There is a current of 10A in a flat circular coil having 60 closely wound turns, with a radius of 12 cm. What is the flux density at the center of the coil?
Q: A straight wire of radius a is aligned with the 2 axis and supports a cur I Σπα2 H=- Determine the…
A: Current through wire is I. Radius of wire is a. Current density is given by J=CurrentArea
Q: There is a long coaxial cable. The 2 mm radius inner wire carries .4 amps and the thin outer sheath…
A: Given that :R1=2 mmR2=6 mmI=0.4 A
Q: A metallic tube has inner radius a and outer radius b. A current I runs through the tube and is…
A: Given data- A metallic tube has inner radius a and outer radius b. A current I runs through the tube…
Q: tic field exceeds 0.10
A: The formula to calculate the magnitude of magnetic field is,Thus, the current will be,
Q: A circular piece of wire with radius 0.48 m has a 75.1 T magnetic field passing through. What is the…
A: Consider the radius of the wire is 0.48 and magnetic field is 751.T. The formula for the magnetic…
Q: Pr3. A long, cylindrical wire has the cross-section of an annulus, i.e. region between two…
A:
Q: A very long and thin conducting sheet lies in the xy plane and it carries he sheet has width w.…
A: We have to assume uniform current distribution given width = w we have to find magnetic field at…
Q: A small, square loop carries a 25 A current. The on-axis magnetic field strength at 50 cm from the…
A: The current in the square loop is I = 25 A. The on axis magnetic field strength at a distance r = 50…
Q: The figure below shows the cross section of a long cylindrical conducting cylinder of radius a =…
A: Magnetic field.
Q: An electromagnet in the shape of a horseshoe has a coil with N turns. The coil carries a current I.…
A: Given:Turns on the electromagnet, NArea of cross section of the poles, Acurrent through the…
Q: The figure shows the cross section of a long cylindrical conductor of radius a = 1.00 cm carrying…
A: Solution:-Given thata=1 cm=0.01 mUniform current (Ia)=100 Ar=0.8 cm=0.8×10-2 m
Q: A very long, straight coaxial cable consists of a copper core of radius a surrounded by a cladding…
A:
Q: A small circular coil of 20 loops of wire having a radius of 1 cm is at rest in the x-y plane (so…
A: 1) magnetic flux = NBACos0° = 20×0.5×π×0.012 = 3.14×10-3 T m2 Option b correct
Q: loop of wire with radius r = 0.079 m is in a magnetic field of magnitude B as shown in the figure.…
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Q: long, straight wire lies in the plane of a circular coil with a radius of 0.017 m. The wire carries…
A: Given Radius of circular coil is R=0.017 m Current passing through a long straight wire is I=7.5 A.…
Q: A uniform magnetic field of 10 x10 i passes through a single loop rectangular coil of dimension of…
A: Given data: Magnetic field, B=10×10-3 T Length of the rectangle loop, l=3.3 m Breadth of the…
Q: A very long cylindrically symmetric conducting cylinder has an inner radius of r1=5.06cm and an…
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Q: 12 R
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Q: The magnetic field between the poles of a magnet has magnitude 0.510 T. A circular loop of wire with…
A: Given data: Magnetic field (B) = 0.510 T Radius of circular loop(r)= 1.40 cm =1.40×10-2 m Angle…
Q: The accompanying figure shows a cross-section of a long, hollow, cylindrical conductor of inner…
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Q: Niobium metal becomes a superconductor when cooled below 9 K. Its superconductivity is destroyed…
A: The magnetic field at the surface of the niobium wire can be given by the Ampere’s law as, Here, I,…
Q: At a particular location, the earth’s magnetic field is 50 μT tipped at an angle of 60° below…
A:
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- A Gaussian surface has the shape of a right circular cylinder and is in a region where there is a magnetic field. There is an inward magnetic flux through the bottom cup of the cylinder 10 Wb. There is an outward magnetic flux through the top cup of the cylinder of 5Wb. Calculate the magnetic flux through the curved surface of the cylinder.The magnetic field between the poles of a magnet has magnitude 0.510 T. A circular loop of wire with radius 1.30 cm is placed between the poles so the field makes an angle of 22.0° with the plane of the loop. What is the magnetic flux through the loop? WbPr4. A solid, long insulating cylinder of radius R is uniformly charged over the entire volume, its volume charge density is e. The cylinder rotates with constant angular velocity w around its symmetry axis. Find the direction and magnitude of the magnetic field created by the rotating cylinder as a function of the distance r measured from the symmetry axis (r < R). Hint: Use Ampere's law.
- loop. The magnetic field in this case is A vertically oriented square loop of copper wire falls from rest in a region in which the field B is horizontal, uniform, and perpendicular to the plane of the loop, into a field- free region, see (Figure 1). The side length of the loop is s and the wire diameter is d. The resistivity of copper is PR and the density of copper is pm. If the loop reaches its terminal speed while its upper segment is still in the magnetic-field region, find an expression for the terminal speed. Part I Find the emf. Express your answer in terms of the variables s, B, and v. ▸ View Available Hint(s) E = Ο ΑΣΦ Submit Figure Square loop of copper wire. Above this line: Buniform and horizontal Below this line: B=0 s = side length X X 1 of 1 X X X XBX X dwire diameter ↑ s = side length Part J Complete previous part(s) Part K Complete previous part(s) Part L Complete previous part(s) Part M Complete previous part(s) Part N Complete previous part(s) EVALUATE Uterminal Part…A2.1 mm -diameter copper wire carries a 39 Acurrent (uniform across its cross section). Determine the magnetic field at the surface of the wire. Determine the magnetic field inside the wire 0.50 mm below the surface5. A long cylindrical conductor of radius R carries a current I. The current density is non- uniform, and is a function of the radius according to J = br, where b is a constant. Find an expression for the magnetic field for both rR (i.e. inside and outside the conductor). Assume that R is measured from the center of the conductor.
- An electrically conductive rod is moving through a uniform magnetic flux at a constant velocity at right angles, as shown by its cross-section in the diagram. The velocity is in the x-direction, the rod is of length 150 mm along z, and the magnetic flux density is 0.2 T in the positive y-direction. Speed If the potential difference (voltage) across the ends of the rod is 5.8 Volts, what is the magnitude of the velocity? m/s Not perpendicular If the rod is passing through the flux with its axis not at right angles what can you be sure of? The speed to generate 5.8 V would have to be smaller. • The speed to generate 5.8 V would have to be bigger. The speed to generate 5.8 V would be the same.A very long hollow cylindrical conductor has a current i flowing in it in the direction 2) out of the page. The current density is constant throughout the conductor. The inner radius of this conductor is R1 and the outer radius is R2. a) What is the current density inside the conductor? A Derive the magnetic field (magnitude and direction) R2 b) for radiusr> R2? c) for R1A. What is the current in the current loop? B. What is the current density J in the current loop? C. To decide whether this is a large or a small current density, find the ratio of the current density J in the current loop to the current density of a 8.0 A current in a 1.6- mm diameter wire. Express your answer using two significant figures.SEE MORE QUESTIONS