Solenoidal Fields: Understanding Curl and Divergence

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In summary, solenoidal fields are vector fields that are both divergenceless and curl-free. This means that there are no sources or sinks at any point in the field, and the flow lines either form closed loops or extend to infinity. The presence of closed lines does not necessarily indicate the presence of curl, but rather the divergenceless nature of the field.
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fisico30
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solenoidal fields...

hello forum,

curl and divergence are "local" concepts.
If a vector field has zero divergence it means that there is no source (or sink) at that point.
It could be divergenceless everywhere.

If the field is solenoidal it automatically is divergenceless.
I do not understand why a solenoidal field needs to have closed lines however.
Is that true only if we consider a field line that encircles many points?
for example, a field could have a curl at every point but not have closed line, like in the case of velocity field of a fluid in a tube. The parabolic velocity profile is such that the field has curl, but the field lines are straight (no closed lines).

thanks!
 
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Flow lines may only start and end on sources and sinks, respectively. Therefore, in a divergenceless vector field, the flow lines must either form closed loops, or they must extend to infinity. For example, a constant vector field is divergenceless...
 
  • #3


thanks Ben,
I see. So the closed line idea has nothing to do with the fact that the vector field has curl or not, but only on the fact that it is divergenceless...
 

1. What is a solenoidal field?

A solenoidal field is a type of vector field in which the divergence is equal to zero at every point. This means that the field is "source-free" and the flow of the field is purely rotational. It is also known as an incompressible field.

2. What is the significance of understanding curl and divergence in solenoidal fields?

Curl and divergence are important concepts in understanding the behavior and characteristics of solenoidal fields. Curl describes the rotational component of the field, while divergence describes the expansion or contraction of the field at any given point. These properties help us understand the flow and direction of the field, as well as its behavior near sources and sinks.

3. How are solenoidal fields used in real-world applications?

Solenoidal fields have a wide range of applications in physics and engineering. They are commonly used in fluid mechanics to model the flow of fluids, as well as in electromagnetics to describe the behavior of magnetic fields. They are also used in image processing, computer graphics, and other fields where vector fields are important.

4. What is the relationship between curl and divergence in solenoidal fields?

In solenoidal fields, the curl and divergence are related by the continuity equation, which states that the divergence of the curl of a vector field is always equal to zero. This means that if the field is solenoidal, its curl must also be solenoidal. In other words, the flow of a solenoidal field can only be rotational if it is also source-free.

5. How can we visualize solenoidal fields?

Solenoidal fields can be visualized using vector field plots, which show the direction and magnitude of the field at different points in space. They can also be represented using streamlines, which are curves that are tangent to the direction of the field at every point. Additionally, solenoidal fields can be visualized using computer simulations and animations, which can help us understand their behavior in complex systems.

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