The special relativity lectures have been divided into 14 modules, listed below, each with a title and a brief description of its content. It is recommended that these be viewed in the order listed, as each module builds on concepts introduced in previous modules. Clicking on the titles below will reveal an active link to the recorded lecture segment that includes a list of key learning outcomes.

SR-1	Spacetime Diagrams An introduction to spacetime diagrams – a first step towards understanding Einstein’s special theory of relativity.		SR-8	Applications of Minkowskian Geometry Learning to use Minkowskian geometry to understand, very simply, a variety of aspects of Einstein’s spacetime. to understand a variety of Discovering how a light particle experience space and time during its journey from one place to another.
SR-2	Spacetime Diagrams for Sound Travelling in Air Drawing spacetime diagrams of simple thought experiments involving sound in air as a warm up exercise for light in vacuum.		SR-9	Synchronization of Clocks A discussion of how to synchronize clocks that are separated in space, and how this leads to the relativity of simultaneity.
SR-3	The Doppler Shift for Sound Continuation of a thought experiment from SR-2 leading up to a derivation of the familiar Doppler shift for sound in air.		SR-10	Coordinate Axes and Length Contraction A discussion of the space and time axes of a moving observer and an introduction to length contraction.
SR-4	Einstein’s Speed of Light Principle (“Principle 2”) Repeating the experiment from SR-3 using light rather than sound, and understanding what Einstein assumed regarding the speed of light.		SR-11	Simultaneity and Length Contraction A continuation of the SR-10 discussion on length contraction.  Resolving Principle 2*.
SR-5	Einstein’s Relativity Principle (“Principle 1”) Einstein’s Relativity Principle applies to both mechanical and electromagnetic phenomena.		SR-12	Einstein’s Rotating Disk Thought Experiment Introduction to Einstein’s famous rotating disk thought experiment, which he used to help him understand the true nature of gravity.
SR-6	Doppler Shift for Light Deriving the Doppler shift for light, from which all of special relativity follows.		SR-13	Artificial Gravity Provides Hints about Real Gravity Analyzing the artificial gravitational field inside a rotating cylinder to discover hints about the nature of real gravitational fields.
SR-7	Minkoskian Geometry Space obeys the rules of Euclidean geometry.  Spacetime obeys the rules of a new kind of geometry called Minkoskian geometry.		SR-14	The Curved Geometry of a Rotating Space The spacetime diagram of a rotating Bob is analyzed, leading us to conclude that his spatial geometry is curved.

 

Most introductions to special relativity misstate what Einstein said in his 1905 paper, obscuring the beauty of the theory and making facts like time dilation and length contraction seem mysterious and hard to believe. By carefully stating the two principles Einstein started with, and working through their logical consequences with simple "spacetime diagrams," we come to see time dilation and length contraction as natural and easy to believe - indeed it would be an odd universe were these to not occur! Moreover, by considering accelerated observers we follow one of Einstein's amazing thought experiments that helped lead him to the idea that gravity might have something to do with "warped" space and time, creating a springboard to his general theory of relativity. As with the quantum mechanics lectures, the focus is on the ideas: gaining substantial insights into the fascinating physics involved, with as little mathematics as possible.

Richard Epp has a Masters degree in electrical engineering and a PhD degree in theoretical physics from the University of Manitoba, Canada, and has held postdoctoral research positions around the world working in general relativity: Einstein's theory of space, time and gravity. With both an engineering and a theoretical physics background, Dr. Epp is knowledgeable and enthusiastic about the entire spectrum of physics, from curiosity-driven research in quantum gravity to the applied physics of how a cell phone works. He has extensive outreach experience, having originated many of PI's outreach initiatives - including the ISSYP - and immensely enjoys introducing people of all ages to the mysteries and wonders of our amazing universe.