davisnotes/lo_dsdiffraction.html

<!DOCTYPE html PUBLIC "-//w3c//dtd html 4.0 transitional//en">
<html>
  <head>
    <meta http-equiv="Content-Type" content="text/html;
      charset=windows-1252">
    <meta name="GENERATOR" content="Mozilla/4.7 [en] (X11; U; OSF1 V4.0
      alpha) [Netscape]">
    <meta name="Author" content="C. L. Davis">
    <title>Light and Optics - Double Slit Diffraction/Interference -
      Physics 299</title>
  </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>Double Slit Diffraction/Interference<br>
      </h1>
    </center>
    <center><img src="celticbar.gif" height="22" width="576"> <br>
      <br>
      <font color="#ff0000"><i>"<span class="bqQuoteLink"></span></i></font><font
        color="#ff0000"><i> </i></font><font color="#ff0000"><i>
          <meta http-equiv="content-type" content="text/html;
            charset=windows-1252">
          All of physics is either impossible or trivial. It is
          impossible until you understand it, and then it becomes
          trivial.
          <meta http-equiv="content-type" content="text/html;
            charset=windows-1252">
          <span></span><span class="bqQuoteLink"></span><span></span>"</i></font><br>
      <font color="#ff0000"><i><span class="bqQuoteLink">
            <meta http-equiv="content-type" content="text/html;
              charset=windows-1252">
          </span></i></font> <font color="#ff0000"><i>
          <meta http-equiv="content-type" content="text/html;
            charset=windows-1252">
        </i></font>
      <meta http-equiv="content-type" content="text/html;
        charset=windows-1252">
      Ernest Rutherford<br>
    </center>
    <img src="netbar.gif" height="40" align="middle" width="100%">
    <blockquote>
      <div align="center">
        <div align="left">
          <div align="center">
            <div align="left">
              <div align="center">
                <div align="left"> </div>
              </div>
            </div>
          </div>
        </div>
      </div>
    </blockquote>
    <div align="center"> </div>
    <ul>
      <li> <big><b>Intensity pattern for single slit diffraction:</b></big></li>
    </ul>
    <div align="center"><img alt="eqn1" src="lo_ssdiffraction_eqn8.jpg"
        height="83" align="middle" width="134">&nbsp;&nbsp;&nbsp;
      &nbsp;&nbsp;&nbsp; where&nbsp;&nbsp;&nbsp; &nbsp;&nbsp;&nbsp; <img
        alt="eqn2" src="lo_ssdiffraction_eqn7.jpg" height="66"
        align="middle" width="129"><br>
    </div>
    <ul>
    </ul>
    <ul>
      <li><big><b>Intensity pattern for double slit interference:</b></big></li>
    </ul>
    <div align="center"><img alt="eqn1" src="lo_dsdiffraction_eqn1.jpg"
        height="37" align="middle" width="118">&nbsp;&nbsp;&nbsp;
      &nbsp;&nbsp;&nbsp; &nbsp;&nbsp;&nbsp; where&nbsp;&nbsp;&nbsp;
      &nbsp;&nbsp;&nbsp; <img alt="eqn4"
        src="lo_dsdiffraction_eqn4.jpg" height="59" align="middle"
        width="119"><br>
      <br>
      <blockquote>
        <div align="left">Note that &#966;' = &#966;/2, where &#966; is defined in the
          double slit interference analysis.<br>
          <br>
        </div>
      </blockquote>
      <div align="left">
        <ul>
          <li>Remember that in the double slit interference analysis we
            (implicitly) assumed that the two slits were "point" wave
            sources.&nbsp; Of course in reality this is impossible, no
            sources are true "point" sources.&nbsp; An accurate
            description of double slit interference must include the
            effect of the finite width of each slit - that is, the
            diffraction phenomena from each slit.&nbsp; A detailed
            mathematical analysis leads to an intensity pattern at point
            P given by,</li>
        </ul>
        <div align="center"><img alt="eqn5"
            src="lo_dsdiffraction_eqn5.jpg" height="63" width="175"><br>
          <blockquote>
            <div align="left">Qualitatively, the interference pattern is
              modulated by the diffraction pattern, as indicated below.<br>
              <div align="center"><img alt="fig1"
                  src="lo_dsdiffraction_fig1.gif" height="339"
                  width="393"><br>
              </div>
            </div>
          </blockquote>
          <blockquote>
            <div align="left"><img alt="exclamatiom"
                src="exclamation-icon.gif" height="30" width="31"> Note
              that the slit width "a" must be smaller than the slit
              separation "d" (center to center).<br>
            </div>
          </blockquote>
          <blockquote>
            <div align="left"><img alt="exclamation"
                src="exclamation-icon.gif" height="30" width="31"> The
              number of interference maximum underneath the central
              maximum of the diffraction envelope depends on the
              relative values of a and d.<br>
              <br>
              <img alt="exclamation" src="exclamation-icon.gif"
                height="30" width="31"> Diffraction minima occur at &#952; =
              &#955;/a , 2&#955;/a , 3&#955;/a...&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; [ asin&#952;
              = n&#955; ]<br>
              &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
              Interference minima occur at&nbsp; &#952; = &#955;/2d , 3&#955;/2d ,
              5&#955;/2d...&nbsp;&nbsp;&nbsp;&nbsp; [ dsin&#952; = (n+1/2)&#955; ]<br>
            </div>
          </blockquote>
          <div align="left">
            <ul>
              <li>In the examples below the first intensity pattern
                has&nbsp; d = 3a, whereas the second pattern has d =
                (15/2)a<br>
              </li>
            </ul>
          </div>
          <blockquote>
            <div align="left"><br>
              <div align="center"><img alt="fig2"
                  src="lo_dsdiffraction_fig2.jpg" height="231"
                  width="489">&nbsp; <img alt="fig3"
                  src="lo_dsdiffraction_fig3.jpg" height="204"
                  width="340"><br>
              </div>
            </div>
          </blockquote>
          <blockquote> </blockquote>
        </div>
      </div>
      <blockquote> </blockquote>
    </div>
    <ul>
    </ul>
    <ul>
    </ul>
    <div align="center">
      <div align="left">
        <div align="center"> </div>
      </div>
      <img src="netbar.gif" height="40" width="100%"><br>
    </div>
    <br>
    <center><i><font color="#ff0000">&nbsp;
          <meta http-equiv="content-type" content="text/html;
            charset=windows-1252">
        </font></i><i><font color="#ff0000">
          <meta http-equiv="content-type" content="text/html;
            charset=windows-1252">
        </font></i><i><font color="#ff0000">A year after almost failing
          her high school physics class, a girl told her older brother,
          <br>
          "You know, my physics teacher <i><b>was</b></i> right about
          the optical Doppler effect. You see those cars. The lights of
          the ones approaching us are white, but the lights of the ones
          moving away from us are red." </font></i><br>
      <br>
      <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>
  </body>
</html>