Venus->earth->jupiter
Apex:)
Earth, Jupiter, Saturn, Uranus, and Neptune. Other planets (Mercury, Venus, and Mars) have magnetic fields too, but they are too tenuous to be detected from anyplace but the surface and don't protect from solar radiation.
Yes, several planets in our solar system have magnetic fields, including Earth, Mercury, Jupiter, Saturn, Uranus, and Neptune. These magnetic fields are generated by the movement of molten metals in their cores. The strength and structure of the magnetic fields vary from planet to planet.
Jupiter has a large, complex, and intense magnetic field that is thought to arise from electrical currents in the rapidly spinning metallic hydrogen interior. The Earth has a strong magnetic field, but Jupiter's magnetic field at the tops of its clouds is 10 times stronger than that of the Earth. Further, the Jovian magnetic field has much higher complexity than that of the Earth, with some aspects of Jupiter's fields having no Earthly counterpart. The intensity and complexity relative to the magnetic field of the Earth is presumably related in some way to the more rapid rotation and larger metallic interior for Jupiter.yes
Well, just like how every artist has their own unique style, each planet in our solar system has its own special characteristics too. Saturn's magnetic field is not necessarily the strongest, but it does have its own beautiful nature - it's unique in size and structure compared to other planets, making it a wonderful subject to explore and learn more about. Remember, it's all about appreciating the diversity and beauty in our cosmic neighborhood!
The magnetosphere is the region around a planet where the solar wind is significantly altered due to the magnetic field of the planet. Planets with a magnetic field arising from internal processes are said to have a global magnetic field. A Global magnetic field will produce a magnetosphere. Six of the planets have global magnetic fields, and hence some magnetosphere; Mercury, Earth, Jupiter, Saturn, Uranus, Neptune. Mars did have one, but when the core froze, that ended the geodynamo. Venus, the near twin of Earth, does not have a geomagnetic field and that is quite perplexing. It too lacks a geodynamo and no one knows why. There are remnant magnetic fields for Mars and Venus, but they are too small to have any significant effect on the solar wind. Jupiter and Saturn have huge magnetic fields and there are only general theories as to what causes them. Uranus has a middling magnetic field, more in the range of Earth's field. The moon has no significant field. We have no idea whether Pluto does or not, but it would be unlikely.
VenusEarthJupiter
south pole
You can tell where the magnetic fields are strongest in a picture by looking for areas where the magnetic field lines are closest together, indicating a higher field strength. The density of the field lines represents the strength of the magnetic field.
Type your answer here... at both poles
Algeria haha
Neptune, Uranus, Saturn, Jupiter, and Earth all have magnetic fields. Mercury has a very weak magnetic field.
the magnet field is the strongest well the summer solstic when the suns gravitational pull is the strongest
The strongest man made magnets are those associated with the Large Hadron Collider. The strongest magnetic fields are produced by collaped stars.
Yes. They don't have actual magnets, but they do have "magnetic fields". Other planets with magnetic fields are Mercury, Jupiter, Saturn, Uranus and Neptune.
It MIGHT have. If the SURFACE of the planet is cold, its interior can still be liquid, for billions of years - allowing the currents that cause the magnetic field. Note, for example, that Jupiter has considerable magnetic fields.
Neodymium magnets are the strongest type of permanent magnets commercially available. They have high magnetic strength and are commonly used in applications requiring strong magnetic fields.
Neutron stars are thought to possess incredibly strong magnetic fields, with the strongest magnetic field ever detected being around 10^15 gauss, which is quadrillions of times stronger than a refrigerator magnet. These magnetic fields are produced by the intense rotation and density of the star's core.