If you are able to turn off the magnet at this time, assuming that it is an electromagnet, you can also easily turn off the current that is flowing through it, which will cause it to stop producing magnetic fields. If you are able to do either of these things, the magnet will no longer produce magnetic fields. Permit me, then, to illustrate both of these available choices. After that, I will show you the way that ought to be followed.
The magnet can be turned on and off whenever you like thanks to the on/off switch. Consequently, let's attempt to stop it by putting some metal on it and seeing if that does the trick.
Due to the fact that we now possess this knowledge, we will be able to observe the magnetic field. By positioning a piece of specialized magnetic paper in front of the magnetic field, we are able to observe the field's magnetic properties. To begin, let's take a sheet of non-ferromagnetic metal and place it in front of you so that you can observe how the magnet does not adhere to it. However, it is clear that the magnetic field is able to pass through this, which indicates that I will not be able to prevent the magnetic field from passing through this location. However, even with this piece of steel, it is still pretty sweet. Now, let's try using a piece of steel so that it can easily stick to this; however, even with this piece of steel, it is pretty sweet.
On the other hand, if we use steel that is significantly thicker, we won't be able to make out anything, which indicates that the magnetic field will continue to pass through this location unimpeded. Even though it does not stop it in any meaningful way, it does stop magnetic flux from escaping into the surrounding air by merely producing a circuit path for it to follow. This is despite the fact that it does not prevent it in any meaningful way. Because of this, no matter how hard we try, nothing will adhere to it. Despite our best efforts, it won't work. Because of this, we are able to use a thick steel like this one to protect the air around us from the effects of a magnetic field. On the other hand, in the end, if I apply a stronger magnet to the steel, the steel will become saturated, which will still cause the steel to become saturated and be unable to hold any more magnetic flux; as a result, the magnetic field will once again be able to permeate into the air that is surrounding it. Please allow me the opportunity to show you my enormous neodymium magnet.
In spite of this, it has become abundantly clear that some magnetic flux does, in fact, still pass through the steel; as a consequence of this, the steel continues to become saturated. As a consequence of this, the probability that the magnetic field needs to be blocked increases in proportion to the size of the magnet.
One of the choices available is to heat it. As a result, all of the magnetic moments in these neodymium magnets that initially pointed in the same direction get enough movement from the thermal energy when the temperature is approximately 600 Kelvin. They are no longer pointing in the same direction as one another.
The fact that it does not function as a magnet any longer is the primary cause of the confounding behavior. You are going to need to find a way to re-magnetize it before you can use the key to open it again. If you turn it around, it will be completely magnetic, but if you turn it the other way, it will act like a vacuum and draw them in.
Iron is the material used to craft this colossal nail. Pulling it out so that I can open it is a really tough challenge for me. If this is the case, it won't show any interest in it at all if this is how it turns out. You can use it to pick up a piece of metal, and it will not slip out of your grasp at any point while you have it in your grasp. It has an effect on the magnetic field that is totally and completely obstructive. A magnetic field can not be detected at this location.
It is beyond our capabilities to even do just enough to pick up the staple. How does this result in the permanent magnet either opening back up or closing back down? Because I have a piece of steel hiding behind this piece of paper, you are able to see that I have attached two neodymium magnets to the distiller. You ought to be able to figure out which side of the magnet points in which direction now that we have established that this particular location marks the beginning of the north pole of these magnets. Take note that there is now absolutely no impediment to it in any way. Therefore, if I just say that this steel coin is my magnet, you can see that it does not have any magnetism; however, if I simply change the direction that one of the magnets is facing, it will become magnetic. This is because changing the direction that one of the magnets is facing causes it to become magnetic.
The question then is, why does something like this take place? What is it about this that stops the magnetic flux from going through? Because of this, when I turn them so that they are facing the same direction, it is almost as if I have placed a magnet here. Because of this, the flux line will wind from this side to this side, which indicates that if another piece of steel is nearby, it will be easy for it to be attracted to it. On the other hand, if you put a piece of steel there, it will act as a barrier for it and prevent it from traveling from the North Pole to the South Pole.
They only want it to go from north to south or from south to north, so all they want to do is wind a small circle there to create a small short circuit. This is because it only wants to go in either direction. They won't be attracted by it at all because they don't want to get out of this steel plate and into the one below it. Therefore, they won't want to leave this one. If I now wrap one of them around the magnetic field line, they only want to wind a small circle there. However, this only happens when I do it. Because it is only interested in traveling in either direction, north to south or south to northAfter that, you essentially repeated what I did by turning one of them through 180 degrees; however, because it is now a cylinder, you can completely surround it on either side, and after that, you can completely block the permanent magnet supplier, causing it to turn from one side to the other. If you are able to join two of these things together, you will be able to rotate them through 180 degrees. If you are able to join two of these things together, you will be able to rotate them through 180 degrees.
I want to express my gratitude once again for your continued attention throughout this portion of the Action Lab. com, or you can view my experiment book by clicking on the link that is provided in my description. Either way, I sincerely hope that you will be able to pick up some information that will be of use to you. The book is now available for purchase through Amazon. I am appreciative of the fact that you chose to watch.
