Aryahi
22 Feb 2017
A bulb is kept burning just right above the following solids. Name the shape of the shadows obtained in each case. Attempt to give a rough sketch of the shadow. (You may try to experiment first and then answer these questions).
4.32 J
2.65 J
3.81 J
5.66 J
or
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Conducting Bubble Radius R Thickness R Potential V Collapses Droplet Find Potential Droplet Determine Work Done Bringing Unit Positive Charge Infinity Mid Point Line Joining Two Q Coulomb CharBulb Kept Burning Right Following Solids Name Shape Shadows Obtained Case Attempt Give Rough Sketch Charge Placed 5 C Determine Work Done Moving Charge 1 C B Elective Dipole Experiences Torque Nm Placed Angle 450 Uniform Electric Field Magnitude Potential EnThree Equal Charges Q Placed Corners Equilateral Triangle Side 1 Determine Work Done Moving Charges Electron Initially Rest Leaves Surface Conductor Reaches Surface Another Conductor Velocity 106 Ms 1Measure Classify Angle Angle Measure Type Aob Aoc Boc Doc Doa Dob Two Circular Loops Radii 0 04 0 08 Placed Common Axis Centres 0 10 Apart Charge 10 8 C Spread UniforCapacitor Capacitance 5 F Charged Potential 250 V Voltage Across Plate Changed 500 V 2 Ms Determine Following Models Perpendicular Lines Adjacent Edges Table Top B Lines Railway Track 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8Three Coins Tossed Let Denote Event Three Heads Show B Denote Event Two Heads One Tail Show C DenoteInitial Angle P E 0 Electric Dipole Needs Turned Completely End End Electric Field Find Amount Work Two Dice Thrown Events B C Follows Getting Even Number First Die B Getting Odd Number First Die C GeFind Equation Circle Passing Points 4 1 6 5 Whose Centre Line 4x 16 Consider Electric Dipole Moment Coulomb Metre Electric Field Vm 1 Find Torque Dipole NFind Energy Uniformly Charged Spherical Shell Total Charge Q Radius R Find Equation Circle Radius 5 Whose Centre Lies X Axis Passes Point 2 3 Find Equation Circle Passing 0 0 Making Intercepts B Coordinate Axes Find Equation Circle Centre 2 2 Passes Point 4 5 Point 2 5 3 5 Lie Inside Outside Circle X2 Y2 25 Find Charges Three Capacitors Shown Figure Coin Tossed Twice Probability Least One Tail Occurs Find Coordinates Focus Axis Parabola Equation Directrix Length Latus Rectum Y2 12xCapacitor Capacitance 50 F Air Another Medium Dielectric 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Position Hydrogen Periodic Table Basis Electronic Configuration Two Square Metallic Plates 1 Side Kept 0 01 Apart Like Parallel Plate Capacitor Air Way One Edges PeFind Effective Capacitance Points Given Network Capacitance Capacitor C Describe Bulk Preparation Dihydrogen Electrolytic Method Role Electrolyte Process Find Capacitance Capacitor Spherical Shape Given Outer Surface Sphere Charged Inner Surface Earthed Equivalent Capacitance Terminals B Shown Figure Capacitor Inserted Two Blocks Dielectric Constants K1 K2 Calculate Capacitance CapacitoCharacteristics Expect Electron Deficient Hydride Respect Structure Chemical Reactions Expect Carbon Hydrides Type Cnh2n 2 Act Lewis Acid Base Justify Answer Plates Capacitor Thickness Kept Medium Whose Dielectric Constant Increases Distance Uniform Rate TwoExpect Metallic Hydrides Useful Hydrogen Storage Explain Atomic Hydrogen Oxy Hydrogen Torch Function Cutting Welding Purposes Explain Among Nh3 H2o Hf Would Expect Highest Magnitude 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C2 Shown Circuit Find BElectric Field Electric Potential Point Due Point Charge 100 V C 50 J C Respectively Magnitude ChargDistance Two Plates Air Capacitor Capacitance Equal Capacitance Spherical Conductor Radius 2 Given AHollow Metal Sphere Radius 10 Cm Charged Potential Surface 5 V Potential Centre Sphere Net Capacitance Three Identical Capacitors Series 2 F Net Capacitance Connected Parallel Ii Find RaTotal Potential Energy Solid Sphere Radius R Uniform Charge Density 40 F Capacitor First Charged 100v Connected Another Uncharged Capacitor Capacitance 60 F Parallel FiUse Following Information Answer Next Question Potential Difference Across Two Capacitors CapacitancUse Following Information Answer Next Question Tyler Constructs Capacitor Shown Figure Capacitance PFind Equivalent Capacitance Resulting Capacitor Instead K2 Capacitor Filled Air Resultant Capacitance Consider Number Identical Charges Equal 1 5 C Placed Along X Axis Distances X 2a X 6a X 12a Upto X 2Effective Capacitance Two Capacitors Connected Parallel Series 10 F 2 1 F Respectively Difference CaElectric Dipole Charge 2 C Length 8 Cm Placed External Uniform Electric Field 2105 Nc 1 Work Done RoUse Following Information Answer Next Question Simone Connects Five Capacitors Shown Figure CapacitaSix Capacitors Capacitances 22 F Connected Points B Shown Figure Point Kept 100 V Point B Grounded TTwo Capacitors Connected Series Shown Figure Charged Potential 100 V Charge Capacitor C1 Find Effective Capacitance Terminals B Circuit Given Electron Starts Move Point Potential 100 V Point N Potential X V Reaches Point N Kinetic Energy Incr2n Charges Placed X X 2a X 3a X 4a Respectively Electric Potential OriginCapacitance Capacitor Given Circuit C Equivalent Capacitance Following Network Across Ab 12 F Find VVariation Electric Potential V Distance X Shown Graph Potential Z Direction Vary Value Ex V 1 Region40 F Capacitor First Charged 100 V Connected Another Uncharged Capacitor Capacitance 60 F Parallel FUse Following Information Answer Next Question Two Point Charges 1 5 C 0 5 C Located 1 Apart Point PUse Following Information Answer Next Question Point Charge Magnitude 3 10 7 C Placed Point Q Shown Use Following Information Answer Next Question Charge Q1 Placed Origin Another Charge Q2 Placed PoinUse Following Information Answer Next Question Two Charges 5 10 7 C 8 10 7 C Placed 0 6 Cm 0 0 0 8 CUse Following Information Answer Next Question System Two Charges Separated Distance 20 Cm Shown GivUse Following Information Answer Next Question Substance Dipole Moment 4 10 8 Cm Placed Electric FieUse Following Information Answer Next Question Two Capacitors Capacitances 5 10 7 F 2 10 7 F ConnectUse Following Information Answer Next Question Five Capacitors Known Capacitances Connected Shown GiUse Following Information Answer Next Question Four Capacitors Equal Capacitance Connected Series NeUse Following Information Answer Next Question 40 F Capacitor Charged 220 V Supply Voltage Charged CUse Following Information Answer Next Question Capacitor Capacitance 100 F Connected Discharge Tube Use Following Information Answer Next Question Three Dielectrics B C Equal Dimensions Inserted ParalUse Following Information Answer Question Two Capacitors Capacitances 6 F 4 F Connected Series SupplUse Following Information Answer Next Question Length Electric Dipole 6 Cm Axis Dipole Makes Angle UUse Following Information Answer Next Question Work Done Moving Charge Particle One Point Another CaTick Correct Answer 13103 1271000 B 2271000 C 21971000 NoneEvaluate 2163Evaluate 48243 Evaluate 98 162Evaluate 11832023Use Following Information Answer Next Question Simone Connects Five Capacitors Shown Figure CapacitaSubtract X3 3x2 5x 4 3x3 X2 2x 4Following Numbers Divisible 9 524618 Ii 7345845 Iii 8987148Use Following Information Answer Next Question Four Plates Placed Shown Figure Area Plate Distance TCharge Q Moving Potential Difference Change Potential Energy EqualUse Following Information Answer Next Question Figure Area Plate Distance Two Consecutive Parallel PSimple Electric Circuit Consists Combination Four Plates Represented Given Figure Distance Two ConseElectron Proton Placed Two Parallel Plates Uniform Electric Field E Particles Experience Equal Unequ500 Pf Capacitor Charged 500 V Power Supply Disconnected Power Source Connected Uncharged Capacitor Two Equi Potential Surfaces Intersect Give Reasons Ii Two Charges Q Q Located Points 0 0 B 0 0 RespThree Identical Capacitors C1 C2 C3 Capacitance 6 F Connected 12 V Battery Shown Find Charge CapacitGraph Shows Variation Voltage V Across Plates Two Capacitors B Versus Increase Charge Q Stored Two CFind Total Energy Stored Capacitors Given Network Electric Dipole Length 4 Cm Placed Axis Making Angle 60 Uniform Electric Field Experiences Torque Nm10 F Capacitor Charged 30 V C Supply Connected Across Uncharged 50 F Capacitor Calculate Final PotenElectric Dipole Held Uniform Electric Field Using Suitable Diagram Show Undergo Translatory Motion I12 Pf Capacitor Connected 50 V Battery Much Electrostatic Energy Stored Capacitor Define Term Dielectric Constant Medium Terms Capacitance Capacitor Electric Field Electric Potential Point Due Point Charge Kept Air 20 Nc 1 10 Jc 1 Respectively CalcuGiven Graph Shows Variation Charge Q Versus Potential Difference V Two Capacitors C1 C2 Two CapacitoDeduce Expression Electric Potential Due Electric Dipole Point Axis Mention One Contrasting Feature Parallel Plate Capacitor Plate Area Separation Charged Potential Difference V Battery Used Charge DiDerive Expression Energy Stored Parallel Plate Capacitor Capacitance C Air Medium Plates Charges Q Q500 C Charge Centre Square Side 10 Cm Find Work Done Moving Charge 10 C Two Diagonally Opposite PoinDerive Expression Electric Potential Point Along Axial Line Electric Dipole Using Gauss Law Derive Expression Electric Field Intensity Point Outside Uniformly Charged Thin SphOrientation Electric Dipole Uniform Electric Field Would Correspond Stable Equilibrium Two Point Charges Q1 10 10 8 C Q2 2 10 8 C Separated Distance 60 Cm Air Find Distance 1st Charge Q1 Orientation Dipole Placed Uniform Electric Field Stable Ii Unstable Equilibrium Part Electromagnetic Spectrum Used Radar Systems Depict Equipotential Surfaces System Two Identical Positive Point Charges Placed Distance Apart B DParallel Plate Capacitor Charged Potential Difference V Dc Source Capacitor Disconnected Source DistEquivalent Capacitance Combination B Given Figure 4 F Calculate Capacitance Capacitor C Ii CalculateTwo Parallel Plate Capacitors X Area Plates Separation X Air Plates Contains Dielectric Medium R 4 CTwo Point Charges 10 C 10 C Separated Distance 40 Cm Air Calculate Electrostatic Potential Energy SyX Two Parallel Plate Capacitors Area Plates Separation Plates X Air Plates Contains Dielectric MediuElectric Field Inside Dielectric Decrease Placed External Electric Field Two Dielectric Slabs Dielectric Constants K1 K2 Filled Two Plates Area Parallel Plate Capacitor ShowDerive Expression Potential Energy Electric Dipole Work Done Moving Charge 4 C Distance 2 Equipotential Surface Two Equipotential Surfaces Never Intersect Number Electrons Given Charged Sample Equal Avogadro Number Calculate Work Done Moving Sample PotentElectric Field 600 N C Desired Capacitor Plates Kept 2 Mm Apart Value Potential Difference Must ApplUniform Electric Field Exists Region Shown Given Figure Much Work Done Taking Electron C Path Abc Uniform Electric Field Exists Along X Axis Direction Charge Displaced Work Done Displacing 200 V Cell Connected 8 F Capacitor Removed Capacitor Fully Charged Also Uncharged 4 F Capacitor ConnCapacitor Initially Charged Shown Figure Dielectric Dielectric Constant K 4 Introduced Capacitor PlaElectron 20 Cm Away Fixed Point Charge Q 0 250 C Starts Move Rest Fast Moving Distance B Much Work DMetallic Sphere Radius 0 2 Given 4 C Charge Calculate Electric Potential Distance 0 05 Centre MetallTwo Electric Field Lines Never Intersect Two Capacitors C1 10 F C2 15 F Charged Potential Difference V 120 V Connected Shown Given Figure PotPotential Point P 15 Cm Away 26 C Charge Give Expression Potential Point Two Charges Q1 Q2 Respectively Much Work Required Done Separate Charges Dipole Till Infinity R 0 18 Conducting Sphere Radius 0 15 Potential 200 V V 0 Infinity Answer Following Questions Charge Sphere Solid Non Conducting Sphere Imparted Charge Density R Radius Sphere R Distance Centre Sphere Show ToIllustrate Electric Lines Force Equipotential Surfaces Associated Electric Dipole Consider Given Circuit Find Equivalent Capacitance Points B B Charge Stored Capacitor Vab 20 V PermiState Example Situation E 0 V 0 Small Ball Mass 10 Mg Charge Q 0 3 C Suspended Non Conducting Thread Thread Makes Angle 30 Vertical Explain Following Statement Breakdown Field Air Around 3 106 V Consider Given Charge Distribution Give Signs Potential Difference Metal Sphere Radius 0 5 Cm Hold CState Properties Electric Field Lines Capacity Parallel Plate Capacitor Dielectric Depends Upon FactPotential Region Bound Given Determine Position Potential Zero Electric Field Non Zero B Magnitude DCapacitor Charged Upto 0 1 C Discharges Much Energy Released Given C 0 5 F Potential Point Away Proton Potential Energy System Another Proton Brought Distance 2 10 15 Much WorElectric Field Potential Related Potential Vary One Moves Along Electric Field Line State ConditionsCapacitance C1 Charge C1 600 C Charge Q Distributed Uniformly Spherical Volume Radius R Show Potential Distance R R R Centre SphereElectric Field E Electric Potential V Outside Earth Surface Charge Density 1 Electron M2 Take RadiusConsider Dielectric Slab Dielectric Constant K 9 Kept One End Two Parallel Plate Capacitor Shown FigCapacitor Shown Made Two Conductors X Carrying Equal Opposite Charges Non Uniform Field Varies FunctTwo Point Charges Qa Qb Placed 5 6 10 0 0 1 Respectively Electric Potential Due 8 Kj 1 2 3 Find ValuCombination Capacitors Shown Figure C1 C2 C3 3 F 2 F 4 F Respectively Point P Maintained 120 V PointCircuit Capacitors C1 C2 Connected Two Springs S1 S2 Spring Constant Shown Area Plates Distance PlatThree Masses Equal Charge 2 5 C Placed Corners Equilateral Triangle Side 3 Cm Find Work Done Move OnSpherical Isolated Soap Bubble Radius 2 Cm Potential 50 V Time Collapse Drop Radius 5 Mm Choose CorrThree Capacitors C1 2 F C2 6 F C3 1 5 F Connected Battery 5 V Via Two Switches S1 S2 Shown Figure StKind Lens Used Given Activity Six Capacitors Capacitances 22 F Connected Points B Shown Figure Point Kept 100 V Point B Grounded TTwo Capacitors Connected Series Shown Figure Charged Potential 100 V Charge Capacitor C1 Use Following Information Answer Next Question Point Charge Magnitude 3 10 7 C Placed Point Q Shown Use Following Information Answer Next Question Charge Q1 Placed Origin Another Charge Q2 Placed PoinUse Following Information Answer Next Question Two Charges 5 10 7 C 8 10 7 C Placed 0 6 Cm 0 0 0 8 CUse Following Information Answer Next Question System Two Charges Separated Distance 20 Cm Shown GivUse Following Information Answer Next Question Substance Dipole Moment 4 10 8 C Placed Electric FielUse Following Information Answer Next Question Two Capacitors Capacitances 5 10 7 F 2 10 7 F ConnectUse Following Information Answer Next Question Five Capacitors Known Capacitances Connected Shown GiUse Following Information Answer Next Question Four Capacitors Equal Capacitance Connected Series NeUse Following Information Answer Next Question 40 F Capacitor Charged 220 V Supply Voltage Charged CUse Following Information Answer Next Question Capacitor Capacitance 100 F Connected Discharge Tube Use Following Information Answer Question Three Dielectrics B C Equal Dimensions Inserted Parallel PUse Following Information Answer Next Question Two Capacitors Capacitances 6 F 4 F Connected Series Work Done Moving Charge 4 C Distance 2 Equipotential Surface Two Equipotential Surfaces Never Intersect Number Electrons Given Charged Sample Equal Avogadro Number Calculate Work Done Moving Sample PotentElectric Field 600 N C Desired Capacitor Plates Kept 2 Mm Apart Value Potential Difference Must ApplElectric Field Region Change Dielectric Dielectric Constant K Introduced Region Describe Shape Equipotential Surface Surrounding Line Charge Ii Point ChargeGive Example Charge Distribution Exists Point Zero Potential Non Zero Electric Field Basic Working Principle Van De Graaff Generator Uniform Electric Field Exists Region Shown Given Figure Much Work Done Taking Electron C Path Abc Uniform Electric Field Exists Along X Axis Direction Charge Displaced Work Done Displacing Capacitance C1 Charge C1 600 C Equivalent Capacitance Points B Ii CPotential Point Away Proton Potential Energy System Another Proton Brought Distance 2 10 15 Electric Field Exists Region Given Equation Orientation Shape Equipotential Surface Region Potential Difference Across Combination Charge Capacitor New Capacitance Much Charge Gained Lost Capacitor Dielectric Introduced Much Energy Gained Lost Capacitor Dielectric Introduced Derive Expression Equivalent Capacitance Three Capacitors C1 C2 C3 Connected Series Ii ParallelShow Capacitance Parallel Plate Capacitor Determine Position Potential Zero Electric Field Non Zero Magnitude Direction Electric Field Derive Expression Energy Stored Charged Capacitor Electron 20 Cm Away Fixed Point Charge Q 0 250 C Starts Move Rest Fast Moving Distance Much Work Done Bringing Three Electrons Initially Great Distance Apart Form Equilateral Triangle SidMetallic Sphere Radius 0 2 Given 4 C Charge Calculate Electric Potential Distance 0 05 Centre MetallThree Concentric Spherical Shells P Q R Radii 4 Cm 6 Cm 8 Cm Given Charges 2 C 4 C 6 C Respectively Potential Point P 15 Cm Away 26 C Charge State Unit Electric Potential State Example Situation E 0 V 0 Give Expression Potential Point Two Charges Q1 Q2 Respectively Give Reasons Following Two Equipotential Surfaces Never Intersect Shape Equipotential Surface Linear Charge Distribution Energy Acquired Charge 2 C Moves Two Plates Maintained Potential Difference 3 V Dielectric Constant Metal Graphically Show Capacitance Varies Charge Constant Voltage Two Parallel Plate Capacitors One Dielectric Given Potential Difference One Store Charge Two Conducting Spheres One Solid One Hollow Kept Potential Contain Charge Capacitor Charged Upto 0 1 C Discharges Much Energy Released Given C 0 5 F Energy Stored Parallel Plate Capacitor Affected Dielectric Slab Inserted Plates Explain Following Statement Breakdown Field Air Around 3 106 V Linear Isotropic Dielectrics Electric Field Potential Related Potential Vary One Moves Along Electric Field Line Consider Given Charge Distribution Give Signs Potential DifferenceIllustrate Electric Lines Force Equipotential Surfaces Associated Electric Dipole Much Work Required Done Separate Charges Dipole Till Infinity R 0 18 Metal Sphere Radius 0 5 Cm Hold Charge 1 C Capacity Parallel Plate Capacitor Dielectric Depends Upon Factors Two Dielectrics Dimensions Capacitance Capacitor Shown Figure Two Dielectric Slabs Introducing Dielectric Capacitance Parallel Plate Capacitor Increases 10 F 50 F Dielectric Constant Total Energy Stored Combination Capacitors Shown Given Figure State One Application Van De Graff Generator Infinite Non Conducting Sheet Charge Density Far Apart Equi Potential Surfaces Differ 50 V Charge Sphere Charge Density Electric Potential Region Given Magnitude Direction Electric Field Points 2 3 Consider Given System Charges Third Charge Q3 Moved B Along Diagonal Rectangle Work Increase DecreasGive Expression Electric Potential Energy Associated System Point Charges Cloud Potential 1 2 109 V Magnitude Energy Associated Movement Electron Ground Cloud Distance Separation Two Parallel Plates Area 1 M2 Used Constructing Parallel Plate Capacitor CapacitMany 2 F Capacitors One Connect Parallel Store Charge 3 C Potential 100 V Across Capacitors Consider Given Circuit Switch Closed Many Coulombs Charge Passed Ammeter Capacitor Much Capacitance Required Store 5 Kwh Energy Potential Difference 2000 V Electric Field Magnitude 160 V Exists Certain Region Much Energy Stored Unit Volume Air Region Two Parallel Plates Charged Capacitor Separation 12 Cm Electron Placed Certain Position Two Plates EWrite Expression Electrostatic Potential Energy Terms Electric Field V 0 Centre V R R R Potential Difference Two Points One Situated Centre Surface Sphere Q Positive Two Points Higher Potential Show Potential Distance R R R Centre Sphere V R Assume V 0 Potential Difference Point Surface Centre Sphere Find Equivalent Capacitance Points B Charge Stored Capacitor Vab 20 V Potential Difference Vab Switches S1 S2 Closed Charges Stored Capacitor Switches S1 S2 Closed Use Following Information Answer Next Question Work Done Moving Charge Particle One Point Another CaUse Following Information Answer Next Question Potential Difference V Applied Across Two Ends ChargeUse Following Information Answer Next Question Potential Difference Across Two Capacitors CapacitancTime Constant Capacitor Discharging Resistor Time Charge Capacitor ReducesUse Following Information Answer Next Question Tyler Constructs Capacitor Shown Figure Capacitance PUse Following Information Answer Next Question Two Capacitors Capacitances 9 F 18 F Connected SeriesUse Following Information Answer Next Question Uncharged Capacitor Capacitance 20 F Charged ConstantCapacitor Capacitance 2 0 F Charged 200 V Plates Connected Wire Heat Produced WireUse Following Information Answer Next Question Capacitance Parallel Plate Capacitor 5 F Glass Plate Use Following Information Answer Next Question Simone Connects Five Capacitors Shown Figure CapacitaUse Following Information Answer Next Question Complex Capacitor Constructed Shown Figure CapacitancUse Following Information Answer Next Question Figure Shows Four Parallel Plates Area Distance Two CUse Following Information Answer Next Question Four Plates Placed Shown Figure Area Plate Distance TUse Following Information Answer Next Question Figure Area Plate Distance Two Consecutive Parallel PCharge Q Moving Potential Difference Change Potential Energy EqualUse Following Information Answer Next Question Electron Starts Move Point Potential 100 V Point N ReReference Cathode Ray Tube Amount Angular Deflection Electrons VariesUse Following Information Answer Next Question Charge Q Located Near Four Equal Positive Charges FouUse Following Information Answer Next Question Electric Potential Ofis Caused Point P Two Particles Use Following Information Answer Next Question Two Concentric Metallic Hollow Spheres Radii R1 R2 R1Use Following Information Answer Next Question Two Charges 3 10 8 C 2 10 8 C Located 15 Cm Apart ShoFollowing Figures Show Equipotential Surface Use Following Information Answer Next Question Four Point Charges 2q Q 2q Q Placed Corners Square ShUse Following Information Answer Next Question Point Charge Q Surrounded Symmetrically Six IdenticalCharged Particle Mass Charge Q Released Rest Electric Field Magnitude E Kinetic Energy Particle TimeUncharged Sphere Metal Placed Inside Charged Parallel Plate Capacitor Following Figures Indicates ExUse Following Information Answer Next Question Hollow Metal Sphere Radius 0 1 Cm Holds Charge CreateUse Following Information Answer Next Question Coordinates Three Points B C X1 Y1 Z1 X2 Y2 Z2 X3 Y3 Use Following Information Answer Next Question Two Small Spheres Carrying Charge Q Placed R Meters AUse Following Information Answer Next Question 1000 Small Water Drops Cloud Radius R Charge Q CoalesWork Done Moving Charge 10 C Equipotential Surface Potential 2 VoltUncharged Conductor Placed Near Charged Conductor Net Electric Field SystemUse Following Information Answer Next Four Questions Plates Parallel Plate Capacitor Surface Area SeElectrostatic Stress Acting Plates CapacitorUse Following Additional Information Answer Next Question Point Charge Q Placed Plates Magnitude CouMagnitude Electric Force Acting Plates Capacitor Use Following Information Answer Next Question Charged Particle Mass Charge Q0 Placed Positive PlateUse Following Information Answer Next Question Plates Parallel Plate Capacitor Surface Area SeparateUse Following Information Answer Next Question Plates Parallel Plate Capacitor Surface Area SeparateUse Following Information Answer Next Question Point Charge Q Placed Plates Capacitor Whose Surface Charge 3 C Placed Uniform Electric Field Experience Force 5000 N Potential Difference Two Points SepDielectric Constant K Dielectric Strength Material Used Dielectric Medium CapacitorUse Following Information Answer Next Question N Identical Mercury Drops Charged Potential V Drops CUse Following Information Answer Next Question Air Non Conductor Electricity Certain Threshold FieldUse Following Information Answer Next Question Two Charged Spheres B Radii B Respectively Connected Electric Potential Due Electric Dipole Axial Point Distance R Dipole VariesUse Following Information Answer Next Question Particular Charge Distribution Space Electric PotentiUse Following Information Answer Next Question Presence Uniform Electric Field Charge Moved Point PoDimension Electric PotentialUse Following Information Answer Next Question Point Charge Q Move Point P Point Along Path Pqrs ShoUse Following Information Answer Next Question Mass Proton 1 840 Times Heavier Electron Proton MovinUse Following Information Answer Next Question Potential Difference Plates Parallel Plate Capacitor Conducting Sphere Uniform Charge Density 0 5 C M2 Radius 10 Cm Potential Centre SphereUse Following Information Answer Next Question Two Point Charges Placed Certain Distance R Vacuum ExPossible Value Dielectric Constant K InsulatorWork Done Carrying Charge 5 C Point Another Point 10 Mj Potential Difference PointsUse Following Information Answer Next Question Parallel Capacitor Capacitance 3 F Potential DifferenTotal Charge Capacitor Capacitance 6 F Connected Across Ideal Battery Electromotive Force 12 VUse Following Information Answer Next Question Potential Gradient Along Length Uniform Wire 10 Vm 1 Use Following Information Answer Next Question Electric Field Plates Isolated Parallel Plate CapacitConsider Infinite Number Charges Equal Q Placed Along X Axis Distances X X 2a X 4a X 8a Origin ElectUse Following Information Answer Next Question Parallel Plate Capacitor Capacitance 500 F Charged PoUse Following Information Answer Next Question Point Charge Magnitude 6 C Placed Point Distance PoinUse Following Information Answer Next Question Electric Field Intensity Two Charged Plates Equal DimUse Following Information Answer Next Question Parallel Plate Capacitor Two Parallel Plates Area 0 2Reference Charging Capacitor Following Expressions Incorrect Calculating Total Work Done Use Following Information Answer Next Question Source Potential 12 V Connected System Two CapacitorsUse Following Information Answer Next Question 64 Drops Size Liquid Charged Potential 230 V Drop CoaUse Following Information Answer Next Question Capacitance Three Capacitors Ratio 2 3 4 Capacitance Van De Graff Generator Device UsedVan De Graff Generator Enclosed Steel Tank Containing Gas High PressureFollowing Particles Cannot Accelerated Using Van De Graff Generator Spherical Metal Shell Van De Graff Generator Maximum Potential 5 0 104 V Dielectric Strength Gas SurCharged Particle Change 2e Accelerated Using Van De Graff Generator Spherical Metal Shell Maximum PoFollowing Molecules Non Polar Dimension Atomic Molecular PolarisabilityPotential Difference Two Ends Discharge Tube Van De Graaff Generator 2 1020 Volts Electron Placed OnCharge 10 3 Coulombs Accumulated Spherical Shell Van De Graaff Generator Radius Spherical Shell 3 MaBullet Mass 1 G Charge 2 Microcoulomb Accelerated Using Van De Graaff Generator Acquire Speed 20 PotThree Capacitors Capacity 4 F Connected Way Effective Capacitance 6 F DoneFour Masses Equal Charge 8 0 C Placed Corners Square Side 4 Cm Find Work Done Move One Charges CentrGeometrical Shape Equipotential Surfaces Due Single Isolated Charge Capacitor Unknown Capacitance Connected Across Battery V Volts Charge Stored 360 C Potential Across White Travelling Back Residence Car Dr Pathak Caught Thunderstorm Became Dark Stopped Driving Car WaGeometrical Shape Equipotential Surfaces Due Single Isolated Charge Capacitor Unknown Capacitance Connected Across Battery V Volts Charge Stored 360 C Potential Across White Travelling Back Residence Car Dr Pathak Caught Thunderstorm Became Dark Stopped Driving Car WaGeometrical Shape Equipotential Surfaces Due Single Isolated Charge Capacitor Unknown Capacitance Connected Across Battery V Volts Charge Stored 300 C Potential Across White Travelling Back Residence Car Dr Pathak Caught Thunderstorm Became Dark Stopped Driving Car WaSlab Material Dielectric Constant K Area Plates Parallel Plate Capacitor Thickness 2 Separation PlatSlab Material Dielectric Constant K Area Plates Parallel Plate Capacitor Thickness 3 Separation PlatSlab Material Dielectric Constant K Area Plates Parallel Plate Capacitor Thickness 2d 3 Separation PPotential Inside Hollow Spherical Charged Conductor Constant Value Surface Capacitor 200 Pf Charged 300 V Battery Battery Disconnected Charge Capacitor Connected Another UnchaWork Done Moving Charge One Point Another Equipotential Surface Capacitor 150 Pf Charged 200 V Battery Battery Disconnected Charge Capacitor Connected Another UnchaTest Charge Q Moved Without Acceleration C Along Path B B C Electric Field E Shown Figure Calculate Electric Dipole Held Uniform Electric Field Show Net Force Acting Zero Ii Dipole Aligned Parallel FiDeduce Expression Electrostatic Energy Stored Capacitor Capacitance C Charge Q Energy Stored Ii ElecTest Charge Q Moved Without Acceleration C Along Path B B C Electric Field E Shown Figure Calculate Electric Dipole Held Uniform Electric Field Show Net Force Acting Zero Ii Dipole Aligned Parallel FiDeduce Expression Electrostatic Energy Stored Capacitor Capacitance C Charge Q Energy Stored Ii ElecElectrostatic Field Zero Inside Conductor Draw Plot Showing Variation Electric Field E Ii Electric Potential V Distance R Due Point Charge Q Explain Principle Device Build High Voltages Order Million Volts Draw Schematic Diagram Explain WorkMust Electrostatic Field Normal Surface Every Point Charged Conductor Draw Plot Showing Variation Electric Field E Ii Electric Potential V Distance R Due Point Charge Q Explain Principle Device Build High Voltages Order Million Volts Draw Schematic Diagram Explain WorkElectrostatic Potential Constant Throughout Volume Conductor Value Inside Surface Draw Plot Showing Variation Electric Field E Ii Electric Potential V Distance R Due Point Charge Q Explain Principle Device Build High Voltages Order Million Volts Draw Schematic Diagram Explain Work Charge Configuration Equipotential Surface Point Normal Electric Field Justify Electric Dipole Length 1 Cm Placed Axis Making Angle 60 Uniform Electric Field Experience Torque 63 Obtain Expression Energy Stored Per Unit Volume Charged Parallel Plate Capacitor B Electric Field I Charge Configuration Equipotential Surface Point Normal Electric Field Justify Electric Dipole Length 2 Cm Placed Axis Making Angle 60 Uniform Electric Field Experiences Torque 83 Obtain Expression Energy Stored Per Unit Volume Charged Parallel Plate Capacitor B Electric Field I Charge Configuration Equipotential Surface Point Normal Electric Field Justify Electric Dipole Length 4 Cm Placed Axis Making Angle 60 Uniform Electric Field Experiences Torque 43 Obtain Expression Energy Stored Per Unit Volume Charged Parallel Plate Capacitor B Electric Field IParallel Plate Capacitor Capacitance C Charged Potential V Connected Another Uncharged Capacitor CapDraw Labelled Diagram Van De Graaff Generator State Working Principle Show Introducing Small ChargedParallel Plate Capacitor Capacitance C Charged Potential V Connected Another Uncharged Capacitor CapDraw Labelled Diagram Van De Graaff Generator State Working Principle Show Introducing Small ChargedParallel Plate Capacitor Capacitance C Charged Potential V Connected Another Uncharged Capacitor CapDraw Labelled Diagram Van De Graaff Generator State Working Principle Show Introducing Small ChargedMust Electrostatic Field Surface Charged Conductor Normal Surface Every Point Give Reason Figure Shows Field Lines Positive Charge Work Done Field Moving Small Positive Charge Q P Positive N Point Charge Q Kept Vicinity Uncharged Conducting Plate Sketch Electric Field Lines Charge Plate B Parallel Plate Capacitor Air Plates Plate Area 6 10 3 M2 Separation Plates 3 Mm Calculate CapacitancFigure Shows Field Lines Due Positive Point Charge Give Sign Potential Energy Difference Small NegatMust Electrostatic Field Surface Charged Conductor Normal Surface Every Point Give Reason Point Charge Q Kept Vicinity Uncharged Conducting Plate Sketch Electric Field Lines Charge Plate B Three Concentric Metallic Shells B C Radii B C B C Surface Charge Densities Respectively Shown FigurTwo Capacitors Unknown Capacitances C1 C2 Connected First Series Parallel Across Battery 100 V EnergTwo Capacitors Unknown Capacitances C1 C2 Connected First Series Parallel Across Battery 100 V EnergFind Equivalent Capacitance Network Shown Figure Capacitor 1 F Ends X Connected 6 V Battery Find ChaTwo Capacitors Unknown Capacitances C1 C2 Connected First Series Parallel Across Battery 100 V EnergFour Charges Q Q Q Q Arranged Respectively Four Corners Square Abcd Side Find Work Required Put TogeFind Equivalent Capacitance Network Shown Figure Capacitor 1 F Ends X Connected 6 V Battery Find ChaPoint Charge Q Placed Point Shown Figure Potential Difference Va Vb Positive Negative Zero Two Parallel Plate Capacitors X Area Plates Separation X Air Plates Contains Dielectric Medium R 4 CDefine Equipotential Surface Draw Equipotential Surfaces Case Single Point Charge Ii Constant Electr Use Gauss Law Find Electric Field Due Uniformly Charged Infinite Plane Sheet Direction Field PositiPoint Charge Q Placed Point Shown Figure Potential Difference Va Vb Positive Charge Q Negative PositFollowing Arrangement Capacitors Energy Stored 6 F Capacitor E Find Value Following Energy Stored 12Charge Given Metallic Sphere Depend Whether Hollow Solid Give Reason Answer Find Equivalent Capacitance B Combination Given Capacitor 2 F Capacitance Ii Dc Source 7 V Connecte12 Pf Capacitor Connected 50 V Battery Much Electrostatic Energy Stored Capacitor Another Capacitor Derive Expression Electric Potential Due Electric Dipole Point Axial Line Ii Depict Equipotential STwo Identical Capacitors 12 Pf Connected Series Across Battery 50 V Much Electrostatic Energy StoredTwo Identical Parallel Plate Capacitors B Connected Battery V Volts Switch Closed Switch Opened FreePoint Charge Q Placed Point Shown Figure Potential Point E Va Greater Smaller Equal Potential Vb PoiGiven Circuit Steady Current Calculate Potential Drop Across Capacitor Charge Stored Draw Equipotential Surfaces Due Isolated Point Charge Describe Briefly Process Transferring Charge Two Plates Parallel Plate Capacitor Connected Battery Draw Equipotential Surfaces Due Electric Dipole B Derive Expression Electric Field Due Dipole Dipol Draw Equipotential Surfaces Corresponding Electric Field Uniformly Increases Magnitude Along Z DireFigure Shows Network Five Capacitors Connected 100 V Supply Calculate Total Energy Stored Network Explain Briefly Using Proper Diagram Difference Behavior Conductor Dielectric Presence External Ele Parallel Plate Capacitor Connected Across Dc Battery Explain Briefly Capacitor Gets Charged B ParalGeometrical Shape Equipotential Surface Point Charge Potential Due Electric Dipole Point Axis Direction DipoleRate Change Electrostatic Potential Inside Isolated Conductor Dielectric Constant Ratio Permittivity Divided Permittivity Spherical Capacitor Inner Sphere Radius 12 Cm Outer Sphere Radius 13 Cm Outer Sphere Earthed Inner S200 V Cell Connected 8 F Capacitor Removed Capacitor Fully Charged Also Uncharged 4 F Capacitor ConnDerive Expression Torque Acting Electric Dipole Held Uniform Electric Field Identify Orientation DipObtain Expression Energy Stored Capacitor Connected Across Dc Battery Hence Define Energy Density Ca Two Point Charges Q1 Q2 Kept Distance R12 Air Deduce Expression Electrostatic Potential Energy Syst Write Two Important Characteristics Equipotential Surfaces B Thin Circular Ring Radius R Charged Un Two Point Charges Q1 Q2 Placed R Distance Apart Obtain Expression Amount Work Done Place Third CharTwo Identical Capacitors Connected Series Across Source One Capacitors Filled Dielectric Effect PoteThree Concentric Spherical Shells P Q R Radii 4 Cm 6 Cm 8 Cm Given Charges 2 C 4 C 6 C Respectively Read Following Answer Four Questions V Capacitors Consist Two Parallel Conductive Plates Usually MetThree Concentric Spherical Shells P Q R Radii 4 Cm 6 Cm 8 Cm Given Charges 2 C 4 C 6 C Respectively Assertion Work Done Moving Charged Particle Along Equipotential Surface Zero Reason Equipotential SuRead Following Answer Four Questions V Electric Potential Important Quantity Electrostatics Electric Use Gauss Law Find Electric Field Due Uniformly Charged Infinite Plane Sheet Direction Field PositiFollowing Statements Correct Equipotential Surface Circumference Circle Diameter 2 4 Charges 4 C Placed Form Square Potential Centre CircleTwo Point Charges Q Q Placed Points B 0 0 B 0 0 Respectively Potential Point X 0 0 X BFollowing Question Statement Assertion Followed Statement Reason Choose Correct Answer Following ChoTwo Charges Magnitude 30 C 4 C Separated Distance 5 Cm Work Done Moving 4 C 3 Cm Towards 30 C Work Done Required Deflect Electric Dipole Angle 180o Placed Perpendicular Direction Electric Field Capacitor Unknown Capacitance Connected Across Battery V Volts Charge Stored 180 C Decreasing PotentInitially Two Parallel Plate Capacitors Connected Series Battery Emf One Capacitors Filled Uniform DRelation Electric Field Intensity E Electrostatic Energy Density UTwo Capacitors Capacitance 3 F 6 F Connected Series Entire System Connected Parallel Third Capacitor feedback on
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