How to image the magnetic field

In summary, the conversation discusses the difficulty in visualizing and understanding the generation of magnetic fields compared to electric fields. The use of the right hand rule is suggested to understand the orientation of field lines. The question of how to fix the strength of the magnetic field at the boundary of a plate and a plasma or fluid is also raised, with the suggestion that the strengths of the magnetic fields generated within the two materials may be different. The conversation ends with a request for clarification on the setup of the problem and the boundary conditions of a perturbed magnetic field.
  • #1
jollage
63
0
Hi all,

I'm dealing with a homework connected to the magnetic field. But I can't image how these things are generated.

I can image that for the electric field, one can generate it by just applying a voltage different across two plates and you will get an electric field pointing from one plate to another. For the magnetic field, I guess it's basically the same thing, but I can't image how it's generated. Let's say, I have two plates, between which certain plasma or fluid fill, in this case, how can I fix the strength of the magnetic field at one plate to be B and the other to be 0, at the same time, the direction of magnetic fields are actually parallel to the plates? Sorry since I know this question maybe sound very strange...

Thanks.
 
Physics news on Phys.org
  • #2
jollage said:
Hi all,

I'm dealing with a homework connected to the magnetic field. But I can't image how these things are generated.

I can image that for the electric field, one can generate it by just applying a voltage different across two plates and you will get an electric field pointing from one plate to another. For the magnetic field, I guess it's basically the same thing, but I can't image how it's generated. Let's say, I have two plates, between which certain plasma or fluid fill, in this case, how can I fix the strength of the magnetic field at one plate to be B and the other to be 0, at the same time, the direction of magnetic fields are actually parallel to the plates? Sorry since I know this question maybe sound very strange...

Thanks.

You don't generate a magnetic field with plates. You generate it with current-carrying wires. One of the most efficient ways is with a current passing through a wire coil or solenoid.
 
  • #3
No worries. The magnetic field is a little harder to visualize than the electric field since it doesn't originate from + charges and end at - charges like the electric field does. Unfortunately, I don't know of any way to visualize a magnetic field that helps you understand how it is generated. For example, current running through a straight wire will generate a magnetic field that runs in circular loops around the wire. Since the field lines are circles, they never enter or leave the wire, making it difficult to understand how they are generated.

220px-Manoderecha.svg.png


The only thing I can suggest is to memorize the right hand rule so that you'll know the orientation of the field lines.

It may help to understand that the electric and magnetic lines you see in images don't really exist. They are only there to help you visualize how a charged particle will react when placed in an electric or magnetic field. The lines are like contour lines on a map or latitude and longitude lines on a globe. You don't see these lines when you go outside, as they only exist to help you understand how to get around.
 
  • #4
Thank you very much berkeman and Drakkith

I just want to make sure another thing regarding how to fix the strength of the magnetic field on the boundary of plate. The plasma or fluid and the plate are made of obviously two different materials, so I guess the strengths of the magnetic fields generated (by the current) within these two materials are also different, right? Now in the problem, the plasma is in motion, resulting in a magnetic field also changing with respect to the space. My question is that is the magnetic field on the contact of the plasma and the plate constant? Since the plate isn't motion, I guess the magnetic field there should be not changing, right?

Thanks
 
  • #5
jollage said:
Thank you very much berkeman and Drakkith

I just want to make sure another thing regarding how to fix the strength of the magnetic field on the boundary of plate. The plasma or fluid and the plate are made of obviously two different materials, so I guess the strengths of the magnetic fields generated (by the current) within these two materials are also different, right? Now in the problem, the plasma is in motion, resulting in a magnetic field also changing with respect to the space. My question is that is the magnetic field on the contact of the plasma and the plate constant? Since the plate isn't motion, I guess the magnetic field there should be not changing, right?

Thanks

Can you say more about what you are trying to do? The interaction between a magnetic field and a plasma can be quite complex. Do you have any diagrams or pictures that would help us to understand what you are working toward?
 
  • #6
jollage said:
The plasma or fluid and the plate are made of obviously two different materials, so I guess the strengths of the magnetic fields generated (by the current) within these two materials are also different, right?

What current? You've said nothing about any sort of current in your setup, just something about 2 plates with a plasma or fluid between them. I'm in agreement with Berkeman. It would greatly help if you could tell us or show us the exact setup of the problem.
 
  • #7
Hi Drakkith and berkeman, sorry for the late reply and the unclear sentences.

The current I'm talking about is following your thread (you mentioned how to generate the magnetic field by the current). Actually, all these questions are coming from my mind, just slightly related to the homework. What I eventually want to know is, except the complex physics of the plasma, that

If the magnetic field is perturbed, let's say the magnitude of this perturbation is b, then what's the boundary condition of this perturbed magnetic field on the interface between the fluids (or plasma) and the plates?

Note that b<<B, where B is the unperturbed magnetic field, and B is steady in time.
 

Related to How to image the magnetic field

1. How can I image the magnetic field of an object?

To image the magnetic field of an object, you will need a special type of imaging technique called magnetic resonance imaging (MRI). This involves using a strong magnetic field and radio waves to create detailed images of the internal magnetic field of an object. MRI machines are commonly used in medical settings to image the human body, but they can also be used for other purposes such as imaging the magnetic fields of materials or electronic devices.

2. What are the main components of an MRI machine?

The main components of an MRI machine include a strong magnet, radiofrequency coils, a computer system, and a patient table. The magnet creates a strong and uniform magnetic field, while the radiofrequency coils generate and receive radio waves. The computer system processes the signals and creates images, and the patient table allows for positioning of the object being imaged.

3. How does an MRI machine create images of the magnetic field?

An MRI machine creates images of the magnetic field by measuring the response of the object's atoms to the magnetic field and radio waves. The atoms in the object align themselves with the magnetic field and then absorb and emit radio waves at specific frequencies. This information is then processed by the computer system to create detailed images of the magnetic field.

4. What are the advantages of using MRI to image the magnetic field?

MRI offers several advantages over other imaging techniques for imaging the magnetic field. It is non-invasive, does not use ionizing radiation, and can produce highly detailed images with good spatial resolution. MRI can also differentiate between different types of tissues or materials based on their unique magnetic properties.

5. Are there any limitations to using MRI to image the magnetic field?

While MRI is a powerful imaging technique, there are some limitations to consider. MRI machines are expensive and require specialized training to operate. They are also not suitable for imaging objects that are sensitive to strong magnetic fields, such as pacemakers or metal implants. Additionally, MRI images may be affected by motion artifacts, so it is important for the object being imaged to remain still during the scanning process.

Similar threads

I Induced electric fields and induced magnetic fields confusion
    • Electromagnetism
Replies
9
Views
2K
B Confusing diagram of a rotating coil in a magnetic field
    • Electromagnetism
Replies
4
Views
1K
Exploring Magnetic Fields: Is the Plate Affecting My Magnet?
    • Electromagnetism
Replies
1
Views
918
I Behaviour of Magnetic Fields Underwater
    • Electromagnetism
Replies
2
Views
1K
B Magnetic fields attracting two disc-shaped magnets
    • Electromagnetism
Replies
11
Views
1K
I Hall effect -- is it always applicable?
    • Electromagnetism
Replies
7
Views
1K
I Relation between electric & magnetic fields in terms of field strength
    • Electromagnetism
2
Replies
41
Views
3K
I What is the ideal fluid and setup for observing Magnetohydrodynamics?
    • Electromagnetism
Replies
1
Views
652
Why a steel plate can shield magnetic field?
    • Electromagnetism
Replies
12
Views
2K
I Is the magnetic field from this current rotationally symmetric?
    • Electromagnetism
Replies
12
Views
880

Hot Threads

Recent Insights

Back
Top