loop of copper passes through regions of the magnetic field with a constant velocity, as indicated in Figure 2. (a) Determine the direction of the current (if any) induced in the copper loop at each point, 1 through 5, along its path. Assume the field is uniform and of constant magnitude inside the dashed boundary and zero outside. (b) Rank the currents according to their magnitude from greatest to least for points 1 through 5. Indicate ties, if any.
Q: Problem 4: A conducting rod spans a gap of length L = 0.179 m and acts as the fourth side of a…
A: aϕ = BxL b a = At2dVdt = At2 ⇒dV = At2dtIntegrate both sides,∫dV = ∫At2 dtV = At33
Q: Questions 3-5 all refer to Figure 1 attached. A loop of wire sits in a uniform magnetic field,…
A:
Q: A specific configuration with the direction of the current through a very long wire, either in or…
A: Detailed solution is given below Explanation:
Q: According to the figure, a uniform bar of length L carries a current I in the direction from point…
A: Given, A current carrying bar is in magnetic field
Q: The figure below shows a rectangular coil of length and width w consisting of N turns of conducting…
A: The magnetic flux is ϕ=BA where B is the magnetic flux and A is the area of the coil. The area of…
Q: to the faces of the loops is out of the screen (towards you) and assume the positive vertical…
A:
Q: A circular coil of copper wire is lying flat on a horizontal table. A bar magnet is held with its…
A:
Q: In the drawing below a wire is looped as shown -- note that the wire crosses over top of itself with…
A: Given data: Resistance R = 4 ohms side of upper loop lU =16 cm side of lower loop ll=lU2 Magnetic…
Q: A square loop of wire with edge length a sits in a uniform magnetic field as shown in figure 2,…
A: Given : Magnetic field, B = Boe-λt2 Side of the square loop = a Resistance of the loop = R
Q: (a) Calculate the magnetic flux (g) through the flat surface S₁. (Use any variable or symbol stated…
A:
Q: In each of the figures below, a uniform magnetic field B points in the +x-direction. The magnitude…
A: given B = 2.25T A = 0.3252 m2 A = 0.1056 m2 to claculate- magnetic flux
Q: What is the magnetic flux (in Wb) through the loop in each of the three cases shown? (a)…
A: magnetic field line passing through a closed area known as flux Flux = B. A. Cosθ θ = angle…
Q: A single loop of nickel wire, lying flat in a plane, has an area of 7.00 cm2 and a resistance of…
A:
Q: A current I is passed through a wire. A second wire of length L is moving perpendicular to the…
A: b. Use the expression for the magnetic field of a current-carrying wire. This is essential. The…
Q: 45° Loop 1 r= 1 Loop 2 r= 1 Loop 3 r= 2 Loop 4 r= 2 The figure shows four circular loops in a…
A: Given, Four loop with different radius in magnetic field
Q: Shown in the figure below is a rectangle of wire immersed in a magnetic field. The rectangle has…
A: Given :l=2 mw=2 mR=7.02 ohmB(t)=5t3+2t4
Q: There is a constant magnetic field directed into the page in the shaded region. The field is zero…
A:
Q: a long rectangular conducting loop, of width L, resistance R, and mass m, is hung in a horizontal,…
A: The figure below shows the given situation. The magnetic field is perpendicular into the page above…
Q: conducting bar of length 0.2 m and mass 11 g is suspended by a pair of flexible leads in a uniform…
A:
Q: First Question
A: We are given magnetic field as function of time and position. We first find the total flux through…
Q: Refer to diagram 3. A closed circular loop (N = 555 turns, radius r= 5.54 cm, resistance R = 6.32 2)…
A: From figure we can see the magnetic field is directed downward and from the given equation for…
Q: (X) (X) W X (X) Bin Bin A uniform magnetic field points from the S to N and has a magnitude of 0.02…
A:
Q: Refer to diagram 3. A closed circular loop (N = 8,666 turns, radius r, resistance R = 4.19 Q) sits…
A: When a coil carrying current is placed in either a varying magnetic field or the coil itself is…
Q: The figure below shows a top view of a bar that can slide on two frictionless rails. The resistor is…
A: Given,
Q: A cube of edge length ℓ = 2.00 cm is positioned as shown in the figure below. A uniform magnetic…
A:
Q: As shown in the figure below, you exert a constant force F to the right on a conducting rod of…
A: a) Write the expression for the induced emf and substitute the corresponding values.…
Q: Use Ampere's Law to determine the resultant magnetic field due to the four different wires at the…
A:
Q: Is the current in the wire from A to B or B to A?
A: Given: length of the conductor = l mass of the conductor = m resistance of the conductor = R…
Q: A rectangular conducting loop has sides a = 0.065 m, sides b = 0.15 m, and resistance R = 55 Ω. It…
A:
Q: Consider the magnetic field on the axis of a circular circuit in which a current I flows. Find the…
A: The integrated magnetic field surrounding a closed loop is proportional to the electric current…
Q: The diagram below depicts a rectangular wire loop of width a = 17.5 cm and height b = 7.95 cm, that…
A:
Q: A conductive rectangular loop is being pulled at constant speed v out of a region of uniform…
A:
Q: A loop with resistance 2.0 \OmegaΩ is oriented as shown below inside a region of uniform and…
A: Concept This is the application of Faraday’s law of the electromagnetic induction. According to this…
Q: Consider the following:A uniform magnetic field B= -0.033TK is present in a region of space, as…
A: The total force on charged particle of charge q in a electric and magnetic field moving with a…
Q: cm (see figure below). The larger loop, which initially carries a current I = 8.8 A, is cut and its…
A: We know that the formula of the magnetic field is B = μ0I2r where I is a current r is the radius…
A loop of copper passes through regions of the magnetic field with a constant velocity, as indicated in Figure 2.
(a) Determine the direction of the current (if any) induced in the copper loop at each point, 1 through 5, along its path. Assume the field is uniform and of constant magnitude inside the dashed boundary and zero outside.
(b) Rank the currents according to their magnitude from greatest to least for points 1 through 5. Indicate ties, if any.
Step by step
Solved in 2 steps
- Question in the attachmentsIn each of the figures below, a uniform magnetic field B points in the +x-direction. The magnitude of the field is 1.75 T. In each figure, a square loop, shown edge-on, with sides of length = 0.380 m, is oriented within the magnetic field as shown. In the left figure, the loop is oriented vertically, perpendicular to the magnetic field. In the middle figure, it is tilted such that the plane of the loop makes a 60.0° angle with the magnetic field. In the right figure, the loop is oriented horizontally, parallel to the magnetic field. y (b) 60.0° from the magnetic field Wb B What is the magnetic flux (in Wb) through the loop in each of the three cases shown? (a) perpendicular to the magnetic field Wb (c) parallel to the magnetic field Wb B 60.0°What is the magnitude of the magnetic flux (Pinitial) through the coil before it is rotated? Express your answer numerically, in webers, to at least three significant figures. In a physics laboratory experiment, a coil with 250 turns enclosing an area of 13.1 cm? is rotated during the time interval 3.80x10-2 s from a position in which its plane is perpendicular to Earth's magnetic field to one in which its plane is parallel to the field. The magnitude of Earth's magnetic field at the lab location is 6.00x10-5 T. • View Available Hint(s) V ΑΣφ ? |Pinitial| = Wb Submit Part B What is the magnitude of the magnetic flux Pfinal through the coil after it is rotated? Express your answer numerically, in webers, to at least three significant figures. • View Available Hint(s) ΑΣφ |Pfinal| = Wb 圓
- Please don't provide handwritten solution .....A battery is connected to wires that hand vertically (gravity acts down in the diagram). Hooks at the ends of the wires hold a horizontal copper bar (the thick bar) of mass 0.6 kg and length 0.5 meters. Another apparatus (not shown) can create a uniform magnetic field in the region of space given by the dashed rectangle. The total resistance of the circuit is 1.20 Ohms and the battery supplies 24 Volts. The magnetic field can be adjusted in strength until the bar lifts off of the hooks and levitates magnetically – not moving just above the hooks as shown. a) Determine the necessary direction of the magnetic field in the dashed rectangle. b) Calculate the required magnitude of the magnetic field.Please asap
- 17. A U-shaped wire is bridged by a small metal rod AB of length I, and the distance of the rod from the left end of wire is a at initial moment t=0 as indicated in the right figure. A uniform magnetic field is directed into of page. Now move the rod at constant velocity y to the right as indicated.(a) Calculate the magnetic flux through the loop formed by the wire and rod at any instant t. (b) Find the emf induced in the loop as the rod is moving. (c) Indicate the direction of the current induced in the loop. O wire 8 Al -rod t30In each of the figures below, a uniform magnetic field B points in the +x-direction. The magnitude of the field is 1.50 T. In each figure, a square loop, shown edge-on, with sides of length l = 0.255 m, is oriented within the magnetic field as shown. In the left figure, the loop is oriented vertically, perpendicular to the magnetic field. In the middle figure, it is tilted such that the plane of the loop makes a 60.0° angle with the magnetic field. In the right figure, the loop is oriented horizontally, parallel to the magnetic field. y 60.0° What is the magnetic flux (in Wb) through the loop in each of the three cases shown? (a) perpendicular to the magnetic field Wb (b) 60.0° from the magnetic field Wb (c) parallel to the magnetic field WbIn each of the figures below, a uniform magnetic field B points in the +x-direction. The magnitude of the field is 3.00 T. In each figure, a square loop, shown edge-on, with sides of length { = 0.380 m, is oriented within the magnetic field as shown. In the left figure, the loop is oriented vertically, perpendicular to the magnetic field. In the middle figure, it is tilted such that the plane of the loop makes a 60.0° angle with the magnetic field. In the right figure, the loop is oriented horizontally, parallel to the magnetic field. 60.0 What is the magnetic flux (in Wb) through the loop in each of the three cases shown? (a) perpendicular to the magnetic field Wb (b) 60.0° from the magnetic field Wb (c) parallel to the magnetic field Wb
- The figure below shows a top view of a bar that can slide on two frictionless rails. The resistor is R = 5.60 0, and a 2.50-T magnetic field is directed perpendicularly downward, into the page. Let { = 1.20 m. Bin R app (a) Calculate the applied force required to move the bar to the right at a constant speed of 2.30 m/s. N (to the right) (b) At what rate is energy delivered to the resistor? WA current I is passed through a wire. A second wire of length L is moving perpendicular to the magnetic field generated by the first wire (see sketch below) with velocity v at a distance d. Write down the expression for the potential difference V between the ends of the moving wire. Consider the magnetic field B to be constant over the range of motion of the second wire (i.e. d » 1). Use μ for the vacuum permittivity. Please use appropriate algebraic symbols for multiplication (* for a × b), division (/ for a/b), exponents (a^b for a³), square root (sqrt(a*b/c) for √a× b/c) etc. For Greek letters use their names e.g. "theta", "alpha", "pi", "mu" (without the quotes) and for trigonometric functions use "cos", "tan", "sin" (without the quotes). Thus for Acose use A*cos theta. Please use the "Display response" button to check you entered the answer you expect. Wire 1 Wire 2 d VIn this problem, you will use Lenz's law to explore what happens when an electromagnet is activated a short distance from a wire loop. You will need to use the right-hand rule to find the direction of the induced current. Figure < 1 of 1 Switch open E Iron core 0