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+<!DOCTYPE html PUBLIC "-//w3c//dtd html 4.0 transitional//en">
+<html>
+  <head>
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+      charset=windows-1252">
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+    <meta name="Author" content="C. L. Davis">
+    <title>Magnetism - Magnetic Energy - Physics 299</title>
+    <meta content="C. L. Davis" name="author">
+  </head>
+  <body style="color: rgb(0, 0, 0); background-color: rgb(255, 255,
+    255);" link="#0000ee" alink="#ff0000" vlink="#551a8b">
+    <center>
+      <h1> <img src="ULPhys1.gif" height="50" align="texttop"
+          width="189"></h1>
+    </center>
+    <center>
+      <h1>Displacement Current<br>
+      </h1>
+    </center>
+    <center><img src="celticbar.gif" height="22" width="576"><br>
+      <br>
+      <font color="#ff0000"><i>
+          <meta http-equiv="content-type" content="text/html;
+            charset=windows-1252">
+        </i></font><font color="#ff0000"><i>
+          <meta http-equiv="content-type" content="text/html;
+            charset=windows-1252">
+        </i></font>
+      <div class="copy-paste-block"><font color="#ff0000"><i><span
+              class="bqQuoteLink">"A</span></i></font><font
+          color="#ff0000"><i><span class="bqQuoteLink"> fact is a simple
+              statement that everyone believes.&nbsp; It is innocent,
+              unless found guilty.&nbsp; A hypothesis is a novel
+              suggestion that no one wants to believe.&nbsp; It is
+              guilty, until found effective</span></i><span></span>"</font><br>
+      </div>
+      <font color="#ff0000"><i> </i><font color="#000000">Edward Teller</font></font><br>
+    </center>
+    <img src="netbar.gif" height="40" align="middle" width="100%">
+    <blockquote> </blockquote>
+    <ul>
+      <li> Having discussed Gauss' Law for Magnetism, we now have four
+        equations describing electromagnetism,</li>
+    </ul>
+    <div align="center">Gauss' Law: &nbsp; <img alt="elecgausseqn3"
+        src="elec_gauss_eqn3.jpg" height="84" align="middle" width="233"><br>
+      <br>
+    </div>
+    <div align="center">Ampere's Law:&nbsp; <img alt="magampereeqn1"
+        src="mag_ampere_eqn1.jpg" height="60" align="middle" width="180"><br>
+      <br>
+    </div>
+    <div align="center"> Faraday's Law:&nbsp; <img alt="magfaradayeqn6"
+        src="mag_faraday_eqn6.jpg" height="58" align="middle"
+        width="297"><br>
+      <br>
+      Nobody's Law:&nbsp; <img alt="magmonopolefig5"
+        src="mag_monopole_fig5.jpg" height="48" align="middle"
+        width="171"><br>
+      <br>
+      <div align="left">
+        <ul>
+          <li>Looking carefully at these equations, the two flux
+            equations are now consistent with our physical understanding
+            of electric and magnetic charges.&nbsp; <br>
+          </li>
+        </ul>
+        <ul>
+          <li>The line integrals are a different matter.&nbsp; The right
+            hand side of Ampere's Law has a summation over electric
+            currents.&nbsp; Naively we would expect a similar sum over
+            "magnetic currents" on the right hand side of Faraday's
+            Law.&nbsp; But since there are no magnetic charges,
+            "magnetic currents" do not exist and the necessity for such
+            an additional term disappears.</li>
+        </ul>
+        <ul>
+          <li>However, in words, Faraday's Law states that</li>
+        </ul>
+        <div align="center">
+          <blockquote>
+            <p><b>"A changing magnetic field ( </b><b><img
+                  alt="magdisplacementeqn1"
+                  src="mag_displacement_eqn1.jpg" height="31"
+                  align="middle" width="45"></b><b> ) gives rise to an
+                electric field ( </b><b><img alt="magdisplacementeqn2"
+                  src="mag_displacement_eqn2.jpg" height="29"
+                  align="middle" width="54"></b><b> </b>)"<br>
+            </p>
+            <p align="left">For a more complete correspondence between <b>E</b>
+              and <b>B</b> we would expect a term added to the right
+              hand side of Ampere's Law which indicates,<br>
+            </p>
+            <p align="center">&nbsp;<b>"A changing electric field ( </b><img
+                alt="magdisplacementeqn3"
+                src="mag_displacement_eqn3.jpg" height="31"
+                align="middle" width="45">)<b>&nbsp; gives rise to a
+                magnetic field ( </b><img alt="magdisplacementeqn4"
+                src="mag_displacement_eqn4.jpg" height="29"
+                align="middle" width="54"><b> )</b>"<br>
+            </p>
+          </blockquote>
+          <div align="left">
+            <ul>
+              <li>Maxwell proposed this addition, the existence of which
+                is now physically verified.&nbsp; Furthermore, Maxwell
+                showed that this additional term, known as the
+                displacement current, is essential for the description
+                of electromagnetic waves.</li>
+            </ul>
+            <ul>
+              <li>The form of the displacement current term can be
+                obtained by the argument described below.</li>
+            </ul>
+            <ul>
+              <li>We have seen that current and current density are
+                related by the following equation</li>
+            </ul>
+            <div align="center"><img alt="eleccurrenteqn3"
+                src="elec_current_eqn3.jpg" height="38" width="103"><br>
+              <blockquote>
+                <div align="left">Suppose we consider a closed surface,
+                  then charge conservation tells us that this flux
+                  integral must be zero.&nbsp; Charge cannot be created
+                  or destroyed inside the closed surface, therefore,<br>
+                  <div align="center"><img alt="magdisplacementeqn5"
+                      src="mag_displacement_eqn5.jpg" height="46"
+                      width="117"><br>
+                    <div align="left"><img alt="exclamation"
+                        src="exclamation-icon.gif" height="30"
+                        width="31"> This equation can be considered as a
+                      formal statement of conservation of charge.<br>
+                    </div>
+                  </div>
+                </div>
+              </blockquote>
+              <div align="left">
+                <ul>
+                  <li><img alt="magdisplacementfig1"
+                      src="mag_displacement_fig1.jpg" height="305"
+                      align="right" width="284">Consider a parallel
+                    plate capacitor (at right).&nbsp; The closed surface
+                    over which we will apply the above integral is S<sub>1</sub>
+                    and S<sub>2</sub>.&nbsp; Current I passes in though
+                    S<sub>1</sub>, but since S<sub>2</sub> is between
+                    the capacitor plates, no current passes out of the
+                    closed surface.&nbsp; As it stands, we have violated
+                    conservation of charge... What to do&nbsp; ?&nbsp;
+                    Propose that there is an equal current passing out
+                    of the closed surface through S<sub>2</sub> - the
+                    "displacement current".</li>
+                </ul>
+                <ul>
+                  <li>Now</li>
+                </ul>
+                <div align="center"><img alt="magdisplacementeqn6"
+                    src="mag_displacement_eqn6.jpg" height="65"
+                    width="441"><br>
+                  <br>
+                  <blockquote>
+                    <div align="left">Therefore, if we define<br>
+                      <div align="center"><img alt="magdisplacementeqn7"
+                          src="mag_displacement_eqn7.jpg" height="67"
+                          width="126"><br>
+                        <div align="left">as the displacement current,
+                          by writing<br>
+                          <div align="center"><img
+                              alt="magdisplacementeqn8"
+                              src="mag_displacement_eqn8.jpg"
+                              height="39" width="135"><br>
+                            <div align="left">we can ensure charge is
+                              conserved.<br>
+                            </div>
+                          </div>
+                        </div>
+                      </div>
+                    </div>
+                  </blockquote>
+                  <div align="left">
+                    <div align="center">
+                      <div align="left">
+                        <div align="center">
+                          <div align="left">
+                            <ul>
+                              <li>Therefore, including the displacement
+                                current, Ampere's Law becomes,</li>
+                            </ul>
+                            <div align="center"><img alt=""
+                                src="mag_displacement_eqn9.jpg"
+                                height="64" width="252"></div>
+                          </div>
+                        </div>
+                      </div>
+                    </div>
+                  </div>
+                </div>
+              </div>
+            </div>
+          </div>
+        </div>
+      </div>
+    </div>
+    <ol>
+    </ol>
+    <div align="center">
+      <div align="left">
+        <div align="center">
+          <div align="left">
+            <div align="center">
+              <div align="left">
+                <div align="center">
+                  <div align="left">
+                    <div align="center">
+                      <div align="left"> </div>
+                    </div>
+                  </div>
+                </div>
+              </div>
+            </div>
+          </div>
+        </div>
+      </div>
+    </div>
+    <blockquote>
+      <div align="left"> </div>
+    </blockquote>
+    <div align="center">
+      <div align="left">
+        <div align="center">
+          <div align="left">
+            <div align="center">
+              <div align="left">
+                <div align="center">
+                  <div align="left">
+                    <div align="center">
+                      <div align="center">
+                        <div>
+                          <div align="left">
+                            <div align="center">
+                              <div align="left"> </div>
+                            </div>
+                          </div>
+                        </div>
+                      </div>
+                    </div>
+                  </div>
+                </div>
+              </div>
+            </div>
+          </div>
+          <blockquote>
+            <div align="left"> </div>
+          </blockquote>
+        </div>
+      </div>
+      <blockquote> </blockquote>
+    </div>
+    <div align="center"><img src="netbar.gif" height="40" width="100%"></div>
+    <div align="center">
+      <div align="center"> </div>
+      <center>
+        <p style="color: rgb(255, 0, 0); font-style: italic;"
+          class="MsoNormal">
+          <meta http-equiv="content-type" content="text/html;
+            charset=windows-1252">
+        </p>
+        <font color="#ff0000"><i>This girl said she recognized me from
+            the vegetarian club, but I'd never met herbivore. </i></font><br>
+        <br>
+        &nbsp;<img src="celticbar.gif" height="22" width="576"> <br>
+        &nbsp;
+        <p><i>Dr. C. L. Davis</i> <br>
+          <i>Physics Department</i> <br>
+          <i>University of Louisville</i> <br>
+          <i>email</i>: <a href="mailto:c.l.davis@louisville.edu">c.l.davis@louisville.edu</a>
+          <br>
+          &nbsp; </p>
+        <p><img src="header-index.gif" height="51" width="92"> </p>
+      </center>
+      <p><br>
+      </p>
+      <blockquote> </blockquote>
+    </div>
+  </body>
+</html>