Deepa Publisher

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• Deepa Publishers

Chemistry
2
1.Metallurgy-2
4Hours

• 1.0 Introduction
• Metallurgy is considerer as the art (physical)
  and Science (Chemicals) of the extraction of
  metals.
• 1.1 Desilverisation of lead by Parkes Process
• 1.2 Ellingham diagrams
• 1.3 Metallurgy of iron
• 1.4 Additional information for CET and IIT
• 1.5 Summary

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2.Industrially important compounds
4Hours

• 2.0 Introduction
• 2.1 Sodium Hydroxide (NaOH)
• 2.2 Ammonia(NH3)
• 2.3 Sulphuric Acid (H2SO4)
• 2.4 Potassium Dichromate (K2Cr2O7)
• 2.5 Chemical properties of Sulphuric acid
• 2.6 Chemical properties of Potassium dichromate
• 2.7 Additional Information for CET and IIT
• 2.8 Summary

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3.Group 18, Noble Gases
2Hours

• 3.0 Introduction
• 3.1 Isolation for Rare Gases
• 3.2 separation of Noble Gases by Dewars Charcoal
  adsorption Method
• 3.3 Application of Noble Gases
• 3.4 Additional Information for CET and IIT
• 3.5 Summary

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4.d-Block Elements 2Hours

• 4.0 Introduction
• 4.1 Definition of d-Block Elements
• 4.2 Characteristic Properties of Transition
  Metals
• 4.3 Additional Information for CET and IIT
• 4.4 Summary

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5.Coordination Compounds 5Hours

• 5.0 Introduction
• 5.1 Types of Inorganic Salts
• 5.2 Complex Ions
• 5.3 Ligands
• 5.4 Types of Ligands
• 5.5 Coordination Number
• 5.6 Werners Theory
• 5.7 Sidgwicks electronic theory
• 5.8 Effective Atomic Number (EAN)
• 5.9 Nomenclature of Coordination Compounds
• 5.10 Isomerism in complexes
• 5.11 Valence Bond Theory
• 5.12 Additional Information for CET and IIT
• 5.13 Summary

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6.Chemical Bonding-2 4Hours

• 6.0 Introduction
• 6.1 Molecular Orbit Theory
• 6.2 Formation of molecular orbital by (LCAO)
  Linear Combination of Atomic orbitals
• 6.3 Rules for combination of atomic orbitals
• 6.4 Energy level diagram
• 6.5 Rules for filling the electrons in molecular
  orbitals
• 6.6 Molecular orbital arrangement of electrons
• 6.7 Metallic Bond Introduction
• 6.8 Electron Sea Model
• 6.9 Electron Gas Theory
• 6.10 Comparison between metallic bonding with
  covalent bonding and ionic bonding
• 6.11 Additional Information for CET and IIT
• 6.12 Summary

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7.Chemical Kinetics 5Hours

• 7.0 Introduction
• 7.1 Commercial importance of rate studies
• 7.2 Order of a reaction
• 7.3 Factors deciding the order of a reaction
• 7.4 Pseudo-first order reaction
• 7.5 Derivation of equation for the rate constant
  of a first order reaction
• 7.6 Half-Life period
• 7.7 Determination of order of a reaction
• 7.8 Effect of temperature on the rate of a
  reaction
• 7.9 Arrhenius Equation
• 7.10 Influence of catalyst
• 7.11 Additional Information for CET and IIT
• 7.12 Summary

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8.Electrochemistry 12Hours

• 8.0 Introduction
• 8.1 Electrolytes and Non-electrolytes
• 8.2 Electrolysis
• 8.3 Faradys laws of electrolysis
• 8.4 Arrhenius theory of electrolytic dissociation
  (Ionic theory)
• 8.5 conductance, Specific and molar Conductance
• 8.6 Theories of acids and bases
• 8.7 Lewis theory
• 8.8 Strengths of acids and bases
• 8.9 Ostwalds dilution law
• 8.10 Common ion effect
• 8.11 Ionic product of water (Kw)
• 8.12 pH of a Solution
• 8.13 pKa for weak acids pKb for weak bases
• 8.14 Buffer solutions
• 8.15 Hendersons equations
• 8.16 Principles involved in the preparation for
  buffer solutions
• 8.17 Solubility product (Ks)
• 8.18 Application of solubility product and common
  ion effect in qualitative analysis

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9.Theory of dilute Solutions 3Hours

• 9.0 Introduction
• 9.1 Collagative Properties
• 9.2 Osmotic Pressure
• 9.3 Vant Hoffs theory of dilute solutions
• 9.4 Relative lowering of vapour pressure
• 9.5 RAoults law of relative lowering of vapour
  pressure (RLVP)
• 9.6 Relation between relative lowering of vapour
  pressure and molecular mass of the solute
• 9.7 Ostwald and walkers dynamic method
• 9.8 Elevation in boiling point
• 9.9 Depression in freezing point
• 9.10 Ideal and Non-ideal
• 9.11 Classification of binary liquid solutions
• 9.12 Additional Information for CET and IIT
• 9.13 Summary

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10.Chemical Themodynamics 3Hours

• 10.0 Introduction
• 10.1 Spontaneous and Non-spotaneous process
• 10.2 Entropy (S)
• 10.3 Criteria for spontaneity
• 10.4 Second law of Thermodynamics
• 10.5 Gibbs Free energy (G)
• 10.6 Predicting the feasibility of process using
  Gibbs equation
• 10.7 Standard free energy change of a reaction
• 10.8 Additional Information for CET and IIT
• 10.9 Summary

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11.Colloids 3Hours

• 11.0 Introduction
• 11.1 Colloidal system and particle size
• 11.2 Types of colloids
• 11.3 Lyophilic and Lyophobic sols
• 11.4 Preparation of sols
• 11.5 Purification of sols
• 11.6 Properties of sols
• 11.7 Hardy and Schulze rule
• 11.8 Protective action of sols
• 11.9 Application of colloids
• 11.10 Additional Information for CET and IIT
• 11.11 Summary

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12.Solid state 2Hours

• 12.0 Introduction
• 12.1 Types of Solids
• 12.2 Types of crystalline solids
• 12.3 Crystal lattice
• 12.4 Lattice points
• 12.5 Unit cell
• 12.6 Co-ordination number
• 12.7 Types of Cubic Lattice
• 12.8 Calculation of number of particles present
  in cubic unit cells
• 12.9 Ionic crystals
• 12.10 Ionic radius
• 12.11 Radius ratio
• 12.12 Relation between radius ratio and
  coordination number
• 12.13 Structure of Rock salt (NaCL)
• 12.14 Structure of caesium chloride (CsCL)
• 12.16 Additional Information for CET and IIT
• 12.17 Summary

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13.Concepts in organic chemistry
1Hour

• 13.0 Introduction
• 13.1 Inductive effect
• 13.2 Electromeric effect
• 13.3 Mesomeric effect
• 13.4 Hyper conjugative effect
• 13.5 Additional Information for CET and IIT
• 13.6 Summary

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14.Synthetic organic chemistry
1Hour

• 14.0 Introduction
• 14.1 Conversion of methane to ethane
• 14.2 Additional Information for CET and IIT
• 14.3 Summary

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15.Isomerism-2
1Hour

• 15.0 Introduction
• 15.1 Geometrical isomerism
• 15.2 Optical isomerism
• 15.3 Chirality
• 15.4 Additional Information for CET and IIT
• 15.5 Summary

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16. Hydrocarbons-2
4Hours

• 16.0 Introduction
• 16.1 Bayers Strain theory
• 16.2 Sachse-Mohr thoery of strainless rings
• 16.3 Structure of Benzene
• 16.4 Mechanism of electrophilic substitution
  reactions of benzene
• 16.5 Additional Information for CET and IIT
• 16.6 Summary

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17.Haloalkanes

3Hours

• 17.0 Introduction
• 17.1 Nomenclature
• 17.2 General methods of preparation
• 17.3 Physical properties
• 17.4 Chemical properties
• 17.5 Mechanism of nucleophilic substitution
  reactions
• 17.6 Additional Information for CET and IIt
• 17.7 Summary

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18.Organic compounds containing oxygen-2
8Hours

• 18(a). Phenols
• 18(b). Aldehydes and ketones
• 18(c). Monocarboxylic acids
• 18(d). Summary

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18(a).Phenols

• 18a.0 Introduction
• 18a.1 Classification
• 18a.2 Methods of preparation
• 18a.3 Manufacture of phenol
• 18a.4 Physical properties
• 18a.5 Chemical properties
• 18a.6 Uses of phenol
• 18a.7 Additional Information for CET and IIT
• 18a.8 Summary

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18(b).Aldehydes and ketones

• 18b.0 Introduction
• 18b.1 Nomenclature
• 18b.2 General Methods of Preparation from
  Alcohols
• 18b.3 Physical properties
• 18b.4 Chemical properties
• 18b.5 Uses of Aldehydes and Ketones
• 18b.6 Additional Information for CET and IIT
• 18b.7 Summary

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18(c).Monocarboxylic acids

• 18c.0 Introduction
• 18c.1 Nomenclature
• 18c.2 General methods of preparation
• 18c.3 Chemical properties
• 18c.4 Physical properties
• 18c.5 Acidity of Carboxylic acids
• 18c.6 Uses of Carboxylic acids
• 18c.7 Additional Information for CET and IIT
• 18c.8 Summary

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19.Amines 2Hours

• 19.0 Introduction
• 19.1 Classification
• 19.2 Nomenclature of amines
• 19.3 General methods of preparation of primary
  amines
• 19.4 Physical properties
• 19.5 Basic character of amines
• 19.6 Chemical Properties
• 19.7 Distinction between primary, secondary, and
  tertiary amines
• 19.8 Uses of Aniline
• 19.9 Additional Information for CET and IIT
• 19.10 Summary

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20.Carbohydrates
2Hours

• 20.0 Introduction
• 20.1 Classification
• 20.2 Glucose
• 20.3 Structure of glucose
• 20.4 Fructose (C6H12O6)
• 20.5 Maltose (C12H22O11)
• 20.6 Sucrose (C12H22O11)
• 20.7 Biological Importance of carbohydrates
• 20.8 Additional Information for CET and IIT
• 20.9 Summary

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21.Oils and Fats
2Hours

• 21.0 Introduction
• 21.1 Composition of oils and fats
• 21.2 Triglycerides
• 21.3 Properties
• 21.4 Biological Importance of oils and fats
• 21.5 Additional Information for CET and IIT
• 21.6 Summary

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22.Amino acids and Proteins
2Hours

• 22.0 Introduction
• 22.1 Amino acids
• 22.2 Classification
• 22.3 General properties
• 22.4 Peptic bond
• 22.5 Proteins
• 22.6 Classification
• 22.7 General properties of proteins
• 22.8 Denaturation of proteins
• 22.9 Insulin
• 22.10 Biological importance of proteins
• 22.11 Additional Information for CET and IIT
• 22.12 Summary

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• Umarani umaranis

Mathematics
29
1.Elements of Number Theory and Congruences

• 1.1 Elements of number theory
• 1.2 Prime, Composite and relatively Prime Numbers
  
• 1.3 Congruences
• 1.4 Exercise

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2.Matrices and Determinants

• 2.1 Matrices
• 2.2 Determinants
• 2.3 Cramers rule
• 2.4 Multiplication of determinants
• 2.5 Inverse of a square matrix
• 2.6 Eigen values of a Square matrix
• 2.7 Cayley-Hamilton Theory
• 2.8 Exercise

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3. Group Thoery

• 3.1 Group
• 3.2 Sub group
• 3.3 Exercise

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4.Vector algebra

• 4.1 Preliminaries
• 4.2 Scalar product
• 4.3 Vector product
• 4.4 Scalar Triple Product
• 4.5 Vector Triple Product
• 4.6 Exercise

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5.The Circle

• 5.1 Equation of the circle
• 5.2 Eqaution of the Tangent
• 5.3 Length of the Tangent
• 5.4 Radical axis of two circles
• 5.5 Orthogonal Circles
• 5.6 Exercise

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6.Conic Sections

• 6.1 Parabola
• Tangent and Normal
• 6.2 The Ellipse
• Tangent and Normal
• 6.3 Hyperbola
• Tangent and Normal
• 6.4 Exercise

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7.Inverse Trigonometric Functions

• 7.1 Definition
• 7.2 Exercise

36
8.General Solution of Trigonometric Equations

• 8.1 Some Results
• 8.2 Exercise

37
9.Complex Numbers

• 9.1 Preliminaries
• 9.2 De Moivers Theorem
• 9.3 nth roots of a complex number
• 9.4 Exercise

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10.The Derivative

• 10.1 The derivative of a function
• 10.2 Rules of differentiation
• 10.3 Hyperbolic and Inverse Hyperbolic Functions
• 10.4 Differentiation of inverse trigonometric
  functions using substitutions
• 10.5 Implicit functions
• 10.6 Parametric Equations
• 10.7 Differentiation of one function w.r.t.
  another function
• 10.8 Logarithmic Differentiation
• 10.9 Successive Differentiation
• 10.10 Exercise

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11.Application of the Derivative

• 11.1 Tangent and Normal
• 11.2 Angle between two curves
• 11.3 Subtangent and Subnormal
• 11.4 Derivative as a rate measure
• 11.5 Increasing and decreasing functions
• 11.6 Maxima and minima
• 11.7 Exercise

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12. Integration

• 12.1 Indefinite Integral
• 12.2 Integration by the method of substitution
• 12.3 Integrals of functions involving a2x2 and
  their radicals
• 12.4 Integrals of the form dx/ax2bxc
• 12.5 Integrals of the form dx/ax2bxc
• 12.6 Integrals of the form pxq/ax2bxc
• 12.7 Integrals of the form pxq/ax2bxc
• 12.8 Integrals of the form dx/acosxbsinxc
• 12.9 Integrals of the form pcosxqsinx/acosxbsin
  xdx
• 12.10 Integrals by the method of partial
  fractions
• 12.11 Integration by parts
• 12.12 Exercise

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13.Definite Integral

• 13.1 Definite integral
• 13.2 Exercise

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14.Application of the Definite Integral to Areas

• 14.1 Applications to areas
• 14.2 Exercise

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15.Differential equations

• 15.1 Formation of differential equations
• 15.2 Exercise

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• MES Publishers

Physics
46
Geometrical Optics1.Refraction at a plane
surface
3Hours

• 1.1 Introduction
• 1.2 Refraction of light at a plane surface
• 1.3 Relative refractive index (rri) and Absolute
  refractive index (ari)
• 1.4 Relation between rri and ari
• 1.5 Refraction through multiple refracting media
• 1.6 Refraction through a parallel sided glass
  slab
• 1.7 Normal shift
• 1.8 Total internal reflection
• 1.9 Relation between critical angle and
  refractive index
• 1.10 Application of total internal reflection
• 1.11 Worked examples
• 1.12 Problems

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2.Refraction through a prism
2Hours

• 2.1 Prism
• 2.2 Refraction through a parallel sided glass
  slab
• 2.3 Derivation of expression for lateral shift,
  and normal shift (Object in denser medium)
• 2.4 Total internal reflection and its
  apllications
• 2.5 Optical fibres and its application in
  communication
• 2.6 Pure and impure spectrum
• 2.7 Dispersive power
• 2.8 Worked examples
• 2.9 Problems

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3.Refraction at a spherical surface
3Hours
49
Physical optics1.Introduction to theories of
light
1Hour
50
2.Interference
3Hours
51
3.Diffraction
3Hours
52
4.Polarisation
4Hours
53
5.Speed of light
1Hours
54
Electrostatics1.Electric Charge
1Hours
55
2. Electrostatic field
4Hours
56
3.Capacitors
4Hours
57
Current Electricity1. Electric current

4Hours
58
2.Kirchoffs laws
2Hours
59
3.Magnetic effect of electric current
4Hours
60
4.Mechanical effect of electric current
3Hours
61
5.Electromagnetic induction
6Hours
62
Atomic Physics1.Introduction to atomic physics
2Hours
63
2.Photo electric effect
2Hours
64
3.Dual nature of matter
2Hours
65
4.Bohrs atomic model
3Hours
66
5.Scattering of light
1Hours
67
6.Lasers
2Hours
68
7.Nuclear physics
4Hours
69
8.Radioactivity
3Hours
70
9.Elementary Particles
1Hours
71
10.Solid state electronics
4 Hours
72
11.Digital Electronics
1Hours
73
12.Soft condensed matter physics
2Hours
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Expert publication
Biology
76
Botany (Theory)B1.Nucleic acids

• Definition
• Types and definition

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B2.Gene structure and Functions

• Gene Definition
• Types

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B3.Biotechnology

• 3.1 Definition
• 3.2 Tissue Culture
• 3.3 Applications
• 3.4 DNA Finger Printing

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Plant PhysiologyB4.Water relations of plants

• 4.1 Fundamental Concepts
• 4.2 Absorption of water
• 4.3 Ascent of Sap
• 4.4 Loss of Water
• 4.4.1 Transpiration
• 4.4.2 Guttation
• 4.5 Translocation of solutes

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B5. Bioenergetics

• 5.1 Bioenergetics
• 5.2 Photosynthesis
• 5.3 Respiration

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B6.Growth and Growth Regulators in Plants

• 6.1 Growth
• 6.2 Growth Regulators

82
Botany (Practical)

• 1.1 Plant Histology
• 1.2 Plant Anatomy
• 1.3 Plant Physiology

83
Zoology (Theory)Z.1Genetics

• 1.1 Mendelian Genetics
• 1.2 Deviations from Mendelian laws
• 1.3 Genetic Disorders in Man

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Z2.Biodiversity

• 2.1 Definition and Types
• 2.2 Biodiversity Profiles of india and Karnataka
• 2.3 Benefits of Biodiversity
• 2.4 Biodiversity Depletion
• 2.5 Intellectual property rights
• 2.6 Concepts of ecosystem sustainability

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Z3.Man in Health and Diseases

• 3.1 Concept of homeostasis The central Dogma in
  Physiology
• 3.2 Body defence and immunity
• 3.3 Digestion
• 3.4 Circulation
• 3.5 Respiration
• 3.6 Excretion
• 3.7 Nervous system

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Z4. Continuity of Life

• 4.1 Gametogenesis
• 4.2 Fertilization
• 4.3 Early development of frog
• 4.4 Human reproduction
• 4.5 Fertility control
• 4.6 Infertility Control
• 4.7 Sexually transmitted diseases

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Zoology (Practical)

• 1.1 Animal Histology
• 1.2 Organ Histology
• 1.3 Embryology Frog
• 1.4 Physiology
• 1.5 Human Organs

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