Virtual and real labs for introductory physics II, : optics, modern physics, and electromagnetism /
Optics, modern physics, and electromagnetism.
Daniel Erenso.
- 1 online resource (various pagings) : illustrations (some color).
- [IOP release $release] IOP ebooks. [2021 collection] .
- IOP (Series). Release 21. IOP ebooks. 2021 collection. .
"Version: 202111"--Title page verso.
Includes bibliographical references.
4. Diffraction and gratings -- 4.1. Basic theory -- 4.2. Virtual lab I : two slits -- 4.3. Virtual lab II : circular aperture -- 4.4. Real lab : diffraction grating and circular aperture 5. Blackbody radiation -- 5.1. Basic theory -- 5.2. Virtual lab : blackbody radiation 6. The photoelectric effect -- 6.1. Basic theory -- 6.2. Virtual lab : photoelectric effect 7. Introduction to atomic physics -- 7.1. Basic theory -- 7.2. Virtual lab : the hydrogen atom -- 7.3. Real lab : spectroscopy 8. Introduction to nuclear physics -- 8.1. Basic theory -- 8.2. Virtual lab : beta decay -- 8.3. Real lab : radioactivity and half-life time 9. Introduction to electronics -- 9.1. Basic theory -- 9.2. Virtual lab I : Coulomb's law -- 9.3. Virtual lab II : conductors and insulators -- 9.4. Real lab : conductors and insulators 10. Resistors and Ohm's law -- 10.1. Basic theory -- 10.2. Virtual lab : Ohm's law -- 10.3. Real lab : Ohm's law 11. Constant current circuit -- 11.1. Basic theory -- 11.2. Virtual lab I : resistors in series and parallel -- 11.3. Virtual lab II : mixed circuits and Kirchhoff's laws -- 11.4. Real lab I : resistors in series and parallel -- 11.5. Real lab II : mixed circuits and Kirchhoff's laws 12. Capacitor and RC circuits -- 12.1. Basic theory -- 12.2. Virtual lab : capacitors and RC circuits -- 12.3. Real lab : capacitors and RC circuits 13. Oscilloscope and fast time constant -- 13.1. Basic theory -- 13.2. Virtual lab I : function generator and voltage chart -- 13.3. Virtual lab II : fast capacitive time constant -- 13.4. Real lab I : introduction to oscilloscope -- 13.5. Real lab II : fast capacitive time constant RC circuit 14. The magnetic field -- 14.1. Basic theory -- 14.2. Virtual lab : magnetic field -- 14.3. Real lab : magnetic field 15. Faraday's law -- 15.1. Basic theory -- 15.2. Virtual lab : Faraday's law -- 15.3. Real lab : Faraday's law 16. Induction and RL circuits -- 16.1. Basic theory -- 16.2. Virtual lab : RL circuit -- 16.3. Real lab : RL circuits 17. Introduction to AC circuits -- 17.1. Basic theory -- 17.2. Virtual lab : AC circuits and impedance -- 17.3. Real lab : AC circuits and impedance 18. AC filters and resonance -- 18.1. Basic theory -- 18.2. Virtual lab I : AC filters -- 18.3. Virtual lab II : RLC circuit and resonance -- 18.4. Real lab I : AC filters -- 18.5. Real lab II : resonance 19. Introduction to digital electronics -- 19.1. Basic theory -- 19.2. Real lab A : integrated-circuit chips -- 19.3. Real lab B : digital circuit design. 1. Reflection and refraction of light -- 1.1. Basic theory -- 1.2. Virtual lab : reflection and refraction -- 1.3. Real lab : reflection and refraction 2. Thin lenses -- 2.1. Basic theory -- 2.2. Virtual lab A : converging lens -- 2.3. Virtual lab B : converging -- 2.4. Real lab : thin lens equation 3. Human eye and corrective lenses -- 3.1. Basic theory -- 3.2. Real lab : corrective lenses
Virtual and Real Labs for Introductory Physics II: Optics, modern physics, and electromagnetism provides the lab component for Introductory Physics II taught in a remote, on-ground, or a hybrid environment with little or no instructor guidance. The book offers the opportunity to realize these purposes by providing virtual and real lab components.
Introductory physics courses whether Algebra or Calculus based are core courses for science, engineering, pre-medicine, and pre-pharmacy students in all educational institutions across the world. Therefore, the primary market for this book are students taking these courses if instructors chose to adapt this book in their curriculum.
Mode of access: World Wide Web. System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
Daniel Erenso has been a professor of physics at Middle Tennessee State University (MTSU) since 2003. Interested in both theoretical and experimental physics research, he has extended his research at MTSU to experimental biophysics and quantum optics/quantum information. He has published more than 35 and presented over 60 research works, received more than 15 recognitions/honors/awards including the MTSU, College of Basic & Applied Sciences Distinguished Research Award (2016), the Fulbright Scholar Award (2016), the MTSU, College of Basic & Applied Sciences Excellence in Teaching award (2011), Sigma Xi the Scientific Research Society Aubrey E Harvey Outstanding Graduate Research Award UA (2003), the International Center for Scientific Culture (ICSC) World Laboratory Scholarship Award (2001), and The Abdus Salam International Centre for Theoretical Physics (ICTP).