A Textbook in Electricity and Magnetism |
From inside the book
Page 2
... zero . Then , by this law , the acceleration , a , is also equal to zero . What does this mean ? If the acceleration is zero , then the velocity is constant - from which Newton's first law follows . For , if the force is zero , a body ...
... zero . Then , by this law , the acceleration , a , is also equal to zero . What does this mean ? If the acceleration is zero , then the velocity is constant - from which Newton's first law follows . For , if the force is zero , a body ...
Page 25
... zero . The only work done then is over the sections of radii dı , d2 , dз , and d4 . Let us compute this work . The ... zero . It follows that the total potential energy gained by a mass in traveling around a completely closed path is ...
... zero . The only work done then is over the sections of radii dı , d2 , dз , and d4 . Let us compute this work . The ... zero . It follows that the total potential energy gained by a mass in traveling around a completely closed path is ...
Page 70
... zero . This is called Kirchhoff's loop rule and is usually stated as : COROLLARY II . The total potential change in bringing a charge around a complete loop is zero . We can attack this problem in a much simpler manner . The potential ...
... zero . This is called Kirchhoff's loop rule and is usually stated as : COROLLARY II . The total potential change in bringing a charge around a complete loop is zero . We can attack this problem in a much simpler manner . The potential ...
Contents
CHAPTER | 1 |
GRAVITATIONAL POTENTIAL | 16 |
ENERGY RELATIONS | 28 |
Copyright | |
19 other sections not shown
Common terms and phrases
acceleration ammeter Ampère's law amperes atom axis battery body Calculate called capacitance cathode cell centimeters charge Q circuit coil Compute condenser conductor connected Consider constant copper coulomb deflection density dielectric dielectric constant direction distance dynes E₁ earth effect electric field electrolyte electromagnetic electron electron volts electrostatic emitted equal equation equipotential ergs example field due field H filament flow flux frequency galvanometer Gauss's law given gram gravitational grid heat impedance induced emf ionization ions kinetic energy Kirchhoff's law lines of force magnetic field mass maximum measured metal method motion moving negative charge Ohm's law ohms parallel path plane plate current pole potential difference potential drop R₁ radius resistance resultant rotation self-inductance shown in Fig solenoid solution sphere surface temperature thermocouple torque tube unit vacuum vector velocity voltage voltmeter volts wave wire zero