5) – z (into page)

... the use of instructors in teaching their courses and assessing student learning. Dissemination or sale of any part of this work (including on the World Wide Web) will destroy the integrity of the work and is not permitted. The work and materials from it should never be made available to students exc ...

5) – z (into page)

... x x x x x x x x x x x x Two particles of the same mass enter a magnetic field with the same speed and follow the paths shown. Which particle has the ...

Magnetism Notes

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Lesson 15 - Magnetic Fields II

4 Electromagnetism

Lesson 15

chapter 18 notes for eighth grade physical science

... ALL MAGNETS HAVE TWO POLES, EXERT FORCES, AND ARE SURROUNDED BY A MAGNETIC FIELD. THE MAGNETIC EFFECTS ARE STRONGEST NEAR THE ENDS OF THE BAR MAGNET. THE PARTS OF A MAGNET WHERE THE MAGNETIC EFFECTS ARE STRONGEST ARE CALLED POLES. A NATURAL MAGNET IS CALLED A LODESTONE. MAGNETIC P0LES ALWAYS OCCUR I ...

Magnet facts

... wire created a magnetic field that, while small because it was only from a D battery, was enough to pick up the paper clips or iron filings. To make the electromagnet stronger, you would wrap the wire more times around the nail. Using a different core will also make it stronger. The last thing is th ...

A multi-instrument analysis of sunspot umbrae

... Conclusions and future work This poster shows some of our recent results from looking at large numbers of sunspots to derive statistically meaningful properties. We see that the previously studied magnetic field – intensity relationship holds for our three datasets. We then compare magnetic fields o ...

Chapter 36 – Magnetism

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Liquid Magnets Worksheet – Answers

... magnetic field directions and varying strengths. KEY: Single domain arrow is characteristic of the nanoparticle because of the particle size can only contain one domain. 5. Why do ferrofluid materials behave differently than bulk magnetic materials? Ferromagnetic particles within the fluid specifica ...

Lab 2: Magnetic Fields - Island Energy Inquiry

III-5

... • It is illustrative to look at a classical planetary model of electron, even if it is not realistic, to see where the dependence on the specific charge comes from. ...

Plasma Physics - 123SeminarsOnly.com

... between closely spaced metalized surfaces which constrain the beam. Then the beam is deflected by the desired geometry of the ...

Solar Wind-Magnetosphere-Ionosphere Coupling: Dynamics in

Magnetism 1

Making a Stronger Electromagnet J0727

... to be lifted by the electromagnet, a ball bearing, sits in a hole in the platform. Relative magnetic power of the electromagnet is determined by raising the ball bearing on the platform under the electromagnet. When the ball bearing gets lifted off of the platform, it is stopped from raising any fur ...

スライド 1 - Nanjing University

Chapter V: The Fluxgate Magnetometer

... a dozen volunteers inhale small amounts of iron oxide dust, which is harmless but can be magnetized. Over a year's time, each subject stood between a pair of coils, through which a large current was briefly passed. This magnetized the dust grains inside the lungs and aligned them with ______________ ...

Magnetic Interaction

Magnets - kdavis10

... magnets have been helpful to people for hundreds of years. ...

What is magnetism

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Magnetosphere of Saturn

The magnetosphere of Saturn is the cavity created in the flow of the solar wind by the planet's internally generated magnetic field. Discovered in 1979 by the Pioneer 11 spacecraft, Saturn's magnetosphere is the second largest of any planet in the Solar System after Jupiter. The magnetopause, the boundary between Saturn's magnetosphere and the solar wind, is located at a distance of about 20 Saturn radii from the planet's center, while its magnetotail stretches hundreds of radii behind it.Saturn's magnetosphere is filled with plasmas originating from both the planet and its moons. The main source is the small moon Enceladus, which ejects as much as 1,000 kg/s of water vapor from the geysers on its south pole, a portion of which is ionized and forced to co-rotate with the Saturn’s magnetic field. This loads the field with as much as 100 kg of water group ions per second. This plasma gradually moves out from the inner magnetosphere via the interchange instability mechanism and then escapes through the magnetotail.The interaction between Saturn's magnetosphere and the solar wind generates bright oval aurorae around the planet's poles observed in visible, infrared and ultraviolet light. The aurorae are related to the powerful saturnian kilometric radiation (SKR), which spans the frequency interval between 100 kHz to 1300 kHz and was once thought to modulate with a period equal to the planet's rotation. However, later measurements showed that the periodicity of the SKR's modulation varies by as much as 1%, and so probably does not exactly coincide with Saturn’s true rotational period, which as of 2010 remains unknown. Inside the magnetosphere there are radiation belts, which house particles with energy as high as tens of megaelectronvolts. The energetic particles have significant influence on the surfaces of inner icy moons of Saturn.In 1980–1981 the magnetosphere of Saturn was studied by the Voyager spacecraft. As of 2010 it is a subject of the ongoing investigation by Cassini mission, which arrived in 2004.

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Magnetosphere of Saturn