The Top Quark and other Recent Discoveries

in Particle Physics

Course Announcement

PY482
Spring 1999

Since 1974 experiments in high energy physics have searched for the top quark, the heaviest constituent of matter predicted to exist by the Standard Model of particle physics. The Standard Model describes the most fundamental constituents of matter which we know today, and their interactions. In 1995, experiments at Fermi National Accelerator Lab, near Chicago, were finally able to detect the top quark in high energy collisions of protons and anti-protons. Its mass turned out to be as large as 174 GeV, approximately the same as that of the gold atom!

PY482 will discuss the discovery of the top quark in its theoretical and experimental context. During the course, students will have the opportunity to analyze data from the D0 experiment at the Fermilab Tevatron, including decays of W bosons, Z bosons, and top quarks.

An outline of the discussion topics is given below:

The Standard Model: The course will begin with an introduction to the fundamental particles and forces. We will discuss the role of the top quark within this model and why we expected it to exist.
Accelerators: To study the fundamental constituents of matter, very high energies are needed. We will discuss particle accelerators using the example of the Fermilab Tevatron, which is currently the highest energy accelerator in the world.
Detectors: To record the particles produced in high energy collisions, very large and complex detectors are needed. Using the D0 and CDF detectors at Fermilab as examples we will discuss the techniques used to detect these particles.
Discovery of the W and Z bosons: The discovery of these particles confirmed predictions of the Standard Model. We will learn what the signatures of these particles are and how to measure their mass.
Discovery of the top quark: We will discuss the history of the search for and the discovery of the top quark. In this part of the course, we will also learn about the importance of statistical data analysis techniques in the search and discovery of fundamental particles.
Measurement of the properties of the top quark: This part of the course will introduce the experimental techniques used to measure the mass and other properties of the top quark.