Apply for KCET Online Is it Possible or Not

I want to apply for KCET Medical exam online is it possible or not, please provide me information about it ?

[Raman Vij]

Yes you can apply for this exam Online, and as you want to get dates of this exam so here I am giving you tentative dates of this exam because exam date has been gone for this year you can apply for this in next year.

Tentative dates:
Last Day to Pay Bank Fee after downloading Challan
First week of April 2015

Last date for submitting Demand Draft by Speed Post
First week of April 2015

Availability of KCET Medical brochure cum application form
Last week of March 2015

Last Date for Receipt of Application Form
First week of April 2015

Karnataka CET Exam Date
First week of May 2015

Here I am giving you syllabus of this exam:
Physics
1. INTRODUCTION

Introduction to Physics SI units - dimensions - dimensional formulae - dimensional analysis -

limitations Scalars and vectors - unit vector - vector addition - resolution of a vector - scalar

and vector products

2. DYNAMICS

Motion of a particle in one dimension - derivations of equations of motion velocity - time curve.

- Problems Newton’s laws of motion, f=ma derivation - conservation of momentum (statement and to

arrive at) - illustrations - problems Motion in two dimensions - equation for the trajectory of a

projectile - range, height and time of flight - uniform circular motion - centripetal

acceleration (derivation of expression) - centripetal and centrifugal forces with illustrations -

problems Work, energy and power - work done - F.S. - expressions for potential and kinetic energy

- conservation of energy (statement with illustrations - problems) Gravitation - Law of

gravitation - variation of g with altitude, depth and latitude - motion of planets and

satellites - statement of Kepler’s laws, orbital velocity - escape velocity - weightlessness -

problems Rotational motion of rigid body - angular displacement, velocity, acceleration and

momentum, torque - equations for angular motion - moment of inertia - radius of gyration,

comparison of linear and rotational motions - problems Elasticity - stress and strain - Hooke’s

law - moduli of elasticity - expression for Young’s modulus in the case of stretching Simple

harmonic motion - characteristics - examples and equation for SHM (y = a sin wt)

3. STATICS

Coplanar concurrent forces - resultant of two forces - magnitude and direction (derivation)

equilibrium of three forces - law of triangle of forces - Lami’s theorem - problems Moment of a

force - law of moment (statement) - application to find the resultant of two parallel forces -

couple - statement of conditions of equilibrium of parallel forces - problems

4. HYDROSTATICS AND HYDRODYNAMICS

Hydrostatics - fluid thrust and pressure - atmospheric pressure (units) pressure at a point due

to a liquid - Archimedes’ principle (statement) - problems Hydrodynamics - streamline and

turbulent flow - Bernoulli’s theorem - explanation with examples Surface tension - cohesion and

adhesion - surface tension and angle of contact - capillary rise (without derivation) Viscosity -

velocity gradient - co-efficient of viscosity - Poiseuille’s formula for the flow of a liquid

through a capillary tube and Stoke’s law (without derivation)

5. HEAT

Heat and temperature - measurement of temperature - Mention of different thermometers - effect of

heat like expansion and change of state Gas laws - absolute scale of temperature - perfect gas

equation - isothermal and adiabatic changes - mention of equations of state - problems Absorption of heat - specific heat - thermal capacity - principle of calorimetry - latent heat – specific heat - specific heats of gases - (Cp - Cv) and their relation (Cp - Cv = R) - degrees of freedom- equipartition of energy - importance of g Conduction of heat - steady state - temperature

gradient - thermal conductivity - problems Radiation - emissive and absorptive powers - Stefan’s

law - Prevost’s theory of exchanges - Kirchhoff’s law - Wien’s displacement law - Plank’s law -

solar constant - temperature of the sun (qualitative treatment of the topics without derivation)

- problems Thermodynamics - relation between heat and work (first law) - heat engine - efficiency

- reversible and irreversible process - Carnot’s cycle - pV diagram - efficiency of a Carnot
engine (without derivation) (Second Law) – problems

For full Syllabus here I am uploading a PDF file:

KCET Medical Syllabus

PHYSICS

1. INTRODUCTION

Introduction to Physics SI units - dimensions - dimensional formulae - dimensional analysis -

limitations Scalars and vectors - unit vector - vector addition - resolution of a vector - scalar

and vector products

2. DYNAMICS

Motion of a particle in one dimension - derivations of equations of motion velocity - time curve.

- Problems Newton’s laws of motion, f=ma derivation - conservation of momentum (statement and to

arrive at) - illustrations - problems Motion in two dimensions - equation for the trajectory of a

projectile - range, height and time of flight - uniform circular motion - centripetal

acceleration (derivation of expression) - centripetal and centrifugal forces with illustrations -

problems Work, energy and power - work done - F.S. - expressions for potential and kinetic energy

- conservation of energy (statement with illustrations - problems) Gravitation - Law of

gravitation - variation of g with altitude, depth and latitude - motion of planets and

satellites - statement of Kepler’s laws, orbital velocity - escape velocity - weightlessness -

problems Rotational motion of rigid body - angular displacement, velocity, acceleration and

momentum, torque - equations for angular motion - moment of inertia - radius of gyration,

comparison of linear and rotational motions - problems Elasticity - stress and strain - Hooke’s

law - moduli of elasticity - expression for Young’s modulus in the case of stretching Simple

harmonic motion - characteristics - examples and equation for SHM (y = a sin wt)

3. STATICS

Coplanar concurrent forces - resultant of two forces - magnitude and direction (derivation)

equilibrium of three forces - law of triangle of forces - Lami’s theorem - problems Moment of a

force - law of moment (statement) - application to find the resultant of two parallel forces -

couple - statement of conditions of equilibrium of parallel forces - problems

4. HYDROSTATICS AND HYDRODYNAMICS

Hydrostatics - fluid thrust and pressure - atmospheric pressure (units) pressure at a point due

to a liquid - Archimedes’ principle (statement) - problems Hydrodynamics - streamline and

turbulent flow - Bernoulli’s theorem - explanation with examples Surface tension - cohesion and

adhesion - surface tension and angle of contact - capillary rise (without derivation) Viscosity -

velocity gradient - co-efficient of viscosity - Poiseuille’s formula for the flow of a liquid

through a capillary tube and Stoke’s law (without derivation)

5. HEAT

Heat and temperature - measurement of temperature - Mention of different thermometers - effect of

heat like expansion and change of state Gas laws - absolute scale of temperature - perfect gas

equation - isothermal and adiabatic changes - mention of equations of state - problems Absorption of heat - specific heat - thermal capacity - principle of calorimetry - latent heat – specific heat - specific heats of gases - (Cp - Cv) and their relation (Cp - Cv = R) - degrees of freedom- equipartition of energy - importance of g Conduction of heat - steady state - temperature

gradient - thermal conductivity - problems Radiation - emissive and absorptive powers - Stefan’s

law - Prevost’s theory of exchanges - Kirchhoff’s law - Wien’s displacement law - Plank’s law -

solar constant - temperature of the sun (qualitative treatment of the topics without derivation)

- problems Thermodynamics - relation between heat and work (first law) - heat engine - efficiency

- reversible and irreversible process - Carnot’s cycle - pV diagram - efficiency of a Carnot

engine (without derivation) (Second Law) - problems

6. GEOMETRICAL OPTICS

Introduction to light - optical medium - rectilinear propagation of light Reflection of light -

laws of reflection - reflection at curved surfaces - image formation in the case of spherical

mirrors - mirror formula (without derivation) - sign convention - problems Refraction at a plane

surface - laws of refraction - absolute and relative refractive indices (Symbol n to be used for

RI) - refraction through multiple refracting media - lateral shift and normal shift (expressions

without derivation) - total internal reflection - conditions for total internal reflection -

relation between critical angle and refractive index (n) - applications of optical fibres and

total reflecting prisms - problems Refraction through a prism - derivation of the expression for

the refractive index (n) of the material of a prism in terms of A and D - dispersion through a

prism - deviation produced by a thin prism - dispersive power - prism combination for dispersion

without deviation - problems Refraction at spherical surfaces - derivation of the relation

connecting n,u,v and r for refraction at a spherical surface (concave towards point object in

denser medium) - refraction through a lens - lens maker’s formula - power of a lens - Image

formation in the case of thin lenses, linear magnification - lenses in contact - problems

Spherical and chromatic aberrations - qualitative discussion - achromatic combination of lenses

Optical instruments - microscopes, telescopes, prism binoculars, direct vision spectroscope and

spectrometer (qualitative) Photometry - basic concepts - units - principle of photometry -

problems

7. WAVES AND SOUND

· Waves: formation of waves, types of waves, wave amplitude, frequency,

wave length and velocity - relation n =f l - equation for progressive wave,

intensity, super position of waves. Problems

· Sound: Properties, velocity in gases, Newton - Laplace formula, factors affecting velocity -

intensity and loudness, units, Noise and Music beats as an example of superposition of waves,

Doppler effect, formula for general case, discussion for individual cases. Problems

· Stationary waves: Modes of vibration in pipes, laws of vibration of stretched strings,

sonometer, Problems.

· Ultrasonics: Production (mention of methods), properties and applications

· Acoustics of buildings: reverberation, Sabine’s formula (mention), requisites for good

acoustics and methods of achieving them.

8. PHYSICAL OPTICS

· Introduction to theories of light

· Interference of light: Coherent sources, Young’s double slit experiment, expression for path

difference, conditions for constructive and destructive interference, width of interference

fringes. Problems

· Diffraction of light: Fresnel and Fraunhofer diffraction, Fraunhofer diffraction through a

single slit (qualitative explanation), limit of resolution, Rayleigh’s criterion, resolving

powers of telescopes and microscope. Problems

· Polarisation of light: transverse nature of light waves, methods of producing plane polarised

light, Brewster’s law, double refraction, dichroism, polariods and their applications, optical

activity and specific rotation. Problems.

9. ELECTROSTATICS

· Electric charge: Coulomb’s law, dielectric constant, SI unit of charge, electric intensity and

potential, relation connecting them, derivation of expression for potential at a point due to an

isolated charge. Gauss theorem and applications, intensity at a point (a) due to a charged

spherical conductor (b) near the surface of a charged conductor, Problems

· Capacitors: parallel plate, spherical, cylindrical, expressions for the capacitances, principle

of a capacitor, effect of dielectric, energy stored in a capacitor, combination of capacitors,

uses, Problems

10. CURRENT ELECTRICITY

· Different effects of electric current: potential difference, resistance, colour code, Ohm’s law

and its limitations, variation of resistance of a conductor with length- area of cross section

and temperature, resistivity, superconductivity, thermistor and its applications, combination of

resistors, EMF of a cell, current in a circuit, branch currents, grouping of cells, expression

for different cases, potentiometer, problems

· Kirchhoff’s laws: Condition for balance of a Wheatstone’s bridge, metre bridge, Problems

· Magetic effect of current: direction of field, right hand clasp rule and magnitude - Laplace’s

law, force on a charged particle moving across a magnetic field (qualitative), magnetic field

strength, flux density, magnetic flux density at a point on the axis of (a) a circular coil

carrying current (derivation), (b) a solenoid carrying current (without derivation), tangent law,

tangent galvanometer (with theory), Problems

· Force on a current carrying conductor in a magnetic field: Fleming’s left hand rule, force

between two parallel conductors carrying current, definition of ampere, suspended coil

galvanometer (with theory), conversion of galvanometer into ammeter and voltmeter, Problems

· Magnetic materials: Intensity of Magnetising field (H), intensity of magnetisation (I) and

magnetic induction (B) - relation connecting them, permeability and susceptibility, properties of

dia, para and ferromagnetic substances, hysteresis cycle and its significance, retentivity and

coercivity, uses of magnetic materials.

· Electromagnetic induction: Laws, self and mutual induction, induction coil (principle),

principle and working of a generator, expression for sinusoidal emf, peak, mean and rms values,

impedance, current in R, L & C and RLC circuits, power factor, choke and transformer (principle),

principles of a ac meters (moving iron and hot wire types) Problems.



11. MODERN PHYSICS

· Introduction to modern physics: types of spectra, E. M. spectrum, types of electron emission.

· Quantum theory of radiation: Explanation and applications of photoelectric effect, atom models,

Bohr’s theory of hydrogen atom, derivation of expressions for orbital radius, orbital velocity,

energy of electron and wave number, spectral series, energy level diagram, de Broglie matter

waves, Problems.

· Nuclear Physics: Nuclear size, charge, mass and density, constituents, amu in terms of electron

volts, magnetic moment and nuclear forces, mass defect and binding energy, nuclear fission, chain

reaction, critical size, nuclear reactor, nuclear fusion, stellar energy, radiation hazards,

Problems.

· Radioactivity: Properties of radioactive radiations, decay law, decay constant, Soddy’s group

displacement law, half life and mean life, expression for half life, radio isotopes and their

uses, Problems.

· Solid state electronics: Band theory of solids (qualitative), classification into conductors,

insulators and semi conductors, p-type and n-type semi conductors, characteristics of p-n

junction, rectifying action of diode, half wave and full wave rectifiers. Transistors, pnp and

npn, characteristics, relation between alph and beta transistors as an amplifier (qualitative

-npn in CE mode)

CHEMISTRY

1. KINETIC THEORY OF GASES

Postulates, Derivation of expression for pressure of a gas. (PV = 1/3mnc2) Deduction of gas laws,

Boyle’s law, Charle’s law, Graham’s law of diffusion and Dalton’s law of partial pressures.

Expression for Kinetic energy and RMS velocities of gases (problems based on these) Ideal and

real gases. Deviation of real gases from ideal behaviour. Derivation of Van der Waal’s equation.

2. STOCHIOMETRY

Mole concept and Avogadro number (Problems)

Atomic weight: Definition with evaluation of atomic weight by Dulong and Petit’s law (problems)

Equivalent weight of elements ; definition, methods of determination (hydrogen displacement,

oxide and chloride methods) (problems)

Equivalent weights of acids and bases, oxidising, reducing agents. Concept of normality, molality

and molarity.

Volumetric analysis: Calulations involving acid-base and red-ox titrations. (Problems)

Empirical and Molecular formula from % composition (problems) Relation between vapour density and molecular weight. Molecular weight of oxygen and carbon dioxide and volatile liquids (Victor Meyer’s method)

(problems)

3. ATOMIC STRUCTURE

Fundamental particles (electron, proton & neutron) Rutherford’s model of the atom. Bohr’s

theory-postulates (derivation of expression of energy and radius to be omitted) spectrum of

Hydrogen Balmer, Lyman and Brackett series. Explanation on the basis of Bhor’s theory. Quantum numbers - Orbital concepts. Shape of s.p.d. orbital, Pauli’s exclusive principle. Hund’s rule.Electronic configuration of atoms (elements upto atomic number 30)



4. LONG FORM OF PERIODIC TABLE

Based on electronic configuration of elements-periodic properties - ionisation energy and

electron affinity, atomic and ionic radii.

5. CHEMICAL BONDING

Types of bonding (ionic, covalent, coordinate & hydrogen bonding) Covalent bond - orbital

overlap, p-p (Cl2), s-s(H2). Sigma & Pi bonds. Hybrid orbital. Shapes of molecules (CH4, C2H4 and C2H2) Hydrogen bonding - anamolous properties of water.

6. SPECIFIC MATTER

Ozone: Preparation and properties, Ozon layer.

Hydrogen peroxide: preparation, concentration, properties and uses.

Sulphur: Preparation, properties and uses of SO2, Manufacture of H2SO4 by contact process,

properties and uses.

Nitrogen: Nitric acid - Manufacture by Ostwald’s process, properties and uses. Nitrogenous

fertilizers - manufacture of ammonium sulphate from gypsum, CAN, urea, Nitrogen cycle.

Halogens: Preparation, properties and uses of flourine. Manufacture of chlorine (Nelson cell) -

properties and uses. Bromine from sea water. Iodine from sea weeds.

Carbon: Activated carbon. Commericial production, properties and uses of carbon monoxide.

Silicon: Occurrance, preparation, semiconducting properties (n and p type) , silicate glasses.

Phosphorus: Occurrance, manufacture (electrothermal process) Structure of oxyacids of phosphorus. Super phosphate of lime.

Ceramics: Clay properties - white pottery (porcelain’s process or china process) Applications.

7. ORGANIC CHEMISTRY

(IUPAC nomenclature to be adopted)

Aliphatic hydrocarbons: saturated and unsaturated hydrocarbons. Preparation, properties and uses of methane, ethylene and acetylene - homologous series

Isomerism - chain, functional and position

Concepts of free radicals - electrophiles and nucleophiles to be illustrated with the study of

mechanism involving -

1) chlorination of methane

2) addition of bromine to ethylene and

3) addition of hydrogen chloride to propylene (Markownikoff’s rule)

Petroleum - Theory of formation, cracking (catalytic and thermal) fractionation, synthetic petrol

Destructive distillation of coal - separation of benzene, toluene, naphthalene from coal

tar.Structure of benzene. Properties of benzene and toluene. Mechanism of halogenation,

nitration, sulphonation and Friedel - craft’s alkylation

Biogas- Production and uses.

8. ENVIRONMENTAL POLLUTION

· Pollutants, definition - types of pollution, air - Automobile exhaust smoke, CO, oxides of

nitrogen and lead. water - Industrial effluents with relevance to paper and rayon industries.

9. THERMODYNAMICS AND THERMOCHEMISTRY

Law of conservation of energy - Mechanical work done. Isothermal and adiabatic changes – concept of enthalpy - enthalpy of reaction, formation, solution, combustion, transition and

neutralisation - constancy of enthalpy of neutralisation of a strong acid and a strong base

Thermochemical equations - Laplace - Lavoisier law - Hess’s law. Problems

10. CHEMICAL EQUILIBRIUM

Law of mass action, application of law of mass action to the following systems:

i) 2HI <==> H2 + I2

ii) N2 + 3H2 <==> 2NH3

Derivation of KP for both reactions

Le-Chatelier’s principle and its application to the synthesis of Ammonia.

Free energy change - standard free energies - Idea of a system tending to attain a state of

minimum free energy and maximum entropy. Relationship between free energy change and equilibrium constant. Problems

11. REACTION KINETICS

Order and molecularity of a reaction. Derivation of the equation for the velocity constant of a

first order reaction - Half life period - Relationship between half life period and order of the

reaction - Experimental study of the acid hydrolysis of methyl acetate.

Influence of temperature on the velocity of a reaction - Arrhenius theory - Arrhenius factor and

energy of activation. Problems

12. SURFACE CHEMISTRY

· Adsorption - Distinction between adsorption and absorption. Types of adsorption - adsorption of

gases on solids.

· Colloids - Distinction between colloids and crystalloids - classification, preparation of

colloids (electrical and chemical methods, one method each), Purification by dialysis -

Properties: Tyndall effect and Brownian movement. Application in food, medicine, precipitaion of

smoke.

· Catalysis - Characteristics - Influence of catalyst on reaction path. Theories of catalysis

(Intermediate compound theory and adsorption theory)


13. ELECTROCHEMISTRY

· Arrhenius theory of electrolytic dissociation - merits and demerits. Ionic conduction by

migration. Definition of specific, equivalent and molar conductivities - strong and weak

electrolytes.

· Acids and bases - Bronsted - Lowry concept - Lewis concept. Acid-Base equilibrium, Hydrogen ion concentration - pH scale - pK values.

· Buffers - Buffer equation (Henderson’s equation to be assumed). Importance of buffer solutions.

· Ionic equilibrium - solubility product, common ion effect. Applications of solubility product

in qualitative analysis.

· Electrode potential - Nernst equation to be assumed, Standard electrode potential - Hydrogen

electrode - Electro-chemical series and its significance - corrosion of metals.

· Problems





14. SOLIDS

Types of solids - radius ratio (r+ / r-), coordination number - unit cell. Structure of ionic

crystals. Ionic radii - imperfections in solids - superconductivity.


15. RADIOACTIVITY

· Natural radioactivity - Properties of alpha, beta and gamma radiations - rate of disintegration

- Half life period - Isotopes - separation by thermal diffusion method.

· Artificial radioactivity - Rutherford’s artificial nuclear reaction.

7N14 + 2He4Y8O17 + 1H1

Explanation of artificial radioactivity using

13Al27 + 2He4 Y15P30 + 0n1

15P30 Y 14Si30 + +1e0

Preparation and uses of artificial radioactive isotopes - Co60, I131, P32 and Na24

Radioactive dating, Elementary account of fission and fusion.

16. METALLURGY

General principles of metallurgy - Concentration of ores (gravity process, magnetic separation

and froth flotation) - Extraction of crude metal (pyrometallurgy, hydrometallurgy and

electro-metallurgy), Refining (Liquation, poling, electrolytic method)

Occurrence, extraction, properties and uses of Sodium, Copper, Aluminium and Iron. Role of iron

and sodium in biological systems. Manufacture of steel by LD process, Properties of steel (carbon

content) Heat treatment - alloy steels.

17. COORDINATION COMPOUNDS

Postulates of Werner’s theory - Sidgwick’s interpretation - concept of EAN using Potassium

ferrocyanide, potassium ferricyanide and cuprammonium sulphate.

18. MANUFACTURE, properties, uses of Sodium hydroxide (Nelson’s cell), Sodium Carbonate - Alum.

19. ORGANIC CHEMISTRY

· Preparation, Properties and Uses of the following:

· Alkyl halides 1) Ethyl bromide and isopropyl chloride 2) Vinyl chloride

· Aromatice halogen compounds: 1) Chlorobenzene and benzyl chloride, comparison of reactives with

alkyl halides. 2) Grignard reagent and its synthetic applications.

· Alcohols - Ethyl alcohol (Manufacture from molasses), Benzyl alcohol

· Phenol

· Aldehydes and ketones - Formaldehyde, Acetaldehyde, Benzaldehyde, Acetone, Acetophenone.

· Acids - Formic, Acetic, Benzoic, Salicylic acids.

· Esters - Ethyl acetate, Ethyl benzoate

· Amines - Methylamine, Aniline

20. POLYMERS

Classification - Synthetic and natural, preparation and uses of polythene, nylon, terylene.

Natural rubber.





21. CARBOHYDRATES

Classification - Monosaccharides - open and ring structure of glucose, fructose, galactose

Oligosaccharides - Ring structure of sucrose, maltose and lactose

Polysaccharides - Partial representation of structure of cellulose, starch and glycogen -

Carbohydrates as a source of energy.


22. OILS AND FATS

Chemical nature of fatty acids - saturated and unsaturated fatty acids - Examples. Triglycerides

- General structure of triglycerides - Hydrolysis with acid and saponification.

Rancidity - Refining and hydrogenation of oils - drying oils.

23. PROTEINS

Amino acids as building units of proteins. General structure of amino acids such as glycine,

alanine, serine, cysteine, aspartic acid, lysine, tyrosine, peptide linkage. Functional

properties of proteins as enzymes, antibodies, transport agents, biochemical messengers

(hormones-insulin and oxytocin) and structural material.

24. NUCLEIC ACIDS

Types - DNA and RNA - Components - purine and pyrimidine bases, sugars and phosphates -

Biological importance of nucleic acids.

25. CHEMOTHERAPY

Antipyretics - Aspirin, Antibiotics - Penicillin, Analgesics - Paracetamol

Antiseptic - chloroxylenol (dettol), Antimalarial - chloroquine Tranquilizers - Barbituric acid

· Structure and uses of the above.