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0. Math Review31m
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1. Intro to Physics Units1h 29m
2. 1D Motion / Kinematics3h 56m
3. Vectors2h 43m
4. 2D Kinematics1h 42m
5. Projectile Motion3h 6m
6. Intro to Forces (Dynamics)3h 22m
7. Friction, Inclines, Systems2h 44m
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9. Work & Energy1h 59m
10. Conservation of Energy2h 54m
11. Momentum & Impulse3h 40m
12. Rotational Kinematics2h 59m
13. Rotational Inertia & Energy7h 4m
14. Torque & Rotational Dynamics2h 5m
15. Rotational Equilibrium3h 39m
16. Angular Momentum3h 6m
17. Periodic Motion2h 9m
18. Waves & Sound3h 40m
19. Fluid Mechanics4h 27m
20. Heat and Temperature3h 7m
21. Kinetic Theory of Ideal Gases1h 50m
22. The First Law of Thermodynamics1h 26m
23. The Second Law of Thermodynamics3h 11m
24. Electric Force & Field; Gauss' Law3h 42m
25. Electric Potential1h 51m
26. Capacitors & Dielectrics2h 2m
27. Resistors & DC Circuits3h 8m
28. Magnetic Fields and Forces2h 23m
29. Sources of Magnetic Field2h 30m
30. Induction and Inductance3h 38m
31. Alternating Current2h 37m
32. Electromagnetic Waves2h 14m
33. Geometric Optics2h 57m
34. Wave Optics1h 15m
35. Special Relativity2h 10m

35. Special Relativity

Inertial Reference Frames

Physics

35. Special Relativity

Inertial Reference Frames

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8:20 minutes

Problem 27a

Textbook Question

A 2.0-μm-diameter water droplet is moving with a speed of 1.0 μm/s in a 20-μm-long box. Estimate the particle’s quantum number.

Verified step by step guidance

Step 1: Understand the problem. The quantum number of a particle is related to its energy levels and the quantization of its motion. For this problem, we will use the concept of the de Broglie wavelength and the particle-in-a-box model to estimate the quantum number.

Step 2: Calculate the de Broglie wavelength of the water droplet. The de Broglie wavelength is given by \( \lambda = \frac{h}{p} \), where \( h \) is Planck's constant and \( p \) is the momentum of the particle. The momentum \( p \) can be calculated using \( p = mv \), where \( m \) is the mass of the droplet and \( v \) is its velocity.

Step 3: Determine the mass of the water droplet. The mass \( m \) can be estimated using the formula \( m = \rho \cdot V \), where \( \rho \) is the density of water (approximately \( 1000 \; \text{kg/m}^3 \)) and \( V \) is the volume of the droplet. The volume of a spherical droplet is given by \( V = \frac{4}{3} \pi r^3 \), where \( r \) is the radius of the droplet.

Step 4: Relate the de Broglie wavelength to the quantum number. In the particle-in-a-box model, the quantum number \( n \) is related to the length of the box \( L \) and the de Broglie wavelength \( \lambda \) by the equation \( n = \frac{2L}{\lambda} \). Substitute the values of \( L \) (20 μm) and \( \lambda \) into this equation to estimate \( n \).

Step 5: Verify the assumptions and approximations. Ensure that the calculated quantum number is reasonable given the size and speed of the droplet. Discuss how the classical and quantum mechanical descriptions converge for macroscopic objects like water droplets.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Quantum Number

In quantum mechanics, a quantum number is a value that quantizes certain properties of particles, such as energy levels, angular momentum, and position. For a particle in a confined space, like the water droplet in the box, the quantum number can help determine its allowed energy states and behavior. The quantum number is often denoted by 'n' and is integral to understanding the particle's wave function and its spatial distribution.

De Broglie Wavelength

The de Broglie wavelength is a fundamental concept that relates a particle's momentum to its wave-like behavior. It is given by the formula λ = h/p, where λ is the wavelength, h is Planck's constant, and p is the momentum of the particle. For small particles like the water droplet, this wavelength becomes significant in determining the quantum effects that may be observed, especially in confined spaces.

Particle in a Box Model

The particle in a box model is a simplified quantum mechanical model that describes a particle confined to a finite region of space, where it cannot exist outside the boundaries. This model helps in calculating the energy levels and quantum states of the particle. The quantization of energy levels in this model leads to discrete values for the quantum number, which is essential for estimating the behavior of the water droplet in the given scenario.

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