Flying dolphin travels through space and time, exploring different planets and different dimensions. Music video with no narration. Video created by Eugene Khutoryansky
Animation of lights with music composed by Kira Vincent, who narrates the Physics Videos.
Understanding the properties and relationship of electricity to magnetism.
Easy to understand animation explaining all of Einstein's Theory. Covers both Special Relativity and General Relativity.
How to draw 4, 5, 6, and 7 dimensional objects.
Covers topics of wave particle duality (including the double slit), Schrodinger's cat, EPR / Bell inequality, and the relationship between measurement and entanglement. Quantum Mechanics and Quantum Physics.
Easy to understand animation explaining energy, entropy, and all the basic concepts including refrigeration, heat engines, and the end of all life in the Universe.
Flying dolphin travels through space and time, exploring different planets and different dimensions.
Explains variables, systems of equations, Cartesian coordinates, and many other concepts. Fun and educational for all ages.
Easy to understand explanation of integrals and derivatives using 3D animations.
Explains the difference between an Open Universe, Closed Universe, and Flat Universe. Also discusses the expansion of space-time.
Newton’s Laws of Motion, angular precession, coriolis effect, Bernoulli's principle, and Albert Einstein’s General Theory of Relativity.
Maxwell’s Equations, including explanations of induction motors, magnetic materials, electromagnetic waves, and many other topics.
Including the Law of Cosines and angle relationships.
Physics of waves: Covers Quantum Waves, sound waves, and light waves. Easy to understand explanation of refraction, reflection, and many other topics. Important correction: In the section of refraction, the colors are reversed. Violet light slows down in water more than red light, and violet light therefore bends more than red light when it transitions from air to water.
Explains how and why gravity affects the flow of time according to General Relativity.
A more detailed description of the Twin Paradox in Albert Einstein's General Theory of Relativity.
How the Big Bang can be reconciled with the possibility that we live in an infinite Universe.
Discusses why we can't go faster than the speed of light by adding relativistic velocities in Albert Einstein's Theory of Relativity.
How to visualize the derivatives of polynomials.
Does Relativistic Mass actually exist?
Nature of time and simultaneity according to Albert Einstein's Theory of Relativity.
Shows how voltage can be visualized as electric potential energy. Includes topics such as why the voltage is the same everywhere inside a metal conductor.
The Universe from light's point of view.
Visual representation of the product rule for derivatives in Calculus.
Batteries in parallel and in series. 3D visualization of energy, voltage, and the flow of electric current in a circuit.
Introduction to electric circuits and electricity. Includes Kirchhoff's Voltage Law and Kirchhoff's Current Law.
Easy to understand explanation of force vectors.
3D animation explaining why an induction motor rotates
How to make all the logic gates from a field effect transistor, or from other logic gates.
An intuitive understanding of what it means to divide by a fraction.
Includes discussion of the space-time invariant interval and how the axes for time and space transform in Special Relativity.
Quantum physics at its most profound: Delayed Choice Quantum Eraser experiment and its implications.
Covers angular momentum, moment of inertia, torque, center of mass, angular acceleration, and many other topics regarding the physics of rotation.
How the angular momentum vector is affected by torque, and why this results in gyroscopic precession and for the operation of gyroscopes used for navigation.
Why the fact that the entropy of the Universe always increases is a fundamental law of physics.
AC to DC voltage conversions visualized with 3D animations. Includes half wave and full wave rectifiers.
Matrix multiplication and linear algebra explained.
Ohm's Law and how resistors work.
Fourier Series and Fourier Transform with easy to understand 3D animations.
How high voltage ladders create extremely high DC voltages using just diodes and capacitors.
Single slit and double slit interference patterns explained with phasor diagrams.
The Law of Large Numbers and the Central Limit Theorem. Probability explained with easy to understand 3D animations.
Special Relativity's Train in a Tunnel Paradox.
Visualization of the conservation of the momentum and angular momentum of everything in the universe.
How inductors behave in a circuit, and how inductors can generate extremely high voltages by opposing changes to the flow of current.
Visualization explaining imaginary numbers and functions of complex variables. Includes exponentials (Euler’s Formula) and the sine and cosine of complex numbers.
Quantum Entanglement, EPR paradox, Bell Inequality, and the implication for Einstein's Theory of Relativity.
Explaining circularly polarized, linearly polarized, and unpolarized electromagnetic waves.
Visualization of how electric transformers operate.
Rotation of 4D tetrahedrons, tesseracts, and spheres.
Visualization of the Divergence and Curl of a vector field.
From Newton and Maxwell to General Relativity, Quantum Mechanics, Dark Matter, and Dark Energy. The nature of fundamental physical laws.
Covers electromagnetic interference, ground loops, and other topics involving the grounding and shielding of electric circuits.
3D visualization of partial derivatives and gradient vectors.
Nuclear fusion and fission, gamma rays, neutron scattering & capture, alpha & beta decay, binding energy, and many other topics. **Correction: At 13:57, the proton is converting into a neutron.**
Adders, integrators, differentiators, buffers, and a basic introduction to op amp circuits.
Visual explanation of the cross product and the dot product of two vectors.
Superposition, wave function collapse, and uncertainty principle in Quantum Physics. Shows real & imaginary components of quantum wave functions for free particles and confined particles.
Covers lift, stalls, angle of attack, wing flaps, and many other topics.
Quantum tunneling explained with 3D simulations of Schrodinger’s equation for quantum wave functions.
Double integrals in rectangular and polar coordinates. Explained with easy to understand 3D animations.
Quantum Operators for measurements of Energy, Position, and Momentum in Quantum Physics.
Schrodinger's Equation for wave functions in Quantum Physics.
Capacitor physics and circuit operation explained with easy to understand 3D animations.
How to create a neutron generator using a small, linear particle accelerator.
How current & voltage oscillate at resonant frequency for both parallel and series inductor-capacitor combinations.
How physics simulations can predict future probabilities, and applying this to the human brain.
Why frequency of AC voltage affects impedance and current flow through capacitors and inductors.
Entropy and the difference between micro-states and macro-states.
Quantum spin states explained with 3D animations.
Visualization of the voltages and currents for electrical signals along a transmission line.
Visualizing General Relativity.
How entanglement destroys interference, and why all quantum measurements are a form of entanglement.
Mutually Assured Destruction and the Fermi Paradox - Nuclear Deterrence and Nuclear War
3D visualization of eigenvectors and eigenvalues. Includes imaginary and real components.
Introduction to Stability and to State Space. Visualization of why real components of all eigenvalues must be negative for a system to be stable.
Switching Power Converters: Electric Power supplies.
Optics, lenses, and optical illusions created by the refraction of light explained with 3D ray diagrams.
Tensors of rank 1, 2, and 3 visualized with covariant and contravariant components.
General Relativity & curved space time: Visualization of Christoffel symbols, Riemann curvature tensor, and all the terms in Einstein's Field Equations.
Circuit operation of MOSFETs (N channel and P channel) and Bipolar junction transistors (NPN and PNP) explained with 3D animations.
Curved and shattered mirrors. Specular and diffuse reflection.
Relationship between gravity of moving mass and magnetism of moving electric charge in Einstein’s General Relativity: Gravito-Electromagnetism.
Laplace Transform explained and visualized with 3D animations, giving an intuitive understanding of the equations.
James Clerk Maxwell’s idea for violating the Second Law of Thermodynamics. Video also covers reconciling the information theory of entropy with the macro-state / micro-state definition of entropy.
Quantum Chromodynamics (QCD) and the Strong Nuclear Force. Quarks and Gluons explained.
Standard Model, Chirality, Helicity, W & Z bosons, and the Weak Nuclear Force.
Lagrangian Mechanics from Newton to Quantum Field Theory.
Electricity and Three phase power: Voltage and current "Line to Neutral", "Line to Line", and Phasor Diagrams.
Zener diodes, reverse breakdown voltage, and its applications. Includes linear voltage regulators and bidirectional transient voltage suppressors.
The Dirac delta function, the Unit Impulse Response, and Convolution explained intuitively. Also discusses the relationship to the transfer function and the Laplace Transform. Signal Analysis for Linear Systems.
Positively, negatively, and infinitely curved space explained. Covers Ricci scalar (scalar curvature) and Gaussian curvature. Useful for Einstein's General Theory of Relativity.
Straight Lines in Curved Space explained and visualized. Useful for the four dimensional space-time of Einstein’s General Relativity.
The electric field in a uniform charge density throughout an infinite space.
Wave Propagation: Explanation of Group Velocity, Phase Velocity, and Dispersion.
Physics of rolling motion mechanics and the beautiful patterns created.
Economists use exponential functions to model economic growth. The human population is presently growing exponentially. However, any exponential growth that continues indefinitely would eventually expand faster than the speed of light, in direct violation of the known laws of physics.
Bipolar junction transistors and diodes explained with energy band levels and electron/hole densities.
Why do individual atoms exert less pressure if a fluid or gas flows with a higher velocity?
How Archimedes' Principle emerges from the behavior of atoms and molecules.
What can the physics of a double pendulum teach us about life?
Explanation of the various interpretations of Quantum Mechanics.
Beautiful patterns made from the interference of waves.
Intuitive explanation of why capacitors in series produce a smaller capacitance, and why capacitors in parallel produce a larger capacitance.
What would happen if we connected a superconducting short circuit across a voltage source such as a battery?
Physics simulations demonstrating Pascal's Law and the hydraulic lift.
Explains exchange forces between identical particles and the origin of the Pauli Exclusion Principle.
How do forces affect you when you are travelling near the speed of light?
Transfer Functions, Resonance, and Frequency Response.
Breaking the sound barrier in water or air.
Explains why there is no such thing as a centrifugal force.
Node Voltage method for calculating currents and voltages in large electric circuits.
Do gravitational slingshots violate the conservation of energy and momentum?
Why are the Electric and Magnetic fields in phase in an Electromagnetic Wave?
Does gravitational attraction violate the Second Law of Thermodynamics?
Explanation of why the wavefunction for a trapped quantum particle looks different than the wavefunction for a particle moving freely through space.
Explanation of the difference between Real Power, Apparent Power, and Reactive Power.
Heat Capacity explained at the molecular level.
Includes ideas of scientists centuries before the scientific revolution, such as Ibn al-Haytham, as well as the ideas of modern philosophers of science such as Thomas Kuhn and Karl Popper.
Also known as the Dzhanibekov Effect or Tennis Racket Theorem.
Visual demonstration of how osmosis works.
Black Holes and the affect on light and perception of time as gravity affects items that pass the Event Horizon.
Current energy effects on a magnetic field, relative to voltage differences.
The motion of particles when introducing a material to fluids.
Gamma Ray interactions with matter. Includes photofission, photodisintegration, pair production, Compton scattering, and the photoelectric effect.
Entropy and the Maxwell-Boltzmann velocity distribution. Also discusses why this is different than the Bose-Einstein and Fermi-Dirac energy distributions for quantum particles.
Scientific arguments regarding a multiverse.
Race of marbles through various obstacle courses and studying the physics between met expectations and those that are not.
How to convert DC voltage into AC voltage and AC current.
Exponential Decay as a measure of growth.
Why beat frequency is equal to the difference in the frequencies of the two original waves.
Voltage and Current behavior for the following components: 00:00 Introduction 01:47 Batteries 03:30 Transformers 05:30 Resistors 07:09 Diodes 08:22 Transistors 10:00 Logic Gates 11:32 Op Amps 13:00 Capacitors 14:55 Inductors 16:15 Resonance Circuits 17:18 Transmission Lines
Future videos will return to physics, mathematics, and engineering. But, my personal views regarding some of the questions raised at the end of this video are available on my "Objective Morality" website at http://veg1.org/morals.html
Absolute Convergence versus Conditional Convergence
Demolition with dodecahedrons of various masses, trajectories, and velocities.
Is it possible to create an anti-gravity machine?
The real science of time travel. Covers topics such as the Transactional Interpretation of Quantum Mechanics. Also discusses time travel using Albert Einstein’s General Theory of Relativity.
Osmosis and Reverse Osmosis physics simulation
How the idea of a four dimensional block universe is shattered by quantum physics and entanglement.
Unboxing Google Play Button for 1 Million Subscribers
Explains why the area of a circle is exactly equal to π R^2 with easy to understand images.
Surface Tension and Capillary Action simulated using sticky spheres and sticky walls.
Shadows with multi-colored lights in multiple dimensions.
How do objects know to conserve angular momentum?
Torque understood in terms of Newton’s Three Laws of Motion.
How waves behave as they move into a material with a different velocity.
How to make various patterns on a 7x7x7 Rubix cube.
How to make your own 3D animations.
A brief explanation that Physics sometimes gets taught by Arbitrary Social Conventions, when basic physics laws and functions need to be taught and explained first. Uses game of Chess as an example.