This course introduces the basic ideas for understanding the dynamics of continuum systems, by studying specific examples from a range of different fields. Our goal will be to explain the general principles, and also to illustrate them via important physical effects. A parallel goal of this course is to give you an introduction to mathematical modeling.

In this activity, students learn about ocean currents and the difference between salt and fresh water. They use colored ice cubes to see how cold and warm water mix and how this mixing causes currents. Also, students learn how surface currents occur due to wind streams. Lastly, they learn how fresh water floats on top of salt water, the difference between water in the ocean and fresh water throughout the planet, and how engineers are involved in the design of ocean water systems for human use.

The People's Physics Book v3 is intended to be used as one small part of a multifaceted strategy to teach physics conceptually and mathematically

Water is thicker than air and thus the dynamics of sound are vastly different in the sea. Join Scripps Institute's Jules Jaffe for a fascinating exploration of sound in the sea, and the amazing ways that science is using sound to probe the mysteries of the deep. (56 minutes0

Ocean Waves not only provide recreation, aesthetic enjoyment and an occasional rearrangement of our shorelines, but can potentially be tapped as a source for cleaner energy. Join Scripps Institution of OceanographyŐs Richard Seymour as he describes how climate variability impacts the "wave climate" of the North Pacific Ocean. Learn how scientists and engineers are combining expertise to harness Waves as a source for renewable electric energy production. (54 minutes)

Join Kendall Melville as he describes his work on Waves that occur both at the surface and in the ocean's interior and learn the profound influence their energy has on oceanographic and climatic processes. (49 minutes)

Continuation of Physics 1. Topics include: simple harmonic motion, gravitation, fluid mechanics, waves, the kinetic theory of gases, and the first and second laws of thermodynamics. This course is a calculus-based physics course that is required by four-year colleges in science and engineering studies.

Vibrations and waves are everywhere. If you take any system and disturb it from a stable equilibrium, the resultant motion will be waves and vibrations. Think of a guitar string—pluck the string, and it vibrates. The sound waves generated make their way to our ears, and we hear the string’s sound. Our eyes see what’s happening because they receive the electromagnetic waves of the light reflected from the guitar string, so that we can recognize the beautiful sinusoidal waves on the string. In fact, without vibrations and waves, we could not recognize the universe around us at all!

The amazing thing is that we can describe many fascinating phenomena arising from very different physical systems with mathematics. This course will provide you with the concepts and mathematical tools necessary to understand and explain a broad range of vibrations and waves. You will learn that waves come from many interconnected (coupled) objects when they are vibrating together. We will discuss many of these phenomena, along with related topics, including mechanical vibrations and waves, sound waves, electromagnetic waves, optics, and gravitational waves.

This is a course for non-science majors that is a survey of the central concepts in physics relating everyday experiences with the principles and laws in physics on a conceptual level. Upon successful completion of this course, students will be able to: Describe basic principles of motion and state the law of inertia; Predict the motion of an object by applying Newtonęs laws when given the mass, a force, the characteristics of motion and a duration of time; Summarize the law of conservation of energy and explain its importance as the fundamental principle of energy as a –law of nature”; Explain the use of the principle of Energy conservation when applied to simple energy transformation systems; Define the Conservation of Energy Law as the 1st Law of Thermodynamics and State 2nd Law of Thermodynamics in 3 ways; Outline the limitations and risks associated with current societal energy practices,and explore options for changes in energy policy for the next century and beyond; Describe physical aspects of waves and wave motion; and explain the production of electromagnetic waves, and distinguish between the different parts of the electromagnetic spectrum.

Developed within Northwest Educational Service District's 2019-20 ClimeTime climate science teacher education proviso grant, this workshop is an opportunity for teachers to gain a better understanding of the physics that drive the climate system and the ocean circulation as well as the implications of a changing climate.

This course is an opportunity for teachers to gain a better understanding of the physics that drive the climate system and the ocean circulation as well as the implications of a changing climate.

The first module encompasses Earth’s radiation balance and the transfer of energy.

The second gives an overview of the ocean circulation, which accomplishes energy (heat) transport. There will be a demo to illustrate the importance of density in the circulation and the vertical structure of the ocean.

The third module discusses the greenhouse effect and global climate change, along with how ocean circulation impacts climate and how a changing climate might impact the ocean circulation.

Lastly, we demo a simple climate model coded in Excel that predicts global mean temperature change.

Explore the properties of quantum "particles" bound in potential wells. See how the wave functions and probability densities that describe them evolve (or don't evolve) over time.

Delve into a microscopic world working with models that show how electron waves can tunnel through certain types of barriers. Learn about the novel devices and apparatuses that have been invented using this concept. Discover how tunneling makes it possible for computers to run faster and for scientists to look more deeply into the microscopic world.

Watch quantum "particles" tunnel through barriers. Explore the properties of the wave functions that describe these particles.

When do photons, electrons, and atoms behave like particles and when do they behave like waves? Watch waves spread out and interfere as they pass through a double slit, then get detected on a screen as tiny dots. Use quantum detectors to explore how measurements change the waves and the patterns they produce on the screen.

The electric field lines from a point charge evolve in time as the charge moves. Watch radiation propagate outward at the speed of light as you wiggle the charge. Stop a moving charge to see bremsstrahlung (braking) radiation. Explore the radiation patterns as the charge moves with sinusoidal, circular, or linear motion. You can move the charge any way you like, as long as you don���������t exceed the speed of light.

Broadcast radio waves from KPhET. Wiggle the transmitter electron manually or have it oscillate automatically. Display the field as a curve or vectors. The strip chart shows the electron positions at the transmitter and at the receiver.

Broadcast radio waves from KPhET. Wiggle the transmitter electron manually or have it oscillate automatically. Display the field as a curve or vectors. The strip chart shows the electron positions at the transmitter and at the receiver.

Learn about the Hubble and Webb telescopes and how their discoveries have changed how we look at the universe.

Teachers, tune in to this special, 50th episode of STEM in 30 to learn all about STEM in real life.

Learn about stealth aircraft and the science behind making a sneaky flying machine.