Textbook Question
What is the capacitance of the two metal spheres shown in FIGURE EX26.22?
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Ch 26: Potential and Field
Knight Calc5th EditionPhysics for Scientists and EngineersISBN: 9780137344796
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Table of contents
- Ch 01: Concepts of Motion35
- Ch 02: Kinematics in One Dimension75
- Ch 03: Vectors and Coordinate Systems58
- Ch 04: Kinematics in Two Dimensions60
- Ch 05: Force and Motion23
- Ch 06: Dynamics I: Motion Along a Line53
- Ch 07: Newton's Third Law27
- Ch 08: Dynamics II: Motion in a Plane52
- Ch 09: Work and Kinetic Energy56
- Ch 10: Interactions and Potential Energy50
- Ch 11: Impulse and Momentum56
- Ch 12: Rotation of a Rigid Body71
- Ch 13: Newton's Theory of Gravity52
- Ch 14: Fluids and Elasticity44
- Ch 15: Oscillations55
- Ch 16: Traveling Waves37
- Ch 17: Superposition39
- Ch 18: A Macroscopic Description of Matter53
- Ch 19: Work, Heat, and the First Law of Thermodynamics60
- Ch 20: The Micro/Macro Connection53
- Ch 21: Heat Engines and Refrigerators34
- Ch 22: Electric Charges and Forces40
- Ch 23: The Electric Field39
- Ch 24: Gauss' Law32
- Ch 25: The Electric Potential63
- Ch 26: Potential and Field57
- Ch 27: Current and Resistance42
- Ch 28: Fundamentals of Circuits39
- Ch 29: The Magnetic Field47
- Ch 30: Electromagnetic Induction60
- Ch 31: Electromagnetic Fields and Waves32
- Ch 32: AC Circuits63
- Ch 33: Wave Optics32
- Ch 34: Ray Optics57
- Ch 35: Optical Instruments30
- Ch 36: Special Relativity38
- Ch 37: The Foundations of Modern Physics25
- Ch 38: Quantization49
- Ch 39: Wave Functions and Uncertainty31
- Ch 40: One-Dimensional Quantum Mechanics35
- Ch 41: Atomic Physics18
- Ch 42: Nuclear Physics27
Knight Calc5th EditionPhysics for Scientists and EngineersISBN: 9780137344796Not the one you use?Change textbook
Chapter 26, Problem 19
Light from the sun allows a solar cell to move electrons from the positive to the negative terminal, doing 2.4×10−19 J of work per electron. What is the emf of this solar cell?
Verified step by step guidance1
Understand the problem: The work done per electron by the solar cell is given as 2.4×10^−19 J. The emf (electromotive force) of the solar cell is the energy provided per unit charge, which is equivalent to the work done per electron in this case. The relationship between work, charge, and emf is given by the formula: , where W is the work, q is the charge, and V is the emf.
Identify the known values: The work done per electron is J, and the charge of an electron is C.
Rearrange the formula to solve for emf (V): . This equation shows that the emf is the work done per electron divided by the charge of the electron.
Substitute the known values into the formula: . Perform the division to find the emf.
Interpret the result: The calculated emf represents the energy provided by the solar cell per unit charge (per electron). This value is typically expressed in volts (V).
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Electromotive Force (emf)
Electromotive force (emf) is the energy provided by a source of electrical energy per unit charge. It is measured in volts and represents the potential difference that drives the flow of electrons in a circuit. In the context of a solar cell, the emf indicates how much energy is available to move electrons from the positive to the negative terminal.
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Work Done on Electrons
The work done on electrons refers to the energy transferred to each electron as it moves through an electric field. In this case, the solar cell does 2.4×10^−19 joules of work per electron, which is the energy gained by each electron as it is excited by sunlight. This work is directly related to the emf of the solar cell, as it quantifies the energy available for electrical work.
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Charge of an Electron
The charge of an electron is a fundamental physical constant, approximately equal to -1.6×10^−19 coulombs. This value is crucial for calculating the emf of the solar cell, as it relates the work done on each electron to the potential difference. By knowing the work done per electron and the charge, one can determine the emf using the formula: emf = work done per charge.
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Related Practice
Textbook Question
Two 3.0-cm-diameter aluminum electrodes are spaced 0.50 mm apart. The electrodes are connected to a 100 V battery. What is the capacitance?
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Textbook Question
What is the potential difference ΔV34 in FIGURE EX26.14?
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Textbook Question
Two 3.0-cm-diameter aluminum electrodes are spaced 0.50 mm apart. The electrodes are connected to a 100 V battery. What is the magnitude of the charge on each electrode?
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Textbook Question
The electric potential along the x-axis is V = 100x2 V, where x is in meters. What is Ex at (a) x=0 m and (b) x=1 m?
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Textbook Question
How much charge does a 9.0 V battery transfer from the negative to the positive terminal while doing 27 J of work?
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