Virtual and Real Labs for Introductory Physics II : Optics, Modern Physics, and Electromagnetism / Daniel Erenso.

Format:

Book

Author/Creator:

Erenso, Daniel, author.

Series:

IOP Ebooks Series

Language:

English

Subjects (All):

Physics.

Physical Description:

1 online resource (384 pages)

Edition:

First edition.

Place of Publication:

Bristol, England : IOP Publishing, [2021]

Summary:

This book serves as a textbook for the laboratory component to algebra-based and calculus-based Introductory Physics II. It provides virtual (simulation) lab replicating (in most cases) the real labs in optics, electricity, magnetism, and modern physics at the introductory level.

Contents:

Intro

Preface

Outline placeholder

Optics

Electricity and magnetism

PASCO's basic optics system

Essential physics modular circuits kit

Acknowledgements

Author biography

Daniel Erenso

Chapter 1 Reflection and refraction of light

1.1 Basic theory

1.2 Virtual lab: reflection and refraction

1.2.1 Introduction

1.2.2 Part I: Law of reflection

1.2.3 Part II: Snell's law (law of refraction)

1.2.4 Part II: Total internal reflection (TIR)

1.2.5 Result and conclusion

1.3 Real lab: reflection and refraction

1.3.1 Objectives

1.3.2 Supplies

1.3.3 Part 1: Reflection

1.3.4 Part II: Law of refraction and TIR

1.3.5 Result and conclusion

Chapter 2 Thin lenses

2.1 Basic theory

Lens image description

2.2 Virtual lab A: converging lens

2.2.1 Introduction

2.2.2 Part I: an object and a thin lens

2.2.3 Part II: questions

2.2.4 Result and conclusion

2.3 Virtual lab B: converging

2.3.1 Introduction

2.3.2 Part I: an object and a converging lens

2.3.3 Result and conclusion

2.4 Real lab: thin lens equation

2.4.1 Objectives

2.4.2 Supplies

2.4.3 Procedure

2.4.4 Data analyses

2.4.5 Result and conclusion

Chapter 3 Human eye and corrective lenses

3.1 Basic theory

3.2 Real lab: corrective lenses

3.2.1 Objectives

3.2.2 Supplies

3.2.3 Procedure

3.2.4 Data analyses

3.2.5 Result and conclusion

Chapter 4 Diffraction and gratings

4.1 Basic theory

4.2 Virtual lab I: two slits

4.2.1 Introduction

4.2.2 Part I: fringe vs slits separation

4.2.3 Part II: fringe spacing vs screen distance

4.2.4 Result and conclusion

4.3 Virtual lab II: circular aperture

4.3.1 Introduction

4.3.2 Finding the distance of the screen, L

4.3.3 Result and conclusion

4.4 Real lab: diffraction grating and circular aperture.

4.4.1 Objectives

4.4.2 Supplies

4.4.3 Procedure

4.4.4 Result and conclusion

Chapter 5 Blackbody radiation

5.1 Basic theory

5.2 Virtual lab: blackbody radiation

5.2.1 Introduction

5.2.2 Part I: blackbody spectrum

5.2.3 Part II: Wien's constant

5.2.4 Part III: Stefan-Boltzmann constant

5.2.5 Result and conclusion

Chapter 6 The photoelectric effect

6.1 Basic theory

6.2 Virtual lab: photoelectric effect

6.2.1 Introduction

6.2.2 Part I: photoelectric effect in sodium

6.2.3 Part II: cut-off wavelength from photoelectrons KE

6.2.4 Result and conclusion

Chapter 7 Introduction to atomic physics

7.1 Basic theory

7.2 Virtual lab: the hydrogen atom

7.2.1 Introduction

7.2.2 Part I: white light

7.2.3 Part II: monochromatic light

7.2.4 Result and conclusion

7.3 Real lab: spectroscopy

7.3.1 Objective

7.3.2 Supplies

7.3.3 Procedure

7.3.4 Part I: the visible blackbody spectrum

7.3.5 Part II: emission spectra

7.3.6 Result and conclusion

Chapter 8 Introduction to nuclear physics

8.1 Basic theory

8.2 Virtual lab: beta decay

8.2.1 Introduction

8.2.2 Part I: single atom beta decay

8.2.3 Part II: half-life time and decay constant

8.2.4 Result and conclusion

8.3 Real lab: radioactivity and half-life time

8.3.1 Objectives

8.3.2 Supplies

8.3.3 Procedure

8.3.4 Data analyses

8.3.5 Result and conclusion

Chapter 9 Introduction to electronics

9.1 Basic theory

9.2 Virtual lab I: Coulomb's law

9.2.1 Introduction

9.2.2 Part I: electrical force vs charge

9.2.3 Part I: electrical force vs distance

9.2.4 Result and conclusion

9.3 Virtual lab II: conductors and insulators

9.3.1 Introduction

9.3.2 Part I: conductors and insulators

9.3.3 Part II: dc electrical circuit

9.3.4 Result and conclusion.

9.4 Real lab: conductors and insulators

9.4.1 Objectives

9.4.2 Supplies

9.4.3 Part I: using the multimeter to measure resistance

9.4.4 Part II: mapping the breadboard

9.4.5 Part III: use the breadboard to build a circuit

9.4.6 Result and conclusion

Chapter 10 Resistors and Ohm's law

10.1 Basic theory

10.2 Virtual lab: Ohm's law

10.2.1 Introduction

10.2.2 Ohm's law

10.2.3 Result and conclusion

10.3 Real lab: Ohm's law

10.3.1 Objectives

10.3.2 Supplies

10.3.3 Part I: measuring resistance

10.3.4 Part II: measuring voltage

10.3.5 Part III: measuring current

10.3.6 Result and conclusion

Chapter 11 Constant current circuit

11.1 Basic theory

11.2 Virtual lab I: resistors in series and parallel

11.2.1 Introduction

11.2.2 Part I: resistors in series

11.2.3 Part II: resistors in parallel

11.2.4 Result and conclusion

11.3 Virtual lab II: mixed circuits and Kirchhoff's laws

11.3.1 Introduction

11.3.2 Mixed circuit

11.3.3 Result and conclusion

11.4 Real lab I: resistors in series and parallel

11.4.1 Objectives

11.4.2 Supplies

11.4.3 Part I: resistors in series

11.4.4 Part II: resistors in parallel

11.4.5 Result and conclusion

11.5 Real lab II: mixed circuits and Kirchhoff's laws

11.5.1 Objectives

11.5.2 Supplies

11.5.3 Mixed circuit

11.5.4 Result and conclusion

Chapter 12 Capacitor and RC circuits

12.1 Basic theory

12.2 Virtual lab: capacitors and RC circuits

12.2.1 Introduction

12.2.2 Part I: constructing an RC circuit with switches

12.2.3 Part II: analyzing the results

12.2.4 Result and conclusion

12.3 Real lab: capacitors and RC circuits

12.3.1 Objectives

12.3.2 Supplies

12.3.3 Part I: assembling a circuit with a switch

12.3.4 Part II: the voltage across the capacitor.

12.3.5 Part III: analyzing the results

12.3.6 Result and conclusion

Chapter 13 Oscilloscope and fast time constant

13.1 Basic theory

Oscilloscope

13.2 Virtual lab I: function generator and voltage chart

13.2.1 Introduction

13.2.2 Part I: voltmeter vs voltage chart (oscilloscope)

13.2.3 Part II: A square, TTL, and sinusoidal voltage signals

13.2.4 Result and conclusion

13.3 Virtual lab II: fast capacitive time constant

13.3.1 Introduction

13.3.2 Part I: Charging the capacitor

13.3.3 Part II: Discharging the capacitor

13.3.4 Result and conclusion

13.4 Real lab I: introduction to oscilloscope

13.4.1 Objectives

13.4.2 Supplies

13.4.3 The very basic elements of the oscilloscope

13.4.4 Our first oscilloscope trace!

13.4.5 A fancier trace and time measurements

13.5 Real lab II: fast capacitive time constant RC circuit

13.5.1 Objectives

13.5.2 Supplies

13.5.3 Fast capacitive time constant RC circuit

13.5.4 Result and conclusion

Chapter 14 The magnetic field

14.1 Basic theory

14.2 Virtual lab: magnetic field

14.2.1 Introduction

14.2.2 Part I: a bar magnet

14.2.3 Part II: Earth's magnetic field

14.2.4 Result and conclusion

14.3 Real lab: magnetic field

14.3.1 Objectives

14.3.2 Supplies

14.3.3 Identifying the poles of a compass

14.3.4 Mapping the magnetic field of a current in a long straight wire

14.3.5 Mapping the magnetic field of a current in a solenoid

14.3.6 Ferromagnetism and the electromagnet

14.3.7 Result and conclusion

Chapter 15 Faraday's law

15.1 Basic theory

15.1.1 Motional electromotive force

15.1.2 Magnetic flux, Faraday's law and Lenz's law

15.2 Virtual lab: Faraday's law

15.2.1 Introduction

15.2.2 Part I: a bar magnet-north pole

15.2.3 Part II: a bar magnet-south pole

15.2.4 Result and conclusion.

15.3 Real lab: Faraday's law

15.3.1 Objective

15.3.2 Supplies

15.3.3 Procedure

15.3.4 Current flow in a solenoid and magnetic poles

15.3.5 Inducing voltage (current) by a magnet-north pole

15.3.6 Data analyses (for the north pole)

15.3.7 Data analyses (for the south pole)

15.3.8 Result and conclusion

Chapter 16 Induction and RL circuits

16.1 Basic theory

16.2 Virtual lab: RL circuit

16.2.1 Introduction

16.2.2 Part I: 'charging' an inductor

16.2.3 Part II: 'discharging' the inductor

16.2.4 Result and conclusion

16.3 Real lab: RL circuits

16.3.1 Objective

16.3.2 Supplies

16.3.3 Building the RL circuit

16.3.4 Analyzing the voltage across an inductor

16.3.5 Result and conclusion

Chapter 17 Introduction to ac circuits

17.1 Basic theory

17.2 Virtual lab: ac circuits and impedance

17.2.1 Introduction

17.2.2 Part I: ac circuit with a capacitor

17.2.3 Part II: ac circuit with an inductor

17.2.4 Part II: ac circuit with a resistor

17.2.5 Result and conclusion

17.3 Real lab: ac circuits and impedance

17.3.1 Objectives

17.3.2 Supplies

17.3.3 AC circuit with a resistor

17.3.4 AC circuit with a capacitor

17.3.5 AC circuit with an inductor

17.3.6 Result and conclusion

Chapter 18 AC filters and resonance

18.1 Basic theory

18.2 Virtual lab I: ac filters

18.2.1 Introduction

18.2.2 Part I: high-pass filter

18.2.3 Part II: low-pass filter

18.2.4 Result and conclusion

18.3 Virtual lab II: RLC circuit and resonance

18.3.1 Introduction

18.3.2 RLC circuit

18.3.3 The resonance gain curve

18.3.4 Result and conclusion

18.4 Real lab I: ac filters

18.4.1 Objectives

18.4.2 Supplies

18.4.3 The transition frequency

18.4.4 High-pass and low-pass filters

18.4.5 Filtering music

18.4.6 Result and conclusion.

18.5 Real lab II: resonance.

Notes:

Description based on publisher supplied metadata and other sources.

Description based on print version record.

ISBN:

9780750345286

0750345284

OCLC:

1429722726