EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
6th Edition
ISBN: 9781319321710
Author: Mosca
Publisher: VST
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Chapter 21, Problem 86P

(a)

To determine

The charge on the sphere.

(a)

Expert Solution
Check Mark

Explanation of Solution

Given:

The radius of the microsphere is 5.50×107m .

The Magnitude of electric field is 6.00×104N/m .

The magnitude of the drag force is 6πηrv .

The viscosity of the air is 1.8×105N.s/m2 .

The density of the polystyrene is 1.05×103kg/m3 .

Formula used:

Write the expression for the downward and upward force.

  FEmgFd=may ....... (1)

Here, FE is the electric force, m is the mass, g is acceleration due to gravity, Fd is the drag force.

Write the expression for the force.

  F=qE

Here, F is the force, q is the charge and E is the electric field.

Write the expression for the mass.

  m=ρV

Here, ρ is the density and V is the volume.

Substitute qE for FE , ρV for m , 0 for ay and 6πηrv for Fd in equation (1).

  qEρVg6πηrv=0 ....... (2)

Write the expression for the charge.

  q=Ne

Here, q is the total charge, N is the number of particles and e is the charge on particle.

Write the expression for the volume of the sphere.

  V=43πr3

Here, r is the radius.

Substitute Ne for q and 43πr3 for V in equation (2).

  NeEρ(43πr3)g6πηrv=0

Solve the above equation for Ne .

  Ne=43πr3ρg+6πηrvE ....... (3)

Calculation:

Substitute 5.50×107m for r , 1.05×103kg/m3 for ρ , 9.81m/s2 for g , 1.8×105N.s/m2 for η , 1.16×104m/s for v and 6.00×104N/m for E in equation (3).

  Ne=43π ( 5.50× 10 7 m )31.05× 103kg/ m 3( 9.81m/ s 2 )+6π5.50× 107( 1.8× 10 5 N.s/ m 2 )1.16× 10 4m/s6.00× 104N/mNe=4.8×1019C

Conclusion:

Thus, the charge on the sphere is 4.8×1019C .

(b)

To determine

The number of excess electron on the sphere.

(b)

Expert Solution
Check Mark

Explanation of Solution

Given:

The radius of the microsphere is 5.50×107m .

The Magnitude of electric field is 6.00×104N/m .

The magnitude of the drag force is 6πηrv .

The viscosity of the air is 1.8×105N.s/m2 .

The density of the polystyrene is 1.05×103kg/m3 .

Formula used:

Write the expression for the downward and upward force.

  FEmgFd=may

Here, FE is the electric force, m is the mass, g is acceleration due to gravity, Fd is the drag force.

Write the expression for the force.

  F=qE

Here, F is the force, q is the charge and E is the electric field.

Write the expression for the mass.

  m=ρV

Here, ρ is the density and V is the volume.

Substitute qE for FE , ρV for m , 0 for ay and 6πηrv for Fd in equation (1).

  qEρVg6πηrv=0

Write the expression for the charge.

  q=Ne

Here, q is the total charge, N is the number of particles and e is the charge on particle.

Write the expression for the volume of the sphere.

  V=43πr3

Here, r is the radius.

Substitute Ne for q and 43πr3 for V in equation (2).

  NeEρ(43πr3)g6πηrv=0

Solve the above equation for N .

  N=43πr3ρg+6πηrvEe ....... (4)

Calculation:

Substitute 5.50×107m for r , 1.05×103kg/m3 for ρ , 9.81m/s2 for g , 1.8×105N.s/m2 for η , 1.16×104m/s for v and 6.00×104N/m for E and 1.602×1019C for e in equation (3).

  N=43π ( 5.50× 10 7 m )31.05× 103kg/ m 3( 9.81m/ s 2 )+6π5.50× 107( 1.8× 10 5 N.s/ m 2 )1.16× 10 4m/s( 1.602× 10 19 C)6.00× 104N/mN=3

Conclusion:

Thus, the number of excess electron on the sphere is 3.

(c)

To determine

The new terminal speed.

(c)

Expert Solution
Check Mark

Explanation of Solution

Given:

The radius of the microsphere is 5.50×107m .

The Magnitude of electric field is 6.00×104N/m .

The magnitude of the drag force is 6πηrv .

The viscosity of the air is 1.8×105N.s/m2 .

The density of the polystyrene is 1.05×103kg/m3 .

Formula used:

Write the expression for the forces when electric field is upward.

  FdFEmg=0 ....... (5)

Here, FE is the electric force, m is the mass, g is acceleration due to gravity, Fd is the drag force.

Write the expression for the force.

  F=eE

Here, F is the force, e is the charge and E is the electric field.

Write the expression for the mass.

  m=ρV

Here, ρ is the density and V is the volume.

Substitute qE for FE , ρV for m , 43πr3 for V and 6πηrv for Fd in equation (1).

  6πηrvNeE(43πr3)ρg=0

Solve the above equation for v .

  v=NeE+(43πr3)ρg6πηr ....... (6)

Calculation:

Substitute 5.50×107m for r , 1.05×103kg/m3 for ρ , 9.81m/s2 for g , 1.8×105N.s/m2 for η , 3 for N , 6.00×104N/m for E and 1.602×1019C for e in equation (3).

  v=3( 1.602× 10 19 C)6.00× 104N/m+( 4 3 π ( 5.50× 10 7 m ) 3 )( 1.05× 10 3 kg/ m 3 )9.81m/ s 26π( 1.8× 10 5 N.s/ m 2 )5.50× 107mv=0.19mm/s

Conclusion:

Thus, the new terminal speed is 0.19mm/s .

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Chapter 21 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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