Sulphate Na2SO4 Na+ and SO42–
17 Potassium Chloride KCl K+ and Cl–
18 Potassium Carbonate K2CO3 K+ and CO32–
19 Potassium Sulphate K2SO4 K+ and SO42–
20 Calcium Hydrogen Phosphates CaHPO4 Ca2+, HPO42–

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 Guidelines for Teachers

To implement Outcome Based Education (OBE), knowledge level and skill set of the students should be
enhanced. Teachers should take a major responsibility for the proper implementation of OBE. Some of the
responsibilities (not limited to) for the teachers in OBE system may be as follows:
Within reasonable constraint, they should manoeuvre time to the best advantage of all students.
They should assess the students only upon certain defined criterion without considering any other
potential ineligibility to discriminate them.
They should try to grow the learning abilities of the students to a certain level before they leave the
institute.
They should try to ensure that all the students are equipped with the quality knowledge
as well as competence after they finish their education.
They should always encourage the students to develop their ultimate performance capabilities.
They should facilitate and encourage group work and team work to consolidate newer approach.
They should follow Blooms taxonomy in every part of the assessment.

Bloom’s Taxonomy

Teacher should Student should be Possible Mode of
Level
Check able to Assessment
Students ability to Design or Create Mini project
Creating
create
Students ability to Argue or Defend Assignment
Evaluating
Justify
Students ability to Differentiate or Project/Lab
Analysing
distinguish Distinguish Methodology
Students ability to Operate or Technical Presentation/
Applying
use information Demonstrate Demonstration
Students ability to Explain or Classify Presentation / Seminar
Understanding
explain the ideas
Students ability to Define or Recall Quiz
Remembering
recall (or remember)

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 Guidelines for Students

Students should take equal responsibility for implementing the OBE. Some of the responsibilities
(not limited to) for the students in OBE system are as follows :
Students should be well aware of each UO before the start of a unit in each and every course.
Students should be well aware of each CO before the start of the course.
Students should be well aware of each PO before the start of the programme.
Students should think critically and reasonably with proper reflection and action.
Learning of the students should be connected and integrated with practical and real life consequences.
Students should be well aware of their competency at every level of OBE.

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 CONTENTS

Foreword iii
Acknowledgement v
Preface vii
Outcome Based Education ix
Course Outcomes xi
Abbreviations and Symbols xii
List of Figures xiii
List of Tables xvi
Guidelines for Teachers xx
Guidelines for Students xxi

Unit 1: Atomic Structure, Chemical Bonding and Solutions 1-47
Unit Specifics 1
Rationale 2
Pre-requisites 2
Unit Outcomes 2
1.1 Atomic Structure 2
1.1.1 An Introduction 2
1.1.2 Rutherford Model of an Atom 3
1.1.3 Bohr’s Theory 3
1.1.4 Hydrogen Spectrum Explanation Based on Bohr’s Model of an Atom 5
1.1.5 Heisenberg’s Uncertainty Principle 7
1.1.6 Orbital Concept and Shapes of s, p, d and f Orbitals 7
1.1.7 Quantum Numbers 9
1.1.8 Pauli’s Exclusion Principle 10
1.1.9 Hund’s Rule of Maximum Multiplicity 11
1.1.10 Aufbau Rule 12
1.1.11 Electronic Configuration 12
1.2 Chemical Bonding 13

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 1.2.1 An Introduction, Concept &Causes 13
1.2.2 Types of Bonding 15
1.2.3 Ionic or Electrovalent Bond 15
1.2.4 Covalent bond (H2, F2, HF hybridization in BeCl2, BF3, CH4, NH3, H2O) 17
1.2.5 Coordinate bond 25
1.2.6 Hydrogen Bonding 26
1.2.7 Metallic Bonding 28
1.3 Solution 30
1.3.1 An Introduction 30
1.3.2 The idea of Solute, Solvent, and Solution 30
1.3.3 Methods to Express the Concentration of Solution 31
Solved Problems 32
Unit Summary 34
Exercises 36
Practicals 36-44
Know More 44
References and Suggested Readings 47

Unit 2 : Water 48-92
Unit Specifics 48
Rationale 48
Pre-requisites 49
Unit Outcomes 49
2.1 An Introduction 49
2.1.1 Graphical presentation of Water Distribution on Earth 50
2.1.2 Classification of Soft and Hard Water 50
2.1.3 Salts Causing Water Hardness 50
2.1.4 Unit of Hardness 52
2.2 Causes of Hard Water 53
2.2.1 Cause of Poor Lathering of Soap in Hard Water 53
2.2.2 Problems Caused by the Use of Hard Water in Boiler 54
2.2.3 Quantitative Determination of Water Hardness by ETDA Method 60
2.3 Water Softening Techniques 62
2.3.1 Water Softening Techniques –An Introduction 62
2.3.2 Soda Lime Process 63
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 2.3.3 Zeolite Process 65
2.3.4 Ion Exchange Process for Water Softening 68
2.4 Municipal Water Treatment 71
2.4.1 Municipal Water Treatment- An Introduction 71
2.4.2 Screening 72
2.4.3 Sedimentation 72
2.4.4 Coagulation 72
2.4.5 Filtration 72
2.4.6 Disinfection / Sterilization 73
2.5 Indian Standard Specification of Drinking Water – An Introduction 77
2.6 Water for Human Consumption 79
Solved Problems 80
Unit Summary 82
Exercises 83
Practicals 83-91
Know More 91
References and Suggested Readings 92

Unit 3 : Engineering Materials 93-136
Unit Specifics 93
Rationale 93
Pre-requisites 93
Unit Outcomes 94
3.1 Introduction to Natural Occurrence of Metals 94
3.1.1 Minerals and Ores 94
3.1.2 General Principles of Metallurgy 96
3.1.3 Extraction of Iron from Haematite ore 102
3.1.4 Extraction of Aluminium from Bauxite 106
3.1.5 Alloys 109
3.2 General Chemical Composition, Composition Based Applications 111
3.2.1 Portland Cement 112
3.2.2 Glasses 114
3.2.3 Refractory 116
3.2.4 Composite Materials 116

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 3.3 Polymers 117
3.3.1 Preparation of Thermoplastics and Thermosetting Plastics 118
3.3.2 Rubber 120
3.3.3 Vulcanization of Rubber 120
Unit Summary 121
Exercises 122
Practicals 123-135
Know More 136
References and Suggested Readings 136

Unit 4 : Chemistry of Fuels and Lubricants 137 -174
Unit Specifics 137
Rationale 137
Pre-requisites 138
Unit Outcomes 138
4.1 Fuel and Combustion of Fuel- An Introduction 138
4.1.1 Fuel and Combustion 138
4.1.2 Classification of Fuels 139
4.1.3 Calorific Values (HCV and LCV) 139
4.1.4 Calculation of HCV and LCV using Dulong’s formula. 140
4.2 Analysis of Coal 141
4.2.1 Proximate Analysis of Coal (Solid Fuel) 141
4.2.2 Fuel rating of Petrol and Diesel (Octane and Cetane Numbers) 142
4.2.3 Chemical Composition, Calorific Values and Applications of Fuel 144
4.3 Lubrication – An Introduction 145
4.4 Functions of Lubricant 145
4.5 Characteristic Properties of Good Lubricant 146
4.6 Classification of Lubricants 146
4.6.1 Liquid Lubricants, Classification and Properties 146
4.6.2 Semi-solid Lubricants, Classification and Properties 148
4.6.3 Solid Lubricants, Classification and Properties 148
4.6.4 Emulsion 150
4.7 Mechanism of Lubrication 151
4.8 Physical Properties of Lubricant 152

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 4.8.1 Viscosity 152
4.8.2 Viscosity Index 152
4.8.3 Oiliness 153
4.8.4 Flash Point and Fire Point 153
4.8.5 Cloud Point and Pour Point 154
4.9 Chemical Properties of Lubricants. 154
4.9.1 Coke Number or Carbon Residue 154
4.9.2 Total Acid Number (TAN) 155
4.9.3 Saponification Value (SV) or Saponification Number (SN) 156
Unit Summary 156
Exercises 157
Practicals 158-173
Know More 174
References and Suggested Readings 174

Unit 5 : Electro Chemistry 175–216
Unit Specifics 175
Rationale 175
Pre-requisites 176
Unit Outcomes 176
5.1 An Introduction 176
5.1.1 Electronic Concept of Oxidation-Reduction 176
5.2 Electrolytes and Non Electrolytes 178
5.2.1 Electrolytes 178
5.2.2 Non Electrolytes 179
5.2.3 Faradays Laws of Electrolysis 179
5.3 Industrial Application of Electrolysis 181
5.3.1 Electrometallurgy 181
5.3.2 Electroplating 182
5.3.3 Electrolytic refining. 183
5.4 Application of Redox Reactions in Electrochemical Cells 184
5.4.1 Primary cells – Dry cell 184
5.4.2 Secondary cell 185
5.4.2 (A) Lead Acid Storage Cell 185

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 5.4.2 (B) Fuel Cell 187
5.4.2 (C ) Solar Cells. 189
5.5 Corrosion – An Introduction 190
5.5.1 Dry or Chemical Corrosion 191
5.5.2 Wet or Electrochemical Corrosion 192
5.6 `Factors influencing Rate of corrosion. 194
5.6.1 Nature of Metals 194
5.6.2 Nature of Corroding Environment 195
5.7 Internal Corrosion Preventive Measures 196
5.7.1 Purification 196
5.7.2 Alloying 196
5.7.3 Heat Treatment 197
5.8 External Corrosion Preventive Measures 197
5.8.1 Cathodic Protection 197
5.8.2 Anodic Protection 198
5.8.3 Organic Inhibitors 199
Solved Problems 200
Unit Summary 201
Exercises 202
Practicals 202-215
Know More 215
References and Suggested Readings 216
Appendices 217-218
Appendix- A : Records for Practicals 217
Annexures 219-221
Annexure - I General, Specific Instructions and Common Laboratory Glasswares 219
References for further learning 222
CO-PO Attainment Table 223
Index 225-227

(xxviii)
 1 Atomic Structure, Chemical
Bonding and Solutions

UNIT SPECIFICS
This unit comprises of the following major topics :

Atomic structure

Chemical bonding

Solution
The different concepts have been explained through examples for generating further curiosity
and inquisitiveness and also developing creative problem solving abilities in the students, with the
mention of their practical applications in the industries/day to day life.
Assessment for learning at different intervals within the unit, at different levels of cognitive
domain is carried out by designing formative assessment questions.
For effective implementation of the outcome based curriculum in true spirit, wide spectrum
of activities such as micro projects, assignments, industrial visits etc, are designed and integrated
in the unit for the benefit and exposure of the students. Sample QR codes have been provided on
various topics/sub topics for supplementary reading and reinforcing the learning.

RATIONALE
Diploma engineers need to understand the arrangement of all existing elements, the structural
arrangement of fundamental particles, atoms and molecules. Theories put forward by different
scientists in the form of laws and principles have been explained for understanding the structure
of the atom.
The chemical bonds are important in human physiology. The proteins and carbohydrates
needed for our body are all result of chemical bonding between atoms. Oxygen we breathe,
medicines we need are result of chemical bonding between atoms. It helps to explain how atoms
are held together in different types of structures.
The knowledge of chemical bonding and solution is extremely important to chemists,
scientists, and every individual. Chemical bonding creates substances/compounds that everyone
uses. It helps scientists to design new engineering materials and form chemical compounds with
desirable properties for specific uses. Scientists could present 118 elements in the periodic table due
to chemical bonding. While considering the future scenario, students have to work in different areas
so as to comprehend the fundamental aspects such as bond formation and different anomalous
behaviour of atoms, ions and molecules.
2 | Applied Chemistry
PRE-REQUISITES
Chemistry : Composition of matter

Mathematics : Basic algebra and geometry

Other : Basic ICT skills

Unit Outcomes
List of outcomes of this unit are as follows :

U1-O1 Apply the different atomic theories, models and principles for structural illustration.

U1-O2 Write the electronic configuration of different elements.

U1-O3 Differentiate among the ionic, covalent and coordinate compounds based on the type of chemical
bonding.

U1-O4 Prepare the solution of given concentration (Normality, Molarity)

Unit - 1 Expected Mapping of Unit Outcomes with the Course Outcomes
Outcomes (1- Weak Correlation; 2- Medium Correlation; 3- Strong Correlation)
CO-1 CO-2 CO-3 CO-4 CO-5
U1-O1 3 - - - -
U1-O2 3 - - - -
U1-O3 3 - - - -
U1-O4 3 - - - -

1.1 ATOMIC STRUCTURE
1.1.1 An Introduction
An atom is the smallest part of the existing universe. To understand the structure and arrangement
of the smallest part of matter, thinkers and philosophers from all over the world put forward
different theories for explaining the smallest particle of matter. In this unit, we will be learning
about basic structure of atom, which is confirmed after performing different experiments.

Interesting fact : The structure of an atom explained by Bohr is just like our solar system
where the sun is at the centre and planets are revolving around it.
 Atomic Structure,Chemical Bonding and Solutions | 3

1.1.2 Rutherford Model of an Atom
In the early 1900, scientists from different countries tried to explain the structure of an atom. J.J.
Thomson discovered the presence of electron in an atom in 1897, still he was unable to predict
the structure of an atom. J.J Thomson won the Noble Prize of 1906 for the discovery of electrons.

Gold Foil

Screen of α-Particles
Zinc Sulphide
(ZnS)

Beam of a-Particle
Legend
Ra Radioactive Element Deflected Rays
Source of a-Particles 2He4 Undeflected Rays
Lead box
Scattered Rays

(a) Gold Foil Experiment (b) Scattering of α- Rays through an Atom

Fig. 1.1 : Rutherford Experiment

Rutherford discovered the presence of proton in his famous gold foil experiment.
Rutherford used Radium as a source of alpha particles which was placed inside the
lead box. A beam of alpha particles bombarded on an ultra-thin gold foil and then
the presence of undeflected, scattered and deflected alpha particles were recorded
Rutherford
over zinc sulphide (ZnS) screen due to its fluorescent nature as shown in [Fig. 1.1( a)]. Model of an
He concluded that all of the positive charge and the majority of the mass of the Atom

atom must be concentrated in a very small space in the centre of an atom, which he
called the nucleus.[Fig. 1.1(b)].
The nucleus is the dense, central core of the atom and is composed of protons and neutrons
which contribute nearly all of the mass of the atom. The electrons are distributed around the
nucleus and occupy most of the volume of the atom.

1.1.3 Bohr’s Theory
Bohr proposed his atomic model to overcome the drawbacks of Rutherford’s nuclear model.
Bohr’s atomic model is based on the following postulates.

An atom consists of a dense positively charged central part known as the
nucleus which is at rest.

The nucleus contains protons and neutrons combinedly called nucleons.

The fixed circular path in which electrons revolve around the nucleus is Bohr’s
known as orbits or shells. Model
4 | Applied Chemistry

Orbits/Shells/
Centrifugal Force n=4
Energy levels
acting on Electron n=3
Nucleus
Electrostatic n=2
P+N
Force of n=1
attraction
N M L K +
between
Electron and
Proton 2
Maximum
number of 8
Electrons 18
32
(a) Electrostatic Force of Attraction (b) Structure of Bohr’s Atom
between Proton and Electron Exactly
equal to the Centrifugal Force

Fig. 1.2 : Bohr’s Representation of Forces acting on Electrons and Orbits in an Atom

Stationary orbits or non-radiating orbits are those orbits in which electrons do not radiate
energy i.e. they are permitted to rotate without loss of energy.

Permitted shells or orbits are those for which the angular momentum of the electron is
an integral multiple of i.e. mvr =n , where n is a principal quantum number or

shell number, momentum is nothing but the product of mass and velocity (mv), r is
radius, h is Planks constant h = 6.626 x 10–34 J sec

Angular momentum of an electron for n=1, 2, 3, 4…are respectively as

mvr =1 , mvr =2 , mvr =3 , mvr = 4 …

The shape of orbit is circular. Orbits are designated by K, L, M, N…. or denoted as 1, 2,
3, 4…. from the nucleus as shown in [Fig. 1.2 (b)].

The maximum capacity to accommodate electrons is given by formula 2n2, where n is
orbit number.

The electrostatic force of attraction between the nucleus and electron is exactly balanced
by the centrifugal force as shown in [Fig. 1.2 (a)], that is why the electrons do not fall into
the nucleus or do not go away from the orbit and hence the atom remains stable.

*SAQ 1 The capacity of the shell to accommodate the maximum number of electrons is
given by the formula

1. 1/2n2 2. 2n2 3. 3/2n2 4. 4/2n2

Key : 2
 Atomic Structure,Chemical Bonding and Solutions | 5

SAQ 2 In the Rutherford experiment, the maximum number of undeflected particles
represent that
1. maximum 2. maximum 3. maximum 4. maximum
space of an number of number of positive number of
atom is empty nucleus present charge present negative charge
in an atom at the centre present at the
centre
Key : 1
SAQ 3 According to Bohr’s theory, the angular momentum of an electron for n = 4 is

1. 2. 3. 4.

Key : 4
(*SAQ denotes Self Assessment Question)
1.1.4 Hydrogen Spectrum Explanation Based on Bohr’s Model of an Atom

hv-(quanta)

Emitted
Energy

(a) : Electron Absorbs Energy & (b) : Electron Emits Energy &Jump to
Jump to Higher Energy Level Lower Energy Level
Fig. 1.3 : Jumping of an Electron after Absorbing and Emitting the Energy

When the electron absorbs energy, the electron moves from the lower energy level to a higher
energy level. Jumped electrons are known as excited electrons. As shown in [Fig. 1.3 (a)] when
an electron emits energy, electrons jump from a higher energy level to a lower energy level. The
emitted energy is the difference of energies between two energy levels i.e. hn=Energy of electron
present in higher energy level - Energy of electron present in lower energy level. Absorbed energy
or released energy is in the form of quanta or photon only. The excited electron cannot jump along
with high energy to lower energy orbitals.
There is a difference in energies when an electron jumps from a higher energy level to a lower
one. [Fig. 1.3 (b)]. When an electron emits energy it releases energy in the form of photons. i.e. E=
hn. Due to loss of energy, there is a development of spectral lines of different frequencies which
shows that distance between two different orbits is not equal.
As we move away from the nucleus, the energy of orbits goes on increasing, while the distance
between the orbits goes on decreasing. Jumping of the electron from one orbit to another orbit
6 | Applied Chemistry
results in the emission of energy known as the transition of the electron. Transition frequency
emitted in the form of the photon is given by

Where RH is Rydberg’s Constant, ni is initial stationary orbit, nf is final stationary orbit. The
wave numbers is reciprocal of the wavelength. Hence wave number of photons of the various
spectral series are developed as shown in table 1.1 and [Fig. 1.4]. Bohr theory successfully accounts
for the spectra of hydrogen and hydrogen like atoms like He+, Li2+, Be3+, B4+. Different spectrums
are developed due to transition of electron from higher energy level to lower energy level. e.g.
Lyman series is a spectral series for the transitions of electron from energy level 2 or 3 or 4 or… to
first energy level. Similarly other series are developed (table 1.1)
n=7
n=6
n=5 Humphreys series

n=4 Pfund series

Brackette series
n=3

Paschen series

n=2

Balmer series

n=1

Lyman series
Fig. 1.4.: Hydrogen Spectrum Lines due to Jumping of Electrons

Table 1.1 : Appearance of Hydrogen Spectrum in Different Region
Name of Series nf Electrons ≥ ni Electrons Appearing in Region
Jumping at Jumping from
Lyman Series 1 2, 3, 4 …. Ultraviolet region
Balmer Series 2 3, 4, 5, 6…. Visible region
Paschen Series 3 4, 5, 6, 7 … Infrared region
Brackette Series 4 5, 6, 7,.. Infrared region
Pfund Series 5 6, 7,... Infrared region
Humphreys Series 6 7,8,…. Infrared region
 Atomic Structure,Chemical Bonding and Solutions | 7

1.1.5 Heisenberg’s Uncertainty Principle
It is not possible to determine precisely the exact position and momentum of moving
electron simultaneously.

Suppose Dx is uncertainty related to the position of an electron and Dp is the uncertainty related
to the momentum of an electron.

Mathematically it is stated as(Dx).(Dp) ≥

when (Dx) is tremendously small we can predict the approximate position of the particle at the
same time Dp i.e. uncertainty related to momentum will be more. where Dx is the uncertainty in
position and Dp is the uncertainty in momentum (or velocity) of the particle. If the position of the
electron is known with high degree of accuracy (Dx is small), then the velocity of the electron will
be uncertain [Dp is large]. On the other hand, if the velocity of the electron is known precisely (Dp
is small), then the position of the electron will be uncertain(Dx will be large). Heisenberg won the
Noble prize in 1932 for the creation of quantum mechanics, the application of which has led to the
discovery of the allotropic forms of hydrogen.
SAQ 4 “It is not possible to determine precisely the exact position and momentum of
a small moving particle simultaneously “ is
1. Orbital 2. Aufbau 3. Pauli’s 4. Heisenberg’s
Concept Principle Exclusion Principle Uncertainty
Key: 4

1.1.6 Orbital Concept and Shapes of s, p, d and f Orbitals
An orbit, as proposed by Bohr, is a fixed circular path around the nucleus in which an electron
moves. A precise description of this path of the electron is impossible according to the Heisenberg
uncertainty principle.
An atomic orbital thus represents a region in three-dimensional space around the nucleus
where there is a maximum probability of finding an electron of specific energy.
There are four types of orbitals as follows :
Y
s-Orbital
These orbitals are having spherical and non-directional Z
shape [Fig. 1.5]. Each s orbital can accommodate 2
electrons in the opposite spin. One electron with +1/2
X
spin, another electron with - 1/2 spin. In another way one
with upward spin and another with downward spin or 1s
one with clockwise spin another with counter-clockwise 2s
(anticlockwise spin). Size of 1s is less than 2s orbital; 3s
size of 2s is less than 3s orbital.

Box Diagram Fig. 1.5 : Shape of s-Orbitals
8 | Applied Chemistry
The empty region between two s-orbitals, where zero per cent probability of finding the
electrons is known as the zero electron density region.

p-Orbital
There are three p- sub orbitals (px, py and pz ) orbitals having dumb-bell shape [Fig. 1.6]. These
orbitals are directional and along the axis orbital. Each p suborbital can accommodate 2 electrons
in opposite spin hence the capacity of p orbital is 6 electrons. These sub orbitals are degenerate
(having an equal amount of energy). If the lobe of the orbital is sprayed along the x-axis, then that
orbital is called px orbital. Similarly if the lobe is sprayed along y-axis then that orbital is called py
orbital and if lobe is sprayed along z-axis then that orbital is called pz orbital.

Box Diagram

Fig. 1.6 : Dumbbell Shape of p-Orbitals

d-Orbital
There are five d- sub orbitals (dxy, dyz, dxz, dx2–y2 and dz2) orbitals [Fig. 1.7]. d-orbitals are having
the double dumb-bell shape or four-lobe planar structure. These orbitals are directional and along
the axis orbital (dx2–dy2 and dz2) as well as in between the axis orbitals (dxy, dyz and dxz). Each d
sub orbital can accommodate 2 electrons in opposite spin hence the maximum capacity of d orbital
to accommodate electrons is 10 electrons.

dxy dyz dxz dx2–y2 dz2

In between the Along the
axis orbitals axis orbitals
Box Diagram

Fig. 1.7 : Double Dumbbell Shape of d-Orbitals

f-Orbital

There are seven f- sub orbitals fx(x2-3y2), fy(3x2-y2),fz(x2-y2),fxz2, fyz2, fz3, fxyz
 Atomic Structure,Chemical Bonding and Solutions | 9

f-orbitals are having a complicated shape.

Each f-orbital are having seven f-sub orbitals hence capacity to accommodate electrons is
14 electrons.

1.1.7 Quantum Numbers
The Bohr model was a one-dimensional model that used one quantum number to
describe the distribution of electrons in the atom. It explains the size of the orbit, which was
described by the principal quantum number (n). Schrodinger’s model allowed the electron to
occupy three-dimensional space. It therefore required set of four quantum numbers, to describe
the orbitals in which electrons can be found.
Four quantum numbers as principal quantum number(n) give information about main energy
level; azimuthal quantum number (l)provides information about sub energy level; magnetic
quantum number (m) gives information of orientation of sub-energy level and spin quantum
number (ms) gives the direction of spin.
These four quantum numbers in an atom give the exact position of the electron, it is just like
working of global positioning system (GPS) location or address, we can say that these quantum
numbers give the exact location or address of electron.

(A) Principal Quantum Number (n)

This quantum number is represented by the letter (n).

This number gives information on the position of the electron as well as the energy
associated with the electron.

The values of ‘n’ are positive integral numbers as 1, 2, 3, 4…etc. corresponding to K, L,
M, N…etc. shells.

(B) Angular Momentum Quantum Number or Azimuthal Quantum Number (l)

This quantum number is represented by the letter (l).

It is used to describe sub-energy level.

Values of azimuthal quantum numbers are all possible whole numbers from 0 to n-1
When n=1 thus l=0 (Represents s-orbital)
When n=2 thus l=0,1 (Represents s and p orbital)
When n=3 thus l=0,1,2 (Represents s, p and d orbital)
When n=4 thus l=0,1,2,3 (Represents s, p, d and f orbital)

Thus various subshells are designated as s, p, d, f according to the value of l=0, 1, 2, 3
respectively.

(C) Magnetic Quantum Number (m)

This quantum number is represented by the letter (m).

It is used to describe the orientation of the orbitals.

The number of values allowed to m depends on the values of l.

Possible values of m range from –l through 0 to +l thus making a total of 2l+1 values.
table 1.2
10 | Applied Chemistry
Table 1.2 : Magnetic Quantum Number

Azimuthal Calculation of Values of Magnetic Orientation around
Quantum Number (l) Magnetic Quantum Quantum Number the nucleus
Number (m= 2l + 1)

l=0 (s-orbital) m=2 x 0+1= 1 0 one

l=1 (p-obital) m=2 x 1+1= 3 -1,0, +1 three

l=2 (d-orbital) m=2 x 2+1= 5 -2, -1, 0, +1, +2 five

l=3 (f-orbital) m=3 x 2+1= 7 -3, -2,-1,0,+1,+2,+3 seven

(D) Spin Quantum Number (ms)
This quantum number is represented by (ms).
It shows the direction in which the electron is spinning about its own axis.
The spin quantum number shows two possible values i.e. clockwise spin as + and
anticlockwise spin as –

1.1.8 Pauli’s Exclusion Principle
No two electrons in a single atom can have same set of four quantum numbers.
In an atom two electrons can have a same set of three quantum numbers but they must differ
in the value of fourth quantum number table 1.3
The first two electrons in [Ne] gas have the same set of three quantum numbers but

differ in spin quantum number i.e. one with + spin and other with - spin.

Table 1.3 : Four Quantum Numbers for First 10 Electrons in [Ne]
Principal Azimuthal Quantum Magnetic Spin Remarks
Quantum No. (l ) = 0 to n-1 Quantum Quantum
No. (n) No. (m)=-l No. (ms)
to + l

1 (K shell) 0 (s-sub energy level) 0 + First s electron in 1s

0 (s- sub energy level) 0 – Second s electron in 1s

2 (L shell) 0 (s- sub energy level) 0 + First s electron in 2s

0 (s- sub energy level) 0 – Second s electron in 2s
 Atomic Structure,Chemical Bonding and Solutions | 11

1 (p- sub energy level) -1 + First p electron in 2px

1 (p- sub energy level) 0 + First p electron in 2py

1 (p- sub energy level) +1 + First p electron in 2pz

1 (p- sub energy level) -1 – Second p electron in 2px

1 (p- sub energy level) 0 – Second p electron in 2py

1 (p- sub energy level) +1 – Second p electron in 2pz

1.1.9 Hund’s Rule of Maximum Multiplicity
When several orbitals with same energy are available, the electrons enters in all orbitals
with parallel spin, before pairing in any one orbital.

Electron pairing in any orbital is not possible until the available orbitals of the same energy from
the given subshell contains one electron each. Electrons of different atoms while entering into
p-orbital follows Hund’s rule as shown in table 1.4

Table 1.4 : Pairing Arrangement of Electrons Permitted by Hund’s Rule

Description Orbital Permitted by Not Permitted by
Hund’s Rule Hund’s Rule

With one p electron e.g. B p
px py pz
With two p electrons e.g. C p

px py pz px py pz
With three p electrons e.g. N p

px py pz px py pz
With four p electrons e.g. O p

px py pz px py pz

With five p electrons e.g. F p
px py pz
12 | Applied Chemistry

With six p electrons e.g. Ne
p
px py pz

1.1.10 Aufbau Rule
When several orbitals are available, electron enters into all available orbitals with an
increasing amount of energy. i.e. orbitals with lower energy are filled first then electrons
enters into higher energy orbitals.
1s