A2 Level Magnetic Field
You Might Also Like
10th Class Physics Chapter 1 - Class 10 Physics Chapter 10 - Physics Class 10 Chapter 1
Fluid Dynamics
Class 11th | Punjab Board (2025-26) | Chapter 3 | Numerical Problems Solved
O Levels Kinetic Theory of Particles
9th Class Physics Chapter 3 Dynamics
Foundations of Quantum Physics (Urdu/Hindi)
Federal Board 9th Physics Ch. 1 Physical Quantities and Measurement
Class 12 Punjab physics Textbook
A2 Level Alternating Current
9th Class Chapter 4 Turning Effect of Forces
11th Class Physics Chapter 1 - New Book 2025
O Levels/ IGCSE Physics Dynamics By MHBA
Comments
10 Comments
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
Link to our latest notes and resources: https://drive.google.com/drive/u/2/folders/15FnZdp3NJ15WmXnkrSWgi5ltd5rUI9Bg 20 Magnetic fields 20.1 Concept of a magnetic field Candidates should be able to: 1 understand that a magnetic field is an example of a field of force produced either by moving charges or by permanent magnets 2 represent a magnetic field by field lines 20.2 Force on a current-carrying conductor Candidates should be able to: 1 understand that a force might act on a current-carrying conductor placed in a magnetic field 2 recall and use the equation F = BIL sin θ, with directions as interpreted by Fleming’s left-hand rule 3 define magnetic flux density as the force acting per unit current per unit length on a wire placed at rightangles to the magnetic field 20.3 Force on a moving charge Candidates should be able to: 1 determine the direction of the force on a charge moving in a magnetic field 2 recall and use F = BQv sin θ 3 understand the origin of the Hall voltage and d
