Table of Contents
Charging of Insulators
Since charge cannot flow through insulators, neither conduction nor induction can be used to charge, insulators, so in order to charge an insulator friction is used. Whenever an insulator is rubbed against a body exchange of electrons takes place between the two. This results in appearance of equal and opposite charges on the insulator and the other body. Thus the insulator is charged.
For example rubbing of plastic with fur, silk with glass causes charging of these things.
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Electric Field of a Line Charge
Last modified on:3 years agoReading Time:3MinutesElectric Field of a Line Charge Positive charge q is distributed uniformly along a line with length 2a, lying along the y-axis between y=–a and y=+a. We are here interested in finding the electric field at point P on the x-axis. Derivation of electric field due to a line charge: Thus,…
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Electric Field Lines
Last modified on:3 years agoReading Time:5MinutesElectric Field Lines Electric charges create an electric field in the space surrounding them. It is useful to have a kind of “map” that gives the direction and indicates the strength of the field at various places. Field lines, a concept introduced by Michael Faraday, provide us with an easy way…
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Human Ear
Last modified on:4 years agoReading Time:3MinutesHuman Ear The human ear, like that of other mammals, contains sense organs that serve two quite different functions: that of hearing and that of head and eye movements. Anatomically, the ear has three distinguishable parts: the outer, middle, and inner ear. How Human Ear Works? Different sounds produced in our surroundings are collected by…
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Samp
Last modified on:3 years agoReading Time:1Minute Adobe Acrobat Services PDF Embed API Sample Adobe Acrobat Services PDF Embed API Sample Adobe Acrobat Services PDF Embed API Sample Adobe Acrobat Services PDF Embed API Sample Lets meet lets discuss Adobe Acrobat Services PDF Embed API Sample
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Important Derivations for Class 12 Physics Chapter 3 Current Electricity
Last modified on:3 years agoReading Time:20MinutesImportant Derivations for Class 12 Physics Chapter 3 Current Electricity Deduction of Ohm’s law. When a potential difference ‘V’ is applied across a conductor of length ‘l’, the drift velocity in terms of ‘V’ is given by $$ v_d=\frac{e E \tau}{m}=\frac{e V \tau}{m l} $$ If the area of cross-section of…
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Important Derivations for Class 12 Physics Chapter 2 Electrostatic Potential and Capacitance
Last modified on:3 years agoReading Time:9MinutesImportant Derivations for Class 12 Physics Chapter 2 Electrostatic Potential and Capacitance Derivations Related to Potential due to an Electric Dipole Derivation 1: Electric potential due to electric dipole at a point on its axial line. Solution: Let ‘P’ be an axial point at distance ‘r’ from the centre of the…
