davisnotes/mag_force_charge.html

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    <title>Magnetism - Force on Charges - Physics 299</title>
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      <h1> <img src="ULPhys1.gif" align="texttop" height="50"
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      <h1>Magnetic Forces on Charged Particles <br>
      </h1>
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      <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>
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      <font color="#ff0000"><i> </i><font color="#000000">Edward Teller</font></font><br>
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    <ul>
      <li> Proceeding under the assumption that magnetic fields exist -
        created by an as yet not described mechanism - the magnetic
        force on a <b>positively</b> charged particle is found
        experimentally to be given by
        <div align="center"><img alt="magforcechargeeqn1"
            src="mag_force_charge_eqn1.jpg" align="middle" height="33"
            width="135"></div>
      </li>
    </ul>
    <blockquote>
      <p>where q is the charge (positive) of the particle, <b>v </b>its












        velocity, <b>F<sub>B</sub> </b>the force it experiences and <b>B</b>
        the magnetic field causing the force.<br>
      </p>
    </blockquote>
    <ul>
      <li>
        <div align="center">
          <div align="left"> <img alt="exclamation"
              src="exclamation-icon.gif" height="30" width="31"> Note
            that this equation is the magnetic equivalent of the
            electric expression&nbsp; <b>F<sub>E</sub> = </b>q<b>E</b></div>
        </div>
      </li>
    </ul>
    <ul>
      <div align="left">
        <li>The expression for the magnetic force is written in terms of
          a vector (cross) product, which means, like it or not, you
          have to work in three dimensions.&nbsp; Several important
          facts emerge from this equation. <br>
          <ol>
            <br>
            <li>If <b>v</b> = 0 there is no force.&nbsp; Electric
              charges at rest in a magnetic field do not feel a magnetic
              force. </li>
            <br>
            <li>The magnitude of <b>F<sub>B</sub> </b>is given by
              <div align="center"><img alt="magforcechargeeqn2"
                  src="mag_force_charge_eqn2.jpg" height="37"
                  width="162"></div>
              <br>
              where &#966; is the angle between <b>v</b> and <b>B</b>.
              <ul>
              </ul>
              <ul>
                <li> So that, when <b>v</b> is parallel to <b>B</b> (&#966;
                  = 0) or antiparallel to <b>B (</b>&#966; = 180<sup>o</sup>)
                  then sin&#966; = 0 and <b>F<sub>B</sub> </b>= 0.&nbsp;
                  Therefore, charged particles moving along magnetic
                  field lines experience no magnetic force. </li>
              </ul>
              <ul>
                <li> When <b>v</b> and <b>B</b> are at 90<sup>o</sup>
                  <b>F<sub>B</sub> </b>has its maximum value, F<sub>B</sub>
                  = qvB. </li>
              </ul>
            </li>
            <br>
            <li> <b>F<sub>B</sub> </b>is at right angles to <b>v</b>
              and <b>B</b>.&nbsp; The "sense" is given by the usual
              rules for the vector (cross) product, sometimes called
              (the) "<b>Right Hand Rule"</b>.
              <div align="center"><img alt="magforcechargefig1"
                  src="mag_force_charge_fig1.jpg" height="243"
                  width="479"><br>
              </div>
              <br>
              This leads to circular (or spiral) motion around the <b>B</b>
              field lines.<br>
              <br>
              <div align="center"><img alt="magforcechargefig2"
                  src="mag_force_charge_fig2.jpg" height="378"
                  width="337"> &nbsp; &nbsp; &nbsp; <img
                  alt="magforcechargefig3"
                  src="mag_force_charge_fig3.jpg" height="315"
                  width="401"><br>
                <br>
              </div>
              <div align="center">
                <div><img alt="hot" src="hot.gif" height="43" width="79">Don't




                  forget that the direction of the magnetic force
                  obtained above is for a <b>positive</b> charge.&nbsp;
                  For a negative charge the direction of <b>F<sub>B</sub>&nbsp;</b>
                  is reversed. <br>
                </div>
              </div>
            </li>
            <div align="left"> <br>
              <li>The work done by the magnetic force when a charged
                particle is displaced by <b>ds</b> is given by, </li>
            </div>
            <br>
            <div align="center"><br>
              <img alt="magforcechargeeqn3"
                src="mag_force_charge_eqn3.jpg" height="32" width="244">
            </div>
            <div align="left">where &#952; is the angle between <b>F<sub>B</sub></b><sub>&nbsp;













              </sub>and <b>ds</b>.<br>
            </div>
            <div align="left"> The displacement <b>ds</b> and the
              velocity of the particle, <b>v</b>, are in the same
              direction, so &#952; is also the angle between <b>F<sub>B</sub></b><sub>&nbsp;













              </sub>and <b>v</b>.&nbsp; But from the form of the
              magnetic force we know <b>F<sub>B</sub></b><sub>&nbsp; </sub>and












              <b>v </b>are perpendicular (&#952; = 90<sup>o</sup>) therefore
              dW is always zero.&nbsp; In other words the <i><b>magnetic












                  force does no work,</b></i> which means, unlike the
              electric force, it cannot give a charged particle energy
              (increase or decrease its kinteic energy). The effect of a
              magnetic force is to change the direction not the kinetic
              energy.</div>
          </ol>
        </li>
      </div>
      <br>
    </ul>
    <div align="center"><img alt="divider" src="divider_ornbarblu.gif"
        height="64" width="393"><br>
    </div>
    <ul>
      <li> If a charged particle feels both a magnetic and electric
        field the resultant force is given by </li>
    </ul>
    <br>
    <div align="center"><img alt="magforcechargeeqn4"
        src="mag_force_charge_eqn4.jpg" height="35" width="189"><br>
      <blockquote> </blockquote>
      <blockquote>
        <div align="left">this is known as the Lorentz Force Law.<br>
          <br>
          <div align="center"><img alt="divider"
              src="divider_ornbarblu.gif" height="64" width="393"><br>
            <br>
          </div>
        </div>
      </blockquote>
      <div align="left">
        <div align="left">
          <ul>
            <li><big><u><b>UNITS</b></u></big></li>
          </ul>
          <blockquote>
            <p>From the form of the magnetic force we see that the units
              of <b>B</b> are&nbsp; N/(C.m/s) = N/(A.m).&nbsp; This
              combination of basic units is defined as the Tesla.<br>
            </p>
            <div align="center"> <img alt="magforcechargeeqn5"
                src="mag_force_charge_eqn5.jpg" height="56" width="153">
            </div>
            <p>The Tesla is a very large unit of magnetic field.&nbsp;
              For this reason you may occasionally come across the
              smaller unit of magnteic field, the Gauss; where&nbsp; 1
              Tesla = 10<sup>4</sup> Gauss.<br>
            </p>
          </blockquote>
        </div>
      </div>
      <blockquote>
        <div align="left"> </div>
      </blockquote>
      <blockquote> </blockquote>
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      <font color="#ff0000"><i>Q: What did one quantum physicist say
          when he wanted to fight another quantum physicist?<br>
          A: Let me <font color="#ff0000">atom</font>. </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>
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