r/cm0.002.004.006.008.0010.012.014.016.018.020.0x=0.00 cm719719719717710696669620527415284x=2.00 cm719719719719715704682639550432289Bx/μTx 4.00 cm x=6.00 cm x 8.00 cm71870271970472471172772472774872778272083369791562410724951210304486714716720728741757775791776653338Table 3 Values for the x-component of the magnetic field for various valuesof r and x.(i) At r = 0, over what approximate range of x does Bø remain above98% of its value at the origin of the coordinate system? Considernegative x coordinates as well the positive à coordinates shown inthe table.(ii)At x = 0, over what approximate range of r does B. remain above98% of its value at the origin of the coordinate system?X(iii) What is the approximate shape of the volume in which B is above98% of its value at the centre? Give the approximate dimensions ofthis shape.Hint: You may find it useful to consider how the field will evolvewith rotation about the x axis.x10.0 cm68168469270773677784295712502002 The student sets up a new arrangement in the interactive screenexperiment. This comprises two coils, each of radius R = 20.0 cm. Theseparation between the coils is also 20.0 cm. Each coil has N = 40.0turns and carries a current of I = = 4.00 A. The arrangement is illustratedin Figure 2 below. The coils are centred on the x-axis and the origin ofthe coordinate system is midway between the centres of the two coils.

Answered: Image /qna-images/answer/92b6093f-704e-4a8d-b0c0-cab74f531220.jpg

Table 3 Values for the x-component of the magnetic field for various values of r and x. (i) At r = 0, over what approximate range of x does B remain above 98% of its value at the origin of the coordinate system? Consider negative coordinates as well the positive x coordinates shown in the table. (ii) At x = 0, over what approximate range of r does B remain above 98% of its value at the origin of the coordinate system? (iii) What is the approximate shape of the volume in which B is above 98% of its value at the centre? Give the approximate dimensions of this shape. Hint: You may find it useful to consider how the field will evolve with rotation about the x axis.

Table 3 Values for the x-component of the magnetic field for various values of r and x. (i) At r = 0, over what approximate range of x does B remain above 98% of its value at the origin of the coordinate system? Consider negative coordinates as well the positive x coordinates shown in the table. (ii) At x = 0, over what approximate range of r does B remain above 98% of its value at the origin of the coordinate system? (iii) What is the approximate shape of the volume in which B is above 98% of its value at the centre? Give the approximate dimensions of this shape. Hint: You may find it useful to consider how the field will evolve with rotation about the x axis.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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Concept explainers

Magnetic Field Of Coaxial Cable

The word coaxial means same axis. So for a long straight cable to be coaxial, it must have concentric cylindrical shaped conductor around it. Coaxial cable (popularly called ‘coax’) has various applications ranging from current conductors to radiofrequency signal transmitters. This cable has lower emission losses and provides protection from electromagnetic interference which allows signals with less power to transmit over longer distances.For example, currents produced in the pickup of a stereo turntable generally travel to the amplifier through a coaxial cable.The self-inductance of a coaxial cable is another important characteristic, because it influences the propagation of electrical signals in the cable.

Question

100%

r/cm
0.00
2.00
4.00
6.00
8.00
10.0
12.0
14.0
16.0
18.0
20.0
x=0.00 cm
719
719
719
717
710
696
669
620
527
415
284
x=2.00 cm
719
719
719
719
715
704
682
639
550
432
289
Bx/μT
x 4.00 cm x=6.00 cm x 8.00 cm
718
702
719
704
724
711
727
724
727
748
727
782
720
833
697
915
624
1072
495
1210
304
486
714
716
720
728
741
757
775
791
776
653
338
Table 3 Values for the x-component of the magnetic field for various values
of r and x.
(i) At r = 0, over what approximate range of x does Bø remain above
98% of its value at the origin of the coordinate system? Consider
negative x coordinates as well the positive à coordinates shown in
the table.
(ii)
At x = 0, over what approximate range of r does B. remain above
98% of its value at the origin of the coordinate system?
X
(iii) What is the approximate shape of the volume in which B is above
98% of its value at the centre? Give the approximate dimensions of
this shape.
Hint: You may find it useful to consider how the field will evolve
with rotation about the x axis.
x
10.0 cm
681
684
692
707
736
777
842
957
1250
2002

The student sets up a new arrangement in the interactive screen
experiment. This comprises two coils, each of radius R = 20.0 cm. The
separation between the coils is also 20.0 cm. Each coil has N = 40.0
turns and carries a current of I = = 4.00 A. The arrangement is illustrated
in Figure 2 below. The coils are centred on the x-axis and the origin of
the coordinate system is midway between the centres of the two coils.

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