Flipping Physics
Solenoid Magnetic Field
Good morning, physics enthusiasts! Today on Flipping Physics, we're delving into the fascinating realm of ideal solenoids, those remarkable tools for generating a uniform magnetic field. Join us as we explore the anatomy of a solenoid,...
Flipping Physics
Ampère's Law
Welcome back to Flipping Physics! Today, let's unravel the mysteries of Ampère’s law, the magnetic field counterpart to Gauss’ law in electricity. Ampère’s law, using a closed loop integral, relates the magnetic field to the current...
Flipping Physics
Biot Savart Law and Magnetic Field around a Current Carrying Wire
Explore the fascinating world of magnetism with today's lesson on the Biot-Savart Law! Join us at Flipping Physics as we delve into the equation that defines the infinitesimally small magnetic field (dB) created by current through a...
Flipping Physics
Magnetic Force Direction: Right-Hand Rule
Explore the fascinating world of magnetic forces with Flipping Physics! In this engaging video, we delve into the right-hand rule, an essential tool to understand the direction of magnetic forces on moving charges. From positive charges...
Flipping Physics
Mass Spectrometer
Delve into the mass spectrometer, a crucial tool for understanding particles and their properties. Consisting of a velocity selector and a deflection chamber, it begins with charges entering the crossed fields of magnetic and electric...
Flipping Physics
Magnetic Fields and Magnetic Forces on Moving Charges
In this episode of Flipping Physics, we delve into the fascinating world of magnetic fields and dipoles. Exploring the properties of magnetic poles and dipoles, we emphasize how they interact and align just like electric charges. We...
Flipping Physics
Magnetic Force on Current
In this episode of Flipping Physics, we delve into the intriguing world of magnetic forces in current-carrying wires. Ever wondered how the net magnetic force on a wire is calculated when charges are on the move in a wire? We break down...
Flipping Physics
Electric Power
In this video, we learn about and derive equations for electric power using Ohm's law. We explore the relationship between electric power, electric potential difference, electric current, and resistance. We also discuss the unit of...
Flipping Physics
Electric Circuit Basics
In this video, the basics of electric circuits are discussed. The components of an electric circuit such as wires, batteries, resistors, capacitors, and switches are introduced with their respective symbols. The concept of electromotive...
Flipping Physics
Resistor Series and Parallel Circuits
Good morning! In this episode of Flipping Physics , Bo reviews the concept of resistors in series using the anthropomorphic charge analogy. Learn how charges navigate through resistors and why they are considered in series. We also...
Flipping Physics
Resistance and Ohm's Law
In this video, the relationship between current density, conductivity, and electric field is discussed, with a focus on Ohm's law and resistivity. The video also covers the differences between resistance and resistivity. The practical...
Flipping Physics
Energy Stored in a Capacitor
Learn about the energy stored in a capacitor. Derive the equation and explore the work needed to charge a capacitor.
Flipping Physics
Capacitance
This video explores the science behind capacitors, including what they are, how they work, and how they store electric potential energy in an electric field. The definition of capacitance is given, as well as the units and symbols used...
Flipping Physics
Current and Drift Velocity
We explore the concept of electric current and conventional current, which is the direction that positive charges flow, and the reality that electrons move in the opposite direction in most circuits. We derive the equation for average...
Flipping Physics
Parallel Plate Capacitors
We derive the equation for the capacitance of a parallel plate capacitor. Learn how adding a dielectric material to a capacitor affects its capacitance and discover the definition of the dielectric constant.
Flipping Physics
3 Properties of Conductors in Electrostatic Equilibrium
Learn 3 of the 4 things you need to remember about conductors in electrostatic equilibrium, including that the electric field inside is zero, excess charges are located on the surface, and the electric field just outside the surface is...
Flipping Physics
Irregularly Shaped Conductors in Electrostatic Equilibrium
Learn about conductors in electrostatic equilibrium! Today, we'll go over the last of the four key points to remember. See how the local surface charge density is at its maximum where the radius of curvature is at its minimum. Learn how...
Flipping Physics
You Gonna Rock It!
You are gonna rock that AP Physics Exam! Best of luck to you my friends!
Flipping Physics
Thin Ring Electric Field using Electric Potential
First we solve for the electric potential along the axis of a uniform thin ring of electric charge. Then we use that electric potential to solve for the electric field at the same location.
Flipping Physics
Equipotential Surfaces
The electric potential difference in a uniform electric field is derived and used to show lines of equal electric potential or equipotential lines. Equipotential lines and surfaces of point charges and dipoles are shown. The equation for...
Flipping Physics
Speed of a Proton in a Uniform Electric Field
Conservation of energy is used to determine the final speed of a proton released at rest in a uniform electric field.
Flipping Physics
Parallel Plates Electric Potential Difference using an Integral
Calculus is used to derive the equation for the electric potential difference between two parallel plates of equal but opposite charge. It’s a uniform electric field. The significance of the negative in the equation is explained.
Flipping Physics
Short Answer for AP Physics Explained
I answer the question, “What are AP Physics Short Answer Questions?”
Flipping Physics
QQT and PASA for AP Physics Explained
Qualitative/Quantitative Translation (QQT) and Paragraph Argument Short Answer (PASA) are explained and examples are given.