The syllabus is in tune with the syllabus adapted by the Telangana State Board of Intermediate Education (TSBIE) for Intermediate course with effect from the academic year 20192020 (1st year) (100%) and 20202021 (2nd year) (70%) and is designed at the level of Intermediate Course and equivalent to 10 + 2 (10 plus 2) scheme of Examination conducted by Telangana State Board of Intermediate Education. The syllabus is designed to indicate the scope of subjects included for TS EAMCET2021. The topics mentioned therein are not to be regarded as exhaustive. Questions may be asked in TS EAMCET2021 to test the student’s knowledge and intelligent understanding of the subject. The syllabus is applicable to students of both the current and previous batches of Intermediate Course, who desire to appear for TS EAMCET 2021.
1)
ALGEBRA
MATHEMATICS
a)
Functions: Types of
functions – Definitions  Inverse functions and Theorems  Domain, Range,
Inverse of real valued functions.
b)
Mathematical
Induction: Principle of Mathematical Induction & Theorems  Applications of
Mathematical Induction  Problems on divisibility.
c)
Matrices: Types of matrices  Scalar multiple
of a matrix and multiplication of matrices
 Transpose of a matrix  Determinants  Adjoint and Inverse of a
matrix  Consistency and
inconsistency of Equations Rank of a matrix  Solution of simultaneous linear
equations.
d)
Complex Numbers:
Complex number as an ordered
pair of real numbers  fundamental
operations
 Representation of complex numbers
in the form 𝑎 + 𝑖𝑏.
e)
De Moivre’s
Theorem: De Moivre’s theorem Integral and Rational indices  nth roots of unity Geometrical Interpretations – Illustrations.
f)
Quadratic
Expressions: Quadratic expressions, equations in one variable  Sign of quadratic
expressions – Change in signs – Maximum and minimum values.
g)
Theory of
Equations: The relation between the roots and coefficients in an equation 
Solving the equations when two or more roots of it are connected by certain
relation  Equation with real coefficients, occurrence of complex roots in
conjugate pairs and its consequences  Transformation of equations  Reciprocal Equations.
h)
Permutations and
Combinations: Fundamental Principle of counting – linear and circular permutations
Permutations of ‘n’ dissimilar things taken ‘r’ at a time – Combinations 
definitions, certain theorems.
i)
Binomial Theorem:
Binomial
theorem for positive integral index  Binomial theorem for rational Index
(without proof).
j)
Partial fractions: Partial fractions of f(x)/g(x) when g(x) contains
non – repeated linear
factors  Partial fractions of f(x)/g(x) when g(x) contains repeated and/or
nonrepeated linear factors  Partial fractions
of f(x)/g(x) when g(x) contains
irreducible factors only.
2)
TRIGONOMETRY:
a)
Trigonometric
Ratios up to Transformations: Graphs and Periodicity of Trigonometric
functions  Trigonometric ratios and Compound angles  Trigonometric ratios of
multiple and sub multiple angles  Transformations  Sum and Product rules.
b)
Trigonometric
Equations: General Solution of Trigonometric Equations  Simple Trigonometric
Equations – Solutions.
c)
Inverse
Trigonometric Functions: To reduce a Trigonometric Function into a bijection
 Graphs of Inverse Trigonometric Functions  Properties of Inverse
Trigonometric Functions.
d)
Hyperbolic
Functions: Definition of Hyperbolic Function – Graphs  Definition of Inverse
Hyperbolic Functions – Graphs  Addition formulae of Hyperbolic Functions.
e)
Properties of
Triangles: Relation between sides and angles of a Triangle  Sine, Cosine, Tangent
and Projection rules  Half angle formulae and areas of a triangle – Incircle
and Excircle of a Triangle.
3)
VECTOR ALGEBRA:
a)
Addition of
Vectors: Vectors as a triad of real numbers  Classification of vectors 
Addition of vectors  Scalar multiplication  Angle between two nonzero vectors
 Linear combination of vectors  Component of a vector in three dimensions 
Vector equations of line and plane including their Cartesian equivalent forms.
b)
Product of
Vectors: Scalar Product  Geometrical Interpretations  orthogonal projections 
Properties of dot product  Expression of dot product in 𝑖, 𝑗, 𝑘 system  Angle between two
vectors  Geometrical Vector methods  Vector equations of plane in normal form
 Angle between two planes  Vector product of two vectors and properties 
Vector product in 𝑖, 𝑗, 𝑘
system
 Vector Areas  Scalar Triple Product  Vector equations of plane in different
forms, skew lines, shortest distance and their Cartesian equivalents. Plane
through the line of intersection of two planes, condition for coplanarity of
two lines, perpendicular distance of a point from a plane, angle between line
and a plane. Cartesian equivalents of all these results  Vector Triple Product
– Results.
4)
PROBABILITY:
a)
Measures of
Dispersion: Range  Mean deviation for ungrouped
data.
b)
Probability: Random
experiments and events  Classical definition of probability, Axiomatic
approach and addition theorem of probability  Independent and dependent events
 conditional probability  multiplication theorem.
c)
Random Variables
and Probability Distributions: Random Variables  Theoretical discrete
distributions – Binomial and Poisson Distributions.
5)
COORDINATE GEOMETRY:
a)
Locus: Definition of
locus – Illustrations  To find equations of locus  Problems connected to it.
b)
Transformation of Axes: Transformation of axes  Rules, Derivations and Illustrations
 Rotation of
axes  Derivations – Illustrations.
c)
The Straight
Line: Revision of fundamental results  Straight line  Normal form –
Illustrations  Straight line  Symmetric form  Straight line  Reduction into
various forms  Intersection of two Straight
Lines  Family
of straight lines  Concurrent lines  Condition
for Concurrent lines  Angle between two lines  Length of perpendicular from a
point to a Line  Distance between two parallel lines  Concurrent lines 
properties related to a triangle.
d)
Pair of Straight lines:
Equations of pair of lines passing through
origin  angle
between a pair of lines  Condition for perpendicular and coincident
lines, bisectors of angles  Pair of bisectors of angles  Pair of lines 
second degree general equation  Conditions
for parallel lines  distance between them, Point of intersection of pair of
lines  Homogenizing a second degree equation with a first degree equation in 𝑥
and 𝑦.
e)
Circle: Equation of circle  standard formcentre and radius of a circle
with a given line segment as diameter & equation of circle through
three non collinear
points  parametric equations of a circle 
Position of a point in the plane of a circle – power of a point definition of
tangent  length of tangent  Position of a straight line in the plane of a
circleconditions for a line to be tangent – chord joining two points on a
circle – equation of the tangent at a point on the circle point of
contactequation of normal  Chord of contact  pole and polar  conjugate
points and conjugate lines  equation of chord with given middle point 
Relative position of two circles  circles touching each other externally, internally  common tangents
– centers of similitude  equation of pair
of tangents from an external point.
f)
System of circles: Angle between two intersecting circles  Radical
axis of two circles
properties  Common chord and common tangent of two circles – radical centre 
Intersection of a line and a Circle.
g)
Parabola: Conic sections – Parabola
 equation of parabola in standard form  different forms of parabola  parametric equations.
h)
Ellipse: Equation of
ellipse in standard form  Parametric equations.
i)
Hyperbola: Equation of
hyperbola in standard form  Parametric equations.
j)
Three Dimensional
Coordinates: Coordinates  Section formulae  Centroid of a triangle and tetrahedron.
k)
Direction Cosines
and Direction Ratios: Direction Cosines  Direction Ratios.
l)
Plane: Cartesian
equation of Plane  Simple Illustrations.
6)
CALCULUS:
a)
Limits and
Continuity: Intervals and neighbourhoods – Limits  Standard Limits – Continuity.
b)
Differentiation: Derivative of a
function  Elementary Properties  Trigonometric, Inverse Trigonometric,
Hyperbolic, Inverse Hyperbolic Function – Derivatives  Methods of
Differentiation  Second Order Derivatives.
c)
Applications of
Derivatives: Errors and approximations  Geometrical Interpretation of a derivative
 Equations of tangents and normals  Lengths of tangent, normal, sub tangent
and sub normal  Angles between two curves and condition for orthogonality of curves
 Derivative as Rate of change  Rolle’s Theorem
and Lagrange’s Mean value
theorem without proofs
and their geometrical interpretation  Increasing and decreasing
functions  Maxima and Minima.
d)
Integration: Integration as
the inverse process of differentiation Standard forms  properties of
integrals  Method of substitution  integration of Algebraic, exponential,
logarithmic, trigonometric and inverse trigonometric functions.
e)
Definite
Integrals: Definite Integral as the limit of sum  Interpretation of Definite
Integral as an area  Fundamental theorem of Integral Calculus – Properties.
f)
Differential
equations: Formation of differential equation  Degree and order of an ordinary
differential equation  Solving differential equation by Variables separable
method.
The
following topics are the deleted content of MATHEMATICS PaperII A (30%) in the
Intermediate Second Year for the Academic Year 202021 by the TSBIE as per
Telugu Academy Text Book. The same is deleted for the TS EAMCET2021
Examination.
1.
Complex
Numbers
1.3 :
Modulus and amplitudes of complex numberillustrations.
1.4 :
Geometrical and polar representation of a complex number in argand plane – argand diagram.
2.Demovier’s Theorem
Exercise 2(b) section II and section III.
3.
Quadratic expressions
3.3 Quadratic inequalities.
5.
Permutations
and Combinations
5.3: Permutations when repetitions are allowed. 5.4:
Circular permutations.
5.5: Permutations with constraint repetitions. Exercise
5(e) Section III.
6.
Binomial
Theorem
Exercise 6(a) Section II 5th problem
onwards and related examples. Exercise 6(b) Section II and related examples.
Exercise 6(c).
7.
Partial
Fractions
Exercise 7(d).
8.
Measures
of Dispersion
8.2.2 Mean Deviation for grouped data.
Exercise 8(a) Section I Problem 3 onwards
8.3
Variance and standard deviation of un
grouped / grouped data.
8.4
Coefficient of Variation and analysis
of frequency distributions with equal means but
different variances.
9.
Probability
9.3.9 Baye’s Theorem and problems on Baye’s theorem.
The
following topics are the deleted content of MATHEMATICS PaperII B (30%) in the
Intermediate Second Year for the Academic Year 202021 by the TSBIE as per
Telugu Academy Text Book. The same is deleted for the TS EAMCET2021
Examination.
3. Parabola
3.2: Equation of tangent and normal at a point on the
parabola.
4. Ellipse
4.2: Equation of tangent and normal at a point on the
ellipse.
5. Hyperbola
5.2: Equation of tangent and normal at a point
on the hyperbola Exercise 5(a) Section II onwards and related examples.
6. Integration
6.2(b) Integration by parts – Integration of
exponential, logarithmic and inverse trigonometric functions.
6.3: Integrationpartial fraction method. 6.4: Reduction
formulae.
7. Definite Integrals
Exercise7(b) Section II (8 to 15).
7.5 :
Reduction formula.
7.6 :
Application of definite integrals to areas.
8. Differential
Equations
8.2(b) Homogeneous Differential Equations. 8.2(c)
NonHomogeneous Differential Equations. 8.2(d) Linear Differential Equations.
****
PHYSICS
1)
PHYSICAL
WORLD: What is physics? Scope and excitement of Physics, Physics, technology
and society, Fundamental forces in nature, Gravitational Force, Electromagnetic
Force, Strong Nuclear Force, Weak Nuclear Force, Towards Unification of Forces,
Nature of physical laws.
2)
UNITS AND
MEASUREMENTS: Introduction, The international system of units, Measurement of Length,
Measurement of Large Distances, Estimation of Very Small Distances: Size of a
Molecule, Range of Lengths, Measurement of Mass, Range of Masses, Measurement
of time, Accuracy, precision of instruments and errors in measurement,
Systematic errors, random errors, least count error, Absolute Error, Relative
Error and Percentage Error, Combination of Errors, Significant figures, Rules
for Arithmetic Operations with Significant Figures, Rounding off the Uncertain
Digits, Rules for Determining the Uncertainty in the Results of Arithmetic
Calculations, Dimensions of Physical Quantities, Dimensional Formulae
and dimensional equations, Dimensional Analysis and its Applications, Checking the Dimensional
Consistency of Equations, Deducing Relation among the Physical Quantities.
3)
MOTION
IN A STRAIGHT LINE: Introduction, Position, path length and displacement, Average velocity and
average speed, Instantaneous velocity and speed, Acceleration, Kinematic
equations for uniformly accelerated motion, Relative velocity.
4)
MOTION
IN A PLANE: Introduction, Scalars and vectors, Position and Displacement Vectors,
Equality of Vectors, Multiplication of vectors by real numbers, Addition and subtraction
of vectors  graphical method, Resolution of vectors, Vector addition 
analytical method, Motion in a plane,
Position Vector and Displacement, Velocity,
Acceleration, Motion in a
plane with constant acceleration, Relative velocity in two dimensions,
Projectile motion, Equation of path of a projectile, Time of Maximum height,
Maximum height of a projectile, Horizontal range of projectile, Uniform
circular motion.
5)
LAWS OF MOTION: Introduction,
Aristotle’s fallacy, The law of inertia, Newton’s first law of motion, Newton’s
second law of motion, momentum, Impulse, Newton’s third law of motion,
Conservation of momentum, Equilibrium of a particle, Common forces in
mechanics, friction, Circular motion, Motion of a car on a level road, Motion
of a car on a Banked road, Solving problems in
mechanics.
6)
WORK, ENERGY
AND POWER: Introduction, The Scalar Product,
Notions of work and
kinetic energy : The workenergy theorem, Work, Kinetic energy, Work done by a
variable force, The workenergy theorem for a variable force, The concept of
Potential Energy, The conservation of Mechanical Energy, The Potential
Energy of a spring, Various
forms of energy: the law of conservation of energy, Heat, Chemical Energy,
Electrical Energy, The Equivalence
of Mass and Energy, Nuclear Energy, The Principle of Conservation of Energy,
Power, Collisions, Elastic and Inelastic Collisions, Collisions in one
dimension, Coefficient of Restitution and its determination, Collisions in Two Dimensions.
7)
SYSTEMS OF
PARTICLES AND ROTATIONAL MOTION: Introduction, What kind of motion can a rigid body have?, Centre of mass, Centre of Gravity, Motion of centre of mass, Linear momentum of a system of
particles, Vector product of two vectors, Angular velocity and its relation with linear velocity,
Angular acceleration, Kinematics of rotational motion
about a fixed axis, Torque and angular momentum, Moment of force
(Torque), Angular momentum of particle, Torque and angular momentum for a
system of particles, conservation of angular momentum, Equilibrium of a rigid
body, Principle of moments, Moment of inertia, Theorems of perpendicular and
parallel axes, Theorem of perpendicular axes, Theorem of parallel axes,
Dynamics of rotational motion about a fixed axis, Angular momentum
in case of rotation about a fixed axis,
Conservation of Angular Momentum, Rolling motion, Kinetic Energy of Rolling Motion.
8)
OSCILLATIONS: Introduction,
Periodic and oscillatory motions, Period and frequency, Displacement, Simple
harmonic motion (S.H.M.), Simple harmonic motion and uniform circular motion,
Velocity and acceleration in simple harmonic motion, Force law for Simple
harmonic Motion, Energy in simple harmonic motion, some systems executing
Simple Harmonic Motion, Oscillations due to a spring, The Simple Pendulum,
Damped simple harmonic motion, Forced oscillations and resonance.
9)
GRAVITATION: Introduction,
Kepler’s laws, Universal law of gravitation, The gravitational constant,
Acceleration due to gravity of the earth, Acceleration due to gravity below and
above the surface of earth, Gravitational potential energy, Escape speed, Earth
satellite, Energy of an orbiting satellite, Geostationary and polar satellites, Weightlessness.
10)
MECHANICAL
PROPERTIES OF SOLIDS: Introduction, Elastic behaviour of solids, Stress and strain, Hooke’s law,
Stressstrain curve, Elastic moduli, Young’s Modulus, Determination of Young’s
Modulus of the Material of a Wire, Shear Modulus, Bulk Modulus, Poisson’s Ratio, Applications of elastic behaviour of materials.
11)
MECHANICAL
PROPERTIES OF FLUIDS: Introduction, Pressure, Pascal’s Law, Variation of
Pressure with Depth, Atmosphere Pressure and Gauge Pressure, Hydraulic
Machines, Streamline flow, Bernoulli’s principle, Speed of Efflux: Torricelli’s
Law, Venturi meter, Blood Flow and Heart Attack, Dynamic
Lift, Viscosity, Variation of Viscosity of fluids
with temperature, Stokes’ Law, Reynolds number, Surface tension, Surface
Energy, Surface Energy and Surface
Tension, Angle of Contact, Drops
and Bubbles, Capillary Rise, Detergents and
Surface Tension.
12)
THERMAL
PROPERTIES OF MATTER: Introduction, Temperature and heat, Measurement of temperature, Idealgas
equation and absolute
temperature, Thermal expansion, Specific heat capacity,
Calorimetry, Change of state, Regelation, Latent Heat, Heat transfer,
Conduction, thermal conductivity, Convection, Radiation, Black body Radiation,
Greenhouse Effect, Newton’s law of cooling.
13)
THERMODYNAMICS: Introduction,
Thermal equilibrium, Zeroth law of thermodynamics, Heat, Internal Energy and
work, First law of thermodynamics, Specific heat capacity, Thermodynamic state
variables and equation of State, Thermodynamic process, Quasistatic process,
Isothermal Process, Adiabatic Process, Isochoric Process, Isobaric process,
Cyclic process, Heat engines, Refrigerators and heat pumps, Second law of
thermodynamics, Reversible and
irreversible processes, Carnot
engine, Carnot’s theorem.
14)
KINETIC THEORY: Introduction,
Molecular nature of matter, Behaviour of gases, Boyle’s Law, Charles’ Law,
Kinetic theory of an ideal gas, Pressure of an Ideal Gas, Law of equipartition of energy, Specific
heat capacity, Monatomic Gases, Diatomic Gases,
Polyatomic Gases, Specific Heat Capacity of Solids, Specific
Heat Capacity of Water, Mean free path.
15)
WAVES: Introduction,
Transverse and longitudinal waves, Displacement relation in a progressive wave,
The speed of a travelling wave, The principle of superposition of waves,
Reflection of waves, Beats.
16)
RAY OPTICS AND
OPTICAL INSTRUMENTS: Introduction, Refraction, Total Internal Reflection,
Refraction at Spherical Surfaces and by Lenses, Refraction through a Prism,
Dispersion by a Prism, Some Natural Phenomena due to Sunlight, Optical Instruments.
17)
WAVE OPTICS: Introduction,
Huygens Principle, Refraction and reflection of plane waves using Huygens Principle, Coherent and Incoherent
Addition of Waves, Interference of Light Waves and Young’s Experiment,
Diffraction  The single slit, seeing the single slit diffraction pattern. The
validity of ray optics.
18)
ELECTRIC CHARGES
AND FIELDS: Introduction, Electric Charges, Conductors and Insulators, Charging by Induction, Basic Properties of Electric Charge,
Coulomb’s Law, Forces between Multiple Charges, Electric
Field, Electric Field Lines, Electric Flux, Electric Dipole, Dipole in a
Uniform External Field, Continuous Charge Distribution, Gauss’s Law,
Application of Gauss’s Law  Field due to an infinitely long straight uniformly
charged wire, Field due to a uniformly charged infinite plane sheet.
19)
ELECTROSTATIC
POTENTIAL AND CAPACITANCE: Introduction, Electrostatic Potential, Potential due
to a Point Charge, Potential due to an Electric Dipole, Potential due to a System of Charges, Equipotential
Surfaces, Potential Energy of a System of Charges, Potential Energy in an
External Field, Electrostatics of Conductors, Dielectrics and Polarisation, Capacitors and
Capacitance, The Parallel Plate Capacitor, Effect of Dielectric on Capacitance,
Combination of Capacitors, Energy Stored in a
Capacitor.
20)
CURRENT
ELECTRICITY: Introduction, Electric Current, Electric Currents in Conductors, Ohm’s law, Drift
of Electrons and the Origin
of Resistivity, Limitations of Ohm’s Law,
Temperature Dependence of Resistivity, Electrical Energy, Power, Cells, emf,
Internal Resistance, Cells in Series and in Parallel, Kirchhoff’s rules, Wheatstone Bridge, Meter Bridge, Potentiometer.
21)
MOVING CHARGES
AND MAGNETISM: Introduction, Magnetic Force, Motion in a Magnetic Field, Magnetic
Field due to a Current
Element, BiotSavart Law, Magnetic Field
on the Axis of a Circular Current Loop, Ampere’s Circuital Law, The
Solenoid and the Toroid, Force between Two Parallel Currents, the Ampere, Torque on Current
Loop, Magnetic Dipole, The Moving Coil Galvanometer.
22)
MAGNETISM AND
MATTER: Introduction, The Bar Magnet  The magnetic field lines, The
Electrostatic analog, Magnetism and Gauss’s Law, The Earth’s Magnetism,
Magnetisation and Magnetic Intensity.
23)
ELECTROMAGNETIC
INDUCTION: Introduction, The Experiments of Faraday and Henry, Magnetic Flux,
Faraday’s Law of Induction, Lenz’s Law and Conservation of Energy, Motional
Electromotive Force, Energy Consideration: A Quantitative Study, Eddy Currents,
Inductance, AC Generator.
24)
ALTERNATING
CURRENT: Introduction, AC Voltage Applied to a Resistor, Representation of AC
Current and Voltage by Rotating VectorsPhasors, AC Voltage Applied
to an Inductor,
AC Voltage Applied to a Capacitor, AC Voltage Applied to a Series LCR Circuit,
LC Oscillations, Transformers.
25)
ELECTROMAGNETIC
WAVES: Introduction, Electromagnetic Waves,
Electromagnetic Spectrum.
26)
DUAL NATURE OF
RADIATION AND MATTER: Introduction, Electron Emission, Photoelectric
Effect, Experimental Study of Photoelectric Effect, Photoelectric Effect and
Wave Theory of Light, Einstein’s Photoelectric Equation: Energy Quantum of
Radiation, Particle Nature of Light: The Photon, Wave Nature of Matter.
27)
ATOMS: Introduction,
Alphaparticle Scattering and Rutherford’s Nuclear Model of Atom, Atomic
Spectra, Bohr Model
of the Hydrogen Atom, The Line Spectra
of the Hydrogen Atom, DE Broglie’s Explanation of Bohr’s Second
Postulate of Quantisation.
28)
NUCLEI: Introduction, Atomic
Masses and Composition of Nucleus, Size of the Nucleus,
MassEnergy, Nuclear Force, Nuclear Energy.
29)
SEMICONDUCTOR
ELECTRONICS: MATERIALS, DEVICES AND SIMPLE CIRCUITS: Introduction, Classification of Materials: Metals,
Semiconductors and Insulators, Intrinsic Semiconductor,
Extrinsic Semiconductor, pn Junction, Semiconductor diode, Application of Junction Diode as a Rectifier, Special
Purpose pn Junction Diodes – optoelectronic junction devices, Junction
Transistor – transistor  structure and action, basic transistor circuit
configurations and transistor characteristics, Digital Electronics and Logic
Gates, Integrated Circuits.
30)
COMMUNICATION
SYSTEMS: Introduction, Elements of a Communication System,
Basic Terminology Used in Electronic Communication Systems, Bandwidth of
Signals, Bandwidth of Transmission Medium, Propagation of Electromagnetic Waves,
Modulation and its Necessity, Amplitude
Modulation, Production of Amplitude Modulated
Wave, Detection of Amplitude Modulated Wave.
The following topics are the deleted content
of PHYSICS (30%)
in the Intermediate Second
Year for the Academic Year 202021 by the TSBIE as per Telugu Academy text
Book. The same is deleted for the TS EAMCET2021 Examination.
CHAPTER –
1: WAVES
1.8 Doppler Effect
CHAPTER– 2: RAY OPTICS AND OPTICAL
INSTRUMENTS
2.2 Reflection of light by Spherical Mirrors
2.8.2 Scattering of light
CHAPTER – 3: WAVE OPTICS
3.6.3 Resolving power of optical instruments
3.7 Polarization
CHAPTER –
4: ELECTRIC CHARGES AND FIELDS
4.15.3 Field due to a uniformly charged thin spherical
shell
CHAPTER– 5: ELECTROSTATIC POTENTIAL
AND CAPACITANCE
5.16 Van de Graaf generator
CHAPTER – 6: CURRENT ELECTRICITY
6.7 Resistivity of various Materials
6.10 Combination of resistorsseries and parallel
CHAPTER – 7: MOVING CHARGES AND
MAGNETISM
7.4 Motion in combined electric and magnetic fields
CHAPTER – 8: MAGNETISM AND MATTER
8.2.2
Bar Magnet as a equivalent solenoid
8.2.3
The dipole in a uniform magnetic field
8.6
Magnetic properties of materials
8.7
Permanent magnets and electromagnets
CHAPTER – 10: ALTERNATING CURRENT
10.7 Power in AC Circuit: The Power Factor
CHAPTER –
11: ELECTRO MAGNETIC WAVES
11.2 Displacement Current
CHAPTER–12: DUAL NATURE OF RADIATION
AND MATTER
12.9 Davisson and Germer Experiment
CHAPTER–14: NUCLEI
14.4.2 Nuclear Binding energy
14.6 Radioactivity
CHAPTER–15
SEMICONDUCTOR ELECTRONICS: MATERIALS, DEVICES AND SIMPLE CIRCUITS
15.8.1 Zener diode
15.9.3
Transistor as a device
15.9.4
Transistor as an amplifier (CE configuration)
15.9.5
Feedback amplifier and transistor oscillator
****
CHEMISTRY
1) ATOMIC STRUCTURE: Introduction; Sub atomic
particles; Atomic models – Thomson’s Model; Rutherford’s Nuclear model of atom,
Drawbacks; Developments to the Bohr’s model of atom; Nature of electromagnetic
radiation; Particle nature of electromagnetic radiation Planck’s quantum
theory; Bohr’s model for Hydrogen atom; Explanation of line spectrum of
hydrogen; Limitations of Bohr’s model; Quantum mechanical considerations of sub
atomic particles; Dual behaviour of
matter; Heisenberg’s uncertainty principle; Quantum mechanical model of an
atom. Important features of Quantum mechanical model of atom; Orbitals and
quantum numbers; Shapes of atomic orbitals; Energies of orbitals; Filling of
orbitals in atoms. Aufbau Principle, Pauli’s exclusion Principle and Hund’s
rule of maximum multiplicity; Electronic configurations of atoms; Stability of
half filled and completely filled orbitals.
2) CLASSIFICATION OF ELEMENTS AND PERIODICITY IN
PROPERTIES: Need to classify elements; Genesis of periodic classification; Modern
periodic law and present form of the
periodic table; Nomenclature of elements with atomic number greater than 100;
Electronic configuration of elements and the periodic
table; Electronic configuration and types of elements
s, p, d and f blocks; Trends in physical properties: (a) Atomic radius, (b)
Ionic radius (c) Variation of size in inner transition elements, (d) Ionization
enthalpy, (e) Electron gain enthalpy, (f) Electro negativity; Periodic trends
in chemical properties: (a) Valence or Oxidation states, (b) Anomalous properties
of second period elements  diagonal relationship; Periodic trends and chemical reactivity.
3) CHEMICAL BONDING AND MOLECULAR STRUCTURE: Kossel  Lewis approach
to chemical bonding, Octet rule, Representation of simple molecules, formal
charges, limitations of octet rule; Ionic or electrovalent bond  Factors
favorable for the formation of ionic compoundsCrystal structure of sodium
chloride, Lattice enthalpy; General properties of ionic compounds; Bond Parameters  bond length, bond angle,
bond enthalpy, bond order, resonance  Polarity
of bonds dipole
moment; Valence Shell Electron Pair Repulsion (VSEPR) theory; Predicting the geometry of
simple molecules; Valence bond theoryOrbital overlap conceptDirectional
properties of bondsoverlapping of atomic orbitals, strength
of sigma and pi bondsFactors favouring the formation of covalent bonds;
Hybridisation different types of hybridization involving s, p and d orbitals
shapes of simple covalent molecules; Coordinate bond definition with examples;
Molecular orbital theory  Formation of molecular orbitals, Linear combination
of atomic orbitals (LCAO)conditions for combination of atomic orbitals
 Energy level diagrams for molecular orbitals Bonding in some homo
nuclear diatomic
molecules H2, He2, Li2, B2, C2, N2 and
O2; Hydrogen
bondingcause of formation of hydrogen bond  Types of hydrogen
bondsinter and intra molecularGeneral properties of hydrogen bonds.
4) STATES OF MATTER: GASES AND LIQUIDS: Intermolecular
forces; Thermal Energy; Intermolecular forces vs Thermal interactions; The Gaseous State; The Gas Laws; Ideal gas
equation; Graham’s law of diffusion  Dalton’s Law of partial pressures;
Kinetic molecular theory of gases; Kinetic gas equation of an ideal gas (No
derivation); deduction of gas laws from Kinetic gas equation; Distribution of
molecular speeds  rms, average and most probable speedsKinetic energy of gas
molecules; Behaviour of real gases  Deviation from Ideal gas behaviour 
Compressibility factor vs Pressure
diagrams of real gases; Liquefaction of gases; Liquid State  Properties of
Liquids in terms of Inter molecular interactions  Vapour
pressure, Viscosity and Surface tension (Qualitative idea only. No
mathematical derivation).
5) STOICHIOMETRY: Some basic concepts  Properties
of matter  uncertainty in Measurementsignificant figures, dimensional
analysis; Laws of Chemical Combinations  Law of Conservation of Mass, Law of
Definite Proportions, Law of Multiple Proportions, GayLussac’s Law of Gaseous
Volumes, Dalton’s Atomic Theory, Avogadro’s Law, Atomic and molecular masses
mole concept and molar mass. Concept of equivalent weight; Percentage
composition of compounds and calculations of empirical and molecular formulae
of compounds; Stoichiometry and stoichiometric calculations; Methods of
expressing concentrations of solutionsmass percent, mole fraction, molarity,
molality and normality; Redox reactionsclassical idea of redox reactions,
oxidation and reduction reactionsredox reactions in terms of electron
transfer; Oxidation number concept; Types of Redox reactions combination,
decomposition, displacement and disproportionation reactions; Balancing of redox reactions  oxidation number
method Half reaction (ionelectron) method; Redox reactions in Titrimetry.
6) THERMODYNAMICS: Thermodynamic Terms; The system
and the surroundings; Types of systems
and surroundings; The state of the system;
The Internal Energy
as a State Function.
(a) Work (b) Heat (c) The general
case, the first law of Thermodynamics; Applications; Work; Enthalpy, H a useful new state function; Extensive and
intensive properties; Heat capacity; The relationship between Cp and Cv;
Measurement of DU and DH:
Calorimetry; Enthalpy change, DrH of reactions 
reaction Enthalpy (a) Standard enthalpy of reactions, (b) Enthalpy changes during phase
transformations, (c) Standard enthalpy of formation, (d) Thermo chemical
equations (e) Hess’s law of constant heat summation; Enthalpies for different
types of
reactions. (a) Standard enthalpy of combustion (∆cH^{q}), (b) Enthalpy of atomization (∆aH^{q}), phase transition, sublimation and ionization, (c) Bond
Enthalpy (∆bondH^{q} ), (d) Enthalpy of solution (∆solH^{q}) and dilution; Spontaneity. (a) Is decrease in enthalpy
a criterion for spontaneity?
(b) Entropy and spontaneity, the second law of thermodynamics, (c) Gibbs Energy and spontaneity; Gibbs Energy
change and equilibrium; Absolute entropy and the third law of thermodynamics.
7) CHEMICAL EQUILIBRIUM AND ACIDSBASES: Equilibrium in
Physical processes; Equilibrium in chemical processes
 Dynamic Equilibrium; Law of chemical
Equilibrium  Law of mass action and Equilibrium
constant; Homogeneous Equilibria, Equilibrium constant in gaseous systems.
Relationship between KP and
Kc; Heterogeneous Equilibria; Applications of Equilibrium constant; Relationship between
Equilibrium constant K, reaction quotient Q and Gibbs energy G; Factors
affecting Equilibria.Le Chatelier’s principle application to industrial
synthesis of Ammonia and Sulphur trioxide; Ionic Equilibrium in solutions;
Acids, bases and salts Arrhenius,
BronstedLowry and Lewis concepts of acids and bases; Ionisation of Acids and
Bases Ionisation constant of water and its ionic product pH scaleionisation constants of weak acidsionisation of weak basesrelation between Ka and KbDi and poly basic acids and di and poly acidic BasesFactors
affecting acid strengthCommon ion effect in the ionization of acids and
basesHydrolysis of salts and pH of their solutions; Buffer solutions
designing of buffer solutionPreparation of Acidic buffer; Solubility
Equilibria of sparingly soluble salts. Solubility product constant, Common ion
effect on solubility of ionic salts.
8) HYDROGEN AND ITS COMPOUNDS: Position of
hydrogen in the periodic table; DihydrogenOccurrence and Isotopes; Preparation
and properties of Dihydrogen; Hydrides: Ionic, covalent, and nonstoichiometric
hydrides; Water: Physical properties; structure of water, ice. Chemical
properties of water; hard and soft water, Temporary and permanent hardness of water; Hydrogen
peroxide: Preparation; Physical
properties; structure and chemical
properties; storage and uses; Heavy Water; Hydrogen as a fuel.
9) THE s  BLOCK ELEMENTS (ALKALI AND ALKALINE EARTH
METALS) Group 1 Elements : Alkali metals; Electronic configurations; Atomic and
Ionic radii; Ionization enthalpy; Hydration enthalpy; Physical properties;
Chemical properties; Uses; General characteristics of the compounds of the
alkali metals: Oxides; Halides; Salts of oxo Acids; Anomalous properties of Lithium: Differences and similarities with other alkali
metals, Diagonal relationship; similarities between Lithium and
Magnesium; Some important compounds of Sodium: Sodium Carbonate; Sodium
Chloride; Sodium Hydroxide; Sodium hydrogen
carbonate; Biological importance of Sodium and
Potassium.
Group 2 Elements: Alkaline earth elements; Electronic configuration; Ionization
enthalpy; Hydration enthalpy; Physical properties, Chemical properties; Uses;
General characteristics of compounds
of the Alkaline Earth Metals: Oxides, hydroxides, halides, salts of oxoacids
(Carbonates; Sulphates and Nitrates); Anomalous behavior of Beryllium; its
diagonal relationship with Aluminium; Some important compounds of calcium: Preparation and uses of Calcium Oxide; Calcium Hydroxide;
Calcium Carbonate; Plaster of Paris; Cement;
Biological importance of Calcium and
Magnesium.
10)
p BLOCK ELEMENTS GROUP 13
(BORON FAMILY):
General introduction  Electronic configuration, Atomic radii,
Ionization enthalpy, Electro negativity; Physical & Chemical properties;
Important trends and anomalous properties of boron; Some important compounds of
boron  Borax, Ortho boric acid, diborane; Uses of boron, aluminium and their
compounds.
11)
pBLOCK ELEMENTS  GROUP 14
(CARBON FAMILY):
General introduction  Electronic configuration, Atomic radii,
Ionization enthalpy, Electro negativity; Physical & Chemical properties;
Important trends and anomalous properties of carbon; Allotropes of carbon; Uses
of carbon; Some important compounds of carbon and silicon – carbon monoxide,
carbon dioxide, Silica, silicones, silicates and zeolites.
12)
ENVIRONMENTAL CHEMISTRY:
Definition of terms: Air, Water and Soil Pollutions; Environmental
Pollution; Atmospheric pollution; Tropospheric Pollution; Gaseous Air
Pollutants (Oxides of Sulphur; Oxides of Nitrogen; Hydrocarbons; Oxides of Carbon (CO,
CO2)). Global warming and Greenhouse effect; Acid rain Particulate Pollutants Smog; Stratospheric
Pollution: Formation and breakdown of Ozone Ozone hole effects of depletion
of the Ozone Layer; Water Pollution: Causes of Water Pollution; International
standards for drinking water; Soil Pollution: Pesticides, Industrial Wastes;
Strategies to control environmental pollution waste Management collection and
disposal; Green Chemistry: Green chemistry in daytoday life; Dry cleaning of
clothes; Bleaching of paper; Synthesis of chemicals
13)
ORGANIC CHEMISTRYSOME BASIC
PRINCIPLES, TECHNIQUES AND HYDROCARBONS
SOME BASIC PRINCIPLES AND TECHNIQUES
General introduction; Tetravalency of Carbon: shapes of organic
compounds; Structural representations of organic compounds; Classification of
organic compounds; Nomenclature of organic compounds; Isomerism;
Fundamental concepts in organic reaction mechanisms; Fission of covalent bond;
Nucleophiles and electrophiles; Electron movements in organic reactions;
Electron displacement effects in covalent bonds: inductive effect, resonance,
resonance effect, electromeric effect, hyperconjugation; Types of Organic
Reactions; Methods of
purification of organic compounds; Qualitative elemental analysis of organic
compounds; Quantitative elemental analysis of organic compounds.
HYDROCARBONS
Classification of Hydrocarbons; Alkanes
 Nomenclature, isomerism (structural and conformations of ethane only);
Preparation of alkanes; Properties  Physical properties and chemical
Reactivity, Substitution reactions  Halogenation(free radical mechanism),
Combustion, Controlled Oxidation, Isomerisation, Aromatization, reaction with
steam and Pyrolysis; Alkenes Nomenclature,
structure of ethene, Isomerism (structural and geometrical); Methods of
preparation; Properties Physical and chemical reactions: Addition of Hydrogen,
halogen, water, sulphuric acid, Hydrogen halides (Mechanism ionic and peroxide effect, Markovnikov’s,
antiMarkovnikov’s or Kharasch effect). Oxidation, Ozonolysis and
Polymerization; Alkynes  Nomenclature
and isomerism, structure of acetylene. Methods
of preparation of acetylene; Physical
properties, Chemical reactions acidic character of acetylene, addition reactions of hydrogen,
Halogen, Hydrogen halides and water.
Polymerization; Aromatic Hydrocarbons: Nomenclature
and isomerism, Structure of benzene, Resonance and aromaticity; Preparation of
benzene. Physical properties. Chemical properties: Mechanism of electrophilic
substitution. Electrophilic substitution reactions Nitration, Sulphonation,
Halogenation, FriedelCrafts alkylation and acylation; Directive influence of
functional groups in mono substituted benzene, Carcinogenicity and toxicity
14)
SOLID STATE:
General characteristics of solid state; Amorphous and crystalline
solids; Classification of crystalline solids based on different binding forces
(molecular, ionic, metallic and covalent solids); Probing the structure of
solids: Xray crystallography; Crystal lattices and unit cells. Number of atoms
in a unit cell (primitive, body centred and face centred cubic unit cell);
Close packed structures: Close packing in one dimension, in two dimensions and
in three dimensions tetrahedral and
octahedral voids formula of a compound and number of voids filledlocating
tetrahedral and octahedral voids; Packing efficiency in simple cubic, bcc and
in hcp, ccp lattice; Calculations involving unit cell dimensionsdensity of the
unit cell; Imperfections in solidstypes of point defectsstoichiometric and
nonstoichiometric defects.
15)
SOLUTIONS:
Types of solutions; Expressing concentration of solutions  mass
percentage, volume percentage, mass by volume percentage, parts per million,
mole fraction, molarity and molality; Solubility: Solubility of a solid in a liquid, solubility of a gas in a liquid, Henry’s
law; Vapour pressure of liquid solutions: vapour pressure of liquid
liquid solutions. Raoult’s law as a special case of Henry’s law vapour
pressure of solutions of solids in liquids; Ideal and nonideal solutions;
Colligative properties and determination of molar massrelative lowering of vapour
pressureelevation of boiling
pointdepression of freezing
pointosmosis and osmotic pressurereverse osmosis and water purification.
16) ELECTROCHEMISTRY AND CHEMICAL KINETICS: ELECTROCHEMISTRY:
Nernst
equationequilibrium constant from Nernst equation  electro chemical cell and
Gibbs
energy of the cell reaction; Conductance of electrolytic solutions 
measurement of the conductivity of ionic solutionsvariation of conductivity
and molar conductivity with concentrationstrong electrolytes and weak
electrolytesapplications of Kohlrausch’s law; Electrolysis: Faraday’s laws of
electrolysisproducts of electrolysis.
CHEMICAL KINETICS:
Rate of a chemical reaction; Factors influencing rate of a reaction:
dependance of rate on concentration rate expression and rate constant order of a reaction,
molecularity of a reaction; Integrated rate equationszero
order reactionsfirst order reactions  half life of a reaction;
Pseudo first order reaction; Temperature dependence of the rate of a reaction 
Effect of catalyst.
17) SURFACE CHEMISTRY: Adsorption and absorption:
Distinction between adsorption and absorptionmechanism of adsorptiontypes of
adsorptioncharacteristics of physisorption characteristics of
chemisorptionadsorption isothermsadsorption from solution phase applications
of adsorption.
Colloids; Classification of colloids: Classification based on
physical state of dispersed phase and dispersion medium classification based
on nature of interaction between dispersed phase and dispersion medium
classification based on type of particles of the dispersed phase multi
molecular, macromolecular and associated colloids cleansing action of
soapspreparation of colloidspurification of colloidal solutions properties
of colloidal solutions: Tyndal effect, colour, Brownian movementcharge on colloidal
particles, electrophoresis. Coagulation or precipitation, Coagulation of
lyophilic sols, protection of colloids, Colloids around us, Applications of
colloids.
18) pBLOCK ELEMENTS:
GROUP15 ELEMENTS: Occurrence electronic configuration, atomic and ionic radii,
ionisation enthalpy, electronegativity, physical and chemical properties;
Dinitrogen preparation, properties and uses; Compounds of
nitrogenpreparation, properties and uses of ammonia; Oxides of nitrogen; Preparation and properties and uses of nitric acid; Phosphorous
allotropic forms;
GROUP16 ELEMENTS: Occurrence electronic configuration, atomic and ionic radii,
ionisation enthalpy, electron gain enthalpy, electronegativity, physical and
chemical properties; Dioxygenpreparation, properties and uses; Simple oxides;
Ozonepreparation, properties, structure and uses; Sulphurallotropic forms;
Sulphur dioxidepreparation, properties and uses; Oxoacids of sulphur;
Sulphuric acid properties and uses only.
GROUP17 ELEMENTS: Occurrence, electronic configuration, atomic and ionic radii,
ionisation enthalpy, electron
gain enthalpy, electronegativity, physical and chemical
properties; Chlorine preparation, properties and uses; Hydrogen
chloride preparation, properties and uses; Oxoacids of halogens; Interhalogen compounds.
GROUP18 ELEMENTS: Occurrence, electronic configuration, ionization enthalpy, atomic
radii, electron gain enthalpy, physical and chemical properties(a)
Xenonfluorine compounds

XeF2, XeF4 and XeF6 preparation,
hydrolysis and formation of
fluoro anionsstructures of XeF2, XeF4 and XeF6 (b)
Xenonoxygen compounds XeO3 and XeOF4  their
formation and
structures. Uses.
19) d AND f BLOCK ELEMENTS & COORDINATION COMPOUNDS:
d AND f BLOCK ELEMENTS :Position in the periodic
table; Electronic configuration of the dblock
elements; General properties of the transition elements (dblock) physical
properties, variation in atomic and ionic sizes of transition series,
ionisation enthalpies, oxidation states, trends in the M²+/M
and M³+/M²+ standard electrode potentials, trends in stability of higher
oxidation states, chemical reactivity and Eθ values, magnetic
properties, formation of coloured ions, formation of complex compounds, catalytic properties, formation of
interstitial compounds, alloy formation.
COORDINATION COMPOUNDS: Werner’s theory of coordination compounds; Definitions of
some terms used
in coordination compounds; Nomenclature of coordination compoundsIUPAC nomenclature;
Isomerism in coordination compounds
(a)Stereo isomerismGeometrical and optical isomerism (b)Structural
isomerismlinkage, coordination, ionisation and hydrate isomerism; Bonding in
coordination compounds. (a)Valence bond theory  magnetic properties of
coordination compoundslimitations of valence bond theory (b) Crystal field
theory (i) Crystal field splitting in octahedral and tetrahedral coordination
entities (ii) Colour in coordination compoundslimitations of crystal field
theory; Bonding in metal carbonyls; Stability of coordination compounds;
Importance and applications of coordination compounds.
20) BIOMOLECULES: Carbohydrates Classification
of carbohydratesMonosaccharides: preparation of glucose from sucrose and
starch Properties and structure of glucose  D, L and (+), () configurations
of glucose Structure of fructose.
Amino acids: Natural amino acids  classification of amino acids  structures and
D and L formsZwitterions; Proteins: Structures,
classification, fibrous and globular primary, secondary, tertiary and
quaternary structures of proteins Denaturation of proteins.
Nucleic acids: chemical composition of nucleic acids, structures of nucleic acids, DNA finger printing, biological functions
of nucleic acids.
21) HALOALKANES AND HALOARENES: Classification
and nomenclature; Nature of CX bond; Methods of preparation: Alkyl halides and
aryl halidesfrom alcohols, from hydrocarbons (a) by free radical halogenation
(b) by electrophilic substitution (c) by replacement of diazonium group
(Sandmeyer reaction) (d) by the addition of hydrogen halides and halogens to
alkenesby halogen exchange (Finkelstein reaction); Physical propertiesmelting
and boiling points, density and solubility; Chemical reactions: Reactions of haloalkanes (i) Nucleophilic substitution reactions (a) SN² mechanism (b) SN¹ mechanism
(c) stereochemical aspects of nucleophilic substitution
reactionsoptical activity (ii) Elimination reactions (iii) Reaction with
metalsReactions of haloarenes: (i) Nucleophilic substitution (ii)Electrophilic
substitution and (iii) Reaction with metals.
22)
ORGANIC COMPOUNDS CONTAINING C,
H AND O (Alcohols, Phenols, Ethers, Aldehydes, Ketones and Carboxylic acids):
ALCOHOLS, PHENOLS AND ETHERS
Alcohols, phenols and ethers  classification; Nomenclature:
(a)Alcohols, (b)phenols and
(c) ethers;
Structures of hydroxy and ether functional groups; Methods of preparation: Alcohols from alkenes and carbonyl
compounds (reduction and reaction with Grignard reagents); Phenols from haloarenes, benzene sulphonic acid, diazonium salts,
cumene; Physical properties of alcohols and phenols; Chemical reactions of
alcohols and phenols (i) Reactions involving cleavage of OH bondAcidity of
alcohols and phenols, esterification (ii) Reactions involving cleavage of CO bond 
reactions with HX, PX3,
dehydration and oxidation (iii) Reactions of
phenols  electrophilic aromatic substitution, Kolbe’s reaction, Reimer 
Tiemann reaction, reaction with zinc dust, oxidation.
EthersMethods of preparation: By dehydration of alcohols, Williamson
synthesis  Physical Properties 
Chemical reactions: Cleavage of CO bond and electrophilic substitution of
aromatic ethers.
ALDEHYDES AND KETONES
Nomenclature and structure
of carbonyl group; Preparation of aldehydes and ketones
(1) by oxidation of
alcohols (2) by dehydrogenation of alcohols (3) from hydrocarbons  Preparation
of aldehydes (1) from acyl chlorides (2) from nitriles and esters (3) from
hydrocarbonsPreparation of ketones
(1) from acyl chlorides (2) from nitriles
(3) from benzene or substituted benzenes; Physical properties of aldehydes and ketones;
Chemical reactions of
aldehydes and
ketonesnucleophilic addition, reduction, oxidation, reactions due to alpha
Hydrogen and other reactions (Cannizzaro reaction, electrophilic substitution
reaction); Uses of aldehydes and ketones.
CARBOXYLIC ACIDS
Nomenclature and structure of
carboxyl group; Methods of preparation
of carboxylic acids (1)from primary alcohols and aldehydes
(2) from alkylbenzenes(3)from nitriles and amides (4)from Grignard reagents (5)
from acyl halides and anhydrides (6) from esters; Physical properties; Chemical reactions: (i) Reactions involving cleavage of OH bondacidity,
reactions with metals and alkalies (ii) Reactions involving cleavage of COH
bondformation of anhydride, reactions with PCl5, PCl3, SOCl2, esterification and reaction with ammonia
(iii) Reactions involvingCOOH groupreduction, decarboxylation (iv)
Substitution reactions in the hydrocarbon part  halogenation and ring
substitution; Uses of carboxylic acids.
23) ORGANIC COMPOUNDS CONTAINING NITROGEN:
AMINES
Structure of amines; Classification; Nomenclature; Preparation of
amines: reduction of nitro compounds, ammonolysis of alkyl halides, reduction
of nitriles, reduction of amides, Gabriel phthalimide synthesis and Hoffmann
bromamide degradation reaction; Physical properties; Chemical reactions: basic
character of amines, alkylation, acylation, carbyl amine reaction, reaction
with nitrous acid, reaction with
aryl sulphonyl chloride, electrophilic substitution of aromatic
aminesbromination, nitration and Sulphonation.
The
following topics are the deleted content of CHEMISTRY (30%) in the Intermediate
Second Year for the Academic Year 202021 by the TSBIE as per Telugu
Academy text Book. The same is deleted for the TS EAMCET2021 Examination.
Chapter 1
Solid state
1.11 Electrical properties
1.12 Magnetic
properties (Band theory of metals, conductors, semiconductors and insulators and n and p type semiconductors)
Chapter 2 Solutions
2.7 Abnormal molar massesVan’t Hoff factor.
Chapter
3 Electrochemistry and Chemical Kinetics Electrochemistry
3.1 Electrochemical cells
3.2 Galvanic cells
3.5 Electrolytic
cells
3.6 Batteries:
primary and secondary batteries
3.7 Fuel cells
3.8 Corrosion
of metalsHydrogen economy
Chemical kinetics
3.14 Collision theory of chemical reaction rates.
Chapter 4 Surface Chemistry
4.2 catalysis,
homogenous and heterogenous, Adsorption theory of heterogenous catalysis,
activity and selectivity of solid catalysis, Shapeselective catalysis by
zeolites, Enzyme catalysis, Catalysts in industry.
4.5 Emulsions – types of emulsions
Chapter 5 General Principles of Metallurgy
Entire chapter is deleted
Chapter 6 Pblock Elements Group15 Elements
6.7
Phosphinepreparation, properties and uses
6.8
Phosphorous halides
6.9
Oxoacids of phosphorous
Group 16
Elements
6.17 Sulphuric acidmanufacture.
Chapter 7 d and f Block Elements & Coordination
Compounds d and f Block Elements
7.4
Some important compounds of transition elements
7.5
Inner transition elements
7.6
Actinoids
7.7
Some applications of d and f block elements.
Chapter 8
Polymers
Entire chapter is deleted
Chapter 9
Biomolecules
9.1 Disaccharides (sucrose, lactose, maltose),
polysaccharides (starch, cellulose, glycogen), importance of carbohydrates.
9.3 Enzymes:
Enzymes, mechanism of enzyme action
9.4 Vitamins
9.6 Hormones.
Chapter 10
Chemistry in Everyday life
Entire chapter is deleted
Chapter 11
Halo Alkanes and Halo Arenes
11.6 Polyhalogeno compounds.
Chapter 12 Organic Compounds
Containing C, H and O
12.7
Some Commercially important
alcohols (uses with special reference to methanol and ethanol)
Chapter 13
Organic Compounds Containing Nitrogen
II. Diazonium salts
13.7 Methods
of preparation of diazonium salts
13.8 Physical properties
13.9 Chemical reactions
13.10 Importance
of diazonium salts in synthesis of aromatic compounds
III. Cyanides and
Isocyanides
13.11 Structure
and nomenclature of cyanides and isocyanides
13.12 Preparation,
physical properties and chemical reactions of cyanides and isocyanides.
****