The magnetic field at origin.

Question

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Answer 1

Question

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

(b)

To determine

The magnetic field at x=0, y=1.0 m .

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

(c)

To determine

The magnetic field at x=0, y=3.0 m .

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

(d)

To determine

The magnetic field at x=0, y=4.0 m .

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^

Conclusion:

Therefore, the magnetic field is (9.0 pT)k^ .

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The force of the quadriceps (Fq) and force of the patellar tendon (Fp) is identical (i.e., 1000 N each). In the figure below angle in blue is Θ and the in green is half Θ (i.e., Θ/2). A) Calculate the patellar reaction force (i.e., R resultant vector is the sum of the horizontal component of the quadriceps and patellar tendon force) at the following joint angles: you need to provide a diagram showing the vector and its components for each part. a1) Θ = 160 degrees, a2) Θ = 90 degrees. NOTE: USE ONLY TRIGNOMETRIC FUNCTIONS (SIN/TAN/COS, NO LAW OF COSINES, NO COMPLICATED ALGEBRAIC EQUATIONS OR ANYTHING ELSE, ETC. Question A has 2 parts!

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Answer 2

Question

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

(b)

To determine

The magnetic field at x=0, y=1.0 m .

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

(c)

To determine

The magnetic field at x=0, y=3.0 m .

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

(d)

To determine

The magnetic field at x=0, y=4.0 m .

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^

Conclusion:

Therefore, the magnetic field is (9.0 pT)k^ .

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Answer 3

Question

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

(b)

To determine

The magnetic field at x=0, y=1.0 m .

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

(c)

To determine

The magnetic field at x=0, y=3.0 m .

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

(d)

To determine

The magnetic field at x=0, y=4.0 m .

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^

Conclusion:

Therefore, the magnetic field is (9.0 pT)k^ .

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Answer 4

Question

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

(b)

To determine

The magnetic field at x=0, y=1.0 m .

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

(c)

To determine

The magnetic field at x=0, y=3.0 m .

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

(d)

To determine

The magnetic field at x=0, y=4.0 m .

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^

Conclusion:

Therefore, the magnetic field is (9.0 pT)k^ .

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Answer 5

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

(b)

To determine

The magnetic field at x=0, y=1.0 m .

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

(c)

To determine

The magnetic field at x=0, y=3.0 m .

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

(d)

To determine

The magnetic field at x=0, y=4.0 m .

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^

Conclusion:

Therefore, the magnetic field is (9.0 pT)k^ .

Answer 6

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

Answer 7

Chapter 27, Problem 13P

(a)

To determine

The magnetic field at origin.

Answer 8

(a)

Expert Solution

Answer to Problem 13P

The magnetic field at origin is −(9.0 pT)k^ .

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given:

The charge is q=12 μC .

The velocity is v→=30 m/s i^ .

Formula used:

The expression for magnetic field is given by,

B→=μ04πqv→×r^r2

Calculation:

The magnetic field at origin is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 2.0 m ) 2 )=−(9.0 pT)k^

Conclusion:

Therefore, the magnetic field at origin is −(9.0 pT)k^ .

Answer 13

(b)

To determine

The magnetic field at x=0, y=1.0 m .

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

Answer 14

(b)

To determine

The magnetic field at x=0, y=1.0 m .

Answer 15

(b)

Expert Solution

Answer to Problem 13P

The magnetic field is −(36.0 pT)k^ .

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +1.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( − j ^ ) ) ( 1.0 m ) 2 )=−(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is −(36.0 pT)k^ .

Answer 20

(c)

To determine

The magnetic field at x=0, y=3.0 m .

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

Answer 21

(c)

To determine

The magnetic field at x=0, y=3.0 m .

Answer 22

(c)

Expert Solution

Answer to Problem 13P

The magnetic field is (36.0 pT)k^ .

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +3.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 1.0 m ) 2 )=(36.0 pT)k^

Conclusion:

Therefore, the magnetic field is (36.0 pT)k^ .

Answer 27

(d)

To determine

The magnetic field at x=0, y=4.0 m .

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^

Conclusion:

Therefore, the magnetic field is (9.0 pT)k^ .

Answer 28

(d)

To determine

The magnetic field at x=0, y=4.0 m .

Answer 29

(d)

Expert Solution

Answer to Problem 13P

The magnetic field is (9.0 pT)k^ .

Answer 30

(d)

Expert Solution

Answer 31

(d)

Expert Solution

Answer 32

Expert Solution

Answer 33

Explanation of Solution

Calculation:

The magnetic field is calculated as,

B→=μ04πqv→×r^r2=( 4π× 10 −7 T⋅m/A 4π)( ( ( 12 μC )( 10 −6 C 1 μC ) )( ( 30 m/s i ^ )× r ^ ) ( 0 i ^ +4.0 j ^ −0 i ^ −2.0 j ^ ) 2 )=(( 36× 10 −12 T⋅ m 2 )( 10 12 pT 1 T ))( ( i ^ ×( j ^ ) ) ( 2.0 m ) 2 )=(9.0 pT)k^