The proof that d B z d z = 0 , d 2 B z d z 2 = 0 and d 3 B z d z 3 = 0 .

Question

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Answer 1

Question

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

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Students have asked these similar questions

You have two coils, one circular with diameter of length 'a' and another square with each side of length 'a', placed in the x-y plane. there is a uniform magnetic field B pointing along the positive z-direction. Each loop has the same number of turns, carries the same current, in the same direction. Therefore the ratio of magnetic moment (u) of the loop, [circular] / [square] =

A conducting rod is free to move along 2 parallel conducting rails. On one end a resistor, R, connects the two rails which forms a circuit. The rails are oriented along the y axis of a coordinate system. There is a constant magnetic B aligned with the z axis making it perpendicular to the plane of the rails and rod. If the rod is given an initial velocity of vo, and hence a kinetic energy of m*vo2 /2, mathematically demonstrate that as the rod rounds to a stop in an infinite time the power lost in the resistor as heat is equal to the initial kinetic energy.

You have a square loop with each side of length 'a' and a circular loop with radius 'a'. Both of these loops lie in the x-y-plane, where there is a uniform magnetic field B pointing at some angle with respect to the positive z-direction. Each loop has the same number of coils and carries the same current, in the same direction. Therefore, the ratio of magnetic moments (u) in the loops, [square] / [circular]

Answer 2

Question

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

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Answer 3

Question

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

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Answer 4

Question

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

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Answer 5

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Answer 6

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Answer 7

Chapter 27, Problem 23P

To determine

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Answer 8

Expert Solution & Answer

Answer to Problem 23P

It is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Formula used:

The expression for total magnetic fieldis given by,

Bz=μ0nR2I2(z1−1+z2−1)

Calculation:

The total magnetic fieldis calculated as,

dBzdz=ddz( μ 0 n R 2 I2( z 1 −1 + z 2 −1 ))=( μ 0 n R 2 I2)(−3z1 −4 d z 1 dz−3z2 −4 d z 2 dz) ....... (1)

Differentiate z1=( z+ 1 2 R)2+R2 with respect to z .

dz1dz=ddz( ( z+ 1 2 R ) 2 + R 2 )=12( ( ( z+ 1 2 R ) 2 + R 2 ) − 1 2 )(2( z+ 1 2 R))=( z+ 1 2 R)z1

Differentiate z2=( z− 1 2 R)2+R2 with respect to z .

dz2dz=ddz( ( z− 1 2 R ) 2 + R 2 )=12( ( ( z− 1 2 R ) 2 + R 2 ) − 1 2 )(2( z− 1 2 R))=( z− 1 2 R)z2

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (1).

dBzdz=( μ 0 n R 2 I2)(−3z1 −4( ( z+ 1 2 R ) z 1 )−3z2 −4( ( z− 1 2 R ) z 2 ))=( μ 0 n R 2 I2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 ) ....... (2)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (2).

dBzdz=( μ 0 n R 2 I2)( −3( 0+ 1 2 R ) 5 4 R 2 + −3( 0− 1 2 R ) 5 4 R 2 )=0

Differentiate equation (2) with respect to z .

d2Bzdz2=ddz[( μ 0 n R 2 I 2)( −3( z+ 1 2 R ) z 1 5 + −3( z− 1 2 R ) z 2 5 )]=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( d z 1 dz ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( d z 2 dz ) )) ....... (3)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (3).

d2Bzdz2=( μ 0 n R 2 I2)(−3)( ( 1 z 1 5 − 5( z+ 1 2 R ) z 1 6 ( ( z+ 1 2 R ) z 1 ) ) +( 1 z 2 5 − 5( z+ 1 2 R ) z 2 6 ( ( z− 1 2 R ) z 2 ) ))=( μ 0 n R 2 I2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 )) ....... (4)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (4).

d2Bzdz2=( μ 0 n R 2 I2)(−3)(( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0+ 1 2 R ) 2 ( 5 4 R 2 ) 7 2 )+( 1 ( 5 4 R 2 ) 5 2 − 5 ( 0− 1 2 R ) 2 ( 5 4 R 2 ) 7 2 ))=( μ 0 n R 2 I2)(−3)(1 ( 5 4 R 2 ) 5 2 −1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 +1 ( 5 4 R 2 ) 5 2 )=0

Differentiate equation (4) with respect to z .

d3Bzdz3=ddz[( μ 0 n R 2 I 2)(−3)(( 1 z 1 5 − 5 ( z+ 1 2 R ) 2 z 1 7 )+( 1 z 2 5 − 5 ( z− 1 2 R ) 2 z 2 7 ))]=( μ 0 n R 2 I2)(−3)[( −5 z 1 6 ( d z 1 dz )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( d z 1 dz ) )+( −5 z 1 6 ( d z 2 dz )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( d z 2 dz ) )] ....... (5)

Substitute (z+12R)z1 for dz1dz and (z−12R)z2 for dz2dz in equation (5)

d 3 B z d z 3 =( μ 0 n R 2 I 2 )( −3 )[ ( −5 z 1 6 ( ( z+ 1 2 R ) z 1 )− 10( z+ 1 2 R ) z 1 7 − −35 ( z+ 1 2 R ) 2 z 1 8 ( ( z+ 1 2 R ) z 1 ) )+ ( −5 z 1 6 ( ( z− 1 2 R ) z 1 )− 10( z− 1 2 R ) z 1 7 − −35 ( z− 1 2 R ) 2 z 1 8 ( ( z− 1 2 R ) z 1 ) ) ]

=( μ 0 n R 2 I 2 )( −3 )( − 15( z+ 1 2 R ) z 1 7 + 35 ( z+ 1 2 R ) 3 z 1 9 − 15( z− 1 2 R ) z 2 7 + 35 ( z− 1 2 R ) 2 z 2 9 )........ (6)

Substitute 0 for z 54R2 for z1 and 54R2 for z2 in equation (6).

d3Bzdz3=( μ 0 n R 2 I2)(−3)( − 15( 0+ 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( 0+ 1 2 R ) 3 ( 5 4 R 2 ) 9 2 − 15( z− 1 2 R ) ( 5 4 R 2 ) 7 2 + 35 ( z− 1 2 R ) 2 ( 5 4 R 2 ) 9 2 )=0

Conclusion:

Therefore, it is proved that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Answer 12

Ch. 27 - Prob. 1P Ch. 27 - Prob. 2P Ch. 27 - Prob. 3P Ch. 27 - Prob. 4P Ch. 27 - Prob. 5P Ch. 27 - Prob. 6P Ch. 27 - Prob. 7P Ch. 27 - Prob. 8P Ch. 27 - Prob. 9P Ch. 27 - Prob. 10P

The proof that d B z d z = 0 , d 2 B z d z 2 = 0 and d 3 B z d z 3 = 0 .

Videos

The proof that dBzdz=0, d2Bzdz2=0 and d3Bzdz3=0 .

Answer to Problem 23P

Explanation of Solution

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