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X-WR-CALNAME:The Warwick Mathematics Society Website | March 11\, 2010 - April 10\, 2010
PRODID:-//strange bird labs//Drupal iCal API//EN
BEGIN:VEVENT
DTSTAMP;VALUE=DATE:20120523T070213Z
DTSTART;VALUE=DATE-TIME:20100315T193000Z
DTEND;VALUE=DATE-TIME:20100315T210000Z
UID:http://warwickmaths.org/events/2010/mar/15/dg-clifford-algebras-and-vector-fields-spheres
URL;VALUE=URI:http://warwickmaths.org/events/2010/mar/15/dg-clifford-algebras-and-vector-fields-spheres
SUMMARY:DG \:= <Clifford algebras and vector fields on spheres>
DESCRIPTION:<p>The determination of how many independent vector fields there are on the <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/f427940eb9576fb3d5bb375c0f65b8319507a314.png\\" alt=\\"$ n $\\" /> sphere <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/42a04cd57bf7f7e8825356de2b14b59991104e28.png\\" alt=\\"$ S^n $\\" /> was one of the great successes of algebraic topology.</p>
 
 <p>The story starts with the Hairy Ball Theorem\: if <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/f427940eb9576fb3d5bb375c0f65b8319507a314.png\\" alt=\\"$ n $\\" /> is even\, there are no nowhere zero (continuous) vector fields on <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/42a04cd57bf7f7e8825356de2b14b59991104e28.png\\" alt=\\"$ S^n $\\" />. We must then turn to odd dimensional spheres\, and wonder how many linearly independent vector fields can there be? On our way to answering this question\, we will encounter many familiar structures\: <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/e349745152f454d978681664294aacf60d87f5d9.png\\" alt=\\"$ \\mathbb{R} $\\" />\, <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/67c5f118f64470684cceafcaa8ae687b23eb0b3e.png\\" alt=\\"$ \\mathbb{C} $\\" />\, <img class=\\"teximage\\" src=\\"/sites/warwickmaths.org/files/tex/5cd1b19fafe29d326bdb4d68a68b2e12357c892c.png\\" alt=\\"$ \\mathbb{H} $\\" /> and even more general algebraic structures known as Clifford algebras\, which will allow us to give a lower bound on the number of linearly independent vecor fields on spheres.</p>
 
 <p>We will find many relations with K-Theory\, similarities and common periodicities\; these have been exploited by Frank Adams to prove that the lower bound provided by Clifford algebras is actually an equality\, although we will not delve into the details.</p>
 
 <p>Come tonight at <span class=\\"caps\\">MS.05 </span>to hear about all this\, and more! After which we find our way to the pub.</p>
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