Volume 2

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A conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre.
05
Dec
A conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre. A conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre. December 5, 2020 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: A conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre. ,
A non-conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre.
05
Dec
A non-conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre. A non-conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre. December 5, 2020 [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: A non-conducting solid sphere of radius R is uniformly charged. The magnitude of electric field due to the sphere at a distance r from its centre. ,
A point charge q and a charge (−q) are placed at x=−a and x=+a respectively. Which of the following represents a part of E−x graph?
05
Dec
A point charge q and a charge (−q) are placed at x=−a and x=+a respectively. Which of the following represents a part of E−x graph? A point charge q and a charge (−q) are placed at x=−a and x=+a respectively. Which of the following represents a part of E−x graph? December 5, 2020 Category: Arihant [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: A point charge q and a charge (−q) are placed at x=−a and x=+a respectively. Which of the following represents a part of E−x graph? ,
Three charged particles are collinear and are in equilibrium. Then :
05
Dec
Three charged particles are collinear and are in equilibrium. Then : Three charged particles are collinear and are in equilibrium. Then : December 5, 2020 Category: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: Three charged particles are collinear and are in equilibrium. Then : ,
The electric field versus distance graph is shown, where distance is measured from the centre of the body, then
05
Dec
The electric field versus distance graph is shown, where distance is measured from the centre of the body, then The electric field versus distance graph is shown then where distance is measured from the centre of the body December 5, 2020 Category: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: The electric field versus distance graph is shown , then , where distance is measured from the centre of the body ,
In a region, electric field varies as E=2x^2 −4 where x is distance in S.I. from origin along x-axis. A positive charge of 1μC is released with minimum velocity from infinity for crossing the origin, then
05
Dec
In a region, electric field varies as E=2x^2 −4 where x is distance in S.I. from origin along x-axis. A positive charge of 1μC is released with minimum velocity from infinity for crossing the origin, then electric field varies as E=2x^2 −4 where x is distance in S.I. from origin along x-axis. A positive charge [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: electric field varies as E=2x^2 −4 where x is distance in S.I. from origin along x-axis. A positive charge of 1μC is released with minimum velocity from infinity for crossing the origin , In a region , then ,
The electric intensity at a point A at distance x from uniformly charged non-conducting plane is E. Then
05
Dec
The electric intensity at a point A at distance x from uniformly charged non-conducting plane is E. Then The electric intensity at a point A at distance x from uniformly charged non-conducting plane is E. Then December 5, 2020 Category: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: The electric intensity at a point A at distance x from uniformly charged non-conducting plane is E. Then ,
If a conductor encloses a charge, then in equilibrium :
05
Dec
If a conductor encloses a charge, then in equilibrium : If a conductor encloses a charge then in equilibrium : December 5, 2020 Category: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: If a conductor encloses a charge , then in equilibrium : ,
An electrostatic field E of magnitude 10 N/C is directed along positive x−axis. A point charge of 10^−6 is shifted from A(1m,0,0) to B(2m,0,1m), then from point B to C(0,0,0), the work done by electrostatic force is
05
Dec
An electrostatic field E of magnitude 10 N/C is directed along positive x−axis. A point charge of 10^−6 is shifted from A(1m,0,0) to B(2m,0,1m), then from point B to C(0,0,0), the work done by electrostatic force is 0 ) 0) to B(2m 1)m. An electrostatic field E of magnitude 10 N/C is directed along positive [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: 0 ) , 0) to B(2m , 1)m. , An electrostatic field E of magnitude 10 N/C is directed along positive x−axis. A point charge of 10^−6 is shifted from A(1m , the work done by electrostatic force is , then from point B to C(0 ,
A spring – block system undergoes vertical oscillation above a large horizontal metal sheet with uniform positive charge. The time period of the oscillation will be is given a charge Q , its time period of oscillation will be
05
Dec
A spring – block system undergoes vertical oscillation above a large horizontal metal sheet with uniform positive charge. The time period of the oscillation will be is given a charge Q , its time period of oscillation will be A spring - block system undergoes vertical oscillation above a large horizontal metal sheet with uniform [...]
Posted in: Arihant Physics by D.C Pandey , Chapter 1 - Electric Charges and Fields , Volume 2 ,
Tags: A spring - block system undergoes vertical oscillation above a large horizontal metal sheet with uniform positive charge. The time period of the oscillation will be is given a charge Q , its time period of oscillation will be ,