How Can We Use Magnetix in 9th Grade Physical Science?

  • Thread starter Thread starter Robert100
  • Start date Start date
  • Tags Tags
    Class Physics
AI Thread Summary
Magnetix kits can be effectively utilized in a 9th grade physical science class to create engaging lessons that teach students about magnetism. Activities include using iron filings to visualize magnetic fields, building 2D and 3D structures, and experimenting with compasses to observe magnetic effects. Students can also construct simple motors and generators to demonstrate electromagnetic induction. Additional experiments involve dropping various materials through a magnetic gap to explore the differences in behavior between conductive and non-conductive objects. These hands-on activities not only enhance understanding but also encourage critical thinking through related quiz questions.
Robert100
Messages
83
Reaction score
0
I like the Magnetix kits that are available in stores nowadays, and I'm trying to think of a way that I can use them in a 9th grade physical science class.

Mindlessly playing and exploring with magnets is nice for a few minutes, but I'm looking for ideas to have mind-engaging lesson that will teach the kids something.

The most obvious thing is to lay paper over the magnets, then add iron fillings. Magic! Then build 2D magnetic structures and have them predict the patterns that might appear. Lay paper over their 2D structure, add more iron filings.

We will move compasses around them and see how they are affected.

But what else to do with them? There must be some neat things to do, especially since it is so easy to make 3D magnetic structures.

This is a 9th grade high school class, so I am not getting into details like you'd find in a textbook like Giancoli Physics!


Robert
 
Physics news on Phys.org
Make little motors and generators with the magnets and some wire. You can use a simple analog current meter to show how moving the magnet past a coil induces a current. And with some creativity, you should be able to make a DC motor with some coils and a battery...
 
Hmm, perhaps pedulums?

i've never used magnetics, but is it possible to make like a car or something with it? you could replace the dynamics trolley with it perhaps...i'm in A level physics at the moment..just started, so it's mostly theory, not many practicals...so i see where your coming from when you want the kids to learn something.
 
capitolmonkey said:
Hmm, perhaps pedulums?
Oh yeah, that reminds me of the great demo of strong magnets forming a thin gap, and you experiment dropping plates of different materials down through the gap. Non-conductive plates go right through, but conducting ones slow way down in the gap. Quiz question -- why? Great demo.
 
or maybe try to magnetize an iron bar under the magnetic field of the earth?
 
berkeman said:
Oh yeah, that reminds me of the great demo of strong magnets forming a thin gap, and you experiment dropping plates of different materials down through the gap. Non-conductive plates go right through, but conducting ones slow way down in the gap. Quiz question -- why? Great demo.
Another on-topic quiz question: What happens if you have a conductive plate/disk that has radially cut slots? Why does it act like a non-conductive plate?
 
Thread 'Motional EMF in Faraday disc, co-rotating magnet axial mean flux'

Thread 'Motional EMF in Faraday disc, co-rotating magnet axial mean flux'

So here is the motional EMF formula. Now I understand the standard Faraday paradox that an axis symmetric field source (like a speaker motor ring magnet) has a magnetic field that is frame invariant under rotation around axis of symmetry. The field is static whether you rotate the magnet or not. So far so good. What puzzles me is this , there is a term average magnetic flux or "azimuthal mean" , this term describes the average magnetic field through the area swept by the rotating Faraday...
View full post »

Thread 'Why measure the speed of light in one direction?'

It may be shown from the equations of electromagnetism, by James Clerk Maxwell in the 1860’s, that the speed of light in the vacuum of free space is related to electric permittivity (ϵ) and magnetic permeability (μ) by the equation: c=1/√( μ ϵ ) . This value is a constant for the vacuum of free space and is independent of the motion of the observer. It was this fact, in part, that led Albert Einstein to Special Relativity.
View full post »

Similar threads

What can I expect from this physics forum as a 9th-grade student?
Replies
1
Views
560
Programs Questions About Referrals for Physics REUs (for Undergrads)
Replies
4
Views
2K
Admissions Statement of purpose critique request (high-energy theory PhD)
Replies
0
Views
2K
Can a physics degree lead to a diverse and fulfilling career?
Replies
1
Views
509
Schools Where to go for physics undergrad?
Replies
6
Views
2K
Is It Too Late to Pursue a Career in Physics?
Replies
6
Views
3K
Studying Class average for my physics mid-term was 8/30, Seriously
2
Replies
56
Views
6K
Can we create a renewable energy toy using a spinning top and magnets?
Replies
6
Views
4K
Huge dilemma about what physics to take. introduction with algebra or
Replies
16
Views
2K
Do AP Classes adequately prepare students for college?
Replies
19
Views
6K

Hot Threads

Recent Insights

Back
Top