A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P
Sahay Sir > Question Answers > A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P
Bainbridge’s mass spectrometer separates ion having the same velocity. The ions, after enteering through slits, S1 and S2, pass through a velocity selector composed of an electric field produced by the charged plates P and P’ and a magnetic field B perpendicular to electric field and the ion path.Thew ions that then pass undeviated through the crossed E 1 and B fields enter into a region where a second magnetic field B exists, where they are made to follow circular path. A photographic plate ( or a modern detector) registors their arrival. If r is the radius of the circular orbit , then specific charge qm of ion is
04
Sep
Bainbridge’s mass spectrometer separates ion having the same velocity. The ions, after enteering through slits, S1 and S2, pass through a velocity selector composed of an electric field produced by the charged plates P and P’ and a magnetic field B perpendicular to electric field and the ion path.Thew ions that then pass undeviated through [...]
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A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P ,
a uniform electric field is switched on so that the particle starts moving along the tangent with uniform velocity. The electric field is ,
after enteering through slits ,
an electron of mass m ,
and low (negligible )speed enters the region between two polates of potential difference V and plate seperation d ,
Bainbridge's mass spectrometer separates ion having the same velocity. The ions ,
charge -e ,
In the below fig ,
S1 and S2 ,
In the below fig, an electron of mass m, charge -e, and low (negligible )speed enters the region between two polates of potential difference V and plate seperation d, initially headed directly toward the top plate. A uniform magnectic field of magnitude B is normal to the plane of the fig. find the minimum value of B such that the electron will not strike the top plate.
04
Sep
In the below fig, an electron of mass m, charge -e, and low (negligible )speed enters the region between two polates of potential difference V and plate seperation d, initially headed directly toward the top plate. A uniform magnectic field of magnitude B is normal to the plane of the fig. find the minimum value [...]
Tags:
A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P ,
a uniform electric field is switched on so that the particle starts moving along the tangent with uniform velocity. The electric field is ,
an electron of mass m ,
and low (negligible )speed enters the region between two polates of potential difference V and plate seperation d ,
charge -e ,
In the below fig ,
A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P, a uniform electric field is switched on so that the particle starts moving along the tangent with uniform velocity. The electric field is
04
Sep
A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P, a uniform electric field is switched on so that the particle starts moving along the tangent [...]
Tags:
A particle having a charge of 10 μC and mass 1 μg moves in a horizontal circle of radius 10 cm under the influence of a magnetic field of 0.1 T. When the particle is at a point P ,
a uniform electric field is switched on so that the particle starts moving along the tangent with uniform velocity. The electric field is ,