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Syllabus

t is given that the energy of the electron beam used to bombard gaseous hydrogen at room temperature is 12.5 eV. Also, the energy of the gaseous hydrogen in its ground state at room temperature is 13.6 eV.

When gaseous hydrogen is bombarded with an electron beam, the energy of the gaseous hydrogen becomes 13.6 + 12.5 eV i.e., 1.1 eV.

Orbital energy is related to orbit level (n)as:

Forn= 3,

This energy is approximately equal to the energy of gaseous hydrogen. It can be concluded that the electron has jumped fromn= 1 ton= 3 level.

During its de-excitation, the electrons can jump fromn= 3 ton= 1 directly, which forms a line of the Lyman series of the hydrogen spectrum.

We have the relation for wave number for Lyman series as:

Where,

R

_{y}= Rydberg constant = 1.097 × 10^{7}m^{1}λ=Wavelength of radiation emitted by the transition of the electron

Forn= 3, we can obtainλas:

If the electron jumps fromn= 2 ton= 1, then the wavelength of the radiation is given as:

If the transition takes place from n = 3 to n = 2, then the wavelength of the radiation is given as:

This radiation corresponds to the Balmer series of the hydrogen spectrum.

Hence, in Lyman series, two wavelengths i.e., 102.5 nm and 121.5 nm are emitted. And in the Balmer series, one wavelength i.e., 656.33 nm is emitted.

Physics Syllabus

General:Units and dimensions, dimensional analysis; least count, significant figures; Methods of measurement and error analysis for physical quantities pertaining to the following experiments: Experiments based on using Vernier calipers and screw gauge (micrometer), Determination of g using simple pendulum, Young's modulus by Searle's method, Specific heat of a liquid using calorimeter, focal length of a concave mirror and a convex lens using u-v method, Speed of sound using resonance column, Verification of Ohm's law using voltmeter and ammeter, and specific resistance of the material of a wire using meter bridge and post office box.

Mechanics:Kinematics in one and two dimensions (Cartesian coordinates only), projectiles; Uniform Circular motion; Relative velocity.

Newton's laws of motion; Inertial and uniformly accelerated frames of reference; Static and dynamic friction; Kinetic and potential energy; Work and power; Conservation of linear momentum and mechanical energy.

Systems of particles; Centre of mass and its motion; Impulse; Elastic and inelastic collisions.

Law of gravitation; Gravitational potential and field; Acceleration due to gravity; Motion of planets and satellites in circular orbits; Escape velocity.

Rigid body, moment of inertia, parallel and perpendicular axes theorems, moment of inertia of uniform bodies with simple geometrical shapes; Angular momentum; Torque; Conservation of angular momentum; Dynamics of rigid bodies with fixed axis of rotation; Rolling without slipping of rings, cylinders and spheres; Equilibrium of rigid bodies; Collision of point masses with rigid bodies.

Linear and angular simple harmonic motions.

Hooke's law, Young's modulus.

Pressure in a fluid; Pascal's law; Buoyancy; Surface energy and surface tension, capillary rise; Viscosity (Poiseuille's equation excluded), Stoke's law; Terminal velocity, Streamline flow, equation of continuity, Bernoulli's theorem and its applications.

Wave motion (plane waves only), longitudinal and transverse waves, superposition of waves; Progressive and stationary waves; Vibration of strings and air columns;Resonance; Beats; Speed of sound in gases; Doppler effect (in sound).

Thermal physics: Thermal expansion of solids, liquids and gases; Calorimetry, latent heat; Heat conduction in one dimension; Elementary concepts of convection and radiation; Newton's law of cooling; Ideal gas laws; Specific heats (C

_{v}and C_{p}for monoatomic and diatomic gases); Isothermal and adiabatic processes, bulk modulus of gases; Equivalence of heat and work; First law of thermodynamics and its applications (only for ideal gases); Blackbody radiation: absorptive and emissive powers; Kirchhoff's law; Wien's displacement law, Stefan's law.Electricity and magnetism:Coulomb's law; Electric field and potential; Electrical potential energy of a system of point charges and of electrical dipoles in a uniform electrostatic field; Electric field lines; Flux of electric field; Gauss's law and its application in simple cases, such as, to find field due to infinitely long straight wire, uniformly charged infinite plane sheet and uniformly charged thin spherical shell.

Capacitance; Parallel plate capacitor with and without dielectrics; Capacitors in series and parallel; Energy stored in a capacitor.

Electric current; Ohm's law; Series and parallel arrangements of resistances and cells; Kirchhoff's laws and simple applications; Heating effect of current.

Biot Savart's law and Ampere's law; Magnetic field near a current-carrying straight wire, along the axis of a circular coil and inside a long straight solenoid; Force on a moving charge and on a current-carrying wire in a uniform magnetic field.

Magnetic moment of a current loop; Effect of a uniform magnetic field on a current loop; Moving coil galvanometer, voltmeter, ammeter and their conversions.

Electromagnetic induction: Faraday's law, Lenz's law; Self and mutual inductance; RC, LR and LC circuits with D.C. and A.C. sources.

Optics:Rectilinear propagation of light; Reflection and refraction at plane and spherical surfaces; Total internal reflection; Deviation and dispersion of light by a prism; Thin lenses; Combinations of mirrors and thin lenses; Magnification.

Wave nature of light: Huygen's principle, interference limited to Young's double-slit experiment.

Modern physics:Atomic nucleus; Alpha, beta and gamma radiations; Law of radioactive decay; Decay constant; Half-life and mean life; Binding energy and its calculation; Fission and fusion processes; Energy calculation in these processes.

Photoelectric effect; Bohr's theory of hydrogen-like atoms; Characteristic and continuous X-rays, Moseley's law; de Broglie wavelength of matter waves.

Chemistry Syllabus

Physical chemistry

General topics:Concept of atoms and molecules; Daltons atomic theory; Mole concept; Chemical formulae; Balanced chemical equations; Calculations (based on mole concept) involving common oxidation-reduction, neutralisation, and displacement reactions; Concentration in terms of mole fraction, molarity, molality and normality.

Gaseous and liquid states:Absolute scale of temperature, ideal gas equation; Deviation from ideality, van der Waals equation; Kinetic theory of gases, average, root mean square and most probable velocities and their relation with temperature; Law of partial pressures; Vapour pressure; Diffusion of gases.

Atomic structure and chemical bonding: Bohr model, spectrum of hydrogen atom, quantum numbers; Wave-particle duality, de Broglie hypothesis; Uncertainty principle; Qualitative quantum mechanical picture of hydrogen atom, shapes of s, p and d orbitals; Electronic configurations of elements (up to atomic number 36); Aufbau principle; Paulis exclusion principle and Hunds rule; Orbital overlap and covalent bond; Hybridisation involving s, p and d orbitals only; Orbital energy diagrams for homonuclear diatomic species; Hydrogen bond; Polarity in molecules, dipole moment (qualitative aspects only); VSEPR model and shapes of molecules (linear, angular, triangular, square planar, pyramidal, square pyramidal, trigonal bipyramidal, tetrahedral and octahedral).

Energetics:First law of thermodynamics; Internal energy, work and heat, pressure-volume work; Enthalpy, Hesss law; Heat of reaction, fusion and vapourization; Second law of thermodynamics; Entropy; Free energy; Criterion of spontaneity.

Chemical equilibrium:Law of mass action; Equilibrium constant, Le Chateliers principle (effect of concentration, temperature and pressure); Significance of ΔG and ΔG in chemical equilibrium; Solubility product, common ion effect, pH and buffer solutions; Acids and bases (Bronsted and Lewis concepts); Hydrolysis of salts.

Electrochemistry:Electrochemical cells and cell reactions; Standard electrode potentials; Nernst equation and its relation to ΔG; Electrochemical series, emf of galvanic cells; Faradays laws of electrolysis; Electrolytic conductance, specific, equivalent and molar conductivity, Kohlrauschs law; Concentration cells.

Chemical kinetics: Rates of chemical reactions; Order of reactions; Rate constant; First order reactions; Temperature dependence of rate constant (Arrhenius equation).

Solid state:Classification of solids, crystalline state, seven crystal systems (cell parameters a, b, c, α, β, γ), close packed structure of solids (cubic), packing in fcc, bcc and hcp lattices; Nearest neighbours, ionic radii, simple ionic compounds, point defects.

Solutions: Raoults law; Molecular weight determination from lowering of vapour pressure, elevation of boiling point and depression of freezing point.

Surface chemistry: Elementary concepts of adsorption (excluding adsorption isotherms); Colloids: types, methods of preparation and general properties; Elementary ideas of emulsions, surfactants and micelles (only definitions and examples).

Nuclear chemistry: Radioactivity: isotopes and isobars; Properties of α, β and γ rays; Kinetics of radioactive decay (decay series excluded), carbon dating; Stability of nuclei with respect to proton-neutron ratio; Brief discussion on fission and fusion reactions.

Inorganic Chemistry

Isolation/preparation and properties of the following non-metals: Boron, silicon, nitrogen, phosphorus, oxygen, sulphur and halogens; Properties of allotropes of carbon (only diamond and graphite), phosphorus and sulphur.

Preparation and properties of the following compounds:Oxides, peroxides, hydroxides, carbonates, bicarbonates, chlorides and sulphates of sodium, potassium, magnesium and calcium; Boron: diborane, boric acid and borax; Aluminium: alumina, aluminium chloride and alums; Carbon: oxides and oxyacid (carbonic acid); Silicon: silicones, silicates and silicon carbide; Nitrogen: oxides, oxyacids and ammonia; Phosphorus: oxides, oxyacids (phosphorus acid, phosphoric acid) and phosphine; Oxygen: ozone and hydrogen peroxide; Sulphur: hydrogen sulphide, oxides, sulphurous acid, sulphuric acid and sodium thiosulphate; Halogens: hydrohalic acids, oxides and oxyacids of chlorine, bleaching powder; Xenon fluorides.

Transition elements (3d series):Definition, general characteristics, oxidation states and their stabilities, colour (excluding the details of electronic transitions) and calculation of spin-only magnetic moment; Coordination compounds: nomenclature of mononuclear coordination compounds,cis-transand ionisation isomerisms, hybridization and geometries of mononuclear coordination compounds (linear, tetrahedral, square planar and octahedral).

Preparation and properties of the following compounds:Oxides and chlorides of tin and lead; Oxides, chlorides and sulphates of Fe

^{2+}, Cu^{2+}and Zn^{2+}; Potassium permanganate, potassium dichromate, silver oxide, silver nitrate, silver thiosulphate.Ores and minerals: Commonly occurring ores and minerals of iron, copper, tin, lead, magnesium, aluminium, zinc and silver.

Extractive metallurgy:Chemical principles and reactions only (industrial details excluded); Carbon reduction method (iron and tin); Self reduction method (copper and lead); Electrolytic reduction method (magnesium and aluminium); Cyanide process (silver and gold).

Principles of qualitative analysis:Groups I to V (only Ag

^{+}, Hg^{2+}, Cu^{2+}, Pb^{2+}, Bi^{3+}, Fe^{3+}, Cr^{3+}, Al^{3+}, Ca^{2+}, Ba^{2+}, Zn^{2+}, Mn^{2+}and Mg^{2+}); Nitrate, halides (excluding fluoride), sulphate and sulphide.Organic Chemistry

Concepts:Hybridisation of carbon; Sigma and pi-bonds; Shapes of simple organic molecules; Structural and geometrical isomerism; Optical isomerism of compounds containing up to two asymmetric centres, (R,SandE,Znomenclature excluded); IUPAC nomenclature of simple organic compounds (only hydrocarbons, mono-functional and bi-functional compounds); Conformations of ethane and butane (Newman projections); Resonance and hyperconjugation; Keto-enol tautomerism; Determination of empirical and molecular formulae of simple compounds (only combustion method); Hydrogen bonds: definition and their effects on physical properties of alcohols and carboxylic acids; Inductive and resonance effects on acidity and basicity of organic acids and bases; Polarity and inductive effects in alkyl halides; Reactive intermediates produced during homolytic and heterolytic bond cleavage; Formation, structure and stability of carbocations, carbanions and free radicals.

Preparation, properties and reactions of alkanes:Homologous series, physical properties of alkanes (melting points, boiling points and density); Combustion and halogenation of alkanes; Preparation of alkanes by Wurtz reaction and decarboxylation reactions.

Preparation, properties and reactions of alkenes and alkynes:Physical properties of alkenes and alkynes (boiling points, density and dipole moments); Acidity of alkynes; Acid catalysed hydration of alkenes and alkynes (excluding the stereochemistry of addition and elimination); Reactions of alkenes with KMnO4 and ozone; Reduction of alkenes and alkynes; Preparation of alkenes and alkynes by elimination reactions; Electrophilic addition reactions of alkenes with X2, HX, HOX (X=halogen) and H2O; Addition reactions of alkynes; Metal acetylides.

Reactions of benzene:Structure and aromaticity; Electrophilic substitution reactions: halogenation, nitration, sulphonation, Friedel-Crafts alkylation and acylation; Effect ofo-, m-andp-directing groups in monosubstituted benzenes.

Phenols:Acidity, electrophilic substitution reactions (halogenation, nitration and sulphonation); Reimer-Tieman reaction, Kolbe reaction.

Characteristic reactions of the following (including those mentioned above): Alkyl halides: rearrangement reactions of alkyl carbocation, Grignard reactions, nucleophilic substitution reactions; Alcohols: esterification, dehydration and oxidation, reaction with sodium, phosphorus halides, ZnCl2/concentrated HCl, conversion of alcohols into aldehydes and ketones; Ethers:Preparation by Williamsons Synthesis; Aldehydes and Ketones: oxidation, reduction, oxime and hydrazone formation; aldol condensation, Perkin reaction; Cannizzaro reaction; haloform reaction and nucleophilic addition reactions (Grignard addition); Carboxylic acids: formation of esters, acid chlorides and amides, ester hydrolysis; Amines: basicity of substituted anilines and aliphatic amines, preparation from nitro compounds, reaction with nitrous acid, azo coupling reaction of diazonium salts of aromatic amines, Sandmeyer and related reactions of diazonium salts; carbylamine reaction; Haloarenes: nucleophilic aromatic substitution in haloarenes and substituted haloarenes (excluding Benzyne mechanism and Cine substitution).

Carbohydrates:Classification; mono- and di-saccharides (glucose and sucrose); Oxidation, reduction, glycoside formation and hydrolysis of sucrose.

Amino acids and peptides:General structure (only primary structure for peptides) and physical properties.

Properties and uses of some important polymers:Natural rubber, cellulose, nylon, teflon and PVC.

Practical organic chemistry:Detection of elements (N, S, halogens); Detection and identification of the following functional groups: hydroxyl (alcoholic and phenolic), carbonyl (aldehyde and ketone), carboxyl, amino and nitro; Chemical methods of separation of mono-functional organic compounds from binary mixtures.

Mathematics Syllabus

Algebra:Algebra of complex numbers, addition, multiplication, conjugation, polar representation, properties of modulus and principal argument, triangle inequality, cube roots of unity, geometric interpretations.

Quadratic equations with real coefficients, relations between roots and coefficients, formation of quadratic equations with given roots, symmetric functions of roots.

Arithmetic, geometric and harmonic progressions, arithmetic, geometric and harmonic means, sums of finite arithmetic and geometric progressions, infinite geometric series, sums of squares and cubes of the firstnnatural numbers.

Logarithms and their properties.

Permutations and combinations, Binomial theorem for a positive integral index, properties of binomial coefficients.

Matrices as a rectangular array of real numbers, equality of matrices, addition, multiplication by a scalar and product of matrices, transpose of a matrix, determinant of a square matrix of order up to three, inverse of a square matrix of order up to three, properties of these matrix operations, diagonal, symmetric and skew-symmetric matrices and their properties, solutions of simultaneous linear equations in two or three variables.

Addition and multiplication rules of probability, conditional probability, Bayes Theorem, independence of events, computation of probability of events using permutations and combinations.

Trigonometry:Trigonometric functions, their periodicity and graphs, addition and subtraction formulae, formulae involving multiple and sub-multiple angles, general solution of trigonometric equations.

Relations between sides and angles of a triangle, sine rule, cosine rule, half-angle formula and the area of a triangle, inverse trigonometric functions (principal value only).

Analytical geometry:

Two dimensions:Cartesian coordinates, distance between two points, section formulae, shift of origin.

Equation of a straight line in various forms, angle between two lines, distance of a point from a line; Lines through the point of intersection of two given lines, equation of the bisector of the angle between two lines, concurrency of lines; Centroid, orthocentre, incentre and circumcentre of a triangle.

Equation of a circle in various forms, equations of tangent, normal and chord.

Parametric equations of a circle, intersection of a circle with a straight line or a circle, equation of a circle through the points of intersection of two circles and those of a circle and a straight line.

Equations of a parabola, ellipse and hyperbola in standard form, their foci, directrices and eccentricity, parametric equations, equations of tangent and normal.

Locus Problems.

Three dimensions:Direction cosines and direction ratios, equation of a straight line in space, equation of a plane, distance of a point from a plane.

Differential calculus:Real valued functions of a real variable, into, onto and one-to-one functions, sum, difference, product and quotient of two functions, composite functions, absolute value, polynomial, rational, trigonometric, exponential and logarithmic functions.

Limit and continuity of a function, limit and continuity of the sum, difference, product and quotient of two functions, L'Hospital rule of evaluation of limits of functions.

Even and odd functions, inverse of a function, continuity of composite functions, intermediate value property of continuous functions.

Derivative of a function, derivative of the sum,

difference, product and quotient of two functions, chain rule, derivatives of polynomial, rational, trigonometric, inverse trigonometric, exponential and logarithmic functions.

Derivatives of implicit functions, derivatives up to order two, geometrical interpretation of the derivative, tangents and normals, increasing and decreasing functions, maximum and minimum values of a function, Rolle's Theorem and Lagrange's Mean Value Theorem.

Integral calculus:Integration as the inverse process of differentiation, indefinite integrals of standard functions, definite integrals and their properties, Fundamental Theorem of Integral Calculus.

Integration by parts, integration by the methods of substitution and partial fractions, application of definite integrals to the determination of areas involving simple curves.

Formation of ordinary differential equations, solution of homogeneous differential equations, separation of variables method, linear first order differential equations.

Vectors:Addition of vectors, scalar multiplication, dot and cross products, scalar triple products and their geometrical interpretations.

Name the waves used in:

1) Killing germs in water purificaton

2) remote sensing

3) treatment of cancer

4) satellite communication

5) studying crustal structure

6) intense heating

7) absorbed by ozone layer

HOW WE CAN SAY THAT EM WAVES CARRY BOTH MOMENTUM AND ENERGY ...?

Name the EM wave used for studying crystal structure of solids. What is its frequency range?

Q:-Name em radiations used for detecting fake currency notes?

tangent laws of magnetism

how.....

I =(1/2)*(E

_{0})*(E^{2})*(c)I=intensity of electromagnetic radiation

E

_{0=}epsilon_{0}i.e permittivity of free spacewhere it is given...??

E=electric field intensity

c=speed of light

State four properties of electromagnetic waves?

Solve this:14. In an electromagnetic wave, the oscillating electric field having a frequency of 3*10

^{10}Hz and an amplitude of 30 V/ m propagates in the positive x-direction.(i) What is the wave length of the electromagnetic-wave?

(ii) Write down the expression to represent the corresponding magnetic field.

$\left[\mathrm{Ans}.{10}^{-2}\mathrm{m},\mathrm{B}=\left({10}^{-7}\mathrm{T}\right)\mathrm{sin}\left(6\mathrm{\pi}\times {10}^{10}\mathrm{t}-200\mathrm{\pi x}\right)\hat{\mathrm{k}}\right]$

why is the wave nature of matter not observed in daily life?

_{c}=i_{d}?optical and radio telescope are built on ground ,while x rays is only from satellite orbiting the earth. why?

What is common between different types of electromagnetic radiations?

In a plane electromagnetic wave, the electric field oscillates sinusoidally at a frequency of 2.0 × 10

^{10}Hz and amplitude 48 V m^{−1}.(a)What is the wavelength of the wave?(b)What is the amplitude of the oscillating magnetic field?(c)Show that the average energy density of theEfield equals the average energy density of theBfield. [c= 3 × 10^{8}m s^{−1}.]Name the waves that are often refered to as Heat Waves. Name the physical quantity that has a lower, higher and same valuefor these waves as compared to its value for x rays

^{8 }ms^{-1}(2)to exihibit the phenomenon ofdiffraction and (3)can the polarized.What conclusion can be drawn about the nature of X-rays from each of these observations?The oscillating magnetic field in a plane electromagnetic wave is given by

_{y}= ( 8 x 10^{-6}) sin ( 2 x 10^{11 }t + 300πx ) Τa capacitor of capacitance "c" is being charged by connecting it across a dc source along with an ammeter .will the ammeter show a momentary deflaction during the process of charging?if so how would you explain this momentary deflection and resulting continuity of current in the circuit?write the expression for the current inside the capacitor.

Sol. Answer (3) why other options also seems correct explain error in them

explain the inadequacy of ampere's circuital law?

A plane electromagnetic wave of energy U is reflected from the surface. Then the momentum transferred by em

wave to the surface

(a) 0 (b) U/c (c) 2U/c (d) U/2c

Discuss the inconsistency in Ampere's circuital law??????What modification was made by Maxwell in this law...???????????

obtain an expression for the energy density of an electromagnetic wave .Inthe electromagnetic wave show that the average energy density of the electric field equals the average energy density of the magnetic field?

Ans - 5l/3

Explain principle and working of Hertz's experiment of accelerated charges with diagram.

WHAT IS THE SOURCE OF DISPLACEMENT CURRENT?

we do not transmit an audio signal by just directly converting it into an electromagnetic wave of the same frequency. Give two reasons for this....

Suppose that the electric field part of an electromagnetic wave in vacuum is

E= {(3.1 N/C) cos [(1.8 rad/m)y+ (5.4 × 10^{6}rad/s)t]} .(a)What is the direction of propagation?(b)What is the wavelength λ?(c)What is the frequencyν?(d)What is the amplitude of the magnetic field part of the wave?(e)Write an expression for the magnetic field part of the wave.^{11}Hz (ii) 5 x 10^{19}Hz & 3 x10^13 Hz belong?_{o}and amplitude of magnetic field is B_{o}. The electric field at some instant becomes 3/4 E_{o}. What will be the magnetic field at this instant. (Wave is travelling in vacuum.)What is Frensel's Biprism.??

Identify the following em radiations as per the wavelengths given below .Write one application of each.

(a)10

^{-3nm }, (b)10^{-3}m, (c)1nmQ.A parallel plate capacitor with circular plates of radius 1m has a capacitance of 1nF. At time t=0, it is connected for charging in series with a resistor R = 1 M ohm across a 2V baterry. Calculate the magnetic field at a point P, halfway between the centre and the periphery of the plates, after t=10 raised to the power -3 seconds

State Ampere Maxwell law and get expression for displacement current.

Q. Name the constituent radiation of electromagnetic spectrum which

(i) is used for studying crystal structure.

(ii) is absorbed from sun light by ozone layer.

(iii) produces intense heating effect.

(iv) is used in cellular phones to transmit voice communication.

(v) is used for sterilising surgical instruments.

(vi) is used for taking photograph in foggy season.

A variable frequency AC source is connected to a capacitor. Will the displacement current increases or decreases with increase in frequency.

1. What is the nature of waves used in radar? Why we prefer that waves?

^{-2}. if it is needed to deliver a volume of 10^{-1}per second the power required will bea)10 kW

b)15 kW

c)25 kW

ratio of speed of gamma rays to radio waves in vaccum?

Welders wear special goggles or face masks with glass windows to protect their eyes from electromagnetic radiation. Name the radiations an write their range of frequency.

how is E=Q/AE

_{0}how do you convince yourself that electromagnetic waves carry energy and momentum?

explain the phenomenon which justified the transverse nature of EMW??/

Explain the mathtematical proof of transverse nature of EM waves.name the electromagnetic waves used for the following and arrange them in increasing order of there penetrating power -

a water purification

b remote sensing

c treatment of cancer

Using a dc a source a capacitor has been fully charged. What are the magnitudes of the conduction and displacement current?

why are alkali metals most suitable for photoelectric emission?

_{1}closed at one end vibrating in its first overtone and another pipe P_{2}open at both ends vibrating in third overtone are in resonance with a given tuning fork. The ratio of the length P_{1}to that of P_{2}is --------(a) r

^{-3}, inductive (b) r^{-1}, radiated (c) r^{-3}, radiated (d) r^{-1}, inductiveplz answer this question :- How does a charge q oscillating at certain frequency produce electromagnetic waves ?

name the radiations of electromagnetic spectrum which are used in studying the structure properties of the atoms and molecules .

which of the following em waves can be polarized?1. X rays 2.sound waves?Give reason for your answer

which em wave helps in eye surgery?

Q. The ratio of contributions made by the electric field and magnetic field components to the intensity of an EM wave is

(1) identify the direction in which the magnetic field oscillations are taking place in the e.m. wave

(2) how are magnitude of elctric and magnetic fields in the electromagnetic wave related to each other?