From 4b0e35482ac06cfd0e6e323ec035e86e2bf70073 Mon Sep 17 00:00:00 2001
From: eggy <eggyrules@gmail.com>
Date: Fri, 5 Feb 2021 18:13:29 -0500
Subject: [PATCH] phys: add magnets

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 The course code for this page is **SPH4U7**.
 
+## Magnetism
+
+Magnets are objects with north/south dipoles that create a field around them. Although ferromagnetic substances can repel each other, paramagnetic substances are always attracted to a magnetic field. See [HL Chemistry#Physics properties of transition elements](/sch3uz/#physical-properties-of-transition-elements) for more details.
+
+### Magnetic fields
+
+<img src="/resources/images/magnetic-field.png" width=700>(Source: Kognity)</img>
+
+Similar to electric and gravitational fields, magnetic fields are drawn by their effect on a north pole. Since magnetic poles always appear in equal magnitude pairs, all magnetic field lines for a magnet must start at its north pole and end at its south pole.
+
+<img src="/resources/images/more-magnetic-fields.png" width=700>(Source: Kognity)</img>
+
+### Straight-line electromagnets
+
+Moving electric charges produce magnetic fields. A circle filled with an "x" indicates that the current is moving away from the viewer in the third dimension while a dotted circle indicates it is moving toward the viewer.
+
+These magnetic fields are centred on the conductor, are in a plane perpendicular to the conductor, and have decreasing magnetic field strength over distance.
+
+<img src="/resources/images/straight-line-electromagnet.png" width=700>(Source: Kognity)</img>
+
+The **right-hand rule** for straight-line conductors indicates that when the conductor would be grasped by the right hand, the thumb would point in the direction of current and the fingers pointing in the direction of the magnetic field.
+
+<img src="/resources/images/right-hand-rule.png" width=700>(Source: Kognity)</img>
+
+### Selenoid electromagnets
+
+A **selenoid** is a conductor coil in a tight helix. Current passed through a selenoid will generate a **uniform magnetic field** inside the coil with a pattern identical to that of a bar magnet outside it.
+
+<img src="/resources/images/selenoid-electromagnet.png" width=700>(Source: Kognity)</img>
+
+The right-hand rule can be applied again to a selenoid to identify the direction of the north pole or direction of magnetic field in the coil:
+
+<img src="/resources/images/selenoid-right-hand-rule.png" width=700>(Source: Kognity)</img>
+
 ## Resources
 
  - [IB Physics Data Booklet](/resources/g11/ib-physics-data-booklet.pdf)