the proof-----seafloor spreading
... Magnetic Reversals occur • When magma cools, the iron cools into the mineral magnetite. It lines up parallel to the Earth’s present magnetic field. This iron is like compass needles, pointing north. So when the rock hardens, a record of the Earth’s magnetic field at that time is locked in stone---s ...
... Magnetic Reversals occur • When magma cools, the iron cools into the mineral magnetite. It lines up parallel to the Earth’s present magnetic field. This iron is like compass needles, pointing north. So when the rock hardens, a record of the Earth’s magnetic field at that time is locked in stone---s ...
Chapter 36 Summary – Magnetism
... 1. Interaction between two magnets, called magnetic ______________________, increases as magnets move closer. 2. A magnetic _____________________, which exerts the magnetic force, surrounds a magnet, and is strongest _____________________ to the magnet. B. Magnetic __________________ - the regions o ...
... 1. Interaction between two magnets, called magnetic ______________________, increases as magnets move closer. 2. A magnetic _____________________, which exerts the magnetic force, surrounds a magnet, and is strongest _____________________ to the magnet. B. Magnetic __________________ - the regions o ...
SA1 REVISION WORKSHEET 2
... 7. How does a solenoid behave like a magnet? Can you determine the north and south poles of a current carrying solenoid with the help of bar magnet? 8. List the properties of magnetic lines of force. A current through a horizontal power line flows in east to west direction. What is the direction of ...
... 7. How does a solenoid behave like a magnet? Can you determine the north and south poles of a current carrying solenoid with the help of bar magnet? 8. List the properties of magnetic lines of force. A current through a horizontal power line flows in east to west direction. What is the direction of ...
Electromagnetic Induction
... Where F force on conductor (N), B = magnetic field strength (T), I = current in conductor (A) and L = length of conductor in magnetic field (m) A current flowing parallel to a magnetic field experiences no force. The formula has been generalised, noting that the force is zero when the angle is zero ...
... Where F force on conductor (N), B = magnetic field strength (T), I = current in conductor (A) and L = length of conductor in magnetic field (m) A current flowing parallel to a magnetic field experiences no force. The formula has been generalised, noting that the force is zero when the angle is zero ...
Magnetic Fields
... two ends called poles. A pole is the area of a magnet where the magnetic effect is strongest. One pole of a magnet points towards magnetic north of the earth and is labeled north. The other pole is labeled south. EEM-11 ...
... two ends called poles. A pole is the area of a magnet where the magnetic effect is strongest. One pole of a magnet points towards magnetic north of the earth and is labeled north. The other pole is labeled south. EEM-11 ...
Presentations
... “I'm not sure I comprehend the drawing correctly, but I think the reaction would gravitate upward in reaction to the north pole of the magnet.” “since the loop is not moving there is no energy produced.” ...
... “I'm not sure I comprehend the drawing correctly, but I think the reaction would gravitate upward in reaction to the north pole of the magnet.” “since the loop is not moving there is no energy produced.” ...
Answer the questions below
... 3. The lights of the Aurora Borealis result from a. particles from the Sun hitting Earth’s magnetosphere. b. static electricity in the troposphere. c. lightning storms taking place over the horizon. d. rainbows that occur at night. ...
... 3. The lights of the Aurora Borealis result from a. particles from the Sun hitting Earth’s magnetosphere. b. static electricity in the troposphere. c. lightning storms taking place over the horizon. d. rainbows that occur at night. ...
Magnetism
... on magnets or other magnetic materials. • A permanent magnet is a material that keeps its magnetic properties even when it is NOT close to other magnets. ...
... on magnets or other magnetic materials. • A permanent magnet is a material that keeps its magnetic properties even when it is NOT close to other magnets. ...
Magnetism.
... separated from each other. The north and south magnetic poles cannot be separated. Every time we saw a magnet in half, it gets the 2 poles. ...
... separated from each other. The north and south magnetic poles cannot be separated. Every time we saw a magnet in half, it gets the 2 poles. ...
Word
... 1. Two fixed wires cross each other perpendicularly so that they do not actually touch but are close to each other as shown in the figure. Equal currents i exist in the wires, in the directions indicated. a. In what region(s) will there be points of zero net magnetic field? b. If the wires are free ...
... 1. Two fixed wires cross each other perpendicularly so that they do not actually touch but are close to each other as shown in the figure. Equal currents i exist in the wires, in the directions indicated. a. In what region(s) will there be points of zero net magnetic field? b. If the wires are free ...
The Dynamic Earth: Plate Tectonics (PowerPoint)
... Your first thought might be that the churning convective motions must be in the outer core, since it is fluid and could clearly move in this way. So, the obvious question: Are big slabs of the overlying mantle-plus-crust ‘floating’ on the outer core, and being carried and moved around by it? ...
... Your first thought might be that the churning convective motions must be in the outer core, since it is fluid and could clearly move in this way. So, the obvious question: Are big slabs of the overlying mantle-plus-crust ‘floating’ on the outer core, and being carried and moved around by it? ...
Earth's magnetic field
Earth's magnetic field, also known as the geomagnetic field, is the magnetic field that extends from the Earth's interior to where it meets the solar wind, a stream of charged particles emanating from the Sun. Its magnitude at the Earth's surface ranges from 25 to 65 microteslas (0.25 to 0.65 gauss). Roughly speaking it is the field of a magnetic dipole currently tilted at an angle of about 10 degrees with respect to Earth's rotational axis, as if there were a bar magnet placed at that angle at the center of the Earth. Unlike a bar magnet, however, Earth's magnetic field changes over time because it is generated by a geodynamo (in Earth's case, the motion of molten iron alloys in its outer core).The North and South magnetic poles wander widely, but sufficiently slowly for ordinary compasses to remain useful for navigation. However, at irregular intervals averaging several hundred thousand years, the Earth's field reverses and the North and South Magnetic Poles relatively abruptly switch places. These reversals of the geomagnetic poles leave a record in rocks that are of value to paleomagnetists in calculating geomagnetic fields in the past. Such information in turn is helpful in studying the motions of continents and ocean floors in the process of plate tectonics.The magnetosphere is the region above the ionosphere and extends several tens of thousands of kilometers into space, protecting the Earth from the charged particles of the solar wind and cosmic rays that would otherwise strip away the upper atmosphere, including the ozone layer that protects the Earth from harmful ultraviolet radiation.