PHY313-CEI544 Home Page

PHY313/CEI544 Home Page

Fall 2006

THE BNL TOUR WILL BE 10-12-2006

The bus will leave campus at 5:20pm and return at approximately 8:30pm. If you strongly prefer to drive yourself to BNL, you should be prepared to leave your car at the entrance and board the bus when it arrives. Be sure to be there by 6pm! Following the tour, the bus will drop you off back at your cars.

To be allowed to enter the Brookhaven Lab site, you must have a picture ID and show it to the guard at the gate when he comes through the bus.
The areas we will visit are not posted for radiation hazards. BNL will allow the tour to be taken by pregnant individuals if they wish to do so.
Reminder: The tour is not required for the course and tour attendance is not included in the grade.

This is the home page for the PHY313 and CEI544 courses entitled "Mystery of Matter" and "From Quarks to the Cosmos" respectively for the Fall 2006 semester.

The course is intended to introduce and explain at a qualitative level the progress physics has made during the past century in understanding the way in which the universe works. We will surpass the "common sense" understanding each of us has learned through our five senses by exploring how the concepts of modern physics were discovered, what they mean, and how they impact our lives today. We will explore:

The Big Picture

The universe is believed to have been born of intense heat sufficient to generate all the mass and energy we see today, as well as a bunch of mass and energy that we can't yet see. The Big Bang is the origin of all the particles, such as quarks, gluons and leptons. As the universe cooled and expanded, matter condensed out, forming neutrons and protons, nuclei, and finally the atoms and molecules that surround us. One route to understanding this origin is to recreate a small chunk of the early universe using powerful accelerators to reheat a tiny region of space (about the size of a nucleus) to conditions we believe existed at a few millionths of a second after the Big Bang. This is done at the Relativistic Heavy Ion Collider (RHIC) at nearby Brookhaven National Laboratory. We will visit this facility and some of the large particle detectors used there.

Development of the Concepts

Quantum Mechanics: The struggle to grasp how all things carry the seemingly opposite properties of both waves and particles. Why bound systems of particles such as electrons trapped by an atom of protons and neutrons residing in a nucleus are like notes on a musical instrument. How particles can leap forbidden regions to appear unscathed on the other side.
Special Relativity: The fact that the experience of time itself is not common to all things, but varies with the velocity of a particle. How light speed becomes the ultimate speed limit.
Nuclear Decays: What radioactivity consists of, how it works, and ways in which we can put it to good use.
The Standard Model: Our current best description of the zoo of subatomic particles and how they fit together to make the world as we know it. We'll also use this model to predict how quarks and gluons existed in a "quark gluon plasma" back when the Universe was a lot hotter and smaller.
Neutrinos: The measurement of neutrinos coming from the sun and how the mystery of the "missing solar neutrinos" was solved. How we finally figured out that these particles, long thought to be massless, do have some mass after all.
Antimatter: What it is and how it was predicted. How antiparticles were discovered experimentally and what's being studied now.

The Players

If we look at matter extremely closely, we see that it is made of "atoms"...bound systems of electrons orbiting a positively charged nucleus.
Looking more closely, the nucleus is seen to be made from protons and neutrons bound together by a force different from the familiar gravity and electromagnetism.
Looking yet more closely, the protons and neutrons are themselves composed of smaller pieces called quarks and gluons.
If we turn our microscope around and look at phenomena at large scales, we see stars and galaxies, all the way to the edge of the visible Universe. We will discuss how the facts learned by studying the smallest scales impact our understanding how large objects work.

The Tools

Accelerators (Atom smashers). Why they are useful. How they work. Why they are so big and getting bigger.
Detectors. How they work. What we learn. How some of the developments for better particle detectors turn into things we use in our daily lives. We will tour the PHENIX experiment
located at the Brookhaven National Laboratory's RHIC Accelerator.
Applications of the tools of modern physics to other areas of modern life, such as nuclear reactors, nuclear medicine, radiocarbon dating, high density computer farms, the world-wide-web, GPS, and more.

The Textbook(s)

We shall not use any particular book as the text for this course. Instead, we will follow along with the web links I have attached on the lecture pages. However, the popular books that are most pertinent to the course are listed here should you choose to purchase one or all:

The Fly In The Cathedral
From Quarks to the Cosmos
The God Particle
Thirty Years that Shook Physics
HyperPhysics web site. Congratulations. This resource is absolutely free and is the web site that most accurately follows the material of the course..
How Stuff Works website and Wikipedia website These two are also free and are excellent places to look up interesting things. Just search on the topic you are after, or follow the science-related links from their home pages.

The books are available via the links for a fraction of the list price as used books.

As we are not following any given text, you should follow the lecture links as your principle resource. Roughly 1/2 of the material for the homeworks can be determined directly from the web link, however, the other 1/2 will require your attendance in lecture.

Grading and Homeworks

The grade in the course is determined entirely by the homework assignments. All homework assignments will be posted via this web site and shown in class. Assignments will be due the following week and will be turned in at the beginning of class. PLEASE NOTE THAT HOMEWORKS WILL NOT BE ACCEPTED ELECTRONICALLY. IF YOU ARE UNABLE TO MAKE IT TO CLASS, YOU WILL NEED TO GET IT TO MY OFFICE BEFORE 5:30PM ON THURSDAY. Please refresh your browser after you have seen the lecture, to ensure that you answer the correct version of the homework!!! Homework assignments will appear right here.

Homework #1 will be due on Thursday September 14.
Homework #2 will be due on Thursday September 21.
Homework #3 will be due on Thursday September 28. Please note that the link to the nuclear radius calculator has been fixed; refresh your browser to see it.
Homework #4 will be due on Thursday October 5.
Homework #5 will be due on Thursday October 19.
Homework #6 will be due on Thursday October 26.
Homework #7 will be due on Thursday November 2.
Homework #8 will be due on Thursday November 9.
Homework #9 will be due on Thursday November 16.
Homework #10 will be due on Thursday November 30.
Homework #11 will be due on Thursday December 7.
Homework #12 will be due on Thursday December 14.

Solutions to all assigned problems will also appear on this web site after the problems due date has passed. Just refresh your browser and you will see the answers! Late homework will not be accepted after the solutions have been published.

Location of Lecture

Lectures take place on Thursdays from 5:20 to 8:20 pm. The lectures will be held in Harriman 137 (the main lecture hall) since this facility has proper projection equipment for displaying the web links during lecture.

Office Hours

Office hours will be held in C-102 (my office) on Wednesdays from 1-2pm, Thursdays from 4-5pm, or by appointment. The best way to make an appointment is to send me an email: Barbara.Jacak@stonybrook.edu.

Lecture Links

Material for the lectures can all be found on the web. The following web links represent material for the lectures. Links will appear during the semester, as the lectures take place.

Although the links are helpful, they are not a textbook. Weaving these into a single consistent story will be done in the lecture. Roughly 1/2 the material for the homework assignments will come from the lecture additions to the web contents. Earning a high grade in the course will almost certainly require attendance of the lecture.

September 7 lecture. The topic is the troubles in 19th century physics and the quantum solution. We'll discuss particles and waves.
September 14 lecture. Topics are waves, quantum numbers, wave functions, and the uncertainty principle. We will start to talk about radioactivity.
September 21 lecture. Topics include Rutherford scattering, nuclei and decays.
September 28 lecture. Topics are nuclear structure, radioactivity and neutrinos.
October 5 lecture. The topic is the tools of modern physics and the 2006 Nobel Prize.
October 19 lecture. The topic is nuclear fission, nuclear bombs, and reactors.
October 26 lecture. The topic is fusion, power and how stars work.
November 2 lecture. The life and death of stars, neutron stars, black holes and the Big Bang.
November 9 lecture. Quarks and the Standard Model of Particle Physics.
November 16 lecture. Special Relativity and Cosmic Rays.
November 30 lecture. Nuclear Medicine.
December 7 lecture. String Theory.
December 14. Last homework handed in. Quiz for extra credit.

Some Cool Links Related to Course

Read about the Double-Slit Garage Experiment.
Here is a clickable Periodic Table.
Here is a clickable Chart of the Nuclides.
Here is a Mendeleev Table.
Here is a website that shows the shape of many electron orbitals.
The "HyperPhysics" web site is a the best reference at the right level for the course. You can simply surf on by and find a detailed resource for working the homework problems.

For further information contact Professor Jacak: Barbara.Jacak@stonybrook.edu

see Prof. Jacak in the middle of the PHENIX detector.